https://embryology.med.unsw.edu.au/embryology/api.php?action=feedcontributions&user=Z5017878&feedformat=atomEmbryology - User contributions [en-gb]2024-03-28T08:53:25ZUser contributionsMediaWiki 1.39.6https://embryology.med.unsw.edu.au/embryology/index.php?title=User:Z5017878&diff=209837User:Z50178782015-10-30T01:04:35Z<p>Z5017878: </p>
<hr />
<div>--[[User:Z8600021|Mark Hill]] ([[User talk:Z8600021|talk]]) 10:47, 6 August 2015 (AEST) Thanks for setting up your page. We will be talking more about this in the [[ANAT2341_Lab_1_-_Online_Assessment|Practical on Friday]].<br />
<br />
==Lab Attendance==<br />
--[[User:Z5017878|Z5017878]] ([[User talk:Z5017878|talk]]) 13:46, 7 August 2015 (AEST)<br />
<br />
--[[User:Z5017878|Z5017878]] ([[User talk:Z5017878|talk]]) 14:57, 14 August 2015 (AEST)<br />
<br />
--[[User:Z5017878|Z5017878]] ([[User talk:Z5017878|talk]]) 12:51, 21 August 2015 (AEST)<br />
<br />
--[[User:Z5017878|Z5017878]] ([[User talk:Z5017878|talk]]) 12:11, 28 August 2015 (AEST)<br />
<br />
--[[User:Z5017878|Z5017878]] ([[User talk:Z5017878|talk]]) 12:37, 4 September 2015 (AEST)<br />
<br />
--[[User:Z5017878|Z5017878]] ([[User talk:Z5017878|talk]]) 13:24, 11 September 2015 (AEST)<br />
<br />
--[[User:Z5017878|Z5017878]] ([[User talk:Z5017878|talk]]) 14:05, 18 September 2015 (AEST)<br />
<br />
--[[User:Z5017878|Z5017878]] ([[User talk:Z5017878|talk]]) 12:43, 25 September 2015 (AEST)<br />
<br />
--[[User:Z5017878|Z5017878]] ([[User talk:Z5017878|talk]]) 13:55, 9 October 2015 (AEDT)<br />
<br />
--[[User:Z5017878|Z5017878]] ([[User talk:Z5017878|talk]]) 12:03, 16 October 2015 (AEDT)<br />
<br />
--[[User:Z5017878|Z5017878]] ([[User talk:Z5017878|talk]]) 13:21, 23 October 2015 (AEDT) <br />
<br />
--[[User:Z5017878|Z5017878]] ([[User talk:Z5017878|talk]]) 12:04, 30 October 2015 (AEDT)<br />
<br />
==Online Assessments==<br />
<br />
===Lab 1 Assessment===<br />
<br />
'''Relationship of polar bodies morphology to embryo quality'''<br />
<br />
This study was conducted in hopes to find a method to forecast the quality of embryo derived from reproductive technology. 355 patients that were undergoing In-Vitro Fertilisation or Intracytoplasmic Sperm Injection (ICSI) were a part of this study. From these patients 3048 zygotes were extracted and placed into two groups; intact or fragmented. <br />
<br />
The oocyte was extracted 37 to 28 hours after recombinant human chorionic gonadotropin administration followed immediately by the collection of semen sample. The semen sample was then treated and prepared for fertilisation of the oocyte. The zygotes were recruited after 16 to 18 hours and their polar bodies examined and placed into their respective groups based on morphology. The development of the zygotes were then closely studied and graded against systems such as the Istanbul consensus and Gardner's grading system. <br />
<br />
At the conclusion of the study it was deduced that the zygotes with intact polar bodies performed remarkably better than those with fragmented polar bodies. During the third day the intact polar body group had better embryo rates, blastocyst rates and available embryo rates. The pregnancy rate and implantation rate of the two groups however were found to have no differences. <br />
<br />
<ref><pubmed>26198980</pubmed></ref><br />
<br />
'''Microdroplet In Vitro Fertilization Can Reduce the Number of Spermatozoa Necessary for Fertilizing Oocytes'''<br />
<br />
During In vitro fertilisation (IVF) usually a large sample of spermatozoa is needed. In the female body only a few spermatozoa reach the oocyte. This study introduces the idea of micro droplet IVF in hopes of mimicking the in vivo conditions and lowering the amount of spermatozoa needed. Mice were used as the subjects for all the experiments performed and the procedures were conducted using HTF fertilisation medium. <br />
<br />
This study involved several counterparts where each experiment tackled different factors that may affect the microdroplet IVF procedure. The microdroplets conprised of only one microlitre containing either 5, 10, 20 or 50 spermatozoa in comparison to the usual 80 - 500 microlitres. Each of the experiments were replicated four times using spermatozoa from different males and either cyropreserved or fresh samples. The first experiment tested the effects that the cumulus cells, GSH and sperm number, the second on varying numbers of oocytes and spermatozoa, third on the effect of using cyropreserved sperm, the fourth on the effects of using volumes of suspension larger than the optimal for the preparation of the cyropreserved sperm and the fifth was to ensure normal development of embryo. <br />
<br />
The study was deemed successful where as little as 5 spermatozoa could fertilise an oocyte. The rate of success was also found to be heightened depending on factors, for example the presence of cumulus cells was found to be beneficial to the spermatozoa fertilisation rate. Microdroplet IVF could be the alternative pathway for those who have depleted numbers of spermatozoa due to factors such as age, genetic conditions or damages to sperm over time.<br />
<br />
<ref><pubmed>24583808</pubmed></ref><br />
<br />
--[[User:Z8600021|Mark Hill]] ([[User talk:Z8600021|talk]]) 17:02, 3 September 2015 (AEST) These are reasonable summaries of these 2 papers. If you intend to use acronyms, they should be spelt out in full the first time they appear with the acronym then in brackets. (5/5)<br />
<br />
===Lab 2 Assessment ===<br />
<br />
{{Uploading Images in 5 Easy Steps table}}<br />
<br />
[[File:Zona Pellucida and ZPC-ubiquitin.jpg]]<br />
<br />
Zona Pellucida and ZPC-ubiquitin<ref><pubmed>21383844</pubmed>| [http://www.ncbi.nlm.nih.gov/pmc/articles/PMC3044170/]</ref><br />
<br />
PMID 21383844<br />
<br />
--[[User:Z8600021|Mark Hill]] ([[User talk:Z8600021|talk]]) 17:07, 3 September 2015 (AEST) The image has now been uploaded correctly and contains reference, copyright and student template. (5/5)<br />
<br />
===Lab 3 Assessment===<br />
<br />
Here are the articles related to 'Prenatal Genetic Diagnosis':<br />
<br />
<pubmed>24810687</pubmed><br />
<br />
<pubmed>23773313</pubmed><br />
<br />
<pubmed>26201722</pubmed><br />
<br />
--[[User:Z8600021|Mark Hill]] ([[User talk:Z8600021|talk]]) 17:10, 3 September 2015 (AEST) These papers are relevant to Prenatal Genetic Diagnosis. Would have been nice to include a sentence abut each paper though. (5/5)<br />
<br />
===Lab 4 Assessment===<br />
<br />
<quiz display=simple><br />
<br />
{Which ONE of the following is true with regard to the male reproductive system?<br />
|type="()"}<br />
+ The midpiece of spermatozoa is responsible for motility <br />
- The male sex hormone, testosterone is produced by spermatozoa<br />
- Only one spermatozoa has to reach the oocyte for fertilisation to occur<br />
- Spermatozoa primarily use their chemotaxic response to oestrogen to locate the oocyte<br />
||The midpiece of spermatozoa contains a large amount of mitochondria which is responsible for producing ATP to drive motility. <br />
<br />
{Which statement is INCORRECT with regard to the female menstrual cycle:<br />
|type="()"}<br />
+ Gonadotropin releasing hormone is only responsible for signalling the release of luteinising hormone (LH)<br />
- The peak of oestrogen occurs during ovulation <br />
- The female body experiences a rise in temperature during the luteal phase and is an indication of menstruation<br />
- Rising levels of progesterone occur in the luteal phase<br />
||GRH is released by the hypothalamus and is responsible for the release of both LH and FSH in the anterior pituitary.<br />
<br />
{Select the CORRECT statement:<br />
|type="()"}<br />
- Fertilisation usually occurs two thirds down the fallopian tube<br />
- Upon entering the vagina, spermatozoa have up to four days to fertilise the oocyte<br />
+ Spermatozoa contributes to only 10% of seminal fluid upon ejaculation.<br />
- Capacitation is the inactivation of spermatozoa motility<br />
||While 10% of the seminal fluid comprises of spermatozoa, the remaining are contributed from accessory glands (60% seminal vesicle, 10% bulbourethral and 30% prostate). The secretions from these glands provide optimal conditions for the spermatozoa to thrive in. <br />
<br />
</quiz><br />
<br />
[[ANAT2341 Student 2015 Quiz Questions]]<br />
<br />
--[[User:Z8600021|Mark Hill]] ([[User talk:Z8600021|talk]]) 17:15, 3 September 2015 (AEST) You left off the closing quiz code, I have added it above. Q1 is not technically correct as the mid piece provides the energy for motility, not actual motility. You need to also explain in your revealed answer why the other options are incorrect. Q3 first option is not a clear statement 2/3 from which end? (8/10)<br />
<br />
===Lab 5 Assessment===<br />
<br />
'''What is the difference between gastroschisis and omphalocele?'''<br />
<br />
Gastroschisis and omphalocele (also known as exomphalos) are gastrointestinal abnormalities. They are the two most common defects of the anterior abdominal wall where gastroschisis occurs in 2.6 per 10,000 babies and omphalocele occurs in 2.1 per 10,000 babies <ref name="PMID19302857"><pubmed>19302857</pubmed></ref> <ref>Abeywardana, S. Sullivan, EA. (2008) '''Congenital anomalies in Australia 2002-2003''' Birth anomalies series no. 3. Cat. No. PER 41. Canberra: AIHW. Retrieved from: {http://npesu.unsw.edu.au/sites/default/files/npesu/surveillances/Congenital%20anomalies%20in%20Australia%202002-2003.pdf}</ref>. Gastroschisis is usually diagnosed around week 6 of gestation and the mothers are most likely to be under 20, undernourished and are smokers where as omphalocele is usually diagnosed 17 weeks into gestation and occurs predominately in women over the age of 30 <br />
<ref name="PMID23915861"><pubmed>23915861</pubmed></ref> <ref name="PMID22004141"><pubmed>22004141</pubmed></ref>.<br />
<br />
Gastroschisis is a congenital anomaly which affects the abdominal wall, most commonly in the area to the right of the umbilicus <ref name="PMID22004141"/>. It is due to the lack of membranous covering over the wall causing herniation of viscera through the abdominal wall <ref name="PMID17560199"><pubmed>17560199</pubmed></ref>. Gastroschisis is caused by the regression of the omphalomesenteric arteries which connect the yolk sac to the dorsal aorta <ref name="PMID19302857"/>. However factors that also link to its occurrence include failure in mesenchymal differentiation, first trimester vascular accident and use of tobacco and illicit drugs <ref name="PMID17560199"/>.<br />
<br />
Omphalocele on the other hand is the herniation of the abdominal viscera into the base of the umbilicus <ref name="PMID23915861"/>. It is mainly caused by failure to complete lateral body fold migration leading to an open body wall and failure of the intestines to return to the abdominal cavity <ref name="PMID19302857"/> <ref name="PMID23915861"/>. Another cause includes the persistence of the primitive stalk <ref name="PMID23915861"/><br />
<br />
===Lab 7 Assessment===<br />
<br />
'''Identify and write a brief description of the findings of a recent research paper on development of one of the endocrine organs covered in today's practical.'''<br />
<br />
Mechanisms involved in glucocorticoid induction of pituitary GH expression during embryonic development.<br />
<br />
Through the use of chicken embryos the study investigates the pathways in which glucocorticoids undergo to initiate growth hormone in the pituitary during embryo development. The research discovered the pathway namely the ERK1/2 pathway. The ERK1/2 pathway was stimulated by corticosterone treatment, however repetitive stimulation of the pathway was also found to suppress corticosterone thus suppressing the release of growth hormone. Corticosterone is the primary type of glucocorticoid in rodents and birds thus this knowledge was applied to glucocorticoids as a whole and provided the conclusion that the ERK1/2 is a strictly regulated cyclical pathway. <br />
<br />
Somatotrophs are responsible for producing growth hormone in the anterior pituitary. Increased circulation of corticosterone lead to maturation of somatotrophs thus an increase production of growth hormone. The study also used exogenous glucocorticoids and found that it had the same effects. <br />
<br />
PMID 25560830<br />
<br />
'''Identify the embryonic layers and tissues that contribute to the developing teeth.'''<br />
<br />
The embryonic origin of developing teeth are from the ectoderm and mesoderm layers of the trilaminar embryo coupled with neural crest contribution as well. Teeth are primarily derived from two types of cells, the odontoblast and ameloblasts. Odontoblasts are neural crest derived mesenchyme cells. They differentiate under the influence of enamel epithelium to form predentin which later calcifies to form dentin. On the other hand, ameloblasts produce enamel. Growth of teeth occurs in ossifying jaws and the periodontal ligament is responsible for holding the tooth in the bone sockets. <br />
<br />
===Lab 9 Assessment (Peer Reviews)===<br />
<br />
'''Group 1'''<br />
<br />
The entire project is presented simplistically and all the content is relevant and easy to understand. Majority of the flaws I found were based around poor grammar and syntax which could be fixed up with some editing. Below is a more detailed breakdown of some of the things you could fix.<br />
<br />
Firstly, I liked that the introduction was brief and concise and gives the reader a basic understanding of the topic of three person embryo. The video was also informative and provided some background information around the topic. I was informed that mitochondrial DNA was the major factor concerning this topic however there was a lack of information about its importance to the body so a short summary could be included along with some examples of diseases it could cause. <br />
<br />
Also, the use of a timeline to present the history is a great idea and I think it could be improved and would look more aesthetically pleasing if it were to be placed into a table. I also think the 1990s, 2000s and 2010s label could be removed to make it look less clustered since they aren’t particularly necessary. <br />
<br />
Some information under the heading ‘Technical Progression’ has yet to be filled in but from what is there I’d like to suggest exchanging the bullet points for numbering instead for the information under ‘Pronuclear transfer’ and ‘Polar body transfer’ since they sounded like sequence steps as opposed to separate points. <br />
<br />
Finally, I found the layout of the table under the heading ‘Legal status’ to be very well put together. There are however some countries placed under the incorrect continents and I found that the order was easily changed and mixed up. I also noticed that several of the countries were linked to the same sources which made the information very unspecific. Instead of just links I think a few sentences explaining the legislation would be more informative. <br />
<br />
'''Group 2''' <br />
<br />
This wikipage is very well put together. Your choice of headings, subheadings and tables and images is remarkable, it definitely makes the whole page flow very well. I particularly like the hand-drawn image which does a great job at simplifying the process of the pathogenesis of OHSS. <br />
<br />
The introduction very concisely explains the contents of the page and I liked how it was finished off with a statement about the aim of the page. I thought it really brought the introduction together nicely. I can’t say much about the content except that it is very engaging and very well written so well done guys! Keep up the good work!<br />
<br />
Some suggestions I have that could improve your page include adding more images. It would be nice to have some graphs to complement the statistical date from the epidemiology. Also, in some of the paragraphs e.g. in the last paragraph of ‘Epidemiology’ there isn’t a citation that accounts for the information at the end of the paragraph so that should be fixed. <br />
<br />
'''Group 3'''<br />
<br />
First and foremost the PCOS Ovary Vs Non-PCOS Ovary hand drawn image is amazing and its placement at the beginning really drew in my attention to the topic. I also particularly liked the purple theme set up throughout the wikipage, I thought it really helped bring the page together.The headings, subheadings and images are all set out neatly making it very presentable and easy to follow. The language used was also very engaging which is always a plus. Content wise there seems to be sufficient information under most of the headings which really showed your efforts and elaborate research on the topic. The only portion that wasn’t particularly well present was the environmental factors. I felt like it needs the inclusion of some examples. <br />
<br />
To improve your page I would like to suggest the addition of a glossary that you could use to briefly define some terms such as ‘Hirsutism’ to allow a better understanding of the text. Additionally, I also noticed that under the ‘Hyperandrogenemia’ heading there was the use of the acronyms ‘GnRH’ and ‘LH’. Be sure to express the full term placing the acronym in brackets upon their first appearance before extensive use. I saw that this was done in the following paragraph where LH was initially correctly expressed as Luteinising Hormone but again this should be done at its very first appearance. The page also lacked some history surrounding the origin of the disease and how some of the treatments were established so that could also be included. <br />
<br />
Overall, the presentation of the page gave me the impression of a good understanding of the topic so well done guys! Keep up the good work. <br />
<br />
'''Group 4''' <br />
<br />
The wikipage is very well organised and the headings, subheadings and tables made everything easy to follow. I particularly liked the blue theme you kept with all the tables, it is very aesthetically pleasing. In terms of content the background information provided a clear overview of the subject especially the information about the physiology of fertility in males which laid down the foundation some basic knowledge surrounding male fertility under normal circumstances which I found useful in grasping other concepts throughout the page. The page is filled with an extensive amount of content and along with the long list of references I was given the impression of good understanding of the topic and commendable effort placed into the research.<br />
<br />
One thing I found that wasn’t quite compatible with your page was the inclusion of the video in the ‘Causes of infertility section’. Although I do agree that it is a very good video, it had little information surrounding male infertility and was more about infertility in general. Perhaps a video exclusively about male infertility would be more suitable for your page. <br />
<br />
As for some additional improvements, it would be beneficial to include a glossary to explain some difficult terms that would help the audience gain a better understanding of the content. Also, the addition of a hand-drawn image would also be nice. A suggestion would be to exchange your existing ‘components and structure of spermatozoa’ image with a more simplified and schematic diagram of the structure of sperm. <br />
<br />
Overall, I enjoyed reading about male infertility and the page is coming together very nicely.<br />
<br />
'''Group 5''' <br />
<br />
The wikipage looks like it’s progressing very well, especially with the amount of content and references I can safely say you guys have worked hard on it and have done a substantial amount of research so well done guys. I liked the flow chart that you guys inserted, it really simplified the understanding of the IVF procedure as opposed to reading lengthy text. I also particularly liked the collapsible timeline which was presented very nicely and summarised the progress of oncofertility over time very well. <br />
<br />
As for improvements, the references definitely need to be fixed up. There were multiple appearances of the same reference and some of the links also did not work such as reference 24 and 25. On top of that the referencing for the websites were not in a consistent format and some were also done incorrectly so be sure to fix that up. I would also look out for the type of sources used such as webmd and medianews today. I’m not entirely sure if they are reliable or acceptable but I suggest you consult Mark about that. <br />
<br />
Additionally, the use of tables is a very good way of presenting information however, for the tables under the topic of fertility preservation for both men and women I initially though that each of the columns was a comparison against each other. Only later did I realise that each of the columns contained an individual list of treatments. To minimise the confusion I suggest rearranging the table and labelling row 1 as ‘Before treatment’, then row 2 as ‘During treatment’ and finally row 3 as ‘After treatment’ then collectively placing the treatments in their rightful spaces in the following column. <br />
<br />
A glossary is also missing from this page, having the definitions of the more difficult terms would assist with understanding the topic. Also on another note in the ‘Types of Chemotherapy drugs’ section, I think it would look more aesthetically pleasing if bullet points were used rather than the dashes. <br />
<br />
Overall, there is a substantial amount of content, and great use of images, videos and tables. Keep up the good work! <br />
<br />
===Lab 10 Assessment===<br />
<br />
'''Embryonic Tongue'''<br />
<br />
Permalink: [https://embryology.med.unsw.edu.au/embryology/Slides/Embryo_Stages/Stage22/11/Stage22-11.html?zoom=5&lat=-2174.37828&lon=4626.63483&layers=B Tongue]<br />
<br />
The tongue is a muscle and is important for sensing taste. All the pharyngeal arches present in the human embryo contribute to the development of the tongue however, the tongue muscle cells are derived from somites and the muscles of mastication are derived from somitomeres. Each pharyngeal contributes a different portion where arch 1 forms the oral part of the tongue, arch 2 forms the initial transient surface, arch 3 forms the pharyngeal part of the tongue and arch 4 forms the epiglottis and adjacent regions. The superior surface of the tongue comprises of taste buds, various papillae and stratified squamous epithelium. The tongue is innervated by the hypoglossal nerve (CNXII) allowing movement. <br />
<br />
[https://embryology.med.unsw.edu.au/embryology/index.php/Tongue_Development Tongue Development]<br />
===References===<br />
<br />
<references/><br />
<br />
==Test Student 2015==<br />
<br />
===References===<br />
<br />
PMID 26244658<br />
<br />
look at this<ref><pubmed>26244658</pubmed></ref><br />
<br />
Here's the list<br />
<references/><br />
<br />
{{StudentPage2015}}</div>Z5017878https://embryology.med.unsw.edu.au/embryology/index.php?title=2015_Group_Project_6&diff=2086392015 Group Project 62015-10-23T12:55:02Z<p>Z5017878: </p>
<hr />
<div>{{ANAT2341Project2015header}}<br />
<br />
<br />
=Preimplantation Genetic Diagnosis and Preimplantation Genetic Screening=<br />
==Introduction==<br />
Preimplantation genetic diagnosis (PGD) and preimplantation genetic screening (PGS) are reproductive options for couples with known family histories of genetic disease or couples undergoing IVF procedures due to infertility issues. PGD can diagnose many genetic disorders caused by known chromosomal abnormalities (number and/or structure) or single gene mutations, and, thus decrease the risk of termination of pregnancy or miscarriages and enable such couples to have an unaffected child<ref name="PMID24907939"><pubmed>24907939</pubmed></ref>. Through major improvements in PGD/S and general laboratory technology, the testing for abnormalities in fetuses has shifted from prenatal diagnosis during the first 2 trimesters <ref> Blackburn, S.L. (2003) '''Maternal, Fetal & Neonatal physiology: a Clinical perspective''' (2nd ed.). Seattle: Saudners </ref>, testing for overall fetal growth, complications of pregnancy, and birth defects<ref> Sadler T.W.(2012) '''Langman's Medical Embryology''' (12th ed.) Philadelphia: Lipincott, Wiliams & Wilkins, a Wolters Kluwer Business </ref>, to an embryonic focus especially in advancements in Artificial Reproductive Technologies (ART)<ref><pubmed>20638568</pubmed></ref>. In 1990 PGD for a recessive X-linked disease resulted in the first live birth<ref><pubmed>2330030</pubmed></ref> and has since been incorporated in clinical routine and applied for a variety of genetic diseases, such as sickle cell anemia, thalassemia, or cystic fibrosis<ref name="PMID24907939"/>.<br />
[[File:Preimplantation Genetic Diagnosis Procedure.jpeg|600px|left|thumb| Simplified steps for PGD<ref name="PMID24907939"/>]]<br />
{|class="wikitable"align="right" <br />
| <html5media height="400" width="533">https://www.youtube.com/watch?v=0e-79qKllqk</html5media><br />
|-<br />
| Preimplantation Genetic Diagnosis<ref>IVF Florida (2011, December 11) IVF Florida - South Florida Fertility Specialists - Pre-Implantation Genetic Diagnosis [Video file]. Retrieved from https://www.youtube.com/watch?v=0e-79qKllqk</ref><br />
|}<br />
==History==<br />
The advances in reproductive technology during the second half of the 20th century, led to PGD's first clinical application in 1990 <ref>Harper, J. (n.d.). The history of PGD. Lecture. UCL Centre for PG&D and CRGH.University College London</ref>.<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
|Year<br />
|<br />
|- bgcolor="FFFAFA"<br />
| '''1967''' <br />
|First PGD on rabbit blastocysts (Gardner& Edwards) <ref name="PMID6036172"><pubmed>6036172</pubmed></ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1986''' <br />
|First Cleavage Biopsy (Wilton & Trounson)<ref>Wilton, L. J., & Trounson, A. O. (1986). Viability of mouse embryos and blastomeres following biopsy of a single cell. In Proceedings of the 18th Annual Conference of the Australian Society for Reproductive Biology, Brisbane, Australia.</ref><br />
|- bgcolor="FFFAFA"<br />
|'''1987''' <br />
|First Blastocyst Biopsy (Muggleton-Harris, Monk, Rawlings, & Whittingham)<ref name="PMID3372699"><pubmed>3372699</pubmed></ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1988''' <br />
|First Polar Body Biopsy (Yury Verlinksy)<ref> Verlinsky, Y., Pergament, E., Andresen, P., Enriquez, G., & Strom, C. (1989). Genetic analysis of polar body DNA: A new approach to preimplantation genetic diagnosis. Am J Hum Genet, 45(4), A272.</ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1990''' <br />
|First Clinical PGD using PCR testing for X-linked (Handyside, Kontogianni, Hardy, & Winston)<ref name="PMID2330030"><pubmed>2330030</pubmed></ref> <br />
|} <br />
==Preimplantation Genetic Diagnosis==<br />
[[File:Pre-PGD workup.jpeg|thumb|400px|Pre-PGD workup for a family with a previous child with spinal muscular atrophy. Panel (a) shows how the study of both parents and grandparents allows the phasing of the SMN mutation relative to polymorphic short tandem repeat (STR) markers; panel (b) shows the maternal and paternal haplotypes M1, M2, P1 and P2 and the distance of the STR markers from the SMN gene; panel (c) shows the four predicted fetal haplotypes. These reflect a Hardy–Weinberg equilibrium of one homozygous non-carrier, two heterozygous carriers and one that is homozygous and affected. Short tandem repeat markers linked with the SMN mutation are shown in red. DEL indicates the presense of the exon 7 (840 C>T) mutation<ref name="PMID26237262"/>.]]<br />
PGD is used to test the genetic makeup of embryos to detect single gene disorders, chromosomal abnormalities and mitochondrial disorders. It also has applications in gender selection for diseases with unequal gender distributions <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Some diseases commonly involved with PGD include cystic fibrosis, spinal muscular atrophy and beta – thalassaemia <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press.">Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press</ref> <ref name="PMID17823145"><pubmed>17823145</pubmed></ref>. It was first used in the United Kingdom in the 1980s, primarily focusing on sex- linked disorders <ref name="PMID17823145"/><ref name="PMID23150080"><pubmed>23150080</pubmed></ref>. PGD is now capable of detecting single cell defects (molecular) and chromosomal disorders resulting from the inversion, translocation or deletion of chromosomes (cytogenic) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/> <ref name="PMID11325751"><pubmed>11325751</pubmed></ref>. PGD can be applied to the embryo at different stages. That is on polar bodies, blastomeres or blastocyst <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>.<br />
Depending on the type of genetic disorder, PGD utilises different methods of genetic testing. These include Fluorescence in situ hybridisation (FISH) which is used for sex – linked disorders and detects chromosomal rearrangements <ref name="PMID11325751"/><ref name="PMID17876073"><pubmed>17876073</pubmed></ref> and Embryo halotyping which allows the identification of chromosomes causing the inherited disorder through knowledge of the pattern of closely linked markers <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. Polymerase chain reaction (PCR) is also widely used to detect molecular abnormalities <ref name="PMID11325751"/>.<br />
PGD is tightly regulated and supported by large organisations namely The American Society for Reproductive Medicine, The European Society for Human Reproduction and Embryology (ESHRE), The European Society of Human Genetics and the Preimplantation Genetic Diagnosis International Society <ref name="PMID25500181><pubmed>25500181</pubmed></ref>.<br />
===Sex-linked disorders===<br />
The determination of a disease as gender specific usually correlates with the presence or absence of specific genes such as SRY on the Y chromosome. It is known that females have two X chromosomes and males have an X and a Y chromosome where abnormalities are more prevalent on the X chromosome. PGD can be used for sex selection where only male embryos are transferred to reduce the chance of inheriting X-linked disorders. However, this does not completely eradicate the problem as male embryos remain susceptible to inheriting an affected X chromosome. Sex determination is only used when the specific mutation is unknown and has yet to be discovered <ref name="PMID24866878"><pubmed>24866878</pubmed></ref>.<br />
===Single gene defects===<br />
Single gene defects can be dominant, recessive, autosomal or X-linked. They are commonly diagnosed using PCR and although the PCR available today is complex and capable of combatting a large range of disease the development of new protocols has been proven to be difficult due to the small DNA sample available <ref name="PMID26168107"><pubmed>26168107</pubmed></ref>.<br />
===Mitochondrial disorders===<br />
Mitochondrial disorders also known as oxidative phosphorylation disorders arise from mutations in the nuclear DNA or mitochondrial DNA <ref name="PMID26312584"><pubmed>26312584</pubmed></ref>. They pose as a problem because they are unrecognisable until the mutations in the cell reach a detrimental level <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Mitochondrial disorders cause miscarriages and stillbirths as well as death in children and young adults. The effects can either be contained in a single organ or more commonly involve multiple organ failure where organs with high energy demands such as the brain, liver muscle and heart and heavily influenced. They are usually occur spontaneously or result from inheritance from the mother. Since mitochondria are solely inherited from the mother oocyte donations have been used as a solution to combat mitochondrial disorders. Additionally, there has been an increasing use in PGD where embryos that stay under the given threshold of 18% gene-mutations are allowed to be transferred and result in normal development. New technology in the areas of nuclear gene transfer and genome editing are also being experimented with <ref name="PMID26312584"/>. <br />
===Chromosomal disorders===<br />
Chromosomal disorders can be reciprocal, Robertsonian translocations, inversions, deletions and insertions <ref name="PMID26168107"/>. Data from ESHRE collected between 2010 and 2011 has shown that the most common chromosomal abnormality confronted in PGD are reciprocal chromosomal abnormalities <ref name"PMID26071418"><pubmed>26071418</pubmed></ref>. PGD has also been used successfully for Robertsonian translocations (RT), a type of structural translocation. Children who carry RT are phenotypically normal, however in their later years it is found that they will suffer from infertility and repeated miscarriages due to the high frequency of abnormal embryos <ref name="PMID22081077"><pubmed>22081077</pubmed></ref>. PCR and FISH are the two main techniques used for chromosomal disorders. To be able to conduct the examinations the cells are required to be at the metaphase stage <ref name="PMID26168107"/>. <br />
[[File:Reasons_for_PGD.jpg|600px|thumb|Reasons for PGD<ref name="PMID24764761"><pubmed><24764761</pubmed></ref>]]<br />
==Preimplantation Genetic Screening==<br />
PGS involves an array of methods or ideas that aim to segregate embryos that have genetic flaws and those that are healthy <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. The occurrence of aneuploidy is high around the stages of early embryonic development and they are the most common cause if miscarriages and congenital birth defects <ref name= "PMID26085841"><pubmed>26085841</pubmed></ref>. They have little effect on the morphology of the embryo making them difficult to identify thus identification heavily relies on genetic testing <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. <br />
Genetic sampling is most commonly conducted using Microarray Comparative Genomic Hybridisation (aCGH) as well as FISH, Quantitative PCR and Single Nucleotide Polymorphism (SNP) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. These methods collectively aim to assess numeral and structural chromosomal errors <ref name= "PMID26085841"/>. Studies have also introduced Next- Generation Sequencing (NGS) <ref name= "PMID26085841"/> and Whole Genome Amplification used to screen imbalances in the complete 24-chromosomes <ref name="PMID25953353"><pubmed>25953353</pubmed></ref>.<br />
Statistics from ESHRE have shown that the most common indications for PGS is advanced age, followed by repeated implantation failure or recurrent miscarriage and male infertility <ref name="PMID26071418"><pubmed>26071418</pubmed></ref>.<br />
===Indications===<br />
A low percentage of structural abnormalities in chromosomes are responsible for the cause of miscarriages. Despite this, they are the most prevalent type of chromosomal abnormality accounted for in PGD <ref name="PMID20638568"/>. The presence of specific gene cycles, initiation of embryonic protein synthesis and evident physiological development are all indicative of a successful in vitro fertilisation procedure <ref name="PMID11576737"><pubmed>11576737</pubmed></ref>. To eliminate further errors from occurring during the PGD procedure it is recommended to undertake further prenatal testing such as amniocentesis in the later stages <ref name="PMID20638568"/>. <br />
====Advanced maternal age====<br />
Data provided by the ESHRE has shown that the mean age of women undergoing PGS is 39 years <ref name="PMID26071418"/>. Women of advanced age have been shown to have a lower rate of pregnancies reaching childbirth <ref name="PMID18583331"><pubmed>18583331</pubmed></ref>. The highlighted concern revolves around the increased occurrence of aneuploidy following maternal age. The optimal age range for the lowest aneuploidy incidence was found to be between 27 to 37 years of age (6%) then progressively higher in women aged up to 42 (33%) and most common in those 44 and above (53%) <ref name="PMID24355045"><pubmed>24355045</pubmed></ref>. <br />
====Recurrent pregnancy loss / IVF failure====<br />
Recurrent pregnancy loss is defined as three or more IVF failures after cumulative transfer of more than 10 good-quality embryos. These are primarily caused by two main factors, reduced endometrium receptivity or embryonic defects. Endometrium receptivity can be negatively influences by instances including uterine pathologies such as thin endometrium, altered expression of adhesive molecules and immunological factors. Additionally, embryonic defects may be due to genetic abnormalities, embryonic aneuploidy or zona hardening. Endometriosis and hydrosalpinx has been known to effect both the endometrium and embryo <ref name="PMID23260857"><pubmed>23260857</pubmed></ref>.<br />
====Human leukocyte antigen matching====<br />
First used in 2001, HLA matching is an option given to parents to save a child with haematological or immunological disease through conceiving another child who would potentially be able to donate cord blood or haematopoietic stem cells from the bone marrow for transplantation. The process namely PGD-HLA has shown to improve haematopoietic stem cell transplant (HSCT). PGD-HLA can only be performed when HSCT is not needed urgently due to the time needed to conceive and delivery the baby <ref name="PMID25500181"><pubmed>25500181</pubmed></ref>. It is most commonly applied to children suffering from relapsed leukaemia <ref name="PMID22524201"><pubmed>22524201</pubmed></ref>. In a case study PGD-HLA was proven to successfully cure 10 diseases including Fanconi anaemia, Diamond-Blackfan anaemia and beta thalassemia <ref name="PMID25066893><pubmed>25066893</pubmed></ref>.<br />
==Biopsy Methods==<br />
Biopsy, the removal of genetic materials, from oocytes or embryos in the preimplantation stage is the primary step in PGD. For the past two decades these biopsies have been performed at three stages, the polar body, blastomere, and blastocyst, and the methodologies optimized to ensure the embryo’s viability. The most common approach involves biopsies at the cleavage stage. However, polar body and blastocyst biopsies are increasingly more often tested and applied. Approached for opening the zona pellucida involve next to the traditional mechanical and chemical means, novel approaches such as noncontact lasers. Their application may simplify and secure the procedure significantly. The most challenging question about PGD procedures remains at what stage biopsies should be taken. Much controversy has developed around this topic, highlighting the varying disadvantages and advantages of temporal biopsies <ref name="PMID22723007"><pubmed>22723007</pubmed></ref>.<br />
[[File:Polar_Body,_Blastomere,_and_Trophectoderm_Biopsy.jpeg|500px|thumb|Polar body (A), blastomere (B) and trophectoderm (C) biopsies<ref name="PMID25625041"><pubmed>25625041</pubmed></ref>.]]<br />
{| class="wikitable"<br />
|- align="center" bgcolor="DDCEF2"<br />
|<br />
| Time of Biopsy<br />
| Prevalence <br />
| Advantages <br />
| Disadvantages<br />
|- bgcolor="FFFAFA"<br />
| Polar Body<br />
| Day 1<br />
| ~16%<br />
| Little to no harm is caused to the oocyte and both PBs can be extracted (more genetic material)<ref name="PMID22723007"/>.<br />
| Only the maternal DNA is tested<ref name="PMID22723007"/>, often PB biopsies need to be coupled to other biopsies, and difficulties arise in distinguishing between the first and second PB<ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. Lower reliability of results compared to other biopsy methods have been reported<ref name="PMID25106935"/>. <br />
|- bgcolor="FFFAFA"<br />
| Blastomere <br />
| Day 3<br />
| ~80%<br />
| Biopsies are safe for good quality embryos and it is performed relatively early, so fresh transfer is possible, yet, it includes both paternal and maternal genetic contributions<ref name="PMID26237262"/>. <br />
| Relatively large decrease in implantation rates for low quality embryos have been reported, embryo mosaicism can influence genetic analysis, and only one to two cells can be safely removed<ref name="PMID26237262"/>. <br />
|- bgcolor="FFFAFA"<br />
| Trophectoderm<br />
| Day 5 and 6 <br />
| ~ 2%<br />
| Little harm to the embryo and large amount of genetic material can be extracted, which allows for more accurate genetic analysis and lessen effects of mosaicism<ref name="PMID26237262"/>. <br />
| The biopsy takes place relatively late and, thus, the time window for procedure is small and embryos often need to be cryopreserved<ref name="PMID22723007"/>. <br />
|}<br />
===Polar Body Analysis===<br />
Day 1<br />
====Description====<br />
[[File:Polar_Body_Biopsy.jpeg|thumb|400px|The presence of a faint but clearly identifiable strand connecting PB2 to the oolemma. The biopsy was performed ∼9 h after ICSI<ref name="PMID21908464"><pubmed>21908464</pubmed></ref>.]] <br />
Polar body (PB) biopsy offers a promising alternative to biopsies performed at the blastomere stage for PGD/S indications on legal and practical grounds<ref name="PMID22723007"/>. The ESHRE calculated the proportion of PB biopsies to be about 16.3%<ref name= "Traeger-Synodinos, J., Coonen, E., Goossens, V., De Mouzon, J., Shenfield, F., Ruiz, A., ... & de Mouzon, J. (2013). Session 09: ESHRE data reporting on PGD cycles and oocyte donation.">Human Reproduction, 28(suppl 1), i18-i19. </ref>. Embryo development does not necessitate the presence of the first and second PB and their removal may not be crucial<ref name="PMID22723007"/>. The idea behind PB biopsies is that each abnormality found in the PB corresponds to an error in the oocyte. On the other hand, in women with known single gene mutations, it is assumed that if the PB contains the mutated allele ,the oocyte will have the normal allele, thus, resulting in a healthy embryo<ref name="PMID26237262"/>. PB biopsy requires precise timing. Keeping track of the meiotic cell cycle is necessary to perform a successful biopsy and, therefore, PB biopsy usually is applied in combination with intracytoplasmic sperm injection (ICSI). During the maturation from the germinal vesicle stage to the metaphase-II stage the first PB is formed. A cytoplasmic bridge containing spindle remnants, that are still in contact with the cellular genetic material, links this PB to the oolemma for about 90 minutes after extrusion. It is possible to visualize these remnants by polarization microscopy and it is crucial to not perform the biopsy until the first PB is no longer firmly attached to the oolemma as this indicates an immature embryo.The oocyte tolerates mechanical zona dissection best during hours four until six after ICSI as the oolemma has stabilized by that time because of the cortical granule reaction. Over time the first PB degenerates stressing a temporal biopsy and its optimal extraction time window is four to 12 hours after ICSI. The second PB forms around two to four hours after ICSI. Its optimal time window for biopsy is set to be eight to 16 hours after ICSI due to the second PB being attached to the oolemma with spindle remnants until six hours after ICSI. Biopsy at this point may cause enucleation of the oocyte. Studies have shown that the amplification efficiency of second PB’s DNA is worse if the PB is extracted prior to eight hours after ICSI. Thus, it is possible to perform sequential and simultaneous biopsies for the first and second PB. If performed, sequentially the first PB may be removed four to 12 hours and the second PB eight to 16 hours after ICSI. The optimal time window for a biopsy for both the first and second PB simultaneously is eight to 12 hours after ICSI. It is highly preferred to analyze both PBs due to potential aneuploidies in either PB and crossing overs during meiosis <ref name="PMID22723007"/>. <br />
====Procedure====<br />
Chemical opening achieved with for example acidic tyrode’s solution of the zona pellucida is not tolerated by the oocyte and may have detrimental effects on the embryo’s development. Therefore, the access to the perivitelline space of the oocyte is provided by mechanical zona dissection or by laser. Both techniques work well if performed by experienced embryologist. However, laser-assisted biopsy is less time consuming when compared to manual dissection. It is critical to consider the size of the introduced opening as it will remain permanent. If it is too large the blastomere may be lost during embryo development and if it is too small it may interfere with hatching of the embryo during blastocyst stage<ref name="PMID22723007"/>.<br />
[[File:Implantation_predictive_value_of_euploid_screening_results.jpeg|thumb|450px|The sustained implantation predictive value (with 95 % confidence interval) of a euploid screening result obtained from the first polar body (PB1), PB1 and the second polar body (PB2), or a direct embryo biopsy for each stage of embryo transfer (cleavage-stage and blastocyst stage)<ref name="PMID25106935"><pubmed>25106935</pubmed></ref>.]]<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JTaQzszVr8o</html5media><br />
|-<br />
| Laser-assisted polar body biopsy<ref>RIUK, R. (2013, June 25) Polar Body Biopsy [Video file]. Retrieved from https://www.youtube.com/watch?v=JTaQzszVr8o</ref><br />
|}<br />
====Advantages & Disadvantages====<br />
PB biopsies can only investigate the maternal contributions to the embryo as they are of maternal origin. Thus, this procedure is appropriate for PGD solely for monogenetic diseases from the maternal side. Recessive diseases may be evaluated with PB biopsies on the basis that the embryo’s outcome will be determined by the paternal contribution. It may still be applied for PGS as it is a fairly safe biopsy option and most aneuploidies either arise during meiosis or origin from the maternal genome. However, diagnosis error has been reported due to the lack of considering paternal contributions<ref name="PMID22723007"/>. About 10% of PB biopsies appear to be wrongfully diagnosed with aneuploidies<ref name="PMID26237262"><pubmed>26237262</pubmed></ref>. Because PB biopsies are performed very early it is not yet known whether the oocyte will develop into a viable embryo. Thus, PBs are commonly frozen or fixed after biopsy and depending on the state of the embryo only chosen PBs will be tested. This is primarily an economic issue as many genetic testing procedures are very cost-intensive<ref name="PMID22723007"/>. Generally the sustained implantation predictive value of screening of PBs is significantly lower than of, for example, biopsies of the blastocyst stage<ref name="PMID25106935"/>. Moreover, it is often difficult to distinguish between the first and the second PB. As the first one degenerates quicker, this may influence diagnostic procedures<ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
===Blastomere biopsy===<br />
Day 3 <br />
====Description====<br />
Blastomere biopsy has been the prevalent method for PGD and PGS in the last two decades. In 2013 the ESHRE reported 79.8% of biopsies to be performed at the cleavage stage<ref name= "Traeger-Synodinos, J., Coonen, E., Goossens, V., De Mouzon, J., Shenfield, F., Ruiz, A., ... & de Mouzon, J. (2013). Session 09: ESHRE data reporting on PGD cycles and oocyte donation."/>. At least one, but up to two, blastomeres are biopsied on day three of the cleavage stage embryo. The right number of blastomeres removed is a controversial topic as two cells allow for more genetic material and more accurate results. However, removing two cells might be too invasive and damaging to the embryo. As PGS tries to improve implantation rates, whereas PGD sets out to avoid known genetic disorders, for the former only one cell is removed, while for the latter often two need to be removed, to ensure results as correct as possible<ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
====Procedure====<br />
Initially a hole was drilled into the zona pellucida using acid Tyrode's solution or by mechanical means. Nowadays the zona pellucida is largely opened using a laser and calcium and magnesium free media have been introduced to decrease junctions between blastomeres, which facilitates the biopsy. This if followed by the consequent aspiration of blastomeres with a pipette.<ref name="PMID21748341"/>. The blastomeres can also be removed by applying pressure on the outside of the zona<ref name="PMID26237262"/>. <br />
[[File:Aspiration_of_a_Blastomere.jpeg|thumb|400px|Aspiration of a Blastomere into the biopsy pipette<ref name=" PMID24783200"><pubmed>24783200</pubmed></ref>.]]<br />
{|class="wikitable"align="left" <br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=TbridWVwipI</html5media><br />
|-<br />
| Laser-assisted blastomere biopsy<ref>Sukprasert, M. (2014, March 5) Day 3 Blastomere Biopsy 1 [Video file]. Retrieved from https://www.youtube.com/watch?v=TbridWVwipI</ref><br />
|}<br />
====Advantages & Disadvantages====<br />
Blastomere biopsy is limited by the presence of embryo mosaicism, which can severely influence the interpretation of the genetic analysis. Approximately 15%-80% of all embryos display mosaicism on day three. Thus, any results might be a misrepresentation of the embryo as a whole. However, if good quality embryos are selected, the procedure overall is safe and does not negatively influence the embryos transition to the blastocyst stage. In a typical IVF cycle, however, not all embryos are of good quality, particularly if they have undergone cryopreservation. Studies have found that in these embryos biopsies reduce implantation rates by 12.5%-25%. Furthermore, unlike PB biopsy, the cells at the blastomere stage contain both paternal and maternal contribution, giving the genetic analysis a fuller perspective on the embryo's genetic make up. Since blastomere biopsy is performed at the third day after fertilization, it is possible complete fresh embryo transfer. Thus, no storage procedures, such as cryopreservation, are necessary<ref name="PMID26237262"/>. <br />
===Trophectoderm biopsy===<br />
Day 5 and 6<br />
====Description====<br />
The improvement of embryo culture media allowed the in vitro development of human embryos until the blastocyst stage and opened up the possibility to take blastocyst biopsies. While currently according to ESHRE datasets only about 2.3% of biopsies are performed at the blastomere stage<ref name= "Traeger-Synodinos, J., Coonen, E., Goossens, V., De Mouzon, J., Shenfield, F., Ruiz, A., ... & de Mouzon, J. (2013). Session 09: ESHRE data reporting on PGD cycles and oocyte donation."/>. During day three to day five the haploid maternal and paternal genomes come together for the first time to form the genome of the embryo. The maternal epigenetic control lessens significantly while preparing for implantation with precisely arranged events happening. The first event includes a rapid increase in the number of embryonic cells which are active in mitotic divisions and apoptosis of aberrant cells. This is followed by the formation of blastocoel (cavitation) which results from the flattening of cell located on the outside of the blastomere. Now the blastocyst will expand until the embryo hatches by rupturing the zona pellucida. The cells of the blastocyst will differentiate to form two distinct cell lineages, the outer trophectoderm and the inner cell mass<ref name="PMID22723007"/>. <br />
====Procedure====<br />
Trophectoderm biopsy is usually performed in Hepes buffered biopsy medium and opening approaches include needle cutting which has been replaced by lasers in past years. Different research groups report different timings of the opening to be the most successful. Some open the blastocyst on day three or four by creating a 25 µm which causes the trophectoderm to herniate through this hole and is, thus, accessible for biopsy. Others create this hole about four hours before biopsy which allows sufficient herniation of trophectoderm cells. It is also possible to open the blastocyst immediately before biopsy. This avoids an extra step and the inner cell mass usually is easy to locate. Blastocyst biopsies involve the removal of trophectoderm cells and the ideal time for the procedure is day five. Successful biopsies on day six have been performed, while little is known about the results of biopsies on day seven. However, since the window of implantation in humans is from day eight to ten after ovulation, day seven biopsies appear to be possible<ref name="PMID22723007"/>.[[File:Microscopic images of human blastocysts for biopsy.jpeg|thumb|300px|(A) Some trophectoderm cells in a blastocyst started to hatch and (B) the trophectoderm cells were biopsied with assisted laser cutting. Images in C–D show the blastocysts after vitrification and warming. Blastocysts had been cultured for 2–4 hrs after warming, showing good (ICM and trophectoderm cells) hatched (C) and hatching (D) blastocysts. The hatching blastocyst in (E) has good ICM but fair trophectoderm while the blastocyst in (F) has both fair ICM and trophectoderm. Arrows indicate ICMs and arrow heads indicate trophectoderm cells. Bar = 40 µm<ref name="PMID2190846"><pubmed>2190846</pubmed></ref>.]]<br />
{|class="wikitable"align="left"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JI_TQ8d8tNM</html5media><br />
|-<br />
| Laser-assisted blastocyst biopsy (at 00:50 min)<ref>Coco, R. (2014, April 30) Trophectoderm biopsy in a Hatching blastocyst protruding ICM [Video file]. Retrieved from https://www.youtube.com/watch?v=JI_TQ8d8tNM</ref><br />
|}<br />
====Advantages & Disadvantages====<br />
Blastocyst biopsies are believed to be less damaging to the embryo and appear to be unrelated to implantation rates. In addition, this biopsy method allows for a larger extraction of cells for genetic testing. However, since they are performed late in in vitro development, the time window for genetic testing is relatively small. Fast and accurate genetic testing methods are needed to ensure a successful and safe result from this biopsy. Thus, blastocyst biopsies may gain more popularity in the future when such methods have been developed or improved<ref name="PMID22723007"/>. Furthermore, the extraction of multiple cells may lessen the effects of mosaicism and problems during PCR, such as ADO. Studies comparing the implantation rate and screening accuracy have found that blastocysts are significantly safer. Blastocyst biopsies decrease implantation rates significantly, while biopsies at day five or six do not seem to influence implantation and delivery rates<ref name="PMID26237262"/>.<br />
==Genetic Techniques==<br />
===Polymerase Chain Reaction===<br />
PCR amplifies DNA specific to genetic sequence of interest . PCR was developed by Kay Mullis in the 1980's, for which he was awarded the Nobel prize for chemistry in 1993 <Ref name= "Pubmed Docs (2015) Polymerase Chain Reaction (PCR) Pubmed."> Pubmed Docs (2015) Polymerase Chain Reaction (PCR) Pubmed. Retrieved from [http://www.ncbi.nlm.nih.gov/probe/docs/techpcr/]</ref>. This technique enables clinicians to monitor and diagnose diseases using minute samples such as embryonic cells <ref>Roche (2015) PCR: How We Copy DNA. Roche Molecular Systems Inc. retrieved From [http://molecular.roche.com/pcr/Pages/Process.aspx]</ref>. PCR is used to detect genetic disorders, as a part of PGD, in conjunction with IVF<ref name="PMID24301057"><pubmed>24301057</pubmed></ref>. It is used to detect molecular abnormalities, such as single gene disorders including Tay Sach, Cycstic fibrosis, Duchenne Muscular Dystrophy, Thalassemia, Huntington disease, Spinal muscular atrophy and many more. Molecular and genetic analysis require a significant amount of DNA, which can be delivered by PCR. It revolutionized the study of DNA, replacing all previous recombinant DNA technology and is a significant component of PGD procedures<ref name="PMID24907939"/>.<br />
[[File:PCR.jpg|450px|thumb|PCR amplifies DNA specific to genetic sequence of interest, enabling the monitoring and diagnose molecular abnormalities such as single gene disorders using minute samples such as embryonic cells, blood & tissue <ref name="NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute">NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref>]]<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="7" |'''Advantages'''<br />
|-bgcolor="FFFAFA"<br />
| Fast and inexpensive way of copying a target sequence of DNA. <ref Name="PMID24301057"><pubmed>24301057</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Particularly useful for the diagnosis of single cell defects.<ref name="NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute">NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref><br />
|-bgcolor="FFFAFA"<br />
| Rapid generation of results (within hours).<ref name="NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute">NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref>]<br />
|-bgcolor="FFFAFA"<br />
| Highly sensitive, a single molecule of DNA is sufficient for reaction.<br />
|-bgcolor="FFFAFA"<br />
| Generates DNA copies exponentially. <br />
|-bgcolor="FFFAFA"<br />
| This enables DNA amplification required for molecular and genetic diagnostic analysis<ref> Dreesen, J., Drusedaul, M., Smeets, H., Die-Smulders, C., Coonen, E., Dumoulin, J., Gielen, M., Evers, J., Herbergers, J. & Geradets, J. (2008) Validation of preimplantation genetic diagnosis by PCR analysis: genotype comparison of the blastomere and corresponding embryo, implications for clinical practice. Mol. Hum. Reprod. 14 (10):573-579.doi: 10.1093/molehr/gan052. Retrieved from [http://molehr.oxfordjournals.org/content/14/10/573.short] </ref> <ref><pubmed>20966460</pubmed></ref>.<br />
|-bgcolor="DDCEF2"<br />
| rowspan="7"|'''Disadvantages'''<br />
|-bgcolor="FFFAFA"<br />
| Only during the exponential DNA replication phase, the starting quantity sequence contained in the original sample (template DNA strand) can be determined.<br />
|-bgcolor="FFFAFA"<br />
| PCR reaction is limited to by presence of inhibitors in the sample.<Ref name= "Pubmed Docs (2015) Polymerase Chain Reaction (PCR) Pubmed."> Pubmed Docs (2015) Polymerase Chain Reaction (PCR) Pubmed. Retrieved from [http://www.ncbi.nlm.nih.gov/probe/docs/techpcr/]</ref><br />
|-bgcolor="FFFAFA"<br />
| Self annealing due to the accumulation of the product and the stopping exponential amplification for the target sequence and reaching of a plateau<br />
quantification of the end point of reaction of PCR products make real time quantitative RT-PCR necessary<ref name="NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute">NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref>.<br />
|-bgcolor="FFFAFA"<br />
| Not a diagnostic method on its own, but requires further analysis.<br />
|-bgcolor="FFFAFA"<br />
|Low-quantity DNA template may result in amplification failure<ref name="PMID24907939"/>.<br />
|-bgcolor="FFFAFA"<br />
|Allele drop-out (ADO) in heterozygous loci is possible<ref name="PMID24907939"/>.<br />
|}<br />
====Procedure====<br />
Samples are obtained from the the blastocyst, a polar body biopsy or the blastomeres stages of the embryo. <br />
*Stage 1 Denaturing: separating the target strands of DNA <br />
The obtained sample is heated to roughly 90 degrees celcius, this heat breaks the relatively weak bonds between nucleotides that form DNA. The double stranded DNA is split into two single strands of DNA that are used as templates.<br />
*Stage 2 Annealing: Binding the Primers to the target DNA sequence <ref name="PMID25250056"><pubmed>25250056</pubmed></ref><br />
PCR will only copy the target sequence of DNA specified by specific PCR primer. These synthesized primers oligonucleotides are small artificial pieces of DNA. TAQ polymerase enzyme synthesize two new strands of DNA duplicate to the single sample DNA stand template indicated by these primers. During this stage the reaction is cooled to a temperature between 40-60 degrees Celsius. <br />
*Stage 3- Extension- making copies <br />
Each of these two copies are then used again as templates generating two further replications This cycle can occur as many 30 -40 times within a couple hours leading to billions of extra copies of the original DNA segment. Generally the optimal temperature for the further replication is roughly 72 degrees Celsius, although, this may vary according to the analysis machines used. <ref name="PMID26092180"><pubmed>26092180</pubmed></ref><br />
This process mediated by a thermocycler machine that is programmed to alter the temperature of the reaction every couple of minutes, perpetuating the cycle of DNA denaturing and synthesis. <br />
This process, generates exponentially exact copies of the original template DNA sequence, as visible in the expandable table below. <ref> Mullins, K., Francois, F.& Gibbs R.A. (1994 ) The Polymerase Chain Reaction. p3. Springer- Science +Business Media. Birkhauser, Boston<br />
Available at [https://books.google.com.au/books?hl=en&lr=&id=gjrTBwAAQBAJ&oi=fnd&pg=PR5&dq=kary+mullis+PCR&ots=mpzAyRh5ZY&sig=PQ4goNoKJ90tb3-MkPk62zrTGbw#v=onepage&q=kary%20mullis%20PCR&f=false] </ref><br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
! colspan="2" | PCR cycles<br />
|-<br />
| '''PCR Cycle'''<br />
| '''Target Copies'''<br />
|-<br />
| 1<br />
| 2<br />
|-<br />
| 2<br />
| 4<br />
|-<br />
| 3<br />
| 8<br />
|-<br />
| 4<br />
| 16<br />
|-"<br />
| 5 <br />
| 32<br />
|-<br />
| 6 <br />
| 64<br />
|-<br />
| 7 <br />
| 128<br />
|-<br />
| 8<br />
| 256<br />
|- <br />
| 9<br />
| 512 <br />
|-<br />
| 10<br />
| 1024<br />
|-<br />
| 15<br />
| 32,768<br />
|-<br />
| 20 <br />
| 1,048,578<br />
|-<br />
| 25<br />
| 33,554,432<br />
|-<br />
| 30 <br />
| 1,073,741,842<br />
|-<br />
|}<br />
===Fluorescent In Situ Hybridisation===<br />
FISH is the one of the most effective and rapid <ref name="PMID26338801"><pubmed>26338801</pubmed></ref> method as part of PGD. This technique locates a specific DNA sequences within a chromosome. FISH facilitates the clinical diagnosis of chromosomal abnormalities indicated by sequential duplications, deletions and rearrangements of chromosome, that are usually missed with microscopic analysis. This technique is especially relevant for female embryos with X-linked diseases<ref name="PMID20809319"><pubmed>20809319</pubmed></ref>. As part of PGD, it enabled the screening for aneuploidies and increased live birth rates in women with advanced age<ref name="PMID24907939"/> <ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. FISH is 99% effective when used in conjunction with competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities<ref name="PMID26338801"/>. <br />
[[File:Fluorescent In Situ Hybridisation (FISH).jpg|thumb|450px|right|'''FISH''' Specific DNA sequences using probes which have been tagged with fluorescent labels are visualised.This technique enables the clinical diagnosis of chromosomal abnormalities, indicated by sequential duplication, deletions and rearrangements of chromosome <ref name="NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute">NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref>]]<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="5" |'''Advantages''' <br />
|-bgcolor="FFFAFA" <br />
| FISH is 99% effective when used in conjunction with CGH to diagnose chromosomal abnormalities<ref name="PMID26338801"><pubmed>26338801</pubmed></ref>.<br />
|-bgcolor="FFFAFA" <br />
| Results are rapidly generated. <ref name="NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute">NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref><br />
|-bgcolor="FFFAFA"<br />
| Very small translocations and aneuploidies that occur within chromosomes, that would usually be missed under microscopic analysis, can be identified<ref name="Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd)">Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref>.<br />
|-bgcolor="FFFAFA" <br />
| The most common chromosomal abnormalities, such as down syndrome chromosomes 13,16,18,21 and 22<ref><pubmed>21749752</pubmed></ref>, and inheritable X-linked disease or sex chromosome anomalies such as Duchenne's Muscular Dystrophy, hemophilia, ectodermal dysplasia<ref><pubmed>17876073</pubmed></ref> can be identified.<br />
|-bgcolor="DDCEF2"<br />
| rowspan="5"|'''Disadvantages'''<br />
|-bgcolor="FFFAFA" <br />
| FISH destroys all cells tested <ref> O'Connor, C. (2008) Fluorescence in situ hybridization (FISH). Nature Education 1(1):171. retrieved from [http://www.nature.com/scitable/topicpage/fluorescence-in-situ-hybridization-fish-327] </ref>.<br />
|-bgcolor="FFFAFA" <br />
| It does not fully access all chromosomes (only ~ 12)<ref name="PMID24907939"/>.<br />
|-bgcolor="FFFAFA" <br />
| The analysis of results is dependent upon the dot quality impacted by hybridisation efficiency or the camera sensitivity<ref name="PMID17970921"><pubmed>17970921</pubmed></ref>.<br />
|-bgcolor="FFFAFA" <br />
| Some studies indicate that using FISH on a day-3 embryo biopsy decreases the rate of live births<ref><pubmed>26168107</pubmed></ref>.<br />
|}<br />
====Procedure====<br />
Samples collected from the embryo<ref name="PMID21748341"><pubmed>21748341</pubmed></ref> are collected, processed, and its DNA strands are heated and denatured causing their the individual DNA strands to break apart. Then, probes of single complimentary stands of DNA a that have been tagged with small chemical agents that glow brightly in the presence of a specific region on a chromosome are added. These specific probes then hybridize and join to their complementary DNA strand. The fluorescent tags enable the correct identification of the presence or lack thereof and location of specific chromosomes that are tested for<ref name="PMID17876073"><pubmed>17876073</pubmed></ref>. The number and the relative location of the fluorescent dots generated by the FISH images is analysed and gives rise to diagnosis<ref name="PMID17970921"><pubmed>17970921</pubmed></ref>. The probe will not fully hybridise if there has been a duplication or a deletion of the DNA - indicating chromosomal and sex chromosomal anomalies like trisomies and aneuploidies. <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref>. Different probes are used for different purposes <ref>Unique, Rare Chromosome Disorder Support Group (2013) Fluorescence in situ hybridisation (FISH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/Other/FISH%20FTNW.pdf]</ref>:<br />
*'''Locus specific tags''' detect very small imbalances, and locate isolated small portions <br />
of genes within a chromosome<br />
*'''Alphoid/Centomeric Repeat probes''' are developed from the repetitive sequence located in the middle region of each chromosome, useful in determining the number of chromosomes , detecting rearrangement and when used in conjunction with locus probes to determine the absence of genetic material on a chromosome. <br />
*'''Paint Probes''' are collections of smaller probes with their own stains that bind to a different section on the chromosome - allowing the full chromosome too be labeled a unique colour, this "full colour map" can be used to know the spectral karyotype- full chromosomal mapping is useful in examining chromosomal abnormalities. <br />
===Array Comparative Genomic Hybridisation (aCGH)===<br />
[[File:aCGH.jpg|thumb|500px|right|'''aCGH''' checks the entire genome for chromosomal imbalances, by comparing control and a sample slides contatining small segements of DNA sample microarrayed slides small segments of DNA. Illustrated by student z5020317 and adapted from <ref> NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation. retrieved from [http://www.phgfoundation.org/file/5237/]</ref> <ref name="Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45"> Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432] </ref>]]<br />
aCGH also known as Microarray analysis efficiently scans the entire genome for chromosomal imbalances. CGH was initially developed to detect the number of changes in a solid tumor mass. It uses 2 genomes comparing the sample to the control, with each labeled in a different fluorescent dye<ref name="PMID1876176"><pubmed>1876176</pubmed></ref>. Earlier CGH techniques were limited by the resolution of the imaging <ref> Lichter, P., et al. Comparative genomic hybridization: Uses and limitations. Seminars in Hematology 37, 348–357 (2000)</ref>, these initial limitations were overcome by using Microarrays in conjunction with CGh to improve the resolution of the imaging, Array Comparative Genomic Hybridisation (aCGH). This method compares sample and control microarrayed slides containing small segments of DNA (probes). <ref> Lucito, R., et al. Representational oligonucleotide microarray analysis: A high-resolution method to detect genome copy number variation. Genome Research 13, 2291–2305 (2003) </ref> the Probes used will vary according from the small (25-85 base pairs) oligonucleotides manufactured to highlight different target sequences, to the very large genomic clones (80,000- 200,00 base pairs), and as these are significantly smaller than the traditional metaphase chromosomes used for CGH, generating a higher resolution of image. <ref name="PMID22467166"><pubmed>22467166</pubmed></ref>.aCGH is used as a diagnostic tool for prenatal detection f chromosomal abnormalities <ref name="PMID19012303"><pubmed>19012303</pubmed></ref>.<br />
{|class="wikitable" align="center"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="12" |'''Advantages''' <br />
|-bgcolor="FFFAFA"<br />
| Multiple applications: prenatal genetic diagnosis, cancer diagnosis, <ref name="PMID20193845"><pubmed>20193845</pubmed></ref> genetic screening for developmental delay (learning disabilities) <ref name="PMID17309648"><pubmed>17309648</pubmed></ref>. or congenital anomalies that are suspected to be genetic in origin <ref>NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation . retrieved from [http://www.phgfoundation.org/file/5237/]</ref><br />
|-bgcolor="FFFAFA"<br />
| trace represents all chromosomes present in the human genome chromosomes 1-22 and the X & Y chromosomes, and therefore is the most accurate method for testing whole embryo aneuploidy<br />
|-bgcolor="FFFAFA"<br />
| aCGH has been extensively tested, and Validated, and is now used world wide.<br />
|-bgcolor="FFFAFA"<br />
| Detects submicroscopic alterations<br />
|-bgcolor="FFFAFA"<br />
| Detects deletions and additions and rearrangements as well as amplification, of the WHOLE genome, simultaneously.<br />
|-bgcolor="FFFAFA"<br />
| Used as a diagnostic tool for prenatal detection of chromosomal abnormalities <ref name="PMID22034057"><pubmed>22034057</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Provides high resolution genomewide screening of segmental genomic copy number variations<br />
|-bgcolor="FFFAFA"<br />
| Very accurate when used in conjunction with FISH<br />
|-bgcolor="FFFAFA"<br />
| Alone is more reliable and in detecting chromosomal abnormalities, with a higher implantation success rate, than FISH <ref name="PMID20494259"><pubmed>20494259</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Allows an in depth research focus upon specific types of rearrangements within selected chromosomal regions, a recent particular area of interest is subtelomeric and pericentromeric rearrangements<br />
|-bgcolor="FFFAFA"<br />
| Reduces the risk of failed implantation and miscarriage, improving the chance of a healthy baby <ref name="Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd)">Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref>><br />
|-bgcolor="DDCEF2"<br />
| rowspan="9" |'''Disadvantages'''<br />
|-bgcolor="FFFAFA"<br />
| Translocations and inversions of DNA are not detected<br />
|-bgcolor="FFFAFA"<br />
| Limited ability diagnosing specific polyploidies such as triploidy <ref> Unique, Rare Chromosome Disorder Support Group (2013) Microarray-based Comparative Genomic Hybridiation (array CGH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/other/array%20cgh%20ftnw.pdf] </ref><br />
|-bgcolor="FFFAFA"<br />
| Will not detect mosaicism detection <20% (cultures where >1 of 5 cells are trisomy 12)<br />
|-bgcolor="FFFAFA"<br />
| Will not detect balanced chromosomal rearrangement<br />
|-bgcolor="FFFAFA"<br />
| Will not detect duplications or deletions <80kb<br />
|-bgcolor="FFFAFA"<br />
| Will not detect point mutations within genes <ref>Washington department of education (CGH- FAQ for physicians. Signature Genomic LAboratories, LLC. Retrieved from [https://depts.washington.edu/dbpeds/Lab%20Tests/SignatureCGH-physician_FAQ.pdf]</ref><br />
|-bgcolor="FFFAFA"<br />
| will not detect chromosomal position of genomic gains<br />
|-bgcolor="FFFAFA"<br />
| Will not detect loos of heterozygosity (LOH) or Absence of heterozygosity (AOH) <ref>WiCell Research Institute Inc. (2012) Comparative Genomic Hybridization Microarray. <br />
retrieved from [http://www.wicell.org/home/cytogenetic-services/cgh-microarray/array-comparative-genomic-hybridization-acgh.cmsx]</ref><br />
|}<br />
====Procedure==== <br />
As a part of PGD fetal cell samples are collected from; the fertilized egg polar bodies, the blastomere (day 3 embryo) or the blastocyst/tropoectoderm stage (day 5 embryo).<br />
Sample DNA is labeled with one fluorescent dye, and the control DNA is labeled with a different colored fluorescent dye. the control DNA is used as the base point of reference. <br />
heated and denatured single DNA strands then hybridize to their complementary single strand probes, which are then combined and applied to a microarray and the results are run through a computer program and a digital imaging system is used to quantify the results( fluorescent intensities of the labeled probes)<ref name="Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45"> Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432] </ref>. <br />
The fluorescent ratio and the hybridization signal at different locations on the genome of the control DNA are used to identify any variances present in the sample DNA. aCGH facilitates the clinical diagnosis of submicroscopic chromosomal duplication, deletion and rearrangements indicative of chromosomal disorders such as trisomies 1-22 and specific sex linked disorders. <br />
Duplication in the DNA are displayed by the computer program as spikes/ peaks over an established threshold and deletions in DNA are displayed by the computer program as spikes/ toughs beneath this threshold. <br />
===Next Generation Sequencing===<br />
The development and advances within ART in the past 20 years, as well as the increasing popularity of IVF, has lead to an influx of new technologies developed to screen embryos for chromosomal anomalies, which are covered by the umbrella term of Next generation Sequencing (NGS). NGS is a general term used to describe all of the new and emerging screening techniques currently being introduced and used as part of PGD for IVF. NGS screens for single gene disorders as well as conducting extensive and very comprehensive chromosome diagnosis by sequencing, counting, and accurately assembling millions of DNA reads, simultaneously<ref name="PMID23499002"><pubmed>23499002</pubmed></ref>. NGS is expected to replace the other limited and outdated testing techniques and be used as the standard test in the future. <br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="13" |'''Advantages''' <br />
|-bgcolor="FFFAFA" <br />
| Cost effective <ref name="PMID23620651"><pubmed>23620651</pubmed></ref> <ref name="PMID3219767"><pubmed>3219767</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Accurately tests the whole genome <ref name="PMID23560931"><pubmed>23560931</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Tests for the presence of monogenic diseases of known genetic background.<ref name="PMID23499002"><pubmed>23499002</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Reduces the number of biopsies required for diagnosis.<br />
|-bgcolor="FFFAFA"<br />
| Higher detection rate of small translocations is possible.<ref name="PMID3725031"><pubmed>3725031</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Testing for compound point mutations, chromosomal duplication, deletions and insertions is highly accurate<ref name="PMID23312231"><pubmed>23312231</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| It accurately detects chromosomal aneuploidy and unbalanced rearrangement<ref name="PMID25685330"><pubmed>25685330</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| NGS single gene disorder screenings can be conducted in conjunction with PCR comprehensive chromosomal screening<ref name="PMID23312231"><pubmed>23312231</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| Human error is reduced.<br />
|-bgcolor="FFFAFA"<br />
| It detects the presence of mosaicism better.<br />
|-bgcolor="FFFAFA"<br />
| Work well in conjunction with CGH and aCGH as part of PGD, improving the chances of IVF. <ref> Morris, R. S. (2015 ) Next generation sequencing for PCG|PGS|CCS. IVF1 retrieved from [http://www.ivf1.com/next-generation-sequencing for-pgd] </ref><br />
|-bgcolor="DDCEF2"<br />
| rowspan="3"|'''Disadvantages''' <br />
|-bgcolor="FFFAFA"<br />
| There are limited information available to clinical applications of NGS <ref name="PMID26100406"><pubmed>26100406</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| More research and progress needed to establish a clinical manifestation<ref name="PMID24907939"/>.<br />
|}<br />
====Procedure====<br />
Samples are collected from either blastomere or the blastocyst/tropoectoderm and processed for analysis by a computer system. <br />
The methodology of each process is unique to the technique being used. The popularity of the new and emerging techniques is due to the cost effective nature of their testing, their speed and the accuracy of their results<ref name="PMID18576944"><pubmed>18576944</pubmed> </ref><ref name="PMID23620651"><pubmed>23620651</pubmed></ref>. Please see the table above for advantages of NGS.<br />
==Diagnosis==<br />
[[File:ACGH tracing after trophectoderm biopsy.jpeg|thumb|450px|Array comparative genomic hybridization (aCGH) tracing after trophectoderm biopsy: (a) normal male embryo (female embryo control in blue); (b) female embryo with monosomy for chromosome 20 (male control in red); (c) an excellent quality blastocyst showing chaotic chromosome abnormalities. Nearly every chromosome is aneuploidy<ref name="PMID26237262"/>.]]<br />
There are a large amount of diseases that PGD can apply to, below are descriptions of the diseases that PGD are more commonly used for. Upon completion of the genetic testing for the genes of concern the cells the embryos are discarded and priority is given to those that are healthy. <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/><br />
===Cystic Fibrosis===<br />
Cystic fibrosis is a single gene disorder. It is autosomal recessive and involves mutations in the cystic fibrosis transmembrane conductance regulator (CTFR) gene. The CTFR gene is normally responsible for the decrease in chloride and the transport of bicarbonate in epithelial cells thus playing a major physiological role. In PGD procedures, identification of the gene is assisted by microsatellite markers that have similar composition to the CTFR gene itself. Biopsy of two cells at the blastocyst stage is recommended if markers are not available. There are many variations of cystic fibrosis the most common being P.Phe508del <ref name="PMID26014425"><pubmed>26014425</pubmed></ref>.<br />
<br />
===Autosomal Recessive Meckel-Gruber Syndrome===<br />
Autosomal recessive genetic defect caused by the TMEM67 gene. It results in cystic dysplasia of the kidneys with fibrotic change in the liber and occipital encephalocele. Other malformations could also be present in the central nervous system. In PGD whole genome amplification of single blastomeres are taken to identify the gene, this is also coupled with PCR techniques. Maternal plasma can also be extracted for PGS. <ref><pubmed>24039893</pubmed></ref> <br />
===β – Thalassemia=== <br />
β – Thalassemia is known as the most common type of autosomal recessive inherited disorder among haemoglobinopathies. It involves the adult β-globin gene and is associated with the absent or decreased expression of the gene. This is commonly caused by a single nucleotide change in the gene. PGD has been used successfully worldwide to identify the β-globin gene where its application is usually performed on a single blastomere or polar body <ref name="PMID19064120"><pubmed>19064120</pubmed></ref>.<br />
<br />
In the collapsible table is a list of diseases and their corresponding genes. These genes are tested for in PGD for the identification of a specific disease. Note that not all the diseases applicable to PGD are listed. Some of the genes listed also have a link attached to them which will bring you to the Online Mendelian Inheritance in Man website which provides extensive information about that particular gene. This web site can be accessed when you click [http://www.omim.org/ here] if you would like to find out more about any of the other genes. <br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
! colspan="2" | Applicable diseases for PGD <ref>Genoma Group (2014). Retrieved September 18th, 2015, from http://www.preimplantationgeneticdiagnosis.it/genetic-diseases-diagnosed-by-pgd.htm </ref> <ref>Genesis Genetics (2015). Retrieved September 18th, 2015, from http://genesisgenetics.org/pgd/what-we-test-for/</ref> <ref>Human Fertilisation & Embryology Authority (2015). Retrieved Septembr 18th, 2015, from http://guide.hfea.gov.uk/pgd/</ref><br />
|-<br />
| '''Disease'''<br />
| '''Involved Genes'''<br />
|-<br />
| 5 Alpha Reductase Deficiency (5ARD)<br />
| SRD5A2 [http://www.omim.org/entry/607306]<br />
|-<br />
| Achondroplasia<br />
|FGFR3 [http://www.omim.org/entry/134934]<br />
|-<br />
| Acute Intermittent Porphyria <br />
| ALAD [http://www.omim.org/entry/125270] , ALAS2 [http://www.omim.org/entry/612732], CPOX [http://www.omim.org/entry/612386], FECH [http://www.omim.org/entry/612386], HMBS [http://www.omim.org/entry/609806], PPOX [http://www.omim.org/entry/600923], UROD [http://www.omim.org/entry/613521], or UROS [http://www.omim.org/entry/606938]<br />
|-<br />
| Adrenoleukodystrophy (Adrenomyeloneuropathy)<br />
| ABCD1 [http://www.omim.org/entry/300371]<br />
|-<br />
| Agammaglobulinaemia (x-linked) <br />
|BTK [http://www.omim.org/entry/300300]<br />
|-<br />
| Agammaglobulinemia Bruton Tyrosine Kinase (BTK) <br />
|BTK [http://www.omim.org/entry/300300]<br />
|-<br />
| Aicardi Goutieres Syndrome 1 (AGS1) <br />
|TREX1 [http://www.omim.org/entry/606609] , RNASEH2A [http://www.omim.org/entry/606034] , RNASEH2B [http://www.omim.org/entry/610326] , RNASEH2C [http://www.omim.org/entry/610330], SAMHD1 [http://www.omim.org/entry/606754]<br />
|-<br />
| Alagille Syndrome<br />
|JAG1 [http://www.omim.org/entry/601920] or NOTCH2<br />
|- <br />
| Alpers-Huttenlocher Syndrome <br />
|POLG [http://www.omim.org/entry/174763]<br />
|-<br />
| Alpha-1-antitrypsin deficiency <br />
|SERPINA1 [http://www.omim.org/entry/107400]<br />
|-<br />
| Alpha-Mannosidosis<br />
| MAN2B1[http://www.omim.org/entry/609458]<br />
|-<br />
| Alpha Thalassemia <br />
|HBA1[http://www.omim.org/entry/141800]or HBA2 [http://www.omim.org/entry/141850] <br />
|-<br />
| Alports Syndrome<br />
|COL4A3 [http://www.omim.org/entry/120070] , COL4A4 [http://www.omim.org/entry/120131] , COL4A5 [http://www.omim.org/entry/303630]<br />
|-<br />
| Alzheimer's Disease - early onset (Type 3 and 4) <br />
|APP [http://www.omim.org/entry/104760] , PSEN1 [http://www.omim.org/entry/104311], or PSEN2 [http://www.omim.org/entry/600759] <br />
|-<br />
| Amyotrophic Lateral Sclerosis 1 (ALS1) <br />
| C9orf72 [http://www.omim.org/entry/614260], SOD1 [http://www.omim.org/entry/147450], TARDBP [http://www.omim.org/entry/605078], FUS [http://www.omim.org/entry/137070], ANG [http://www.omim.org/entry/105850] , ALS2 [http://www.omim.org/entry/205100], SETX [http://www.omim.org/entry/608465], VAPB [http://www.omim.org/entry/605704]<br />
|-<br />
| Argininosuccinic Aciduria <br />
| ASL [http://www.omim.org/entry/608310]<br />
|-<br />
| Arrhythmogenic Right Ventricular Cardiomyopathy/ Dysplasia (ARVC/D)<br />
| DSG2 [http://www.omim.org/entry/125671]; DSP [http://www.omim.org/entry/125647] ; PKP2 [http://www.omim.org/entry/602861]<br />
|-<br />
| Ataxia Telangiectasia<br />
| ATM [http://www.omim.org/entry/607585]<br />
|-<br />
| Autosomal Recessive Meckel-Gruber Syndrome<br />
| TMEM67 [http://www.omim.org/entry/609884]<br />
|-<br />
| Bardet-Biedl Syndrome (BBS)<br />
| BBS1 [http://www.omim.org/entry/209901]; BBS10 [http://www.omim.org/entry/610148]<br />
|-<br />
| Barth Syndrome<br />
| TAZ [http://www.omim.org/entry/300394]<br />
|-<br />
| Beta Thalassaemia<br />
| HBB [http://www.omim.org/entry/141900]<br />
|-<br />
| Birt-Hogg-Dubé Syndrome<br />
| FLCN<br />
|-<br />
| Breast Ovarian Cancer Familial Susceptibility (BRCA2)<br />
| BRCA1; BRCA2<br />
|-<br />
| Canavan Disease <br />
| ASPA<br />
|-<br />
| Carnitine-Acylcarnitine Translocase Deficiency <br />
| SLC25A20<br />
|-<br />
| Cerebral Arteriopathy with Subcortical Infarcts & Leukoencephalopathy (CADASIL)<br />
| NOTCH3<br />
|-<br />
| Cerebral Cavernous Malformation<br />
| CCM1<br />
|-<br />
| Charcot-Marie-Tooth Disease<br />
| GJB1; MPZ; NEFL; PMP22<br />
|-<br />
| CHARGE Syndrome<br />
| CHD7<br />
|-<br />
| Cherubism<br />
| SH3BP2<br />
|-<br />
| Choroideremia<br />
| CHM<br />
|-<br />
| Chronic Granulomatous Disease<br />
| CYBB; NCF1<br />
|-<br />
| Ciliary Dyskinesia<br />
| DNAH5<br />
|-<br />
| Citrullinemia<br />
| ASS1<br />
|-<br />
| Cleidocranial Dysplasia<br />
| RUNX2<br />
|-<br />
| Cockayne Syndrome<br />
| ERCC6<br />
|-<br />
| Congenital Adrenal Hyperplasia<br />
| CYP21A2<br />
|-<br />
| Congenital Cataracts<br />
| GJA8; VSX2<br />
|-<br />
| Congenital Diarrhea, Syndromic<br />
| SPINT2<br />
|-<br />
| Congenital Disorders of Glycosylation (CDG)<br />
| ALG1; ALG6; CDG1C; DOLK; PMM2<br />
|-<br />
| Cornelia de Lange Syndrome <br />
| NIPBL<br />
|-<br />
| Craniosynostosis<br />
| TWIST1<br />
|-<br />
| Crouzon Syndrome<br />
| FGFR2<br />
|-<br />
| Cysteinyl Leukotriene Receptor 1 Deficiency <br />
| CYSLTR1<br />
|-<br />
| Cystic Fibrosis<br />
| CFTR<br />
|-<br />
| Diamond –Blackfan Anemia <br />
| RPS19<br />
|-<br />
| Duchenne Muscular Dystrophy <br />
| DMD<br />
|-<br />
| Dyskeratosis congenita (Male embryos only)<br />
| DKC1<br />
|-<br />
| Ectodermal dysplasia (Hypohidrotic)<br />
| EDA; EDA1; GJB6; IKBKG<br />
|-<br />
| Familial Adenomatous polyposis coli (FAP)<br />
| APC<br />
|-<br />
| Familial Dysautonomia<br />
| IKBKAP<br />
|-<br />
| Fanconi Anemia <br />
| FANCA; FANCC; FANCD2; FANCF; FANCG; FANCJ<br />
|-<br />
| Fragile X Syndrome (FRAX)<br />
| FMR1<br />
|-<br />
| Galactosemia <br />
| GALT<br />
|-<br />
| Gangliosidosis<br />
| GLB1<br />
|-<br />
| Glanzmann Thrombasthenia <br />
| ITGA2B<br />
|-<br />
| Glutaric Acidemia (aciduria)<br />
| GCDH <br />
|-<br />
| Glycogen Storage Disease <br />
| G6PC; GAA; SLC37A4<br />
|-<br />
| Haemophilia A<br />
| F8<br />
|-<br />
| Haemophilia B<br />
| F9<br />
|-<br />
| Hereditary Nonpolyposis Colorectal Cancer: Lynch Syndrome<br />
| MLH1; MSH2; MSH6<br />
|-<br />
| Holt Oram Syndrome<br />
| TBX5<br />
|-<br />
| Huntington Disease<br />
| HD<br />
|-<br />
| Hydrocephalus<br />
| L1CAM<br />
|-<br />
| Ichthyosis <br />
| ABCA12; STS<br />
|-<br />
| Incontinentia Pigmenti (IP)<br />
| NEMO<br />
|-<br />
| Joubert Syndrome 5<br />
| INPP5E<br />
|-<br />
| Krabbe Disease<br />
| GALC<br />
|-<br />
| Leber Congenital Amaurosis (LCA)<br />
| CEP290; GUCY2D<br />
|-<br />
| Leigh Syndrome (Infantile Subacute Necrotising Encephalopathy)<br />
| LRPPRC<br />
|-<br />
| Lesch Nyan Syndrome<br />
| HPRT1<br />
|-<br />
| Leukocyte Adhesion Deficiency (Type I)<br />
| ITGB2<br />
|-<br />
| Li-Fraumeni Syndrome<br />
| TP53<br />
|-<br />
| Macular Dystrophy Retinal <br />
| VMD2<br />
|-<br />
| Maple Syrup Urine Disorder (MSUD)<br />
| BCKDHB<br />
|-<br />
| Marfan Syndrome <br />
| FBN1<br />
|-<br />
| Menkes Syndrome<br />
| ATP7A<br />
|-<br />
| Mitochondrial DNA Depletion Syndrom <br />
| POLG; RRM2B; SUCLA2; TK2<br />
|-<br />
| Mucolipidosis type II<br />
| GNPTAB<br />
|-<br />
| Multiple Endocrine Neoplasia<br />
| MEN1; MEN2A; MEN2B<br />
|-<br />
| Multiple Exostoses<br />
| EXT1; EXT2 <br />
|-<br />
| Myotubular myopathy<br />
| MTM1 <br />
|-<br />
| Nail-Patella Syndrome<br />
| LMX1B<br />
|-<br />
| Neurofibromatosis Type 1<br />
| NF1<br />
|-<br />
| Neurofibromatosis Type 2 <br />
| NF2<br />
|-<br />
| Noonan Syndrome<br />
| KRAS, PTPN11; SOS1<br />
|-<br />
| Norrie Disease<br />
| NDP<br />
|-<br />
| Ocular Albinism <br />
| GPR143<br />
|-<br />
| Oculocutaneous Albinism <br />
| OCA2; TYR <br />
|-<br />
| Oculodentaldigital Dysplasia<br />
| GJA1<br />
|-<br />
| Optic Atrophy<br />
| OPA1<br />
|-<br />
| Ornithine Transcarbamylase Deficiency <br />
| OTC<br />
|-<br />
| Osteogenesis imperfeca <br />
| COL1A1; COL1A2<br />
|-<br />
| Osteopetrosis <br />
| CLCN7; OSTM1; TCIRG1<br />
|-<br />
| Pachyonychia Congenita <br />
| KRT16; KRT6A<br />
|-<br />
| Pancreatitis, Hereditary<br />
| PRSS1 <br />
|-<br />
| Papillorenal syndrome <br />
| PAX2<br />
|-<br />
| Phenylketonuria <br />
| PAH <br />
|-<br />
|}<br />
==Laws & Legal status==<br />
{| class="wikitable" <br />
|-bgcolor="DDCEF2"<br />
|'''Country'''<br />
|'''Legislation'''<br />
|-bgcolor="FFFAFA" <br />
| Australia<br />
| PGD is currently used to detect serious genetic conditions to improve the outcome of ART. In very rare cases it may be used to select an embryo with compatible tissue for a sibling who has a life-threatening disease where other means of treatment is unavailable. This is with the conditions that the use of PGD will not affect the welfare and interests of the child to be born. The parents must also receive adequate counselling and have full understanding of the procedures of PGD. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"> National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art</ref><br />
The use of PGD for sex-selection is prohibited with the exception of reducing the risk of the transmission of serious sex-linked genetic conditions. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"/><br />
|-bgcolor="FFFAFA"<br />
| Brazil<br />
| The laws regarding PGD in Brazil are not strictly regulated. They are vague and there is limited information surround the activities of assisted reproduction in general in the country <ref name="PMID25493379"><pubmed>25493379</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| Czech Republic<br />
| The laws in the Czech Republic allow those with a “defined indication in order to exclude risk of serous genetically conditioned disease and defects with embryos before they are implanted into the cavity of the uterus”. Couples that undergo any assisted reproductive treatment including PGD have to be married. Sex-selection is illegal except in regards to serious sex-linked genetic diseases <ref name="PMID24777348"><pubmed>24777348</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| Greece<br />
| In Greece, ART is open to those up to the age of 50 with written consent. It can only be used if a medical necessity is present such as the susceptibility of serious hereditary diseases. Sex selection is banned apart from cases of sex-linked diseases and sexually transmitted diseases <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| India<br />
| In India there is a cultural preference for boys thus the Prenatal Diagnostic Techniques (Regulation and Prevention of Misuse) Act was introduced in 1994. This law limits the use of PGD for sex determination except in cases of specific congenital diseases. These laws however are not strictly enforced. <ref>World Health Organisation (2015) Gender and Genetics Retrieved on October 21st 2015 from:http://www.who.int/genomics/gender/en/index4.html</ref><br />
|-bgcolor="FFFAFA"<br />
| Portugal <br />
| ART is only available to those who are married or have a similar type of relationship for at least two years. The couples cannot be of the same sex and must be at least 18 years of age. Sex selection is illegal except in cases of sex-linked diseases. The use of PGD is illegal if the predictive value of genetic tests are very low <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| Spain<br />
| PGD can be applied to “serious hereditary diseases not amenable to postnatal curative treatment” and “detection of other abnormalities which may compromise the viability of the pre-embryo”. If PGD is to be used for any other purpose authorisation must be acquired <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| Sweden <br />
| The use of PGD is strictly regulated and couples must achieve authorisation of the National Board of Health and Welfare. It can only be used it can only be used if the child is at risk to inheriting a serious chromosomal or monogenetic disease. It cannot be used for selection of specific characteristics <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| United Kingdom<br />
| Those involved with carrying out the IVF treatment must have a license from the Human Fertilisation and Embryology Authority (HFEA). Only embryos that are approved by the HFEA can be implanted where the embryonic nuclear or mitochondrial DNA cannot be altered with the exception of preventing mitochondrial diseases <ref name="PMID24777348"/>. <br />
|}<br />
==Future/Current Research==<br />
In addition to research efforts for improving overall performance of established PGD/S techniques, such as finding the ideal zona pellucida insection site in an fully automatic manner<ref name="PMID26259216"><pubmed>26259216</pubmed></ref>, many research efforts have been spent to find alternative, non-invasive techniques to test for diseases and abnormalities<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
===Non-invasive Preimplantation Genetic Testing without Embryo Biopsy===<br />
Different parameters of gametes, zygotes, embryos (“vacuoles in sperm heads, spindle position in mature oocytes, cleavage intervals of zygote, and embryo developmental dynamics”) may correlate with aneuploidy rates. This knowledge may be applied in potential noninvasive preimplantation diagnostic methods. Several methods have been proposed and are currently further researched<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Sperm Selection====<br />
Intracytoplasmic morphologically selected sperm injection (IMSI) is common procedure in IVF treatment to improve fertilization rates in patients with poor semen quality. In addition, studies have found that IMSI improves embryo development and that spermatozoa with large vacuoles in their heads correlate with increased aneuploidy rates and disturbed chromosomal structures. Thus, selecting spermatozoa based on morphological hallmarks may decrease aneuploidy rates in the fertilized embryos. As with polar body biopsies, however, this approach will solely be applicable if evidence for severe male detrimental contribution is given<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Blastocoel Fluid Extraction====<br />
In addition, a less invasive retrieval of material for diagnosis could include the extraction of the blastocoel fluid. The cavity of the blastocyst, lined by the trophectoderm, is filled with this blastocoel fluid, which contains metabolites of both trophectoderm and inner cell mass origin. The retrieval does not require a biopsy but merely a small opening to extract the fluid and, thus, causes less harm to the embryo. Multiple studies have applied this method<ref name="PMID22020776"><pubmed>22020776</pubmed></ref> <ref name="PMID23148560"><pubmed>23148560</pubmed></ref> <ref name="PMID26006737"><pubmed>26006737</pubmed></ref> and it may in the future become of clinical relevance.[[File:Aspiration_of_the_Blastocoel_Fluid.jpeg|400px|thumb|Aspiration of the Blastocoel Fluid using a ICSI pipette<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.]]Next to metabolites, the blastocoel fluid can contain DNA. Studies have shown that genomic DNA is present in about 90% of the blastocoel fluid samples tested. Typically the fluid is removed with an ICSI pipette from a day five blastocyst through its mural trophectoderm until the blastocyst fully collapses around the embryo. Several concerns regarding this method in a clinical setting have been raised. The collected DNA may be contaminated by the culture media that contains DNA fractions. The DNA may also be least representative of the actual embryos genome as the DNA may originate from abnormal or degenerated cells. Even though labelled noninvasive, the blastocyst still undergoes manipulation to some degree which may affect its viability. Thus, more research is required until this method can evolve from research to clinical use<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
====Proteomics and Medium Based PGD====<br />
The media in which embryos are kept during the early IVF procedures, gives rise to potential non-invasive techniques. For instance, the protein secretome of blastocysts may be representative of its chromosome constitution Recent studies have found biomarkers such as lipocalin-1, interleukin-10, tumor necrosis factor, stem cell factor, and chemokine ligand 13 to be differently secreted by aneuploid blastocyst than by euploid ones. The most significant biomarker appears to be interleukin-10. Paired with novel proteomic technologies and mass spectrometry this knowledge when extended may contribute to a new invasive PGD method<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. In addition, medium based non-invasive PGD has been researched for the diagnose of human α-thalassemia-SEA. Genomic DNA was collected from the media and the study surprisingly resulted in increased diagnosis efficacy compared to biopsy-based methods<ref name="PMID25816038"><pubmed>25816038</pubmed></ref>.<br />
====Embryo Morphology====<br />
Using time lapse imaging the embryo’s morphology can be closely observed and potential aneuploidy characteristics detected. Such characteristics may include the time of division to five cells, the time between the division from three to four cells, and the duration of the division from one to two and subsequently to three. In addition, the morphological quality of ICM an TE has been positively associated with aneuploidy or euploidy prognosis<ref name="PMID26246880"><pubmed>26246880</pubmed></ref>. These may give rise to an embryo quality screening prior to implantation<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
==Glossary==<br />
'''Allele:''' One of two or more versions of a gene<br />
<br />
'''Aneuploidy:''' Presence of an abnormal number of chromosomes in a cell <br />
<br />
'''Biopsy:''' Sample of tissue taken for examination <br />
<br />
'''Blastocyst:''' Stage of embryo at approximately day 5 consisting of an outer (trophoblast) layer and inner (embryoblast) cell mass.<br />
<br />
'''Blastomere:''' Cell type formed through cleavage of the zygote after fertilization<br />
<br />
'''Chromosome''' Thread-like structure, which is made up of protein and DNA, within the nucleus of a cell<br />
<br />
'''CTFR:''' Cystic Fibrosis Transmembrane Conductance Regulator, responsible for transport of chloride across the cell membrane<br />
<br />
'''Denaturing:''' Proteins or nucleic acids lose their quaternary, tertiary, and secondary structure <br />
<br />
'''DNA:''' DeoxyriboNucleic Acid, hereditary material<br />
<br />
'''Endometriosis:''' Condition in which the endometrium, the tissue lining the uterus, grows outside of it<br />
<br />
'''Enucleation:''' Removal of the nucleus<br />
<br />
'''Epigenetic:''' Phenotypic trait variations due to external or environmental factors that influence gene expression<br />
<br />
'''ESHRE:''' European Society of Human Reproduction and Embryology<br />
<br />
'''FISH:''' Fluorescent In situ Hybridisation, technique used to locate specific gene sequences using fluorescence tags <br />
<br />
'''Heterozygote:''' Diploid organism that contains two different alleles of one gene<br />
<br />
'''Hydrosalphinx:''' Fluid filled fallopian tube <br />
<br />
'''Intracytoplasmic Morphologically Selected Sperm Injection (IMSI):''' IVF technique involving morphological selection of sperm under the microscope to be injected to oocyte<br />
<br />
'''Intracytoplasmic Sperm Injection (ICSI):''' IVF technique used to treat male infertility and involves direct injection of one sperm into an oocyte<br />
<br />
'''IVF:''' In Vitro Fertilisation<br />
<br />
'''Leukocyte:''' White blood cell, involved in immune system<br />
<br />
'''Leukaemia:''' Cancer of the bone marrow, increased numbers of abnormal or premature leukocytes are formed by bone marrow and other organs <br />
<br />
'''NGS:''' Next Generation Sequencing, term used to describe the collection of recent findings regarding embryo screening<br />
<br />
'''Oolemma''': Plasma membrane of the oocyte <br />
<br />
'''PB:''' Polar Body, cell formed during the meiotic stages of the oocyte containing extra genetic material<br />
<br />
'''PCR:''' Polymerase Chain Reaction, technique used to amplify DNA to study a specific genetic sequence<br />
<br />
'''Polyploidy:''' Having more than two sets of homologous chromosomes <br />
<br />
'''PGD:''' Preimplantation Genetic Diagnosis, genetic testing conducted to identify abnormalities in an embryo before implantation in parents with genetic disease history<br />
<br />
'''PGS:''' Preimplantation Genetic Screening, similar to PGS but in couples seeking IVF due to infertility issues to improve implantation rates<br />
<br />
'''Perivitelline Space:''' Space between the oolemma and the zona pellucida <br />
<br />
'''RT:''' Robertsonian Translocations, a type of structural chromosomal translocation <br />
<br />
'''Trisomies:''' Presence of three copies of a chromosome instead of two<br />
<br />
'''Trophoectoderm:''' Outer layer of the mammalian blastocyst<br />
<br />
'''Zona Pellucida:''' Thick membrane surrounding the mammalian oocyte <br />
<br />
<br />
==References==<br />
<br />
<references/><br />
<br />
<br />
{{StudentPage2015}}</div>Z5017878https://embryology.med.unsw.edu.au/embryology/index.php?title=2015_Group_Project_6&diff=2086312015 Group Project 62015-10-23T12:44:10Z<p>Z5017878: </p>
<hr />
<div>{{ANAT2341Project2015header}}<br />
<br />
<br />
=Preimplantation Genetic Diagnosis and Preimplantation Genetic Screening=<br />
==Introduction==<br />
Preimplantation genetic diagnosis (PGD) and preimplantation genetic screening (PGS) are reproductive options for couples with known family histories of genetic disease or couples undergoing IVF procedures due to infertility issues. PGD can diagnose many genetic disorders caused by known chromosomal abnormalities (number and/or structure) or single gene mutations, and, thus decrease the risk of termination of pregnancy or miscarriages and enable such couples to have an unaffected child<ref name="PMID24907939"><pubmed>24907939</pubmed></ref>. Through major improvements in PGD/S and general laboratory technology, the testing for abnormalities in fetuses has shifted from prenatal diagnosis during the first 2 trimesters <ref> Blackburn, S.L. (2003) '''Maternal, Fetal & Neonatal physiology: a Clinical perspective''' (2nd ed.). Seattle: Saudners </ref>, testing for overall fetal growth, complications of pregnancy, and birth defects<ref> Sadler T.W.(2012) '''Langman's Medical Embryology''' (12th ed.) Philadelphia: Lipincott, Wiliams & Wilkins, a Wolters Kluwer Business </ref>, to an embryonic focus especially in advancements in Artificial Reproductive Technologies (ART)<ref><pubmed>20638568</pubmed></ref>. In 1990 PGD for a recessive X-linked disease resulted in the first live birth<ref><pubmed>2330030</pubmed></ref> and has since been incorporated in clinical routine and applied for a variety of genetic diseases, such as sickle cell anemia, thalassemia, or cystic fibrosis<ref name="PMID24907939"/>.<br />
[[File:Preimplantation Genetic Diagnosis Procedure.jpeg|600px|left|thumb| Simplified steps for PGD<ref name="PMID24907939"/>]]<br />
{|class="wikitable"align="right" <br />
| <html5media height="400" width="533">https://www.youtube.com/watch?v=0e-79qKllqk</html5media><br />
|-<br />
| Preimplantation Genetic Diagnosis<ref>IVF Florida (2011, December 11) IVF Florida - South Florida Fertility Specialists - Pre-Implantation Genetic Diagnosis [Video file]. Retrieved from https://www.youtube.com/watch?v=0e-79qKllqk</ref><br />
|}<br />
==History==<br />
The advances in reproductive technology during the second half of the 20th century, led to PGD's first clinical application in 1990 <ref>Harper, J. (n.d.). The history of PGD. Lecture. UCL Centre for PG&D and CRGH.University College London</ref>.<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
|Year<br />
|<br />
|- bgcolor="FFFAFA"<br />
| '''1967''' <br />
|First PGD on rabbit blastocysts (Gardner& Edwards) <ref name="PMID6036172"><pubmed>6036172</pubmed></ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1986''' <br />
|First Cleavage Biopsy (Wilton & Trounson)<ref>Wilton, L. J., & Trounson, A. O. (1986). Viability of mouse embryos and blastomeres following biopsy of a single cell. In Proceedings of the 18th Annual Conference of the Australian Society for Reproductive Biology, Brisbane, Australia.</ref><br />
|- bgcolor="FFFAFA"<br />
|'''1987''' <br />
|First Blastocyst Biopsy (Muggleton-Harris, Monk, Rawlings, & Whittingham)<ref name="PMID3372699"><pubmed>3372699</pubmed></ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1988''' <br />
|First Polar Body Biopsy (Yury Verlinksy)<ref> Verlinsky, Y., Pergament, E., Andresen, P., Enriquez, G., & Strom, C. (1989). Genetic analysis of polar body DNA: A new approach to preimplantation genetic diagnosis. Am J Hum Genet, 45(4), A272.</ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1990''' <br />
|First Clinical PGD using PCR testing for X-linked (Handyside, Kontogianni, Hardy, & Winston)<ref name="PMID2330030"><pubmed>2330030</pubmed></ref> <br />
|} <br />
==Preimplantation Genetic Diagnosis==<br />
[[File:Pre-PGD workup.jpeg|thumb|400px|Pre-PGD workup for a family with a previous child with spinal muscular atrophy. Panel (a) shows how the study of both parents and grandparents allows the phasing of the SMN mutation relative to polymorphic short tandem repeat (STR) markers; panel (b) shows the maternal and paternal haplotypes M1, M2, P1 and P2 and the distance of the STR markers from the SMN gene; panel (c) shows the four predicted fetal haplotypes. These reflect a Hardy–Weinberg equilibrium of one homozygous non-carrier, two heterozygous carriers and one that is homozygous and affected. Short tandem repeat markers linked with the SMN mutation are shown in red. DEL indicates the presense of the exon 7 (840 C>T) mutation<ref name="PMID26237262"/>.]]<br />
PGD is used to test the genetic makeup of embryos to detect single gene disorders, chromosomal abnormalities and mitochondrial disorders. It also has applications in gender selection for diseases with unequal gender distributions <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Some diseases commonly involved with PGD include cystic fibrosis, spinal muscular atrophy and beta – thalassaemia <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press.">Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press</ref> <ref name="PMID17823145"><pubmed>17823145</pubmed></ref>. It was first used in the United Kingdom in the 1980s, primarily focusing on sex- linked disorders <ref name="PMID17823145"/><ref name="PMID23150080"><pubmed>23150080</pubmed></ref>. PGD is now capable of detecting single cell defects (molecular) and chromosomal disorders resulting from the inversion, translocation or deletion of chromosomes (cytogenic) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/> <ref name="PMID11325751"><pubmed>11325751</pubmed></ref>. PGD can be applied to the embryo at different stages. That is on polar bodies, blastomeres or blastocyst <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>.<br />
Depending on the type of genetic disorder, PGD utilises different methods of genetic testing. These include Fluorescence in situ hybridisation (FISH) which is used for sex – linked disorders and detects chromosomal rearrangements <ref name="PMID11325751"/><ref name="PMID17876073"><pubmed>17876073</pubmed></ref> and Embryo halotyping which allows the identification of chromosomes causing the inherited disorder through knowledge of the pattern of closely linked markers <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. Polymerase chain reaction (PCR) is also widely used to detect molecular abnormalities <ref name="PMID11325751"/>.<br />
PGD is tightly regulated and supported by large organisations namely The American Society for Reproductive Medicine, The European Society for Human Reproduction and Embryology (ESHRE), The European Society of Human Genetics and the Preimplantation Genetic Diagnosis International Society <ref name="PMID25500181><pubmed>25500181</pubmed></ref>.<br />
===Sex-linked disorders===<br />
The determination of a disease as gender specific usually correlates with the presence or absence of specific genes such as SRY on the Y chromosome. It is known that females have two X chromosomes and males have an X and a Y chromosome where abnormalities are more prevalent on the X chromosome. PGD can be used for sex selection where only male embryos are transferred to reduce the chance of inheriting X-linked disorders. However, this does not completely eradicate the problem as male embryos remain susceptible to inheriting an affected X chromosome. Sex determination is only used when the specific mutation is unknown and has yet to be discovered <ref name="PMID24866878"><pubmed>24866878</pubmed></ref>.<br />
===Single gene defects===<br />
Single gene defects can be dominant, recessive, autosomal or X-linked. They are commonly diagnosed using PCR and although the PCR available today is complex and capable of combatting a large range of disease the development of new protocols has been proven to be difficult due to the small DNA sample available <ref name="PMID26168107"><pubmed>26168107</pubmed></ref>.<br />
===Mitochondrial disorders===<br />
Mitochondrial disorders also known as oxidative phosphorylation disorders arise from mutations in the nuclear DNA or mitochondrial DNA <ref name="PMID26312584"><pubmed>26312584</pubmed></ref>. They pose as a problem because they are unrecognisable until the mutations in the cell reach a detrimental level <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Mitochondrial disorders cause miscarriages and stillbirths as well as death in children and young adults. The effects can either be contained in a single organ or more commonly involve multiple organ failure where organs with high energy demands such as the brain, liver muscle and heart and heavily influenced. They are usually occur spontaneously or result from inheritance from the mother. Since mitochondria are solely inherited from the mother oocyte donations have been used as a solution to combat mitochondrial disorders. Additionally, there has been an increasing use in PGD where embryos that stay under the given threshold of 18% gene-mutations are allowed to be transferred and result in normal development. New technology in the areas of nuclear gene transfer and genome editing are also being experimented with <ref name="PMID26312584"/>. <br />
===Chromosomal disorders===<br />
Chromosomal disorders can be reciprocal, Robertsonian translocations, inversions, deletions and insertions <ref name="PMID26168107"/>. Data from ESHRE collected between 2010 and 2011 has shown that the most common chromosomal abnormality confronted in PGD are reciprocal chromosomal abnormalities <ref name"PMID26071418"><pubmed>26071418</pubmed></ref>. PGD has also been used successfully for Robertsonian translocations (RT), a type of structural translocation. Children who carry RT are phenotypically normal, however in their later years it is found that they will suffer from infertility and repeated miscarriages due to the high frequency of abnormal embryos <ref name="PMID22081077"><pubmed>22081077</pubmed></ref>. PCR and FISH are the two main techniques used for chromosomal disorders. To be able to conduct the examinations the cells are required to be at the metaphase stage <ref name="PMID26168107"/>. <br />
[[File:Reasons_for_PGD.jpg|600px|thumb|Reasons for PGD<ref name="PMID24764761"><pubmed><24764761</pubmed></ref>]]<br />
==Preimplantation Genetic Screening==<br />
PGS involves an array of methods or ideas that aim to segregate embryos that have genetic flaws and those that are healthy <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. The occurrence of aneuploidy is high around the stages of early embryonic development and they are the most common cause if miscarriages and congenital birth defects <ref name= "PMID26085841"><pubmed>26085841</pubmed></ref>. They have little effect on the morphology of the embryo making them difficult to identify thus identification heavily relies on genetic testing <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. <br />
Genetic sampling is most commonly conducted using Microarray Comparative Genomic Hybridisation (aCGH) as well as FISH, Quantitative PCR and Single Nucleotide Polymorphism (SNP) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. These methods collectively aim to assess numeral and structural chromosomal errors <ref name= "PMID26085841"/>. Studies have also introduced Next- Generation Sequencing (NGS) <ref name= "PMID26085841"/> and Whole Genome Amplification used to screen imbalances in the complete 24-chromosomes <ref name="PMID25953353"><pubmed>25953353</pubmed></ref>.<br />
Statistics from ESHRE have shown that the most common indications for PGS is advanced age, followed by repeated implantation failure or recurrent miscarriage and male infertility <ref name="PMID26071418"><pubmed>26071418</pubmed></ref>.<br />
===Indications===<br />
A low percentage of structural abnormalities in chromosomes are responsible for the cause of miscarriages. Despite this, they are the most prevalent type of chromosomal abnormality accounted for in PGD <ref name="PMID20638568"/>. The presence of specific gene cycles, initiation of embryonic protein synthesis and evident physiological development are all indicative of a successful in vitro fertilisation procedure <ref name="PMID11576737"><pubmed>11576737</pubmed></ref>. To eliminate further errors from occurring during the PGD procedure it is recommended to undertake further prenatal testing such as amniocentesis in the later stages <ref name="PMID20638568"/>. <br />
====Advanced maternal age====<br />
Data provided by the ESHRE has shown that the mean age of women undergoing PGS is 39 years <ref name="PMID26071418"/>. Women of advanced age have been shown to have a lower rate of pregnancies reaching childbirth <ref name="PMID18583331"><pubmed>18583331</pubmed></ref>. The highlighted concern revolves around the increased occurrence of aneuploidy following maternal age. The optimal age range for the lowest aneuploidy incidence was found to be between 27 to 37 years of age (6%) then progressively higher in women aged up to 42 (33%) and most common in those 44 and above (53%) <ref name="PMID24355045"><pubmed>24355045</pubmed></ref>. <br />
====Recurrent pregnancy loss / IVF failure====<br />
Recurrent pregnancy loss is defined as three or more IVF failures after cumulative transfer of more than 10 good-quality embryos. These are primarily caused by two main factors, reduced endometrium receptivity or embryonic defects. Endometrium receptivity can be negatively influences by instances including uterine pathologies such as thin endometrium, altered expression of adhesive molecules and immunological factors. Additionally, embryonic defects may be due to genetic abnormalities, embryonic aneuploidy or zona hardening. Endometriosis and hydrosalpinx has been known to effect both the endometrium and embryo <ref name="PMID23260857"><pubmed>23260857</pubmed></ref>.<br />
====Human leukocyte antigen matching====<br />
First used in 2001, HLA matching is an option given to parents to save a child with haematological or immunological disease through conceiving another child who would potentially be able to donate cord blood or haematopoietic stem cells from the bone marrow for transplantation. The process namely PGD-HLA has shown to improve haematopoietic stem cell transplant (HSCT). PGD-HLA can only be performed when HSCT is not needed urgently due to the time needed to conceive and delivery the baby <ref name="PMID25500181"><pubmed>25500181</pubmed></ref>. It is most commonly applied to children suffering from relapsed leukaemia <ref name="PMID22524201"><pubmed>22524201</pubmed></ref>. In a case study PGD-HLA was proven to successfully cure 10 diseases including Fanconi anaemia, Diamond-Blackfan anaemia and beta thalassemia <ref name="PMID25066893><pubmed>25066893</pubmed></ref>.<br />
==Biopsy Methods==<br />
Biopsy, the removal of genetic materials, from oocytes or embryos in the preimplantation stage is the primary step in PGD. For the past two decades these biopsies have been performed at three stages, the polar body, blastomere, and blastocyst, and the methodologies optimized to ensure the embryo’s viability. The most common approach involves biopsies at the cleavage stage. However, polar body and blastocyst biopsies are increasingly more often tested and applied. Approached for opening the zona pellucida involve next to the traditional mechanical and chemical means, novel approaches such as noncontact lasers. Their application may simplify and secure the procedure significantly. The most challenging question about PGD procedures remains at what stage biopsies should be taken. Much controversy has developed around this topic, highlighting the varying disadvantages and advantages of temporal biopsies <ref name="PMID22723007"><pubmed>22723007</pubmed></ref>.<br />
[[File:Polar_Body,_Blastomere,_and_Trophectoderm_Biopsy.jpeg|500px|thumb|Polar body (A), blastomere (B) and trophectoderm (C) biopsies<ref name="PMID25625041"><pubmed>25625041</pubmed></ref>.]]<br />
{| class="wikitable"<br />
|- align="center" bgcolor="DDCEF2"<br />
|<br />
| Time of Biopsy<br />
| Prevalence <br />
| Advantages <br />
| Disadvantages<br />
|- bgcolor="FFFAFA"<br />
| Polar Body<br />
| Day 1<br />
| ~16%<br />
| Little to no harm is caused to the oocyte and both PBs can be extracted (more genetic material)<ref name="PMID22723007"/>.<br />
| Only the maternal DNA is tested<ref name="PMID22723007"/>, often PB biopsies need to be coupled to other biopsies, and difficulties arise in distinguishing between the first and second PB<ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. Lower reliability of results compared to other biopsy methods have been reported<ref name="PMID25106935"/>. <br />
|- bgcolor="FFFAFA"<br />
| Blastomere <br />
| Day 3<br />
| ~80%<br />
| Biopsies are safe for good quality embryos and it is performed relatively early, so fresh transfer is possible, yet, it includes both paternal and maternal genetic contributions<ref name="PMID26237262"/>. <br />
| Relatively large decrease in implantation rates for low quality embryos have been reported, embryo mosaicism can influence genetic analysis, and only one to two cells can be safely removed<ref name="PMID26237262"/>. <br />
|- bgcolor="FFFAFA"<br />
| Trophectoderm<br />
| Day 5 and 6 <br />
| ~ 2%<br />
| Little harm to the embryo and large amount of genetic material can be extracted, which allows for more accurate genetic analysis and lessen effects of mosaicism<ref name="PMID26237262"/>. <br />
| The biopsy takes place relatively late and, thus, the time window for procedure is small and embryos often need to be cryopreserved<ref name="PMID22723007"/>. <br />
|}<br />
===Polar Body Analysis===<br />
Day 1<br />
====Description====<br />
[[File:Polar_Body_Biopsy.jpeg|thumb|400px|The presence of a faint but clearly identifiable strand connecting PB2 to the oolemma. The biopsy was performed ∼9 h after ICSI<ref name="PMID21908464"><pubmed>21908464</pubmed></ref>.]] <br />
Polar body (PB) biopsy offers a promising alternative to biopsies performed at the blastomere stage for PGD/S indications on legal and practical grounds<ref name="PMID22723007"/>. The ESHRE calculated the proportion of PB biopsies to be about 16.3%<ref name= "Traeger-Synodinos, J., Coonen, E., Goossens, V., De Mouzon, J., Shenfield, F., Ruiz, A., ... & de Mouzon, J. (2013). Session 09: ESHRE data reporting on PGD cycles and oocyte donation.">Human Reproduction, 28(suppl 1), i18-i19. </ref>. Embryo development does not necessitate the presence of the first and second PB and their removal may not be crucial<ref name="PMID22723007"/>. The idea behind PB biopsies is that each abnormality found in the PB corresponds to an error in the oocyte. On the other hand, in women with known single gene mutations, it is assumed that if the PB contains the mutated allele ,the oocyte will have the normal allele, thus, resulting in a healthy embryo<ref name="PMID26237262"/>. PB biopsy requires precise timing. Keeping track of the meiotic cell cycle is necessary to perform a successful biopsy and, therefore, PB biopsy usually is applied in combination with intracytoplasmic sperm injection (ICSI). During the maturation from the germinal vesicle stage to the metaphase-II stage the first PB is formed. A cytoplasmic bridge containing spindle remnants, that are still in contact with the cellular genetic material, links this PB to the oolemma for about 90 minutes after extrusion. It is possible to visualize these remnants by polarization microscopy and it is crucial to not perform the biopsy until the first PB is no longer firmly attached to the oolemma as this indicates an immature embryo.The oocyte tolerates mechanical zona dissection best during hours four until six after ICSI as the oolemma has stabilized by that time because of the cortical granule reaction. Over time the first PB degenerates stressing a temporal biopsy and its optimal extraction time window is four to 12 hours after ICSI. The second PB forms around two to four hours after ICSI. Its optimal time window for biopsy is set to be eight to 16 hours after ICSI due to the second PB being attached to the oolemma with spindle remnants until six hours after ICSI. Biopsy at this point may cause enucleation of the oocyte. Studies have shown that the amplification efficiency of second PB’s DNA is worse if the PB is extracted prior to eight hours after ICSI. Thus, it is possible to perform sequential and simultaneous biopsies for the first and second PB. If performed, sequentially the first PB may be removed four to 12 hours and the second PB eight to 16 hours after ICSI. The optimal time window for a biopsy for both the first and second PB simultaneously is eight to 12 hours after ICSI. It is highly preferred to analyze both PBs due to potential aneuploidies in either PB and crossing overs during meiosis <ref name="PMID22723007"/>. <br />
====Procedure====<br />
Chemical opening achieved with for example acidic tyrode’s solution of the zona pellucida is not tolerated by the oocyte and may have detrimental effects on the embryo’s development. Therefore, the access to the perivitelline space of the oocyte is provided by mechanical zona dissection or by laser. Both techniques work well if performed by experienced embryologist. However, laser-assisted biopsy is less time consuming when compared to manual dissection. It is critical to consider the size of the introduced opening as it will remain permanent. If it is too large the blastomere may be lost during embryo development and if it is too small it may interfere with hatching of the embryo during blastocyst stage<ref name="PMID22723007"/>.<br />
[[File:Implantation_predictive_value_of_euploid_screening_results.jpeg|thumb|450px|The sustained implantation predictive value (with 95 % confidence interval) of a euploid screening result obtained from the first polar body (PB1), PB1 and the second polar body (PB2), or a direct embryo biopsy for each stage of embryo transfer (cleavage-stage and blastocyst stage)<ref name="PMID25106935"><pubmed>25106935</pubmed></ref>.]]<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JTaQzszVr8o</html5media><br />
|-<br />
| Laser-assisted polar body biopsy<ref>RIUK, R. (2013, June 25) Polar Body Biopsy [Video file]. Retrieved from https://www.youtube.com/watch?v=JTaQzszVr8o</ref><br />
|}<br />
====Advantages & Disadvantages====<br />
PB biopsies can only investigate the maternal contributions to the embryo as they are of maternal origin. Thus, this procedure is appropriate for PGD solely for monogenetic diseases from the maternal side. Recessive diseases may be evaluated with PB biopsies on the basis that the embryo’s outcome will be determined by the paternal contribution. It may still be applied for PGS as it is a fairly safe biopsy option and most aneuploidies either arise during meiosis or origin from the maternal genome. However, diagnosis error has been reported due to the lack of considering paternal contributions<ref name="PMID22723007"/>. About 10% of PB biopsies appear to be wrongfully diagnosed with aneuploidies<ref name="PMID26237262"><pubmed>26237262</pubmed></ref>. Because PB biopsies are performed very early it is not yet known whether the oocyte will develop into a viable embryo. Thus, PBs are commonly frozen or fixed after biopsy and depending on the state of the embryo only chosen PBs will be tested. This is primarily an economic issue as many genetic testing procedures are very cost-intensive<ref name="PMID22723007"/>. Generally the sustained implantation predictive value of screening of PBs is significantly lower than of, for example, biopsies of the blastocyst stage<ref name="PMID25106935"/>. Moreover, it is often difficult to distinguish between the first and the second PB. As the first one degenerates quicker, this may influence diagnostic procedures<ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
===Blastomere biopsy===<br />
Day 3 <br />
====Description====<br />
Blastomere biopsy has been the prevalent method for PGD and PGS in the last two decades. In 2013 the ESHRE reported 79.8% of biopsies to be performed at the cleavage stage<ref name= "Traeger-Synodinos, J., Coonen, E., Goossens, V., De Mouzon, J., Shenfield, F., Ruiz, A., ... & de Mouzon, J. (2013). Session 09: ESHRE data reporting on PGD cycles and oocyte donation."/>. At least one, but up to two, blastomeres are biopsied on day three of the cleavage stage embryo. The right number of blastomeres removed is a controversial topic as two cells allow for more genetic material and more accurate results. However, removing two cells might be too invasive and damaging to the embryo. As PGS tries to improve implantation rates, whereas PGD sets out to avoid known genetic disorders, for the former only one cell is removed, while for the latter often two need to be removed, to ensure results as correct as possible<ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
====Procedure====<br />
Initially a hole was drilled into the zona pellucida using acid Tyrode's solution or by mechanical means. Nowadays the zona pellucida is largely opened using a laser and calcium and magnesium free media have been introduced to decrease junctions between blastomeres, which facilitates the biopsy. This if followed by the consequent aspiration of blastomeres with a pipette.<ref name="PMID21748341"/>. The blastomeres can also be removed by applying pressure on the outside of the zona<ref name="PMID26237262"/>. <br />
[[File:Aspiration_of_a_Blastomere.jpeg|thumb|400px|Aspiration of a Blastomere into the biopsy pipette<ref name=" PMID24783200"><pubmed>24783200</pubmed></ref>.]]<br />
{|class="wikitable"align="left" <br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=TbridWVwipI</html5media><br />
|-<br />
| Laser-assisted blastomere biopsy<ref>Sukprasert, M. (2014, March 5) Day 3 Blastomere Biopsy 1 [Video file]. Retrieved from https://www.youtube.com/watch?v=TbridWVwipI</ref><br />
|}<br />
====Advantages & Disadvantages====<br />
Blastomere biopsy is limited by the presence of embryo mosaicism, which can severely influence the interpretation of the genetic analysis. Approximately 15%-80% of all embryos display mosaicism on day three. Thus, any results might be a misrepresentation of the embryo as a whole. However, if good quality embryos are selected, the procedure overall is safe and does not negatively influence the embryos transition to the blastocyst stage. In a typical IVF cycle, however, not all embryos are of good quality, particularly if they have undergone cryopreservation. Studies have found that in these embryos biopsies reduce implantation rates by 12.5%-25%. Furthermore, unlike PB biopsy, the cells at the blastomere stage contain both paternal and maternal contribution, giving the genetic analysis a fuller perspective on the embryo's genetic make up. Since blastomere biopsy is performed at the third day after fertilization, it is possible complete fresh embryo transfer. Thus, no storage procedures, such as cryopreservation, are necessary<ref name="PMID26237262"/>. <br />
===Trophectoderm biopsy===<br />
Day 5 and 6<br />
====Description====<br />
The improvement of embryo culture media allowed the in vitro development of human embryos until the blastocyst stage and opened up the possibility to take blastocyst biopsies. While currently according to ESHRE datasets only about 2.3% of biopsies are performed at the blastomere stage<ref name= "Traeger-Synodinos, J., Coonen, E., Goossens, V., De Mouzon, J., Shenfield, F., Ruiz, A., ... & de Mouzon, J. (2013). Session 09: ESHRE data reporting on PGD cycles and oocyte donation."/>. During day three to day five the haploid maternal and paternal genomes come together for the first time to form the genome of the embryo. The maternal epigenetic control lessens significantly while preparing for implantation with precisely arranged events happening. The first event includes a rapid increase in the number of embryonic cells which are active in mitotic divisions and apoptosis of aberrant cells. This is followed by the formation of blastocoel (cavitation) which results from the flattening of cell located on the outside of the blastomere. Now the blastocyst will expand until the embryo hatches by rupturing the zona pellucida. The cells of the blastocyst will differentiate to form two distinct cell lineages, the outer trophectoderm and the inner cell mass<ref name="PMID22723007"/>. <br />
====Procedure====<br />
Trophectoderm biopsy is usually performed in Hepes buffered biopsy medium and opening approaches include needle cutting which has been replaced by lasers in past years. Different research groups report different timings of the opening to be the most successful. Some open the blastocyst on day three or four by creating a 25 µm which causes the trophectoderm to herniate through this hole and is, thus, accessible for biopsy. Others create this hole about four hours before biopsy which allows sufficient herniation of trophectoderm cells. It is also possible to open the blastocyst immediately before biopsy. This avoids an extra step and the inner cell mass usually is easy to locate. Blastocyst biopsies involve the removal of trophectoderm cells and the ideal time for the procedure is day five. Successful biopsies on day six have been performed, while little is known about the results of biopsies on day seven. However, since the window of implantation in humans is from day eight to ten after ovulation, day seven biopsies appear to be possible<ref name="PMID22723007"/>.[[File:Microscopic images of human blastocysts for biopsy.jpeg|thumb|300px|(A) Some trophectoderm cells in a blastocyst started to hatch and (B) the trophectoderm cells were biopsied with assisted laser cutting. Images in C–D show the blastocysts after vitrification and warming. Blastocysts had been cultured for 2–4 hrs after warming, showing good (ICM and trophectoderm cells) hatched (C) and hatching (D) blastocysts. The hatching blastocyst in (E) has good ICM but fair trophectoderm while the blastocyst in (F) has both fair ICM and trophectoderm. Arrows indicate ICMs and arrow heads indicate trophectoderm cells. Bar = 40 µm<ref name="PMID2190846"><pubmed>2190846</pubmed></ref>.]]<br />
{|class="wikitable"align="left"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JI_TQ8d8tNM</html5media><br />
|-<br />
| Laser-assisted blastocyst biopsy (at 00:50 min)<ref>Coco, R. (2014, April 30) Trophectoderm biopsy in a Hatching blastocyst protruding ICM [Video file]. Retrieved from https://www.youtube.com/watch?v=JI_TQ8d8tNM</ref><br />
|}<br />
====Advantages & Disadvantages====<br />
Blastocyst biopsies are believed to be less damaging to the embryo and appear to be unrelated to implantation rates. In addition, this biopsy method allows for a larger extraction of cells for genetic testing. However, since they are performed late in in vitro development, the time window for genetic testing is relatively small. Fast and accurate genetic testing methods are needed to ensure a successful and safe result from this biopsy. Thus, blastocyst biopsies may gain more popularity in the future when such methods have been developed or improved<ref name="PMID22723007"/>. Furthermore, the extraction of multiple cells may lessen the effects of mosaicism and problems during PCR, such as ADO. Studies comparing the implantation rate and screening accuracy have found that blastocysts are significantly safer. Blastocyst biopsies decrease implantation rates significantly, while biopsies at day five or six do not seem to influence implantation and delivery rates<ref name="PMID26237262"/>.<br />
==Genetic Techniques==<br />
===Polymerase Chain Reaction===<br />
PCR amplifies DNA specific to genetic sequence of interest . PCR was developed by Kay Mullis in the 1980's, for which he was awarded the Nobel prize for chemistry in 1993 <Ref name= "Pubmed Docs (2015) Polymerase Chain Reaction (PCR) Pubmed."> Pubmed Docs (2015) Polymerase Chain Reaction (PCR) Pubmed. Retrieved from [http://www.ncbi.nlm.nih.gov/probe/docs/techpcr/]</ref>. This technique enables clinicians to monitor and diagnose diseases using minute samples such as embryonic cells <ref>Roche (2015) PCR: How We Copy DNA. Roche Molecular Systems Inc. retrieved From [http://molecular.roche.com/pcr/Pages/Process.aspx]</ref>. PCR is used to detect genetic disorders, as a part of PGD, in conjunction with IVF<ref name="PMID24301057"><pubmed>24301057</pubmed></ref>. It is used to detect molecular abnormalities, such as single gene disorders including Tay Sach, Cycstic fibrosis, Duchenne Muscular Dystrophy, Thalassemia, Huntington disease, Spinal muscular atrophy and many more. Molecular and genetic analysis require a significant amount of DNA, which can be delivered by PCR. It revolutionized the study of DNA, replacing all previous recombinant DNA technology and is a significant component of PGD procedures<ref name="PMID24907939"/>.<br />
[[File:PCR.jpg|450px|thumb|PCR amplifies DNA specific to genetic sequence of interest, enabling the monitoring and diagnose molecular abnormalities such as single gene disorders using minute samples such as embryonic cells, blood & tissue <ref name="NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute">NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref>]]<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="7" |'''Advantages'''<br />
|-bgcolor="FFFAFA"<br />
| Fast and inexpensive way of copying a target sequence of DNA. <ref Name="PMID24301057"><pubmed>24301057</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Particularly useful for the diagnosis of single cell defects.<ref name="NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute">NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref><br />
|-bgcolor="FFFAFA"<br />
| Rapid generation of results (within hours).<ref name="NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute">NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref>]<br />
|-bgcolor="FFFAFA"<br />
| Highly sensitive, a single molecule of DNA is sufficient for reaction.<br />
|-bgcolor="FFFAFA"<br />
| Generates DNA copies exponentially. <br />
|-bgcolor="FFFAFA"<br />
| This enables DNA amplification required for molecular and genetic diagnostic analysis<ref> Dreesen, J., Drusedaul, M., Smeets, H., Die-Smulders, C., Coonen, E., Dumoulin, J., Gielen, M., Evers, J., Herbergers, J. & Geradets, J. (2008) Validation of preimplantation genetic diagnosis by PCR analysis: genotype comparison of the blastomere and corresponding embryo, implications for clinical practice. Mol. Hum. Reprod. 14 (10):573-579.doi: 10.1093/molehr/gan052. Retrieved from [http://molehr.oxfordjournals.org/content/14/10/573.short] </ref> <ref><pubmed>20966460</pubmed></ref>.<br />
|-bgcolor="DDCEF2"<br />
| rowspan="7"|'''Disadvantages'''<br />
|-bgcolor="FFFAFA"<br />
| Only during the exponential DNA replication phase, the starting quantity sequence contained in the original sample (template DNA strand) can be determined.<br />
|-bgcolor="FFFAFA"<br />
| PCR reaction is limited to by presence of inhibitors in the sample.<Ref name= "Pubmed Docs (2015) Polymerase Chain Reaction (PCR) Pubmed."> Pubmed Docs (2015) Polymerase Chain Reaction (PCR) Pubmed. Retrieved from [http://www.ncbi.nlm.nih.gov/probe/docs/techpcr/]</ref><br />
|-bgcolor="FFFAFA"<br />
| Self annealing due to the accumulation of the product and the stopping exponential amplification for the target sequence and reaching of a plateau<br />
quantification of the end point of reaction of PCR products make real time quantitative RT-PCR necessary<ref name="NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute">NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref>.<br />
|-bgcolor="FFFAFA"<br />
| Not a diagnostic method on its own, but requires further analysis.<br />
|-bgcolor="FFFAFA"<br />
|Low-quantity DNA template may result in amplification failure<ref name="PMID24907939"/>.<br />
|-bgcolor="FFFAFA"<br />
|Allele drop-out (ADO) in heterozygous loci is possible<ref name="PMID24907939"/>.<br />
|}<br />
====Procedure====<br />
Samples are obtained from the the blastocyst, a polar body biopsy or the blastomeres stages of the embryo. <br />
*Stage 1 Denaturing: separating the target strands of DNA <br />
The obtained sample is heated to roughly 90 degrees celcius, this heat breaks the relatively weak bonds between nucleotides that form DNA. The double stranded DNA is split into two single strands of DNA that are used as templates.<br />
*Stage 2 Annealing: Binding the Primers to the target DNA sequence <ref name="PMID25250056"><pubmed>25250056</pubmed></ref><br />
PCR will only copy the target sequence of DNA specified by specific PCR primer. These synthesized primers oligonucleotides are small artificial pieces of DNA. TAQ polymerase enzyme synthesize two new strands of DNA duplicate to the single sample DNA stand template indicated by these primers. During this stage the reaction is cooled to a temperature between 40-60 degrees Celsius. <br />
*Stage 3- Extension- making copies <br />
Each of these two copies are then used again as templates generating two further replications This cycle can occur as many 30 -40 times within a couple hours leading to billions of extra copies of the original DNA segment. Generally the optimal temperature for the further replication is roughly 72 degrees Celsius, although, this may vary according to the analysis machines used. <ref name="PMID26092180"><pubmed>26092180</pubmed></ref><br />
This process mediated by a thermocycler machine that is programmed to alter the temperature of the reaction every couple of minutes, perpetuating the cycle of DNA denaturing and synthesis. <br />
This process, generates exponentially exact copies of the original template DNA sequence, as visible in the expandable table below. <ref> Mullins, K., Francois, F.& Gibbs R.A. (1994 ) The Polymerase Chain Reaction. p3. Springer- Science +Business Media. Birkhauser, Boston<br />
Available at [https://books.google.com.au/books?hl=en&lr=&id=gjrTBwAAQBAJ&oi=fnd&pg=PR5&dq=kary+mullis+PCR&ots=mpzAyRh5ZY&sig=PQ4goNoKJ90tb3-MkPk62zrTGbw#v=onepage&q=kary%20mullis%20PCR&f=false] </ref><br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
! colspan="2" | PCR cycles<br />
|-<br />
| '''PCR Cycle'''<br />
| '''Target Copies'''<br />
|-<br />
| 1<br />
| 2<br />
|-<br />
| 2<br />
| 4<br />
|-<br />
| 3<br />
| 8<br />
|-<br />
| 4<br />
| 16<br />
|-"<br />
| 5 <br />
| 32<br />
|-<br />
| 6 <br />
| 64<br />
|-<br />
| 7 <br />
| 128<br />
|-<br />
| 8<br />
| 256<br />
|- <br />
| 9<br />
| 512 <br />
|-<br />
| 10<br />
| 1024<br />
|-<br />
| 15<br />
| 32,768<br />
|-<br />
| 20 <br />
| 1,048,578<br />
|-<br />
| 25<br />
| 33,554,432<br />
|-<br />
| 30 <br />
| 1,073,741,842<br />
|-<br />
|}<br />
===Fluorescent In Situ Hybridisation===<br />
FISH is the one of the most effective and rapid <ref name="PMID26338801"><pubmed>26338801</pubmed></ref> method as part of PGD. This technique locates a specific DNA sequences within a chromosome. FISH facilitates the clinical diagnosis of chromosomal abnormalities indicated by sequential duplications, deletions and rearrangements of chromosome, that are usually missed with microscopic analysis. This technique is especially relevant for female embryos with X-linked diseases<ref name="PMID20809319"><pubmed>20809319</pubmed></ref>. As part of PGD, it enabled the screening for aneuploidies and increased live birth rates in women with advanced age<ref name="PMID24907939"/> <ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. FISH is 99% effective when used in conjunction with competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities<ref name="PMID26338801"/>. <br />
[[File:Fluorescent In Situ Hybridisation (FISH).jpg|thumb|450px|right|'''FISH''' Specific DNA sequences using probes which have been tagged with fluorescent labels are visualised.This technique enables the clinical diagnosis of chromosomal abnormalities, indicated by sequential duplication, deletions and rearrangements of chromosome <ref name="NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute">NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref>]]<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="5" |'''Advantages''' <br />
|-bgcolor="FFFAFA" <br />
| FISH is 99% effective when used in conjunction with CGH to diagnose chromosomal abnormalities<ref name="PMID26338801"><pubmed>26338801</pubmed></ref>.<br />
|-bgcolor="FFFAFA" <br />
| Results are rapidly generated. <ref name="NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute">NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref><br />
|-bgcolor="FFFAFA"<br />
| Very small translocations and aneuploidies that occur within chromosomes, that would usually be missed under microscopic analysis, can be identified<ref name="Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd)">Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref>.<br />
|-bgcolor="FFFAFA" <br />
| The most common chromosomal abnormalities, such as down syndrome chromosomes 13,16,18,21 and 22<ref><pubmed>21749752</pubmed></ref>, and inheritable X-linked disease or sex chromosome anomalies such as Duchenne's Muscular Dystrophy, hemophilia, ectodermal dysplasia<ref><pubmed>17876073</pubmed></ref> can be identified.<br />
|-bgcolor="DDCEF2"<br />
| rowspan="5"|'''Disadvantages'''<br />
|-bgcolor="FFFAFA" <br />
| FISH destroys all cells tested <ref> O'Connor, C. (2008) Fluorescence in situ hybridization (FISH). Nature Education 1(1):171. retrieved from [http://www.nature.com/scitable/topicpage/fluorescence-in-situ-hybridization-fish-327] </ref>.<br />
|-bgcolor="FFFAFA" <br />
| It does not fully access all chromosomes (only ~ 12)<ref name="PMID24907939"/>.<br />
|-bgcolor="FFFAFA" <br />
| The analysis of results is dependent upon the dot quality impacted by hybridisation efficiency or the camera sensitivity<ref name="PMID17970921"><pubmed>17970921</pubmed></ref>.<br />
|-bgcolor="FFFAFA" <br />
| Some studies indicate that using FISH on a day-3 embryo biopsy decreases the rate of live births<ref><pubmed>26168107</pubmed></ref>.<br />
|}<br />
====Procedure====<br />
Samples collected from the embryo<ref name="PMID21748341"><pubmed>21748341</pubmed></ref> are collected, processed, and its DNA strands are heated and denatured causing their the individual DNA strands to break apart. Then, probes of single complimentary stands of DNA a that have been tagged with small chemical agents that glow brightly in the presence of a specific region on a chromosome are added. These specific probes then hybridize and join to their complementary DNA strand. The fluorescent tags enable the correct identification of the presence or lack thereof and location of specific chromosomes that are tested for<ref name="PMID17876073"><pubmed>17876073</pubmed></ref>. The number and the relative location of the fluorescent dots generated by the FISH images is analysed and gives rise to diagnosis<ref name="PMID17970921"><pubmed>17970921</pubmed></ref>. The probe will not fully hybridise if there has been a duplication or a deletion of the DNA - indicating chromosomal and sex chromosomal anomalies like trisomies and aneuploidies. <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref>. Different probes are used for different purposes <ref>Unique, Rare Chromosome Disorder Support Group (2013) Fluorescence in situ hybridisation (FISH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/Other/FISH%20FTNW.pdf]</ref>:<br />
*'''Locus specific tags''' detect very small imbalances, and locate isolated small portions <br />
of genes within a chromosome<br />
*'''Alphoid/Centomeric Repeat probes''' are developed from the repetitive sequence located in the middle region of each chromosome, useful in determining the number of chromosomes , detecting rearrangement and when used in conjunction with locus probes to determine the absence of genetic material on a chromosome. <br />
*'''Paint Probes''' are collections of smaller probes with their own stains that bind to a different section on the chromosome - allowing the full chromosome too be labeled a unique colour, this "full colour map" can be used to know the spectral karyotype- full chromosomal mapping is useful in examining chromosomal abnormalities. <br />
===Array Comparative Genomic Hybridisation (aCGH)===<br />
[[File:aCGH.jpg|thumb|500px|right|'''aCGH''' checks the entire genome for chromosomal imbalances, by comparing control and a sample slides contatining small segements of DNA sample microarrayed slides small segments of DNA. Illustrated by student z5020317 and adapted from <ref> NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation. retrieved from [http://www.phgfoundation.org/file/5237/]</ref> <ref name="Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45"> Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432] </ref>]]<br />
aCGH also known as Microarray analysis efficiently scans the entire genome for chromosomal imbalances. CGH was initially developed to detect the number of changes in a solid tumor mass. It uses 2 genomes comparing the sample to the control, with each labeled in a different fluorescent dye<ref name="PMID1876176"><pubmed>1876176</pubmed></ref>. Earlier CGH techniques were limited by the resolution of the imaging <ref> Lichter, P., et al. Comparative genomic hybridization: Uses and limitations. Seminars in Hematology 37, 348–357 (2000)</ref>, these initial limitations were overcome by using Microarrays in conjunction with CGh to improve the resolution of the imaging, Array Comparative Genomic Hybridisation (aCGH). This method compares sample and control microarrayed slides containing small segments of DNA (probes). <ref> Lucito, R., et al. Representational oligonucleotide microarray analysis: A high-resolution method to detect genome copy number variation. Genome Research 13, 2291–2305 (2003) </ref> the Probes used will vary according from the small (25-85 base pairs) oligonucleotides manufactured to highlight different target sequences, to the very large genomic clones (80,000- 200,00 base pairs), and as these are significantly smaller than the traditional metaphase chromosomes used for CGH, generating a higher resolution of image. <ref name="PMID22467166"><pubmed>22467166</pubmed></ref>.aCGH is used as a diagnostic tool for prenatal detection f chromosomal abnormalities <ref name="PMID19012303"><pubmed>19012303</pubmed></ref>.<br />
{|class="wikitable" align="center"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="12" |'''Advantages''' <br />
|-bgcolor="FFFAFA"<br />
| Multiple applications: prenatal genetic diagnosis, cancer diagnosis, <ref name="PMID20193845"><pubmed>20193845</pubmed></ref> genetic screening for developmental delay (learning disabilities) <ref name="PMID17309648"><pubmed>17309648</pubmed></ref>. or congenital anomalies that are suspected to be genetic in origin <ref>NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation . retrieved from [http://www.phgfoundation.org/file/5237/]</ref><br />
|-bgcolor="FFFAFA"<br />
| trace represents all chromosomes present in the human genome chromosomes 1-22 and the X & Y chromosomes, and therefore is the most accurate method for testing whole embryo aneuploidy<br />
|-bgcolor="FFFAFA"<br />
| aCGH has been extensively tested, and Validated, and is now used world wide.<br />
|-bgcolor="FFFAFA"<br />
| Detects submicroscopic alterations<br />
|-bgcolor="FFFAFA"<br />
| Detects deletions and additions and rearrangements as well as amplification, of the WHOLE genome, simultaneously.<br />
|-bgcolor="FFFAFA"<br />
| Used as a diagnostic tool for prenatal detection of chromosomal abnormalities <ref name="PMID22034057"><pubmed>22034057</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Provides high resolution genomewide screening of segmental genomic copy number variations<br />
|-bgcolor="FFFAFA"<br />
| Very accurate when used in conjunction with FISH<br />
|-bgcolor="FFFAFA"<br />
| Alone is more reliable and in detecting chromosomal abnormalities, with a higher implantation success rate, than FISH <ref name="PMID20494259"><pubmed>20494259</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Allows an in depth research focus upon specific types of rearrangements within selected chromosomal regions, a recent particular area of interest is subtelomeric and pericentromeric rearrangements<br />
|-bgcolor="FFFAFA"<br />
| Reduces the risk of failed implantation and miscarriage, improving the chance of a healthy baby <ref name="Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd)">Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref>><br />
|-bgcolor="DDCEF2"<br />
| rowspan="9" |'''Disadvantages'''<br />
|-bgcolor="FFFAFA"<br />
| Translocations and inversions of DNA are not detected<br />
|-bgcolor="FFFAFA"<br />
| Limited ability diagnosing specific polyploidies such as triploidy <ref> Unique, Rare Chromosome Disorder Support Group (2013) Microarray-based Comparative Genomic Hybridiation (array CGH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/other/array%20cgh%20ftnw.pdf] </ref><br />
|-bgcolor="FFFAFA"<br />
| Will not detect mosaicism detection <20% (cultures where >1 of 5 cells are trisomy 12)<br />
|-bgcolor="FFFAFA"<br />
| Will not detect balanced chromosomal rearrangement<br />
|-bgcolor="FFFAFA"<br />
| Will not detect duplications or deletions <80kb<br />
|-bgcolor="FFFAFA"<br />
| Will not detect point mutations within genes <ref>Washington department of education (CGH- FAQ for physicians. Signature Genomic LAboratories, LLC. Retrieved from [https://depts.washington.edu/dbpeds/Lab%20Tests/SignatureCGH-physician_FAQ.pdf]</ref><br />
|-bgcolor="FFFAFA"<br />
| will not detect chromosomal position of genomic gains<br />
|-bgcolor="FFFAFA"<br />
| Will not detect loos of heterozygosity (LOH) or Absence of heterozygosity (AOH) <ref>WiCell Research Institute Inc. (2012) Comparative Genomic Hybridization Microarray. <br />
retrieved from [http://www.wicell.org/home/cytogenetic-services/cgh-microarray/array-comparative-genomic-hybridization-acgh.cmsx]</ref><br />
|}<br />
====Procedure==== <br />
As a part of PGD fetal cell samples are collected from; the fertilized egg polar bodies, the blastomere (day 3 embryo) or the blastocyst/tropoectoderm stage (day 5 embryo).<br />
Sample DNA is labeled with one fluorescent dye, and the control DNA is labeled with a different colored fluorescent dye. the control DNA is used as the base point of reference. <br />
heated and denatured single DNA strands then hybridize to their complementary single strand probes, which are then combined and applied to a microarray and the results are run through a computer program and a digital imaging system is used to quantify the results( fluorescent intensities of the labeled probes)<ref name="Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45"> Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432] </ref>. <br />
The fluorescent ratio and the hybridization signal at different locations on the genome of the control DNA are used to identify any variances present in the sample DNA. aCGH facilitates the clinical diagnosis of submicroscopic chromosomal duplication, deletion and rearrangements indicative of chromosomal disorders such as trisomies 1-22 and specific sex linked disorders. <br />
Duplication in the DNA are displayed by the computer program as spikes/ peaks over an established threshold and deletions in DNA are displayed by the computer program as spikes/ toughs beneath this threshold. <br />
===Next Generation Sequencing===<br />
The development and advances within ART in the past 20 years, as well as the increasing popularity of IVF, has lead to an influx of new technologies developed to screen embryos for chromosomal anomalies, which are covered by the umbrella term of Next generation Sequencing (NGS). NGS is a general term used to describe all of the new and emerging screening techniques currently being introduced and used as part of PGD for IVF. NGS screens for single gene disorders as well as conducting extensive and very comprehensive chromosome diagnosis by sequencing, counting, and accurately assembling millions of DNA reads, simultaneously<ref name="PMID23499002"><pubmed>23499002</pubmed></ref>. NGS is expected to replace the other limited and outdated testing techniques and be used as the standard test in the future. <br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="13" |'''Advantages''' <br />
|-bgcolor="FFFAFA" <br />
| Cost effective <ref name="PMID23620651"><pubmed>23620651</pubmed></ref> <ref name="PMID3219767"><pubmed>3219767</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Accurately tests the whole genome <ref name="PMID23560931"><pubmed>23560931</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Tests for the presence of monogenic diseases of known genetic background.<ref name="PMID23499002"><pubmed>23499002</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Reduces the number of biopsies required for diagnosis.<br />
|-bgcolor="FFFAFA"<br />
| Higher detection rate of small translocations is possible.<ref name="PMID3725031"><pubmed>3725031</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Testing for compound point mutations, chromosomal duplication, deletions and insertions is highly accurate<ref name="PMID23312231"><pubmed>23312231</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| It accurately detects chromosomal aneuploidy and unbalanced rearrangement<ref name="PMID25685330"><pubmed>25685330</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| NGS single gene disorder screenings can be conducted in conjunction with PCR comprehensive chromosomal screening<ref name="PMID23312231"><pubmed>23312231</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| Human error is reduced.<br />
|-bgcolor="FFFAFA"<br />
| It detects the presence of mosaicism better.<br />
|-bgcolor="FFFAFA"<br />
| Work well in conjunction with CGH and aCGH as part of PGD, improving the chances of IVF. <ref> Morris, R. S. (2015 ) Next generation sequencing for PCG|PGS|CCS. IVF1 retrieved from [http://www.ivf1.com/next-generation-sequencing for-pgd] </ref><br />
|-bgcolor="DDCEF2"<br />
| rowspan="3"|'''Disadvantages''' <br />
|-bgcolor="FFFAFA"<br />
| There are limited information available to clinical applications of NGS <ref name="PMID26100406"><pubmed>26100406</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| More research and progress needed to establish a clinical manifestation<ref name="PMID24907939"/>.<br />
|}<br />
====Procedure====<br />
Samples are collected from either blastomere or the blastocyst/tropoectoderm and processed for analysis by a computer system. <br />
The methodology of each process is unique to the technique being used. The popularity of the new and emerging techniques is due to the cost effective nature of their testing, their speed and the accuracy of their results<ref name="PMID18576944"><pubmed>18576944</pubmed> </ref><ref name="PMID23620651"><pubmed>23620651</pubmed></ref>. Please see the table above for advantages of NGS.<br />
==Diagnosis==<br />
[[File:ACGH tracing after trophectoderm biopsy.jpeg|thumb|450px|Array comparative genomic hybridization (aCGH) tracing after trophectoderm biopsy: (a) normal male embryo (female embryo control in blue); (b) female embryo with monosomy for chromosome 20 (male control in red); (c) an excellent quality blastocyst showing chaotic chromosome abnormalities. Nearly every chromosome is aneuploidy<ref name="PMID26237262"/>.]]<br />
There are a large amount of diseases that PGD can apply to, below are descriptions of the diseases that PGD are more commonly used for. Upon completion of the genetic testing for the genes of concern the cells the embryos are discarded and priority is given to those that are healthy. <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/><br />
===Cystic Fibrosis===<br />
Cystic fibrosis is a single gene disorder. It is autosomal recessive and involves mutations in the cystic fibrosis transmembrane conductance regulator (CTFR) gene. The CTFR gene is normally responsible for the decrease in chloride and the transport of bicarbonate in epithelial cells thus playing a major physiological role. In PGD procedures, identification of the gene is assisted by microsatellite markers that have similar composition to the CTFR gene itself. Biopsy of two cells at the blastocyst stage is recommended if markers are not available. There are many variations of cystic fibrosis the most common being P.Phe508del <ref name="PMID26014425"><pubmed>26014425</pubmed></ref>.<br />
<br />
===Autosomal Recessive Meckel-Gruber Syndrome===<br />
Autosomal recessive genetic defect caused by the TMEM67 gene. It results in cystic dysplasia of the kidneys with fibrotic change in the liber and occipital encephalocele. Other malformations could also be present in the central nervous system. In PGD whole genome amplification of single blastomeres are taken to identify the gene, this is also coupled with PCR techniques. Maternal plasma can also be extracted for PGS. <ref><pubmed>24039893</pubmed></ref> <br />
===β – Thalassemia=== <br />
β – Thalassemia is known as the most common type of autosomal recessive inherited disorder among haemoglobinopathies. It involves the adult β-globin gene and is associated with the absent or decreased expression of the gene. This is commonly caused by a single nucleotide change in the gene. PGD has been used successfully worldwide to identify the β-globin gene where its application is usually performed on a single blastomere or polar body <ref name="PMID19064120"><pubmed>19064120</pubmed></ref>.<br />
<br />
In the collapsible table is a list of diseases and their corresponding genes. These genes are tested for in PGD for the identification of a specific disease. Note that not all the diseases applicable to PGD are listed. Some of the genes listed also have a link attached to them which will bring you to the Online Mendelian Inheritance in Man website which provides extensive information about that particular gene. This web site can be accessed when you click [[http://www.omim.org/ here]] if you would like to find out more about any of the other genes. <br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
! colspan="2" | Applicable diseases for PGD <ref>Genoma Group (2014). Retrieved September 18th, 2015, from http://www.preimplantationgeneticdiagnosis.it/genetic-diseases-diagnosed-by-pgd.htm </ref> <ref>Genesis Genetics (2015). Retrieved September 18th, 2015, from http://genesisgenetics.org/pgd/what-we-test-for/</ref> <ref>Human Fertilisation & Embryology Authority (2015). Retrieved Septembr 18th, 2015, from http://guide.hfea.gov.uk/pgd/</ref><br />
|-<br />
| '''Disease'''<br />
| '''Involved Genes'''<br />
|-<br />
| 5 Alpha Reductase Deficiency (5ARD)<br />
| SRD5A2 [http://www.omim.org/entry/607306]<br />
|-<br />
| Achondroplasia<br />
|FGFR3 [http://www.omim.org/entry/134934]<br />
|-<br />
| Acute Intermittent Porphyria <br />
| ALAD [http://www.omim.org/entry/125270] , ALAS2 [http://www.omim.org/entry/612732], CPOX [http://www.omim.org/entry/612386], FECH [http://www.omim.org/entry/612386], HMBS [http://www.omim.org/entry/609806], PPOX [http://www.omim.org/entry/600923], UROD [http://www.omim.org/entry/613521], or UROS [http://www.omim.org/entry/606938]<br />
|-<br />
| Adrenoleukodystrophy (Adrenomyeloneuropathy)<br />
| ABCD1 [http://www.omim.org/entry/300371]<br />
|-<br />
| Agammaglobulinaemia (x-linked) <br />
|BTK [http://www.omim.org/entry/300300]<br />
|-<br />
| Agammaglobulinemia Bruton Tyrosine Kinase (BTK) <br />
|BTK [http://www.omim.org/entry/300300]<br />
|-<br />
| Aicardi Goutieres Syndrome 1 (AGS1) <br />
|TREX1 [http://www.omim.org/entry/606609] , RNASEH2A [http://www.omim.org/entry/606034] , RNASEH2B [http://www.omim.org/entry/610326] , RNASEH2C [http://www.omim.org/entry/610330], SAMHD1 [http://www.omim.org/entry/606754]<br />
|-<br />
| Alagille Syndrome<br />
|JAG1 [http://www.omim.org/entry/601920] or NOTCH2<br />
|- <br />
| Alpers-Huttenlocher Syndrome <br />
|POLG [http://www.omim.org/entry/174763]<br />
|-<br />
| Alpha-1-antitrypsin deficiency <br />
|SERPINA1 [http://www.omim.org/entry/107400]<br />
|-<br />
| Alpha-Mannosidosis<br />
| MAN2B1[http://www.omim.org/entry/609458]<br />
|-<br />
| Alpha Thalassemia <br />
|HBA1[http://www.omim.org/entry/141800]or HBA2 [http://www.omim.org/entry/141850] <br />
|-<br />
| Alports Syndrome<br />
|COL4A3 [http://www.omim.org/entry/120070] , COL4A4 [http://www.omim.org/entry/120131] , COL4A5 [http://www.omim.org/entry/303630]<br />
|-<br />
| Alzheimer's Disease - early onset (Type 3 and 4) <br />
|APP [http://www.omim.org/entry/104760] , PSEN1 [http://www.omim.org/entry/104311], or PSEN2 [http://www.omim.org/entry/600759] <br />
|-<br />
| Amyotrophic Lateral Sclerosis 1 (ALS1) <br />
| C9orf72 [http://www.omim.org/entry/614260], SOD1 [http://www.omim.org/entry/147450], TARDBP [http://www.omim.org/entry/605078], FUS [http://www.omim.org/entry/137070], ANG [http://www.omim.org/entry/105850] , ALS2 [http://www.omim.org/entry/205100], SETX [http://www.omim.org/entry/608465], VAPB [http://www.omim.org/entry/605704]<br />
|-<br />
| Argininosuccinic Aciduria <br />
| ASL [http://www.omim.org/entry/608310]<br />
|-<br />
| Arrhythmogenic Right Ventricular Cardiomyopathy/ Dysplasia (ARVC/D)<br />
| DSG2 [http://www.omim.org/entry/125671]; DSP [http://www.omim.org/entry/125647] ; PKP2 [http://www.omim.org/entry/602861]<br />
|-<br />
| Ataxia Telangiectasia<br />
| ATM [http://www.omim.org/entry/607585]<br />
|-<br />
| Autosomal Recessive Meckel-Gruber Syndrome<br />
| TMEM67 [http://www.omim.org/entry/609884]<br />
|-<br />
| Bardet-Biedl Syndrome (BBS)<br />
| BBS1 [http://www.omim.org/entry/209901]; BBS10 [http://www.omim.org/entry/610148]<br />
|-<br />
| Barth Syndrome<br />
| TAZ [http://www.omim.org/entry/300394]<br />
|-<br />
| Beta Thalassaemia<br />
| HBB [http://www.omim.org/entry/141900]<br />
|-<br />
| Birt-Hogg-Dubé Syndrome<br />
| FLCN<br />
|-<br />
| Breast Ovarian Cancer Familial Susceptibility (BRCA2)<br />
| BRCA1; BRCA2<br />
|-<br />
| Canavan Disease <br />
| ASPA<br />
|-<br />
| Carnitine-Acylcarnitine Translocase Deficiency <br />
| SLC25A20<br />
|-<br />
| Cerebral Arteriopathy with Subcortical Infarcts & Leukoencephalopathy (CADASIL)<br />
| NOTCH3<br />
|-<br />
| Cerebral Cavernous Malformation<br />
| CCM1<br />
|-<br />
| Charcot-Marie-Tooth Disease<br />
| GJB1; MPZ; NEFL; PMP22<br />
|-<br />
| CHARGE Syndrome<br />
| CHD7<br />
|-<br />
| Cherubism<br />
| SH3BP2<br />
|-<br />
| Choroideremia<br />
| CHM<br />
|-<br />
| Chronic Granulomatous Disease<br />
| CYBB; NCF1<br />
|-<br />
| Ciliary Dyskinesia<br />
| DNAH5<br />
|-<br />
| Citrullinemia<br />
| ASS1<br />
|-<br />
| Cleidocranial Dysplasia<br />
| RUNX2<br />
|-<br />
| Cockayne Syndrome<br />
| ERCC6<br />
|-<br />
| Congenital Adrenal Hyperplasia<br />
| CYP21A2<br />
|-<br />
| Congenital Cataracts<br />
| GJA8; VSX2<br />
|-<br />
| Congenital Diarrhea, Syndromic<br />
| SPINT2<br />
|-<br />
| Congenital Disorders of Glycosylation (CDG)<br />
| ALG1; ALG6; CDG1C; DOLK; PMM2<br />
|-<br />
| Cornelia de Lange Syndrome <br />
| NIPBL<br />
|-<br />
| Craniosynostosis<br />
| TWIST1<br />
|-<br />
| Crouzon Syndrome<br />
| FGFR2<br />
|-<br />
| Cysteinyl Leukotriene Receptor 1 Deficiency <br />
| CYSLTR1<br />
|-<br />
| Cystic Fibrosis<br />
| CFTR<br />
|-<br />
| Diamond –Blackfan Anemia <br />
| RPS19<br />
|-<br />
| Duchenne Muscular Dystrophy <br />
| DMD<br />
|-<br />
| Dyskeratosis congenita (Male embryos only)<br />
| DKC1<br />
|-<br />
| Ectodermal dysplasia (Hypohidrotic)<br />
| EDA; EDA1; GJB6; IKBKG<br />
|-<br />
| Familial Adenomatous polyposis coli (FAP)<br />
| APC<br />
|-<br />
| Familial Dysautonomia<br />
| IKBKAP<br />
|-<br />
| Fanconi Anemia <br />
| FANCA; FANCC; FANCD2; FANCF; FANCG; FANCJ<br />
|-<br />
| Fragile X Syndrome (FRAX)<br />
| FMR1<br />
|-<br />
| Galactosemia <br />
| GALT<br />
|-<br />
| Gangliosidosis<br />
| GLB1<br />
|-<br />
| Glanzmann Thrombasthenia <br />
| ITGA2B<br />
|-<br />
| Glutaric Acidemia (aciduria)<br />
| GCDH <br />
|-<br />
| Glycogen Storage Disease <br />
| G6PC; GAA; SLC37A4<br />
|-<br />
| Haemophilia A<br />
| F8<br />
|-<br />
| Haemophilia B<br />
| F9<br />
|-<br />
| Hereditary Nonpolyposis Colorectal Cancer: Lynch Syndrome<br />
| MLH1; MSH2; MSH6<br />
|-<br />
| Holt Oram Syndrome<br />
| TBX5<br />
|-<br />
| Huntington Disease<br />
| HD<br />
|-<br />
| Hydrocephalus<br />
| L1CAM<br />
|-<br />
| Ichthyosis <br />
| ABCA12; STS<br />
|-<br />
| Incontinentia Pigmenti (IP)<br />
| NEMO<br />
|-<br />
| Joubert Syndrome 5<br />
| INPP5E<br />
|-<br />
| Krabbe Disease<br />
| GALC<br />
|-<br />
| Leber Congenital Amaurosis (LCA)<br />
| CEP290; GUCY2D<br />
|-<br />
| Leigh Syndrome (Infantile Subacute Necrotising Encephalopathy)<br />
| LRPPRC<br />
|-<br />
| Lesch Nyan Syndrome<br />
| HPRT1<br />
|-<br />
| Leukocyte Adhesion Deficiency (Type I)<br />
| ITGB2<br />
|-<br />
| Li-Fraumeni Syndrome<br />
| TP53<br />
|-<br />
| Macular Dystrophy Retinal <br />
| VMD2<br />
|-<br />
| Maple Syrup Urine Disorder (MSUD)<br />
| BCKDHB<br />
|-<br />
| Marfan Syndrome <br />
| FBN1<br />
|-<br />
| Menkes Syndrome<br />
| ATP7A<br />
|-<br />
| Mitochondrial DNA Depletion Syndrom <br />
| POLG; RRM2B; SUCLA2; TK2<br />
|-<br />
| Mucolipidosis type II<br />
| GNPTAB<br />
|-<br />
| Multiple Endocrine Neoplasia<br />
| MEN1; MEN2A; MEN2B<br />
|-<br />
| Multiple Exostoses<br />
| EXT1; EXT2 <br />
|-<br />
| Myotubular myopathy<br />
| MTM1 <br />
|-<br />
| Nail-Patella Syndrome<br />
| LMX1B<br />
|-<br />
| Neurofibromatosis Type 1<br />
| NF1<br />
|-<br />
| Neurofibromatosis Type 2 <br />
| NF2<br />
|-<br />
| Noonan Syndrome<br />
| KRAS, PTPN11; SOS1<br />
|-<br />
| Norrie Disease<br />
| NDP<br />
|-<br />
| Ocular Albinism <br />
| GPR143<br />
|-<br />
| Oculocutaneous Albinism <br />
| OCA2; TYR <br />
|-<br />
| Oculodentaldigital Dysplasia<br />
| GJA1<br />
|-<br />
| Optic Atrophy<br />
| OPA1<br />
|-<br />
| Ornithine Transcarbamylase Deficiency <br />
| OTC<br />
|-<br />
| Osteogenesis imperfeca <br />
| COL1A1; COL1A2<br />
|-<br />
| Osteopetrosis <br />
| CLCN7; OSTM1; TCIRG1<br />
|-<br />
| Pachyonychia Congenita <br />
| KRT16; KRT6A<br />
|-<br />
| Pancreatitis, Hereditary<br />
| PRSS1 <br />
|-<br />
| Papillorenal syndrome <br />
| PAX2<br />
|-<br />
| Phenylketonuria <br />
| PAH <br />
|-<br />
|}<br />
==Laws & Legal status==<br />
{| class="wikitable" <br />
|-bgcolor="DDCEF2"<br />
|'''Country'''<br />
|'''Legislation'''<br />
|-bgcolor="FFFAFA" <br />
| Australia<br />
| PGD is currently used to detect serious genetic conditions to improve the outcome of ART. In very rare cases it may be used to select an embryo with compatible tissue for a sibling who has a life-threatening disease where other means of treatment is unavailable. This is with the conditions that the use of PGD will not affect the welfare and interests of the child to be born. The parents must also receive adequate counselling and have full understanding of the procedures of PGD. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"> National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art</ref><br />
The use of PGD for sex-selection is prohibited with the exception of reducing the risk of the transmission of serious sex-linked genetic conditions. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"/><br />
|-bgcolor="FFFAFA"<br />
| Brazil<br />
| The laws regarding PGD in Brazil are not strictly regulated. They are vague and there is limited information surround the activities of assisted reproduction in general in the country <ref name="PMID25493379"><pubmed>25493379</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| Czech Republic<br />
| The laws in the Czech Republic allow those with a “defined indication in order to exclude risk of serous genetically conditioned disease and defects with embryos before they are implanted into the cavity of the uterus”. Couples that undergo any assisted reproductive treatment including PGD have to be married. Sex-selection is illegal except in regards to serious sex-linked genetic diseases <ref name="PMID24777348"><pubmed>24777348</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| Greece<br />
| In Greece, ART is open to those up to the age of 50 with written consent. It can only be used if a medical necessity is present such as the susceptibility of serious hereditary diseases. Sex selection is banned apart from cases of sex-linked diseases and sexually transmitted diseases <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| India<br />
| In India there is a cultural preference for boys thus the Prenatal Diagnostic Techniques (Regulation and Prevention of Misuse) Act was introduced in 1994. This law limits the use of PGD for sex determination except in cases of specific congenital diseases. These laws however are not strictly enforced. <ref>World Health Organisation (2015) Gender and Genetics Retrieved on October 21st 2015 from:http://www.who.int/genomics/gender/en/index4.html</ref><br />
|-bgcolor="FFFAFA"<br />
| Portugal <br />
| ART is only available to those who are married or have a similar type of relationship for at least two years. The couples cannot be of the same sex and must be at least 18 years of age. Sex selection is illegal except in cases of sex-linked diseases. The use of PGD is illegal if the predictive value of genetic tests are very low <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| Spain<br />
| PGD can be applied to “serious hereditary diseases not amenable to postnatal curative treatment” and “detection of other abnormalities which may compromise the viability of the pre-embryo”. If PGD is to be used for any other purpose authorisation must be acquired <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| Sweden <br />
| The use of PGD is strictly regulated and couples must achieve authorisation of the National Board of Health and Welfare. It can only be used it can only be used if the child is at risk to inheriting a serious chromosomal or monogenetic disease. It cannot be used for selection of specific characteristics <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| United Kingdom<br />
| Those involved with carrying out the IVF treatment must have a license from the Human Fertilisation and Embryology Authority (HFEA). Only embryos that are approved by the HFEA can be implanted where the embryonic nuclear or mitochondrial DNA cannot be altered with the exception of preventing mitochondrial diseases <ref name="PMID24777348"/>. <br />
|}<br />
==Future/Current Research==<br />
In addition to research efforts for improving overall performance of established PGD/S techniques, such as finding the ideal zona pellucida insection site in an fully automatic manner<ref name="PMID26259216"><pubmed>26259216</pubmed></ref>, many research efforts have been spent to find alternative, non-invasive techniques to test for diseases and abnormalities<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
===Non-invasive Preimplantation Genetic Testing without Embryo Biopsy===<br />
Different parameters of gametes, zygotes, embryos (“vacuoles in sperm heads, spindle position in mature oocytes, cleavage intervals of zygote, and embryo developmental dynamics”) may correlate with aneuploidy rates. This knowledge may be applied in potential noninvasive preimplantation diagnostic methods. Several methods have been proposed and are currently further researched<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Sperm Selection====<br />
Intracytoplasmic morphologically selected sperm injection (IMSI) is common procedure in IVF treatment to improve fertilization rates in patients with poor semen quality. In addition, studies have found that IMSI improves embryo development and that spermatozoa with large vacuoles in their heads correlate with increased aneuploidy rates and disturbed chromosomal structures. Thus, selecting spermatozoa based on morphological hallmarks may decrease aneuploidy rates in the fertilized embryos. As with polar body biopsies, however, this approach will solely be applicable if evidence for severe male detrimental contribution is given<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Blastocoel Fluid Extraction====<br />
In addition, a less invasive retrieval of material for diagnosis could include the extraction of the blastocoel fluid. The cavity of the blastocyst, lined by the trophectoderm, is filled with this blastocoel fluid, which contains metabolites of both trophectoderm and inner cell mass origin. The retrieval does not require a biopsy but merely a small opening to extract the fluid and, thus, causes less harm to the embryo. Multiple studies have applied this method<ref name="PMID22020776"><pubmed>22020776</pubmed></ref> <ref name="PMID23148560"><pubmed>23148560</pubmed></ref> <ref name="PMID26006737"><pubmed>26006737</pubmed></ref> and it may in the future become of clinical relevance.[[File:Aspiration_of_the_Blastocoel_Fluid.jpeg|400px|thumb|Aspiration of the Blastocoel Fluid using a ICSI pipette<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.]]Next to metabolites, the blastocoel fluid can contain DNA. Studies have shown that genomic DNA is present in about 90% of the blastocoel fluid samples tested. Typically the fluid is removed with an ICSI pipette from a day five blastocyst through its mural trophectoderm until the blastocyst fully collapses around the embryo. Several concerns regarding this method in a clinical setting have been raised. The collected DNA may be contaminated by the culture media that contains DNA fractions. The DNA may also be least representative of the actual embryos genome as the DNA may originate from abnormal or degenerated cells. Even though labelled noninvasive, the blastocyst still undergoes manipulation to some degree which may affect its viability. Thus, more research is required until this method can evolve from research to clinical use<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
====Proteomics and Medium Based PGD====<br />
The media in which embryos are kept during the early IVF procedures, gives rise to potential non-invasive techniques. For instance, the protein secretome of blastocysts may be representative of its chromosome constitution Recent studies have found biomarkers such as lipocalin-1, interleukin-10, tumor necrosis factor, stem cell factor, and chemokine ligand 13 to be differently secreted by aneuploid blastocyst than by euploid ones. The most significant biomarker appears to be interleukin-10. Paired with novel proteomic technologies and mass spectrometry this knowledge when extended may contribute to a new invasive PGD method<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. In addition, medium based non-invasive PGD has been researched for the diagnose of human α-thalassemia-SEA. Genomic DNA was collected from the media and the study surprisingly resulted in increased diagnosis efficacy compared to biopsy-based methods<ref name="PMID25816038"><pubmed>25816038</pubmed></ref>.<br />
====Embryo Morphology====<br />
Using time lapse imaging the embryo’s morphology can be closely observed and potential aneuploidy characteristics detected. Such characteristics may include the time of division to five cells, the time between the division from three to four cells, and the duration of the division from one to two and subsequently to three. In addition, the morphological quality of ICM an TE has been positively associated with aneuploidy or euploidy prognosis<ref name="PMID26246880"><pubmed>26246880</pubmed></ref>. These may give rise to an embryo quality screening prior to implantation<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
==Glossary==<br />
'''Allele:''' One of two or more versions of a gene<br />
<br />
'''Aneuploidy:''' Presence of an abnormal number of chromosomes in a cell <br />
<br />
'''Biopsy:''' Sample of tissue taken for examination <br />
<br />
'''Blastocyst:''' Stage of embryo at approximately day 5 consisting of an outer (trophoblast) layer and inner (embryoblast) cell mass.<br />
<br />
'''Blastomere:''' Cell type formed through cleavage of the zygote after fertilization<br />
<br />
'''Chromosome''' Thread-like structure, which is made up of protein and DNA, within the nucleus of a cell<br />
<br />
'''CTFR:''' Cystic Fibrosis Transmembrane Conductance Regulator, responsible for transport of chloride across the cell membrane<br />
<br />
'''Denaturing:''' Proteins or nucleic acids lose their quaternary, tertiary, and secondary structure <br />
<br />
'''DNA:''' DeoxyriboNucleic Acid, hereditary material<br />
<br />
'''Endometriosis:''' Condition in which the endometrium, the tissue lining the uterus, grows outside of it<br />
<br />
'''Enucleation:''' Removal of the nucleus<br />
<br />
'''Epigenetic:''' Phenotypic trait variations due to external or environmental factors that influence gene expression<br />
<br />
'''ESHRE:''' European Society of Human Reproduction and Embryology<br />
<br />
'''FISH:''' Fluorescent In situ Hybridisation, technique used to locate specific gene sequences using fluorescence tags <br />
<br />
'''Heterozygote:''' Diploid organism that contains two different alleles of one gene<br />
<br />
'''Hydrosalphinx:''' Fluid filled fallopian tube <br />
<br />
'''Intracytoplasmic Morphologically Selected Sperm Injection (IMSI):''' IVF technique involving morphological selection of sperm under the microscope to be injected to oocyte<br />
<br />
'''Intracytoplasmic Sperm Injection (ICSI):''' IVF technique used to treat male infertility and involves direct injection of one sperm into an oocyte<br />
<br />
'''IVF:''' In Vitro Fertilisation<br />
<br />
'''Leukocyte:''' White blood cell, involved in immune system<br />
<br />
'''Leukaemia:''' Cancer of the bone marrow, increased numbers of abnormal or premature leukocytes are formed by bone marrow and other organs <br />
<br />
'''NGS:''' Next Generation Sequencing, term used to describe the collection of recent findings regarding embryo screening<br />
<br />
'''Oolemma''': Plasma membrane of the oocyte <br />
<br />
'''PB:''' Polar Body, cell formed during the meiotic stages of the oocyte containing extra genetic material<br />
<br />
'''PCR:''' Polymerase Chain Reaction, technique used to amplify DNA to study a specific genetic sequence<br />
<br />
'''Polyploidy:''' Having more than two sets of homologous chromosomes <br />
<br />
'''PGD:''' Preimplantation Genetic Diagnosis, genetic testing conducted to identify abnormalities in an embryo before implantation in parents with genetic disease history<br />
<br />
'''PGS:''' Preimplantation Genetic Screening, similar to PGS but in couples seeking IVF due to infertility issues to improve implantation rates<br />
<br />
'''Perivitelline Space:''' Space between the oolemma and the zona pellucida <br />
<br />
'''RT:''' Robertsonian Translocations, a type of structural chromosomal translocation <br />
<br />
'''Trisomies:''' Presence of three copies of a chromosome instead of two<br />
<br />
'''Trophoectoderm:''' Outer layer of the mammalian blastocyst<br />
<br />
'''Zona Pellucida:''' Thick membrane surrounding the mammalian oocyte <br />
<br />
<br />
==References==<br />
<br />
<references/><br />
<br />
<br />
{{StudentPage2015}}</div>Z5017878https://embryology.med.unsw.edu.au/embryology/index.php?title=2015_Group_Project_6&diff=2086092015 Group Project 62015-10-23T12:18:28Z<p>Z5017878: </p>
<hr />
<div>{{ANAT2341Project2015header}}<br />
<br />
<br />
=Preimplantation Genetic Diagnosis and Preimplantation Genetic Screening=<br />
==Introduction==<br />
Preimplantation genetic diagnosis (PGD) and preimplantation genetic screening (PGS) are reproductive options for couples with known family histories of genetic disease or couples undergoing IVF procedures due to infertility issues. PGD can diagnose many genetic disorders caused by known chromosomal abnormalities (number and/or structure) or single gene mutations, and, thus decrease the risk of termination of pregnancy or miscarriages and enable such couples to have an unaffected child<ref name="PMID24907939"><pubmed>24907939</pubmed></ref>. Through major improvements in PGD/S and general laboratory technology, the testing for abnormalities in fetuses has shifted from prenatal diagnosis during the first 2 trimesters <ref> Blackburn, S.L. (2003) '''Maternal, Fetal & Neonatal physiology: a Clinical perspective''' (2nd ed.). Seattle: Saudners </ref>, testing for overall fetal growth, complications of pregnancy, and birth defects<ref> Sadler T.W.(2012) '''Langman's Medical Embryology''' (12th ed.) Philadelphia: Lipincott, Wiliams & Wilkins, a Wolters Kluwer Business </ref>, to an embryonic focus especially in advancements in Artificial Reproductive Technologies (ART)<ref><pubmed>20638568</pubmed></ref>. In 1990 PGD for a recessive X-linked disease resulted in the first live birth<ref><pubmed>2330030</pubmed></ref> and has since been incorporated in clinical routine and applied for a variety of genetic diseases, such as sickle cell anemia, thalassemia, or cystic fibrosis<ref name="PMID24907939"/>.<br />
[[File:Preimplantation Genetic Diagnosis Procedure.jpeg|600px|left|thumb| Simplified steps for PGD<ref name="PMID24907939"/>]]<br />
{|class="wikitable"align="right" <br />
| <html5media height="400" width="533">https://www.youtube.com/watch?v=0e-79qKllqk</html5media><br />
|-<br />
| Preimplantation Genetic Diagnosis<ref>IVF Florida (2011, December 11) IVF Florida - South Florida Fertility Specialists - Pre-Implantation Genetic Diagnosis [Video file]. Retrieved from https://www.youtube.com/watch?v=0e-79qKllqk</ref><br />
|}<br />
==History==<br />
The advances in reproductive technology during the second half of the 20th century, led to PGD's first clinical application in 1990 <ref>Harper, J. (n.d.). The history of PGD. Lecture. UCL Centre for PG&D and CRGH.University College London</ref>.<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
|Year<br />
|<br />
|- bgcolor="FFFAFA"<br />
| '''1967''' <br />
|First PGD on rabbit blastocysts (Gardner& Edwards) <ref name="PMID6036172"><pubmed>6036172</pubmed></ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1986''' <br />
|First Cleavage Biopsy (Wilton & Trounson)<ref>Wilton, L. J., & Trounson, A. O. (1986). Viability of mouse embryos and blastomeres following biopsy of a single cell. In Proceedings of the 18th Annual Conference of the Australian Society for Reproductive Biology, Brisbane, Australia.</ref><br />
|- bgcolor="FFFAFA"<br />
|'''1987''' <br />
|First Blastocyst Biopsy (Muggleton-Harris, Monk, Rawlings, & Whittingham)<ref name="PMID3372699"><pubmed>3372699</pubmed></ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1988''' <br />
|First Polar Body Biopsy (Yury Verlinksy)<ref> Verlinsky, Y., Pergament, E., Andresen, P., Enriquez, G., & Strom, C. (1989). Genetic analysis of polar body DNA: A new approach to preimplantation genetic diagnosis. Am J Hum Genet, 45(4), A272.</ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1990''' <br />
|First Clinical PGD using PCR testing for X-linked (Handyside, Kontogianni, Hardy, & Winston)<ref name="PMID2330030"><pubmed>2330030</pubmed></ref> <br />
|} <br />
==Preimplantation Genetic Diagnosis==<br />
[[File:Pre-PGD workup.jpeg|thumb|400px|Pre-PGD workup for a family with a previous child with spinal muscular atrophy. Panel (a) shows how the study of both parents and grandparents allows the phasing of the SMN mutation relative to polymorphic short tandem repeat (STR) markers; panel (b) shows the maternal and paternal haplotypes M1, M2, P1 and P2 and the distance of the STR markers from the SMN gene; panel (c) shows the four predicted fetal haplotypes. These reflect a Hardy–Weinberg equilibrium of one homozygous non-carrier, two heterozygous carriers and one that is homozygous and affected. Short tandem repeat markers linked with the SMN mutation are shown in red. DEL indicates the presense of the exon 7 (840 C>T) mutation<ref name="PMID26237262"/>.]]<br />
PGD is used to test the genetic makeup of embryos to detect single gene disorders, chromosomal abnormalities and mitochondrial disorders. It also has applications in gender selection for diseases with unequal gender distributions <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Some diseases commonly involved with PGD include cystic fibrosis, spinal muscular atrophy and beta – thalassaemia <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press.">Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press</ref> <ref name="PMID17823145"><pubmed>17823145</pubmed></ref>. It was first used in the United Kingdom in the 1980s, primarily focusing on sex- linked disorders <ref name="PMID17823145"/><ref name="PMID23150080"><pubmed>23150080</pubmed></ref>. PGD is now capable of detecting single cell defects (molecular) and chromosomal disorders resulting from the inversion, translocation or deletion of chromosomes (cytogenic) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/> <ref name="PMID11325751"><pubmed>11325751</pubmed></ref>. PGD can be applied to the embryo at different stages. That is on polar bodies, blastomeres or blastocyst <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>.<br />
Depending on the type of genetic disorder, PGD utilises different methods of genetic testing. These include Fluorescence in situ hybridisation (FISH) which is used for sex – linked disorders and detects chromosomal rearrangements <ref name="PMID11325751"/><ref name="PMID17876073"><pubmed>17876073</pubmed></ref> and Embryo halotyping which allows the identification of chromosomes causing the inherited disorder through knowledge of the pattern of closely linked markers <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. Polymerase chain reaction (PCR) is also widely used to detect molecular abnormalities <ref name="PMID11325751"/>.<br />
PGD is tightly regulated and supported by large organisations namely The American Society for Reproductive Medicine, The European Society for Human Reproduction and Embryology (ESHRE), The European Society of Human Genetics and the Preimplantation Genetic Diagnosis International Society <ref name="PMID25500181><pubmed>25500181</pubmed></ref>.<br />
===Sex-linked disorders===<br />
The determination of a disease as gender specific usually correlates with the presence or absence of specific genes such as SRY on the Y chromosome. It is known that females have two X chromosomes and males have an X and a Y chromosome where abnormalities are more prevalent on the X chromosome. PGD can be used for sex selection where only male embryos are transferred to reduce the chance of inheriting X-linked disorders. However, this does not completely eradicate the problem as male embryos remain susceptible to inheriting an affected X chromosome. Sex determination is only used when the specific mutation is unknown and has yet to be discovered <ref name="PMID24866878"><pubmed>24866878</pubmed></ref>.<br />
===Single gene defects===<br />
Single gene defects can be dominant, recessive, autosomal or X-linked. They are commonly diagnosed using PCR and although the PCR available today is complex and capable of combatting a large range of disease the development of new protocols has been proven to be difficult due to the small DNA sample available <ref name="PMID26168107"><pubmed>26168107</pubmed></ref>.<br />
===Mitochondrial disorders===<br />
Mitochondrial disorders also known as oxidative phosphorylation disorders arise from mutations in the nuclear DNA or mitochondrial DNA <ref name="PMID26312584"><pubmed>26312584</pubmed></ref>. They pose as a problem because they are unrecognisable until the mutations in the cell reach a detrimental level <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Mitochondrial disorders cause miscarriages and stillbirths as well as death in children and young adults. The effects can either be contained in a single organ or more commonly involve multiple organ failure where organs with high energy demands such as the brain, liver muscle and heart and heavily influenced. They are usually occur spontaneously or result from inheritance from the mother. Since mitochondria are solely inherited from the mother oocyte donations have been used as a solution to combat mitochondrial disorders. Additionally, there has been an increasing use in PGD where embryos that stay under the given threshold of 18% gene-mutations are allowed to be transferred and result in normal development. New technology in the areas of nuclear gene transfer and genome editing are also being experimented with <ref name="PMID26312584"/>. <br />
===Chromosomal disorders===<br />
Chromosomal disorders can be reciprocal, Robertsonian translocations, inversions, deletions and insertions <ref name="PMID26168107"/>. Data from ESHRE collected between 2010 and 2011 has shown that the most common chromosomal abnormality confronted in PGD are reciprocal chromosomal abnormalities <ref name"PMID26071418"><pubmed>26071418</pubmed></ref>. PGD has also been used successfully for Robertsonian translocations (RT), a type of structural translocation. Children who carry RT are phenotypically normal, however in their later years it is found that they will suffer from infertility and repeated miscarriages due to the high frequency of abnormal embryos <ref name="PMID22081077"><pubmed>22081077</pubmed></ref>. PCR and FISH are the two main techniques used for chromosomal disorders. To be able to conduct the examinations the cells are required to be at the metaphase stage <ref name="PMID26168107"/>. <br />
[[File:Reasons_for_PGD.jpg|600px|thumb|Reasons for PGD<ref name="PMID24764761"><pubmed><24764761</pubmed></ref>]]<br />
==Preimplantation Genetic Screening==<br />
PGS involves an array of methods or ideas that aim to segregate embryos that have genetic flaws and those that are healthy <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. The occurrence of aneuploidy is high around the stages of early embryonic development and they are the most common cause if miscarriages and congenital birth defects <ref name= "PMID26085841"><pubmed>26085841</pubmed></ref>. They have little effect on the morphology of the embryo making them difficult to identify thus identification heavily relies on genetic testing <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. <br />
Genetic sampling is most commonly conducted using Microarray Comparative Genomic Hybridisation (aCGH) as well as FISH, Quantitative PCR and Single Nucleotide Polymorphism (SNP) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. These methods collectively aim to assess numeral and structural chromosomal errors <ref name= "PMID26085841"/>. Studies have also introduced Next- Generation Sequencing (NGS) <ref name= "PMID26085841"/> and Whole Genome Amplification used to screen imbalances in the complete 24-chromosomes <ref name="PMID25953353"><pubmed>25953353</pubmed></ref>.<br />
Statistics from ESHRE have shown that the most common indications for PGS is advanced age, followed by repeated implantation failure or recurrent miscarriage and male infertility <ref name="PMID26071418"><pubmed>26071418</pubmed></ref>.<br />
===Indications===<br />
A low percentage of structural abnormalities in chromosomes are responsible for the cause of miscarriages. Despite this, they are the most prevalent type of chromosomal abnormality accounted for in PGD <ref name="PMID20638568"/>. The presence of specific gene cycles, initiation of embryonic protein synthesis and evident physiological development are all indicative of a successful in vitro fertilisation procedure <ref name="PMID11576737"><pubmed>11576737</pubmed></ref>. To eliminate further errors from occurring during the PGD procedure it is recommended to undertake further prenatal testing such as amniocentesis in the later stages <ref name="PMID20638568"/>. <br />
====Advanced maternal age====<br />
Data provided by the ESHRE has shown that the mean age of women undergoing PGS is 39 years <ref name="PMID26071418"/>. Women of advanced age have been shown to have a lower rate of pregnancies reaching childbirth <ref name="PMID18583331"><pubmed>18583331</pubmed></ref>. The highlighted concern revolves around the increased occurrence of aneuploidy following maternal age. The optimal age range for the lowest aneuploidy incidence was found to be between 27 to 37 years of age (6%) then progressively higher in women aged up to 42 (33%) and most common in those 44 and above (53%) <ref name="PMID24355045"><pubmed>24355045</pubmed></ref>. <br />
====Recurrent pregnancy loss / IVF failure====<br />
Recurrent pregnancy loss is defined as three or more IVF failures after cumulative transfer of more than 10 good-quality embryos. These are primarily caused by two main factors, reduced endometrium receptivity or embryonic defects. Endometrium receptivity can be negatively influences by instances including uterine pathologies such as thin endometrium, altered expression of adhesive molecules and immunological factors. Additionally, embryonic defects may be due to genetic abnormalities, embryonic aneuploidy or zona hardening. Endometriosis and hydrosalpinx has been known to effect both the endometrium and embryo <ref name="PMID23260857"><pubmed>23260857</pubmed></ref>.<br />
====Human leukocyte antigen matching====<br />
First used in 2001, HLA matching is an option given to parents to save a child with haematological or immunological disease through conceiving another child who would potentially be able to donate cord blood or haematopoietic stem cells from the bone marrow for transplantation. The process namely PGD-HLA has shown to improve haematopoietic stem cell transplant (HSCT). PGD-HLA can only be performed when HSCT is not needed urgently due to the time needed to conceive and delivery the baby <ref name="PMID25500181"><pubmed>25500181</pubmed></ref>. It is most commonly applied to children suffering from relapsed leukaemia <ref name="PMID22524201"><pubmed>22524201</pubmed></ref>. In a case study PGD-HLA was proven to successfully cure 10 diseases including Fanconi anaemia, Diamond-Blackfan anaemia and beta thalassemia <ref name="PMID25066893><pubmed>25066893</pubmed></ref>.<br />
==Biopsy Methods==<br />
Biopsy, the removal of genetic materials, from oocytes or embryos in the preimplantation stage is the primary step in PGD. For the past two decades these biopsies have been performed at three stages, the polar body, blastomere, and blastocyst, and the methodologies optimized to ensure the embryo’s viability. The most common approach involves biopsies at the cleavage stage. However, polar body and blastocyst biopsies are increasingly more often tested and applied. Approached for opening the zona pellucida involve next to the traditional mechanical and chemical means, novel approaches such as noncontact lasers. Their application may simplify and secure the procedure significantly. The most challenging question about PGD procedures remains at what stage biopsies should be taken. Much controversy has developed around this topic, highlighting the varying disadvantages and advantages of temporal biopsies <ref name="PMID22723007"><pubmed>22723007</pubmed></ref>.<br />
[[File:Polar_Body,_Blastomere,_and_Trophectoderm_Biopsy.jpeg|500px|thumb|Polar body (A), blastomere (B) and trophectoderm (C) biopsies<ref name="PMID25625041"><pubmed>25625041</pubmed></ref>.]]<br />
{| class="wikitable"<br />
|- align="center" bgcolor="DDCEF2"<br />
|<br />
| Time of Biopsy<br />
| Prevalence <br />
| Advantages <br />
| Disadvantages<br />
|- bgcolor="FFFAFA"<br />
| Polar Body<br />
| Day 1<br />
| ~16%<br />
| Little to no harm is caused to the oocyte and both PBs can be extracted (more genetic material)<ref name="PMID22723007"/>.<br />
| Only the maternal DNA is tested<ref name="PMID22723007"/>, often PB biopsies need to be coupled to other biopsies, and difficulties arise in distinguishing between the first and second PB<ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. Lower reliability of results compared to other biopsy methods have been reported<ref name="PMID25106935"/>. <br />
|- bgcolor="FFFAFA"<br />
| Blastomere <br />
| Day 3<br />
| ~80%<br />
| Biopsies are safe for good quality embryos and it is performed relatively early, so fresh transfer is possible, yet, it includes both paternal and maternal genetic contributions<ref name="PMID26237262"/>. <br />
| Relatively large decrease in implantation rates for low quality embryos have been reported, embryo mosaicism can influence genetic analysis, and only one to two cells can be safely removed<ref name="PMID26237262"/>. <br />
|- bgcolor="FFFAFA"<br />
| Trophectoderm<br />
| Day 5 and 6 <br />
| ~ 2%<br />
| Little harm to the embryo and large amount of genetic material can be extracted, which allows for more accurate genetic analysis and lessen effects of mosaicism<ref name="PMID26237262"/>. <br />
| The biopsy takes place relatively late and, thus, the time window for procedure is small and embryos often need to be cryopreserved<ref name="PMID22723007"/>. <br />
|}<br />
===Polar Body Analysis===<br />
Day 1<br />
====Description====<br />
[[File:Polar_Body_Biopsy.jpeg|thumb|400px|The presence of a faint but clearly identifiable strand connecting PB2 to the oolemma. The biopsy was performed ∼9 h after ICSI<ref name="PMID21908464"><pubmed>21908464</pubmed></ref>.]] <br />
Polar body (PB) biopsy offers a promising alternative to biopsies performed at the blastomere stage for PGD/S indications on legal and practical grounds<ref name="PMID22723007"/>. The ESHRE calculated the proportion of PB biopsies to be about 16.3%<ref name= "Traeger-Synodinos, J., Coonen, E., Goossens, V., De Mouzon, J., Shenfield, F., Ruiz, A., ... & de Mouzon, J. (2013). Session 09: ESHRE data reporting on PGD cycles and oocyte donation.">Human Reproduction, 28(suppl 1), i18-i19. </ref>. Embryo development does not necessitate the presence of the first and second PB and their removal may not be crucial<ref name="PMID22723007"/>. The idea behind PB biopsies is that each abnormality found in the PB corresponds to an error in the oocyte. On the other hand, in women with known single gene mutations, it is assumed that if the PB contains the mutated allele ,the oocyte will have the normal allele, thus, resulting in a healthy embryo<ref name="PMID26237262"/>. PB biopsy requires precise timing. Keeping track of the meiotic cell cycle is necessary to perform a successful biopsy and, therefore, PB biopsy usually is applied in combination with intracytoplasmic sperm injection (ICSI). During the maturation from the germinal vesicle stage to the metaphase-II stage the first PB is formed. A cytoplasmic bridge containing spindle remnants, that are still in contact with the cellular genetic material, links this PB to the oolemma for about 90 minutes after extrusion. It is possible to visualize these remnants by polarization microscopy and it is crucial to not perform the biopsy until the first PB is no longer firmly attached to the oolemma as this indicates an immature embryo.The oocyte tolerates mechanical zona dissection best during hours four until six after ICSI as the oolemma has stabilized by that time because of the cortical granule reaction. Over time the first PB degenerates stressing a temporal biopsy and its optimal extraction time window is four to 12 hours after ICSI. The second PB forms around two to four hours after ICSI. Its optimal time window for biopsy is set to be eight to 16 hours after ICSI due to the second PB being attached to the oolemma with spindle remnants until six hours after ICSI. Biopsy at this point may cause enucleation of the oocyte. Studies have shown that the amplification efficiency of second PB’s DNA is worse if the PB is extracted prior to eight hours after ICSI. Thus, it is possible to perform sequential and simultaneous biopsies for the first and second PB. If performed, sequentially the first PB may be removed four to 12 hours and the second PB eight to 16 hours after ICSI. The optimal time window for a biopsy for both the first and second PB simultaneously is eight to 12 hours after ICSI. It is highly preferred to analyze both PBs due to potential aneuploidies in either PB and crossing overs during meiosis <ref name="PMID22723007"/>. <br />
====Procedure====<br />
Chemical opening achieved with for example acidic tyrode’s solution of the zona pellucida is not tolerated by the oocyte and may have detrimental effects on the embryo’s development. Therefore, the access to the perivitelline space of the oocyte is provided by mechanical zona dissection or by laser. Both techniques work well if performed by experienced embryologist. However, laser-assisted biopsy is less time consuming when compared to manual dissection. It is critical to consider the size of the introduced opening as it will remain permanent. If it is too large the blastomere may be lost during embryo development and if it is too small it may interfere with hatching of the embryo during blastocyst stage<ref name="PMID22723007"/>.<br />
[[File:Implantation_predictive_value_of_euploid_screening_results.jpeg|thumb|450px|The sustained implantation predictive value (with 95 % confidence interval) of a euploid screening result obtained from the first polar body (PB1), PB1 and the second polar body (PB2), or a direct embryo biopsy for each stage of embryo transfer (cleavage-stage and blastocyst stage)<ref name="PMID25106935"><pubmed>25106935</pubmed></ref>.]]<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JTaQzszVr8o</html5media><br />
|-<br />
| Laser-assisted polar body biopsy<ref>RIUK, R. (2013, June 25) Polar Body Biopsy [Video file]. Retrieved from https://www.youtube.com/watch?v=JTaQzszVr8o</ref><br />
|}<br />
====Advantages & Disadvantages====<br />
PB biopsies can only investigate the maternal contributions to the embryo as they are of maternal origin. Thus, this procedure is appropriate for PGD solely for monogenetic diseases from the maternal side. Recessive diseases may be evaluated with PB biopsies on the basis that the embryo’s outcome will be determined by the paternal contribution. It may still be applied for PGS as it is a fairly safe biopsy option and most aneuploidies either arise during meiosis or origin from the maternal genome. However, diagnosis error has been reported due to the lack of considering paternal contributions<ref name="PMID22723007"/>. About 10% of PB biopsies appear to be wrongfully diagnosed with aneuploidies<ref name="PMID26237262"><pubmed>26237262</pubmed></ref>. Because PB biopsies are performed very early it is not yet known whether the oocyte will develop into a viable embryo. Thus, PBs are commonly frozen or fixed after biopsy and depending on the state of the embryo only chosen PBs will be tested. This is primarily an economic issue as many genetic testing procedures are very cost-intensive<ref name="PMID22723007"/>. Generally the sustained implantation predictive value of screening of PBs is significantly lower than of, for example, biopsies of the blastocyst stage<ref name="PMID25106935"/>. Moreover, it is often difficult to distinguish between the first and the second PB. As the first one degenerates quicker, this may influence diagnostic procedures<ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
===Blastomere biopsy===<br />
Day 3 <br />
====Description====<br />
Blastomere biopsy has been the prevalent method for PGD and PGS in the last two decades. In 2013 the ESHRE reported 79.8% of biopsies to be performed at the cleavage stage<ref name= "Traeger-Synodinos, J., Coonen, E., Goossens, V., De Mouzon, J., Shenfield, F., Ruiz, A., ... & de Mouzon, J. (2013). Session 09: ESHRE data reporting on PGD cycles and oocyte donation."/>. At least one, but up to two, blastomeres are biopsied on day three of the cleavage stage embryo. The right number of blastomeres removed is a controversial topic as two cells allow for more genetic material and more accurate results. However, removing two cells might be too invasive and damaging to the embryo. As PGS tries to improve implantation rates, whereas PGD sets out to avoid known genetic disorders, for the former only one cell is removed, while for the latter often two need to be removed, to ensure results as correct as possible<ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
====Procedure====<br />
Initially a hole was drilled into the zona pellucida using acid Tyrode's solution or by mechanical means. Nowadays the zona pellucida is largely opened using a laser and calcium and magnesium free media have been introduced to decrease junctions between blastomeres, which facilitates the biopsy. This if followed by the consequent aspiration of blastomeres with a pipette.<ref name="PMID21748341"/>. The blastomeres can also be removed by applying pressure on the outside of the zona<ref name="PMID26237262"/>. <br />
[[File:Aspiration_of_a_Blastomere.jpeg|thumb|400px|Aspiration of a Blastomere into the biopsy pipette<ref name=" PMID24783200"><pubmed>24783200</pubmed></ref>.]]<br />
{|class="wikitable"align="left" <br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=TbridWVwipI</html5media><br />
|-<br />
| Laser-assisted blastomere biopsy<ref>Sukprasert, M. (2014, March 5) Day 3 Blastomere Biopsy 1 [Video file]. Retrieved from https://www.youtube.com/watch?v=TbridWVwipI</ref><br />
|}<br />
====Advantages & Disadvantages====<br />
Blastomere biopsy is limited by the presence of embryo mosaicism, which can severely influence the interpretation of the genetic analysis. Approximately 15%-80% of all embryos display mosaicism on day three. Thus, any results might be a misrepresentation of the embryo as a whole. However, if good quality embryos are selected, the procedure overall is safe and does not negatively influence the embryos transition to the blastocyst stage. In a typical IVF cycle, however, not all embryos are of good quality, particularly if they have undergone cryopreservation. Studies have found that in these embryos biopsies reduce implantation rates by 12.5%-25%. Furthermore, unlike PB biopsy, the cells at the blastomere stage contain both paternal and maternal contribution, giving the genetic analysis a fuller perspective on the embryo's genetic make up. Since blastomere biopsy is performed at the third day after fertilization, it is possible complete fresh embryo transfer. Thus, no storage procedures, such as cryopreservation, are necessary<ref name="PMID26237262"/>. <br />
===Trophectoderm biopsy===<br />
Day 5 and 6<br />
====Description====<br />
The improvement of embryo culture media allowed the in vitro development of human embryos until the blastocyst stage and opened up the possibility to take blastocyst biopsies. While currently according to ESHRE datasets only about 2.3% of biopsies are performed at the blastomere stage<ref name= "Traeger-Synodinos, J., Coonen, E., Goossens, V., De Mouzon, J., Shenfield, F., Ruiz, A., ... & de Mouzon, J. (2013). Session 09: ESHRE data reporting on PGD cycles and oocyte donation."/>. During day three to day five the haploid maternal and paternal genomes come together for the first time to form the genome of the embryo. The maternal epigenetic control lessens significantly while preparing for implantation with precisely arranged events happening. The first event includes a rapid increase in the number of embryonic cells which are active in mitotic divisions and apoptosis of aberrant cells. This is followed by the formation of blastocoel (cavitation) which results from the flattening of cell located on the outside of the blastomere. Now the blastocyst will expand until the embryo hatches by rupturing the zona pellucida. The cells of the blastocyst will differentiate to form two distinct cell lineages, the outer trophectoderm and the inner cell mass<ref name="PMID22723007"/>. <br />
====Procedure====<br />
Trophectoderm biopsy is usually performed in Hepes buffered biopsy medium and opening approaches include needle cutting which has been replaced by lasers in past years. Different research groups report different timings of the opening to be the most successful. Some open the blastocyst on day three or four by creating a 25 µm which causes the trophectoderm to herniate through this hole and is, thus, accessible for biopsy. Others create this hole about four hours before biopsy which allows sufficient herniation of trophectoderm cells. It is also possible to open the blastocyst immediately before biopsy. This avoids an extra step and the inner cell mass usually is easy to locate. Blastocyst biopsies involve the removal of trophectoderm cells and the ideal time for the procedure is day five. Successful biopsies on day six have been performed, while little is known about the results of biopsies on day seven. However, since the window of implantation in humans is from day eight to ten after ovulation, day seven biopsies appear to be possible<ref name="PMID22723007"/>.[[File:Microscopic images of human blastocysts for biopsy.jpeg|thumb|300px|(A) Some trophectoderm cells in a blastocyst started to hatch and (B) the trophectoderm cells were biopsied with assisted laser cutting. Images in C–D show the blastocysts after vitrification and warming. Blastocysts had been cultured for 2–4 hrs after warming, showing good (ICM and trophectoderm cells) hatched (C) and hatching (D) blastocysts. The hatching blastocyst in (E) has good ICM but fair trophectoderm while the blastocyst in (F) has both fair ICM and trophectoderm. Arrows indicate ICMs and arrow heads indicate trophectoderm cells. Bar = 40 µm<ref name="PMID2190846"><pubmed>2190846</pubmed></ref>.]]<br />
{|class="wikitable"align="left"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JI_TQ8d8tNM</html5media><br />
|-<br />
| Laser-assisted blastocyst biopsy (at 00:50 min)<ref>Coco, R. (2014, April 30) Trophectoderm biopsy in a Hatching blastocyst protruding ICM [Video file]. Retrieved from https://www.youtube.com/watch?v=JI_TQ8d8tNM</ref><br />
|}<br />
====Advantages & Disadvantages====<br />
Blastocyst biopsies are believed to be less damaging to the embryo and appear to be unrelated to implantation rates. In addition, this biopsy method allows for a larger extraction of cells for genetic testing. However, since they are performed late in in vitro development, the time window for genetic testing is relatively small. Fast and accurate genetic testing methods are needed to ensure a successful and safe result from this biopsy. Thus, blastocyst biopsies may gain more popularity in the future when such methods have been developed or improved<ref name="PMID22723007"/>. Furthermore, the extraction of multiple cells may lessen the effects of mosaicism and problems during PCR, such as ADO. Studies comparing the implantation rate and screening accuracy have found that blastocysts are significantly safer. Blastocyst biopsies decrease implantation rates significantly, while biopsies at day five or six do not seem to influence implantation and delivery rates<ref name="PMID26237262"/>.<br />
==Genetic Techniques==<br />
===Polymerase Chain Reaction===<br />
PCR amplifies DNA specific to genetic sequence of interest . PCR was developed by Kay Mullis in the 1980's, for which he was awarded the Nobel prize for chemistry in 1993 <Ref name= "Pubmed Docs (2015) Polymerase Chain Reaction (PCR) Pubmed."> Pubmed Docs (2015) Polymerase Chain Reaction (PCR) Pubmed. Retrieved from [http://www.ncbi.nlm.nih.gov/probe/docs/techpcr/]</ref>. This technique enables clinicians to monitor and diagnose diseases using minute samples such as embryonic cells <ref>Roche (2015) PCR: How We Copy DNA. Roche Molecular Systems Inc. retrieved From [http://molecular.roche.com/pcr/Pages/Process.aspx]</ref>. PCR is used to detect genetic disorders, as a part of PGD, in conjunction with IVF<ref name="PMID24301057"><pubmed>24301057</pubmed></ref>. It is used to detect molecular abnormalities, such as single gene disorders including Tay Sach, Cycstic fibrosis, Duchenne Muscular Dystrophy, Thalassemia, Huntington disease, Spinal muscular atrophy and many more. Molecular and genetic analysis require a significant amount of DNA, which can be delivered by PCR. It revolutionized the study of DNA, replacing all previous recombinant DNA technology and is a significant component of PGD procedures<ref name="PMID24907939"/>.<br />
[[File:PCR.jpg|450px|thumb|PCR amplifies DNA specific to genetic sequence of interest, enabling the monitoring and diagnose molecular abnormalities such as single gene disorders using minute samples such as embryonic cells, blood & tissue <ref name="NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute">NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref>]]<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="7" |'''Advantages'''<br />
|-bgcolor="FFFAFA"<br />
| Fast and inexpensive way of copying a target sequence of DNA. <ref Name="PMID24301057"><pubmed>24301057</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Particularly useful for the diagnosis of single cell defects.<ref name="NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute">NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref><br />
|-bgcolor="FFFAFA"<br />
| Rapid generation of results (within hours).<ref name="NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute">NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref>]<br />
|-bgcolor="FFFAFA"<br />
| Highly sensitive, a single molecule of DNA is sufficient for reaction.<br />
|-bgcolor="FFFAFA"<br />
| Generates DNA copies exponentially. <br />
|-bgcolor="FFFAFA"<br />
| This enables DNA amplification required for molecular and genetic diagnostic analysis<ref> Dreesen, J., Drusedaul, M., Smeets, H., Die-Smulders, C., Coonen, E., Dumoulin, J., Gielen, M., Evers, J., Herbergers, J. & Geradets, J. (2008) Validation of preimplantation genetic diagnosis by PCR analysis: genotype comparison of the blastomere and corresponding embryo, implications for clinical practice. Mol. Hum. Reprod. 14 (10):573-579.doi: 10.1093/molehr/gan052. Retrieved from [http://molehr.oxfordjournals.org/content/14/10/573.short] </ref> <ref><pubmed>20966460</pubmed></ref>.<br />
|-bgcolor="DDCEF2"<br />
| rowspan="7"|'''Disadvantages'''<br />
|-bgcolor="FFFAFA"<br />
| Only during the exponential DNA replication phase, the starting quantity sequence contained in the original sample (template DNA strand) can be determined.<br />
|-bgcolor="FFFAFA"<br />
| PCR reaction is limited to by presence of inhibitors in the sample.<Ref name= "Pubmed Docs (2015) Polymerase Chain Reaction (PCR) Pubmed."> Pubmed Docs (2015) Polymerase Chain Reaction (PCR) Pubmed. Retrieved from [http://www.ncbi.nlm.nih.gov/probe/docs/techpcr/]</ref><br />
|-bgcolor="FFFAFA"<br />
| Self annealing due to the accumulation of the product and the stopping exponential amplification for the target sequence and reaching of a plateau<br />
quantification of the end point of reaction of PCR products make real time quantitative RT-PCR necessary<ref name="NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute">NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref>.<br />
|-bgcolor="FFFAFA"<br />
| Not a diagnostic method on its own, but requires further analysis.<br />
|-bgcolor="FFFAFA"<br />
|Low-quantity DNA template may result in amplification failure<ref name="PMID24907939"/>.<br />
|-bgcolor="FFFAFA"<br />
|Allele drop-out (ADO) in heterozygous loci is possible<ref name="PMID24907939"/>.<br />
|}<br />
====Procedure====<br />
Samples are obtained from the the blastocyst, a polar body biopsy or the blastomeres stages of the embryo. <br />
*Stage 1 Denaturing: separating the target strands of DNA <br />
The obtained sample is heated to roughly 90 degrees celcius, this heat breaks the relatively weak bonds between nucleotides that form DNA. The double stranded DNA is split into two single strands of DNA that are used as templates.<br />
*Stage 2 Annealing: Binding the Primers to the target DNA sequence <ref name="PMID25250056"><pubmed>25250056</pubmed></ref><br />
PCR will only copy the target sequence of DNA specified by specific PCR primer. These synthesized primers oligonucleotides are small artificial pieces of DNA. TAQ polymerase enzyme synthesize two new strands of DNA duplicate to the single sample DNA stand template indicated by these primers. During this stage the reaction is cooled to a temperature between 40-60 degrees Celsius. <br />
*Stage 3- Extension- making copies <br />
Each of these two copies are then used again as templates generating two further replications This cycle can occur as many 30 -40 times within a couple hours leading to billions of extra copies of the original DNA segment. Generally the optimal temperature for the further replication is roughly 72 degrees Celsius, although, this may vary according to the analysis machines used. <ref name="PMID26092180"><pubmed>26092180</pubmed></ref><br />
This process mediated by a thermocycler machine that is programmed to alter the temperature of the reaction every couple of minutes, perpetuating the cycle of DNA denaturing and synthesis. <br />
This process, generates exponentially exact copies of the original template DNA sequence, as visible in the expandable table below. <ref> Mullins, K., Francois, F.& Gibbs R.A. (1994 ) The Polymerase Chain Reaction. p3. Springer- Science +Business Media. Birkhauser, Boston<br />
Available at [https://books.google.com.au/books?hl=en&lr=&id=gjrTBwAAQBAJ&oi=fnd&pg=PR5&dq=kary+mullis+PCR&ots=mpzAyRh5ZY&sig=PQ4goNoKJ90tb3-MkPk62zrTGbw#v=onepage&q=kary%20mullis%20PCR&f=false] </ref><br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
! colspan="2" | PCR cycles<br />
|-<br />
| '''PCR Cycle'''<br />
| '''Target Copies'''<br />
|-<br />
| 1<br />
| 2<br />
|-<br />
| 2<br />
| 4<br />
|-<br />
| 3<br />
| 8<br />
|-<br />
| 4<br />
| 16<br />
|-"<br />
| 5 <br />
| 32<br />
|-<br />
| 6 <br />
| 64<br />
|-<br />
| 7 <br />
| 128<br />
|-<br />
| 8<br />
| 256<br />
|- <br />
| 9<br />
| 512 <br />
|-<br />
| 10<br />
| 1024<br />
|-<br />
| 15<br />
| 32,768<br />
|-<br />
| 20 <br />
| 1,048,578<br />
|-<br />
| 25<br />
| 33,554,432<br />
|-<br />
| 30 <br />
| 1,073,741,842<br />
|-<br />
|}<br />
===Fluorescent In Situ Hybridisation===<br />
FISH is the one of the most effective and rapid <ref name="PMID26338801"><pubmed>26338801</pubmed></ref> method as part of PGD. This technique locates a specific DNA sequences within a chromosome. FISH facilitates the clinical diagnosis of chromosomal abnormalities indicated by sequential duplications, deletions and rearrangements of chromosome, that are usually missed with microscopic analysis. This technique is especially relevant for female embryos with X-linked diseases<ref name="PMID20809319"><pubmed>20809319</pubmed></ref>. As part of PGD, it enabled the screening for aneuploidies and increased live birth rates in women with advanced age<ref name="PMID24907939"/> <ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. FISH is 99% effective when used in conjunction with competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities<ref name="PMID26338801"/>. <br />
[[File:Fluorescent In Situ Hybridisation (FISH).jpg|thumb|450px|right|'''FISH''' Specific DNA sequences using probes which have been tagged with fluorescent labels are visualised.This technique enables the clinical diagnosis of chromosomal abnormalities, indicated by sequential duplication, deletions and rearrangements of chromosome <ref name="NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute">NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref>]]<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="5" |'''Advantages''' <br />
|-bgcolor="FFFAFA" <br />
| FISH is 99% effective when used in conjunction with CGH to diagnose chromosomal abnormalities<ref name="PMID26338801"><pubmed>26338801</pubmed></ref>.<br />
|-bgcolor="FFFAFA" <br />
| Results are rapidly generated. <ref name="NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute">NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref><br />
|-bgcolor="FFFAFA"<br />
| Very small translocations and aneuploidies that occur within chromosomes, that would usually be missed under microscopic analysis, can be identified<ref name="Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd)">Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref>.<br />
|-bgcolor="FFFAFA" <br />
| The most common chromosomal abnormalities, such as down syndrome chromosomes 13,16,18,21 and 22<ref><pubmed>21749752</pubmed></ref>, and inheritable X-linked disease or sex chromosome anomalies such as Duchenne's Muscular Dystrophy, hemophilia, ectodermal dysplasia<ref><pubmed>17876073</pubmed></ref> can be identified.<br />
|-bgcolor="DDCEF2"<br />
| rowspan="5"|'''Disadvantages'''<br />
|-bgcolor="FFFAFA" <br />
| FISH destroys all cells tested <ref> O'Connor, C. (2008) Fluorescence in situ hybridization (FISH). Nature Education 1(1):171. retrieved from [http://www.nature.com/scitable/topicpage/fluorescence-in-situ-hybridization-fish-327] </ref>.<br />
|-bgcolor="FFFAFA" <br />
| It does not fully access all chromosomes (only ~ 12)<ref name="PMID24907939"/>.<br />
|-bgcolor="FFFAFA" <br />
| The analysis of results is dependent upon the dot quality impacted by hybridisation efficiency or the camera sensitivity<ref name="PMID17970921"><pubmed>17970921</pubmed></ref>.<br />
|-bgcolor="FFFAFA" <br />
| Some studies indicate that using FISH on a day-3 embryo biopsy decreases the rate of live births<ref><pubmed>26168107</pubmed></ref>.<br />
|}<br />
====Procedure====<br />
Samples collected from the embryo<ref name="PMID21748341"><pubmed>21748341</pubmed></ref> are collected, processed, and its DNA strands are heated and denatured causing their the individual DNA strands to break apart. Then, probes of single complimentary stands of DNA a that have been tagged with small chemical agents that glow brightly in the presence of a specific region on a chromosome are added. These specific probes then hybridize and join to their complementary DNA strand. The fluorescent tags enable the correct identification of the presence or lack thereof and location of specific chromosomes that are tested for<ref name="PMID17876073"><pubmed>17876073</pubmed></ref>. The number and the relative location of the fluorescent dots generated by the FISH images is analysed and gives rise to diagnosis<ref name="PMID17970921"><pubmed>17970921</pubmed></ref>. The probe will not fully hybridise if there has been a duplication or a deletion of the DNA - indicating chromosomal and sex chromosomal anomalies like trisomies and aneuploidies. <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref>. Different probes are used for different purposes <ref>Unique, Rare Chromosome Disorder Support Group (2013) Fluorescence in situ hybridisation (FISH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/Other/FISH%20FTNW.pdf]</ref>:<br />
*'''Locus specific tags''' detect very small imbalances, and locate isolated small portions <br />
of genes within a chromosome<br />
*'''Alphoid/Centomeric Repeat probes''' are developed from the repetitive sequence located in the middle region of each chromosome, useful in determining the number of chromosomes , detecting rearrangement and when used in conjunction with locus probes to determine the absence of genetic material on a chromosome. <br />
*'''Paint Probes''' are collections of smaller probes with their own stains that bind to a different section on the chromosome - allowing the full chromosome too be labeled a unique colour, this "full colour map" can be used to know the spectral karyotype- full chromosomal mapping is useful in examining chromosomal abnormalities. <br />
===Array Comparative Genomic Hybridisation (aCGH)===<br />
[[File:aCGH.jpg|thumb|500px|right|'''aCGH''' checks the entire genome for chromosomal imbalances, by comparing control and a sample slides contatining small segements of DNA sample microarrayed slides small segments of DNA. Illustrated by student z5020317 and adapted from <ref> NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation. retrieved from [http://www.phgfoundation.org/file/5237/]</ref> <ref name="Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45"> Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432] </ref>]]<br />
aCGH also known as Microarray analysis efficiently scans the entire genome for chromosomal imbalances. CGH was initially developed to detect the number of changes in a solid tumor mass. It uses 2 genomes comparing the sample to the control, with each labeled in a different fluorescent dye<ref name="PMID1876176"><pubmed>1876176</pubmed></ref>. Earlier CGH techniques were limited by the resolution of the imaging <ref> Lichter, P., et al. Comparative genomic hybridization: Uses and limitations. Seminars in Hematology 37, 348–357 (2000)</ref>, these initial limitations were overcome by using Microarrays in conjunction with CGh to improve the resolution of the imaging, Array Comparative Genomic Hybridisation (aCGH). This method compares sample and control microarrayed slides containing small segments of DNA (probes). <ref> Lucito, R., et al. Representational oligonucleotide microarray analysis: A high-resolution method to detect genome copy number variation. Genome Research 13, 2291–2305 (2003) </ref> the Probes used will vary according from the small (25-85 base pairs) oligonucleotides manufactured to highlight different target sequences, to the very large genomic clones (80,000- 200,00 base pairs), and as these are significantly smaller than the traditional metaphase chromosomes used for CGH, generating a higher resolution of image. <ref name="PMID22467166"><pubmed>22467166</pubmed></ref>.aCGH is used as a diagnostic tool for prenatal detection f chromosomal abnormalities <ref name="PMID19012303"><pubmed>19012303</pubmed></ref>.<br />
{|class="wikitable" align="center"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="12" |'''Advantages''' <br />
|-bgcolor="FFFAFA"<br />
| Multiple applications: prenatal genetic diagnosis, cancer diagnosis, <ref name="PMID20193845"><pubmed>20193845</pubmed></ref> genetic screening for developmental delay (learning disabilities) <ref name="PMID17309648"><pubmed>17309648</pubmed></ref>. or congenital anomalies that are suspected to be genetic in origin <ref>NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation . retrieved from [http://www.phgfoundation.org/file/5237/]</ref><br />
|-bgcolor="FFFAFA"<br />
| trace represents all chromosomes present in the human genome chromosomes 1-22 and the X & Y chromosomes, and therefore is the most accurate method for testing whole embryo aneuploidy<br />
|-bgcolor="FFFAFA"<br />
| aCGH has been extensively tested, and Validated, and is now used world wide.<br />
|-bgcolor="FFFAFA"<br />
| Detects submicroscopic alterations<br />
|-bgcolor="FFFAFA"<br />
| Detects deletions and additions and rearrangements as well as amplification, of the WHOLE genome, simultaneously.<br />
|-bgcolor="FFFAFA"<br />
| Used as a diagnostic tool for prenatal detection of chromosomal abnormalities <ref name="PMID22034057"><pubmed>22034057</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Provides high resolution genomewide screening of segmental genomic copy number variations<br />
|-bgcolor="FFFAFA"<br />
| Very accurate when used in conjunction with FISH<br />
|-bgcolor="FFFAFA"<br />
| Alone is more reliable and in detecting chromosomal abnormalities, with a higher implantation success rate, than FISH <ref name="PMID20494259"><pubmed>20494259</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Allows an in depth research focus upon specific types of rearrangements within selected chromosomal regions, a recent particular area of interest is subtelomeric and pericentromeric rearrangements<br />
|-bgcolor="FFFAFA"<br />
| Reduces the risk of failed implantation and miscarriage, improving the chance of a healthy baby <ref name="Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd)">Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref>><br />
|-bgcolor="DDCEF2"<br />
| rowspan="9" |'''Disadvantages'''<br />
|-bgcolor="FFFAFA"<br />
| Translocations and inversions of DNA are not detected<br />
|-bgcolor="FFFAFA"<br />
| Limited ability diagnosing specific polyploidies such as triploidy <ref> Unique, Rare Chromosome Disorder Support Group (2013) Microarray-based Comparative Genomic Hybridiation (array CGH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/other/array%20cgh%20ftnw.pdf] </ref><br />
|-bgcolor="FFFAFA"<br />
| Will not detect mosaicism detection <20% (cultures where >1 of 5 cells are trisomy 12)<br />
|-bgcolor="FFFAFA"<br />
| Will not detect balanced chromosomal rearrangement<br />
|-bgcolor="FFFAFA"<br />
| Will not detect duplications or deletions <80kb<br />
|-bgcolor="FFFAFA"<br />
| Will not detect point mutations within genes <ref>Washington department of education (CGH- FAQ for physicians. Signature Genomic LAboratories, LLC. Retrieved from [https://depts.washington.edu/dbpeds/Lab%20Tests/SignatureCGH-physician_FAQ.pdf]</ref><br />
|-bgcolor="FFFAFA"<br />
| will not detect chromosomal position of genomic gains<br />
|-bgcolor="FFFAFA"<br />
| Will not detect loos of heterozygosity (LOH) or Absence of heterozygosity (AOH) <ref>WiCell Research Institute Inc. (2012) Comparative Genomic Hybridization Microarray. <br />
retrieved from [http://www.wicell.org/home/cytogenetic-services/cgh-microarray/array-comparative-genomic-hybridization-acgh.cmsx]</ref><br />
|}<br />
====Procedure==== <br />
As a part of PGD fetal cell samples are collected from; the fertilized egg polar bodies, the blastomere (day 3 embryo) or the blastocyst/tropoectoderm stage (day 5 embryo).<br />
Sample DNA is labeled with one fluorescent dye, and the control DNA is labeled with a different colored fluorescent dye. the control DNA is used as the base point of reference. <br />
heated and denatured single DNA strands then hybridize to their complementary single strand probes, which are then combined and applied to a microarray and the results are run through a computer program and a digital imaging system is used to quantify the results( fluorescent intensities of the labeled probes)<ref name="Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45"> Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432] </ref>. <br />
The fluorescent ratio and the hybridization signal at different locations on the genome of the control DNA are used to identify any variances present in the sample DNA. aCGH facilitates the clinical diagnosis of submicroscopic chromosomal duplication, deletion and rearrangements indicative of chromosomal disorders such as trisomies 1-22 and specific sex linked disorders. <br />
Duplication in the DNA are displayed by the computer program as spikes/ peaks over an established threshold and deletions in DNA are displayed by the computer program as spikes/ toughs beneath this threshold. <br />
===Next Generation Sequencing===<br />
The development and advances within ART in the past 20 years, as well as the increasing popularity of IVF, has lead to an influx of new technologies developed to screen embryos for chromosomal anomalies, which are covered by the umbrella term of Next generation Sequencing (NGS). NGS is a general term used to describe all of the new and emerging screening techniques currently being introduced and used as part of PGD for IVF. NGS screens for single gene disorders as well as conducting extensive and very comprehensive chromosome diagnosis by sequencing, counting, and accurately assembling millions of DNA reads, simultaneously<ref name="PMID23499002"><pubmed>23499002</pubmed></ref>. NGS is expected to replace the other limited and outdated testing techniques and be used as the standard test in the future. <br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="13" |'''Advantages''' <br />
|-bgcolor="FFFAFA" <br />
| Cost effective <ref name="PMID23620651"><pubmed>23620651</pubmed></ref> <ref name="PMID3219767"><pubmed>3219767</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Accurately tests the whole genome <ref name="PMID23560931"><pubmed>23560931</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Tests for the presence of monogenic diseases of known genetic background.<ref name="PMID23499002"><pubmed>23499002</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Reduces the number of biopsies required for diagnosis.<br />
|-bgcolor="FFFAFA"<br />
| Higher detection rate of small translocations is possible.<ref name="PMID3725031"><pubmed>3725031</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Testing for compound point mutations, chromosomal duplication, deletions and insertions is highly accurate<ref name="PMID23312231"><pubmed>23312231</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| It accurately detects chromosomal aneuploidy and unbalanced rearrangement<ref name="PMID25685330"><pubmed>25685330</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| NGS single gene disorder screenings can be conducted in conjunction with PCR comprehensive chromosomal screening<ref name="PMID23312231"><pubmed>23312231</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| Human error is reduced.<br />
|-bgcolor="FFFAFA"<br />
| It detects the presence of mosaicism better.<br />
|-bgcolor="FFFAFA"<br />
| Work well in conjunction with CGH and aCGH as part of PGD, improving the chances of IVF. <ref> Morris, R. S. (2015 ) Next generation sequencing for PCG|PGS|CCS. IVF1 retrieved from [http://www.ivf1.com/next-generation-sequencing for-pgd] </ref><br />
|-bgcolor="DDCEF2"<br />
| rowspan="3"|'''Disadvantages''' <br />
|-bgcolor="FFFAFA"<br />
| There are limited information available to clinical applications of NGS <ref name="PMID26100406"><pubmed>26100406</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| More research and progress needed to establish a clinical manifestation<ref name="PMID24907939"/>.<br />
|}<br />
====Procedure====<br />
Samples are collected from either blastomere or the blastocyst/tropoectoderm and processed for analysis by a computer system. <br />
The methodology of each process is unique to the technique being used. The popularity of the new and emerging techniques is due to the cost effective nature of their testing, their speed and the accuracy of their results<ref name="PMID18576944"><pubmed>18576944</pubmed> </ref><ref name="PMID23620651"><pubmed>23620651</pubmed></ref>. Please see the table above for advantages of NGS.<br />
==Diagnosis==<br />
[[File:ACGH tracing after trophectoderm biopsy.jpeg|thumb|450px|Array comparative genomic hybridization (aCGH) tracing after trophectoderm biopsy: (a) normal male embryo (female embryo control in blue); (b) female embryo with monosomy for chromosome 20 (male control in red); (c) an excellent quality blastocyst showing chaotic chromosome abnormalities. Nearly every chromosome is aneuploidy<ref name="PMID26237262"/>.]]<br />
There are a large amount of diseases that PGD can apply to, below are descriptions of the diseases that PGD are more commonly used for. Upon completion of the genetic testing for the genes of concern the cells the embryos are discarded and priority is given to those that are healthy. <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/><br />
===Cystic Fibrosis===<br />
Cystic fibrosis is a single gene disorder. It is autosomal recessive and involves mutations in the cystic fibrosis transmembrane conductance regulator (CTFR) gene. The CTFR gene is normally responsible for the decrease in chloride and the transport of bicarbonate in epithelial cells thus playing a major physiological role. In PGD procedures, identification of the gene is assisted by microsatellite markers that have similar composition to the CTFR gene itself. Biopsy of two cells at the blastocyst stage is recommended if markers are not available. There are many variations of cystic fibrosis the most common being P.Phe508del <ref name="PMID26014425"><pubmed>26014425</pubmed></ref>.<br />
<br />
===Autosomal Recessive Meckel-Gruber Syndrome===<br />
Autosomal recessive genetic defect caused by the TMEM67 gene. It results in cystic dysplasia of the kidneys with fibrotic change in the liber and occipital encephalocele. Other malformations could also be present in the central nervous system. In PGD whole genome amplification of single blastomeres are taken to identify the gene, this is also coupled with PCR techniques. Maternal plasma can also be extracted for PGS. <ref><pubmed>24039893</pubmed></ref> <br />
===β – Thalassemia=== <br />
β – Thalassemia is known as the most common type of autosomal recessive inherited disorder among haemoglobinopathies. It involves the adult β-globin gene and is associated with the absent or decreased expression of the gene. This is commonly caused by a single nucleotide change in the gene. PGD has been used successfully worldwide to identify the β-globin gene where its application is usually performed on a single blastomere or polar body <ref name="PMID19064120"><pubmed>19064120</pubmed></ref>.<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
! colspan="2" | Applicable diseases for PGD <ref>Genoma Group (2014). Retrieved September 18th, 2015, from http://www.preimplantationgeneticdiagnosis.it/genetic-diseases-diagnosed-by-pgd.htm </ref> <ref>Genesis Genetics (2015). Retrieved September 18th, 2015, from http://genesisgenetics.org/pgd/what-we-test-for/</ref> <ref>Human Fertilisation & Embryology Authority (2015). Retrieved Septembr 18th, 2015, from http://guide.hfea.gov.uk/pgd/</ref><br />
|-<br />
| '''Disease'''<br />
| '''Involved Genes'''<br />
|-<br />
| 5 Alpha Reductase Deficiency (5ARD)<br />
| SRD5A2 [http://www.omim.org/entry/607306]<br />
|-<br />
| Achondroplasia<br />
|FGFR3 [http://www.omim.org/entry/134934]<br />
|-<br />
| Acute Intermittent Porphyria <br />
| ALAD [http://www.omim.org/entry/125270] , ALAS2 [http://www.omim.org/entry/612732], CPOX [http://www.omim.org/entry/612386], FECH [http://www.omim.org/entry/612386], HMBS [http://www.omim.org/entry/609806], PPOX [http://www.omim.org/entry/600923], UROD [http://www.omim.org/entry/613521], or UROS [http://www.omim.org/entry/606938]<br />
|-<br />
| Adrenoleukodystrophy (Adrenomyeloneuropathy)<br />
| ABCD1 [http://www.omim.org/entry/300371]<br />
|-<br />
| Agammaglobulinaemia (x-linked) <br />
|BTK [http://www.omim.org/entry/300300]<br />
|-<br />
| Agammaglobulinemia Bruton Tyrosine Kinase (BTK) <br />
|BTK [http://www.omim.org/entry/300300]<br />
|-<br />
| Aicardi Goutieres Syndrome 1 (AGS1) <br />
|TREX1 [http://www.omim.org/entry/606609] , RNASEH2A [http://www.omim.org/entry/606034] , RNASEH2B [http://www.omim.org/entry/610326] , RNASEH2C [http://www.omim.org/entry/610330], SAMHD1 [http://www.omim.org/entry/606754]<br />
|-<br />
| Alagille Syndrome<br />
|JAG1 [http://www.omim.org/entry/601920] or NOTCH2<br />
|- <br />
| Alpers-Huttenlocher Syndrome <br />
|POLG [http://www.omim.org/entry/174763]<br />
|-<br />
| Alpha-1-antitrypsin deficiency <br />
|SERPINA1 [http://www.omim.org/entry/107400]<br />
|-<br />
| Alpha-Mannosidosis<br />
| MAN2B1[http://www.omim.org/entry/609458]<br />
|-<br />
| Alpha Thalassemia <br />
|HBA1[http://www.omim.org/entry/141800]or HBA2 [http://www.omim.org/entry/141850] <br />
|-<br />
| Alports Syndrome<br />
|COL4A3 [http://www.omim.org/entry/120070] , COL4A4 [http://www.omim.org/entry/120131] , COL4A5 [http://www.omim.org/entry/303630]<br />
|-<br />
| Alzheimer's Disease - early onset (Type 3 and 4) <br />
|APP [http://www.omim.org/entry/104760] , PSEN1 [http://www.omim.org/entry/104311], or PSEN2 [http://www.omim.org/entry/600759] <br />
|-<br />
| Amyotrophic Lateral Sclerosis 1 (ALS1) <br />
| C9orf72 [http://www.omim.org/entry/614260], SOD1 [http://www.omim.org/entry/147450], TARDBP [http://www.omim.org/entry/605078], FUS [http://www.omim.org/entry/137070], ANG [http://www.omim.org/entry/105850] , ALS2 [http://www.omim.org/entry/205100], SETX [http://www.omim.org/entry/608465], VAPB [http://www.omim.org/entry/605704]<br />
|-<br />
| Argininosuccinic Aciduria <br />
| ASL [http://www.omim.org/entry/608310]<br />
|-<br />
| Arrhythmogenic Right Ventricular Cardiomyopathy/ Dysplasia (ARVC/D)<br />
| DSG2 [http://www.omim.org/entry/125671]; DSP [http://www.omim.org/entry/125647] ; PKP2 [http://www.omim.org/entry/602861]<br />
|-<br />
| Ataxia Telangiectasia<br />
| ATM [http://www.omim.org/entry/607585]<br />
|-<br />
| Autosomal Recessive Meckel-Gruber Syndrome<br />
| TMEM67 [http://www.omim.org/entry/609884]<br />
|-<br />
| Bardet-Biedl Syndrome (BBS)<br />
| BBS1 [http://www.omim.org/entry/209901]; BBS10 [http://www.omim.org/entry/610148]<br />
|-<br />
| Barth Syndrome<br />
| TAZ [http://www.omim.org/entry/300394]<br />
|-<br />
| Beta Thalassaemia<br />
| HBB [http://www.omim.org/entry/141900]<br />
|-<br />
| Birt-Hogg-Dubé Syndrome<br />
| FLCN<br />
|-<br />
| Breast Ovarian Cancer Familial Susceptibility (BRCA2)<br />
| BRCA1; BRCA2<br />
|-<br />
| Canavan Disease <br />
| ASPA<br />
|-<br />
| Carnitine-Acylcarnitine Translocase Deficiency <br />
| SLC25A20<br />
|-<br />
| Cerebral Arteriopathy with Subcortical Infarcts & Leukoencephalopathy (CADASIL)<br />
| NOTCH3<br />
|-<br />
| Cerebral Cavernous Malformation<br />
| CCM1<br />
|-<br />
| Charcot-Marie-Tooth Disease<br />
| GJB1; MPZ; NEFL; PMP22<br />
|-<br />
| CHARGE Syndrome<br />
| CHD7<br />
|-<br />
| Cherubism<br />
| SH3BP2<br />
|-<br />
| Choroideremia<br />
| CHM<br />
|-<br />
| Chronic Granulomatous Disease<br />
| CYBB; NCF1<br />
|-<br />
| Ciliary Dyskinesia<br />
| DNAH5<br />
|-<br />
| Citrullinemia<br />
| ASS1<br />
|-<br />
| Cleidocranial Dysplasia<br />
| RUNX2<br />
|-<br />
| Cockayne Syndrome<br />
| ERCC6<br />
|-<br />
| Congenital Adrenal Hyperplasia<br />
| CYP21A2<br />
|-<br />
| Congenital Cataracts<br />
| GJA8; VSX2<br />
|-<br />
| Congenital Diarrhea, Syndromic<br />
| SPINT2<br />
|-<br />
| Congenital Disorders of Glycosylation (CDG)<br />
| ALG1; ALG6; CDG1C; DOLK; PMM2<br />
|-<br />
| Cornelia de Lange Syndrome <br />
| NIPBL<br />
|-<br />
| Craniosynostosis<br />
| TWIST1<br />
|-<br />
| Crouzon Syndrome<br />
| FGFR2<br />
|-<br />
| Cysteinyl Leukotriene Receptor 1 Deficiency <br />
| CYSLTR1<br />
|-<br />
| Cystic Fibrosis<br />
| CFTR<br />
|-<br />
| Diamond –Blackfan Anemia <br />
| RPS19<br />
|-<br />
| Duchenne Muscular Dystrophy <br />
| DMD<br />
|-<br />
| Dyskeratosis congenita (Male embryos only)<br />
| DKC1<br />
|-<br />
| Ectodermal dysplasia (Hypohidrotic)<br />
| EDA; EDA1; GJB6; IKBKG<br />
|-<br />
| Familial Adenomatous polyposis coli (FAP)<br />
| APC<br />
|-<br />
| Familial Dysautonomia<br />
| IKBKAP<br />
|-<br />
| Fanconi Anemia <br />
| FANCA; FANCC; FANCD2; FANCF; FANCG; FANCJ<br />
|-<br />
| Fragile X Syndrome (FRAX)<br />
| FMR1<br />
|-<br />
| Galactosemia <br />
| GALT<br />
|-<br />
| Gangliosidosis<br />
| GLB1<br />
|-<br />
| Glanzmann Thrombasthenia <br />
| ITGA2B<br />
|-<br />
| Glutaric Acidemia (aciduria)<br />
| GCDH <br />
|-<br />
| Glycogen Storage Disease <br />
| G6PC; GAA; SLC37A4<br />
|-<br />
| Haemophilia A<br />
| F8<br />
|-<br />
| Haemophilia B<br />
| F9<br />
|-<br />
| Hereditary Nonpolyposis Colorectal Cancer: Lynch Syndrome<br />
| MLH1; MSH2; MSH6<br />
|-<br />
| Holt Oram Syndrome<br />
| TBX5<br />
|-<br />
| Huntington Disease<br />
| HD<br />
|-<br />
| Hydrocephalus<br />
| L1CAM<br />
|-<br />
| Ichthyosis <br />
| ABCA12; STS<br />
|-<br />
| Incontinentia Pigmenti (IP)<br />
| NEMO<br />
|-<br />
| Joubert Syndrome 5<br />
| INPP5E<br />
|-<br />
| Krabbe Disease<br />
| GALC<br />
|-<br />
| Leber Congenital Amaurosis (LCA)<br />
| CEP290; GUCY2D<br />
|-<br />
| Leigh Syndrome (Infantile Subacute Necrotising Encephalopathy)<br />
| LRPPRC<br />
|-<br />
| Lesch Nyan Syndrome<br />
| HPRT1<br />
|-<br />
| Leukocyte Adhesion Deficiency (Type I)<br />
| ITGB2<br />
|-<br />
| Li-Fraumeni Syndrome<br />
| TP53<br />
|-<br />
| Macular Dystrophy Retinal <br />
| VMD2<br />
|-<br />
| Maple Syrup Urine Disorder (MSUD)<br />
| BCKDHB<br />
|-<br />
| Marfan Syndrome <br />
| FBN1<br />
|-<br />
| Menkes Syndrome<br />
| ATP7A<br />
|-<br />
| Mitochondrial DNA Depletion Syndrom <br />
| POLG; RRM2B; SUCLA2; TK2<br />
|-<br />
| Mucolipidosis type II<br />
| GNPTAB<br />
|-<br />
| Multiple Endocrine Neoplasia<br />
| MEN1; MEN2A; MEN2B<br />
|-<br />
| Multiple Exostoses<br />
| EXT1; EXT2 <br />
|-<br />
| Myotubular myopathy<br />
| MTM1 <br />
|-<br />
| Nail-Patella Syndrome<br />
| LMX1B<br />
|-<br />
| Neurofibromatosis Type 1<br />
| NF1<br />
|-<br />
| Neurofibromatosis Type 2 <br />
| NF2<br />
|-<br />
| Noonan Syndrome<br />
| KRAS, PTPN11; SOS1<br />
|-<br />
| Norrie Disease<br />
| NDP<br />
|-<br />
| Ocular Albinism <br />
| GPR143<br />
|-<br />
| Oculocutaneous Albinism <br />
| OCA2; TYR <br />
|-<br />
| Oculodentaldigital Dysplasia<br />
| GJA1<br />
|-<br />
| Optic Atrophy<br />
| OPA1<br />
|-<br />
| Ornithine Transcarbamylase Deficiency <br />
| OTC<br />
|-<br />
| Osteogenesis imperfeca <br />
| COL1A1; COL1A2<br />
|-<br />
| Osteopetrosis <br />
| CLCN7; OSTM1; TCIRG1<br />
|-<br />
| Pachyonychia Congenita <br />
| KRT16; KRT6A<br />
|-<br />
| Pancreatitis, Hereditary<br />
| PRSS1 <br />
|-<br />
| Papillorenal syndrome <br />
| PAX2<br />
|-<br />
| Phenylketonuria <br />
| PAH <br />
|-<br />
| This table does not cover the complete list of diseases that PGD can be applied to.<br />
|}<br />
==Laws & Legal status==<br />
{| class="wikitable" <br />
|-bgcolor="DDCEF2"<br />
|'''Country'''<br />
|'''Legislation'''<br />
|-bgcolor="FFFAFA" <br />
| Australia<br />
| PGD is currently used to detect serious genetic conditions to improve the outcome of ART. In very rare cases it may be used to select an embryo with compatible tissue for a sibling who has a life-threatening disease where other means of treatment is unavailable. This is with the conditions that the use of PGD will not affect the welfare and interests of the child to be born. The parents must also receive adequate counselling and have full understanding of the procedures of PGD. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"> National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art</ref><br />
The use of PGD for sex-selection is prohibited with the exception of reducing the risk of the transmission of serious sex-linked genetic conditions. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"/><br />
|-bgcolor="FFFAFA"<br />
| Brazil<br />
| The laws regarding PGD in Brazil are not strictly regulated. They are vague and there is limited information surround the activities of assisted reproduction in general in the country <ref name="PMID25493379"><pubmed>25493379</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| Czech Republic<br />
| The laws in the Czech Republic allow those with a “defined indication in order to exclude risk of serous genetically conditioned disease and defects with embryos before they are implanted into the cavity of the uterus”. Couples that undergo any assisted reproductive treatment including PGD have to be married. Sex-selection is illegal except in regards to serious sex-linked genetic diseases <ref name="PMID24777348"><pubmed>24777348</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| Greece<br />
| In Greece, ART is open to those up to the age of 50 with written consent. It can only be used if a medical necessity is present such as the susceptibility of serious hereditary diseases. Sex selection is banned apart from cases of sex-linked diseases and sexually transmitted diseases <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| India<br />
| In India there is a cultural preference for boys thus the Prenatal Diagnostic Techniques (Regulation and Prevention of Misuse) Act was introduced in 1994. This law limits the use of PGD for sex determination except in cases of specific congenital diseases. These laws however are not strictly enforced. <ref>World Health Organisation (2015) Gender and Genetics Retrieved on October 21st 2015 from:http://www.who.int/genomics/gender/en/index4.html</ref><br />
|-bgcolor="FFFAFA"<br />
| Portugal <br />
| ART is only available to those who are married or have a similar type of relationship for at least two years. The couples cannot be of the same sex and must be at least 18 years of age. Sex selection is illegal except in cases of sex-linked diseases. The use of PGD is illegal if the predictive value of genetic tests are very low <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| Spain<br />
| PGD can be applied to “serious hereditary diseases not amenable to postnatal curative treatment” and “detection of other abnormalities which may compromise the viability of the pre-embryo”. If PGD is to be used for any other purpose authorisation must be acquired <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| Sweden <br />
| The use of PGD is strictly regulated and couples must achieve authorisation of the National Board of Health and Welfare. It can only be used it can only be used if the child is at risk to inheriting a serious chromosomal or monogenetic disease. It cannot be used for selection of specific characteristics <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| United Kingdom<br />
| Those involved with carrying out the IVF treatment must have a license from the Human Fertilisation and Embryology Authority (HFEA). Only embryos that are approved by the HFEA can be implanted where the embryonic nuclear or mitochondrial DNA cannot be altered with the exception of preventing mitochondrial diseases <ref name="PMID24777348"/>. <br />
|}<br />
==Future/Current Research==<br />
In addition to research efforts for improving overall performance of established PGD/S techniques, such as finding the ideal zona pellucida insection site in an fully automatic manner<ref name="PMID26259216"><pubmed>26259216</pubmed></ref>, many research efforts have been spent to find alternative, non-invasive techniques to test for diseases and abnormalities<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
===Non-invasive Preimplantation Genetic Testing without Embryo Biopsy===<br />
Different parameters of gametes, zygotes, embryos (“vacuoles in sperm heads, spindle position in mature oocytes, cleavage intervals of zygote, and embryo developmental dynamics”) may correlate with aneuploidy rates. This knowledge may be applied in potential noninvasive preimplantation diagnostic methods. Several methods have been proposed and are currently further researched<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Sperm Selection====<br />
Intracytoplasmic morphologically selected sperm injection (IMSI) is common procedure in IVF treatment to improve fertilization rates in patients with poor semen quality. In addition, studies have found that IMSI improves embryo development and that spermatozoa with large vacuoles in their heads correlate with increased aneuploidy rates and disturbed chromosomal structures. Thus, selecting spermatozoa based on morphological hallmarks may decrease aneuploidy rates in the fertilized embryos. As with polar body biopsies, however, this approach will solely be applicable if evidence for severe male detrimental contribution is given<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Blastocoel Fluid Extraction====<br />
In addition, a less invasive retrieval of material for diagnosis could include the extraction of the blastocoel fluid. The cavity of the blastocyst, lined by the trophectoderm, is filled with this blastocoel fluid, which contains metabolites of both trophectoderm and inner cell mass origin. The retrieval does not require a biopsy but merely a small opening to extract the fluid and, thus, causes less harm to the embryo. Multiple studies have applied this method<ref name="PMID22020776"><pubmed>22020776</pubmed></ref> <ref name="PMID23148560"><pubmed>23148560</pubmed></ref> <ref name="PMID26006737"><pubmed>26006737</pubmed></ref> and it may in the future become of clinical relevance.[[File:Aspiration_of_the_Blastocoel_Fluid.jpeg|400px|thumb|Aspiration of the Blastocoel Fluid using a ICSI pipette<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.]]Next to metabolites, the blastocoel fluid can contain DNA. Studies have shown that genomic DNA is present in about 90% of the blastocoel fluid samples tested. Typically the fluid is removed with an ICSI pipette from a day five blastocyst through its mural trophectoderm until the blastocyst fully collapses around the embryo. Several concerns regarding this method in a clinical setting have been raised. The collected DNA may be contaminated by the culture media that contains DNA fractions. The DNA may also be least representative of the actual embryos genome as the DNA may originate from abnormal or degenerated cells. Even though labelled noninvasive, the blastocyst still undergoes manipulation to some degree which may affect its viability. Thus, more research is required until this method can evolve from research to clinical use<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
====Proteomics and Medium Based PGD====<br />
The media in which embryos are kept during the early IVF procedures, gives rise to potential non-invasive techniques. For instance, the protein secretome of blastocysts may be representative of its chromosome constitution Recent studies have found biomarkers such as lipocalin-1, interleukin-10, tumor necrosis factor, stem cell factor, and chemokine ligand 13 to be differently secreted by aneuploid blastocyst than by euploid ones. The most significant biomarker appears to be interleukin-10. Paired with novel proteomic technologies and mass spectrometry this knowledge when extended may contribute to a new invasive PGD method<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. In addition, medium based non-invasive PGD has been researched for the diagnose of human α-thalassemia-SEA. Genomic DNA was collected from the media and the study surprisingly resulted in increased diagnosis efficacy compared to biopsy-based methods<ref name="PMID25816038"><pubmed>25816038</pubmed></ref>.<br />
====Embryo Morphology====<br />
Using time lapse imaging the embryo’s morphology can be closely observed and potential aneuploidy characteristics detected. Such characteristics may include the time of division to five cells, the time between the division from three to four cells, and the duration of the division from one to two and subsequently to three. In addition, the morphological quality of ICM an TE has been positively associated with aneuploidy or euploidy prognosis<ref name="PMID26246880"><pubmed>26246880</pubmed></ref>. These may give rise to an embryo quality screening prior to implantation<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
==Glossary==<br />
'''Allele:''' One of two or more versions of a gene<br />
<br />
'''Aneuploidy:''' Presence of an abnormal number of chromosomes in a cell <br />
<br />
'''Biopsy:''' Sample of tissue taken for examination <br />
<br />
'''Blastocyst:''' Stage of embryo at approximately day 5 consisting of an outer (trophoblast) layer and inner (embryoblast) cell mass.<br />
<br />
'''Blastomere:''' Cell type formed through cleavage of the zygote after fertilization<br />
<br />
'''Chromosome''' Thread-like structure, which is made up of protein and DNA, within the nucleus of a cell<br />
<br />
'''CTFR:''' Cystic Fibrosis Transmembrane Conductance Regulator, responsible for transport of chloride across the cell membrane<br />
<br />
'''Denaturing:''' Proteins or nucleic acids lose their quaternary, tertiary, and secondary structure <br />
<br />
'''DNA:''' DeoxyriboNucleic Acid, hereditary material<br />
<br />
'''Endometriosis:''' Condition in which the endometrium, the tissue lining the uterus, grows outside of it<br />
<br />
'''Enucleation:''' Removal of the nucleus<br />
<br />
'''Epigenetic:''' Phenotypic trait variations due to external or environmental factors that influence gene expression<br />
<br />
'''ESHRE:''' European Society of Human Reproduction and Embryology<br />
<br />
'''FISH:''' Fluorescent In situ Hybridisation, technique used to locate specific gene sequences using fluorescence tags <br />
<br />
'''Heterozygote:''' Diploid organism that contains two different alleles of one gene<br />
<br />
'''Hydrosalphinx:''' Fluid filled fallopian tube <br />
<br />
'''Intracytoplasmic Morphologically Selected Sperm Injection (IMSI):''' IVF technique involving morphological selection of sperm under the microscope to be injected to oocyte<br />
<br />
'''Intracytoplasmic Sperm Injection (ICSI):''' IVF technique used to treat male infertility and involves direct injection of one sperm into an oocyte<br />
<br />
'''IVF:''' In Vitro Fertilisation<br />
<br />
'''Leukocyte:''' White blood cell, involved in immune system<br />
<br />
'''Leukaemia:''' Cancer of the bone marrow, increased numbers of abnormal or premature leukocytes are formed by bone marrow and other organs <br />
<br />
'''NGS:''' Next Generation Sequencing, term used to describe the collection of recent findings regarding embryo screening<br />
<br />
'''Oolemma''': Plasma membrane of the oocyte <br />
<br />
'''PB:''' Polar Body, cell formed during the meiotic stages of the oocyte containing extra genetic material<br />
<br />
'''PCR:''' Polymerase Chain Reaction, technique used to amplify DNA to study a specific genetic sequence<br />
<br />
'''Polyploidy:''' Having more than two sets of homologous chromosomes <br />
<br />
'''PGD:''' Preimplantation Genetic Diagnosis, genetic testing conducted to identify abnormalities in an embryo before implantation in parents with genetic disease history<br />
<br />
'''PGS:''' Preimplantation Genetic Screening, similar to PGS but in couples seeking IVF due to infertility issues to improve implantation rates<br />
<br />
'''Perivitelline Space:''' Space between the oolemma and the zona pellucida <br />
<br />
'''RT:''' Robertsonian Translocations, a type of structural chromosomal translocation <br />
<br />
'''Trisomies:''' Presence of three copies of a chromosome instead of two<br />
<br />
'''Trophoectoderm:''' Outer layer of the mammalian blastocyst<br />
<br />
'''Zona Pellucida:''' Thick membrane surrounding the mammalian oocyte <br />
<br />
<br />
==References==<br />
<br />
<references/><br />
<br />
<br />
{{StudentPage2015}}</div>Z5017878https://embryology.med.unsw.edu.au/embryology/index.php?title=2015_Group_Project_6&diff=2085192015 Group Project 62015-10-23T10:08:32Z<p>Z5017878: </p>
<hr />
<div>{{ANAT2341Project2015header}}<br />
<br />
<br />
=Preimplantation Genetic Diagnosis and Preimplantation Genetic Screening=<br />
==Introduction==<br />
Preimplantation genetic diagnosis (PGD) and preimplantation genetic screening (PGS) are reproductive options for couples with known family histories of genetic disease or couples undergoing IVF procedures due to infertility issues. PGD can diagnose many genetic disorders caused by known chromosomal abnormalities (number and/or structure) or single gene mutations, and, thus decrease the risk of termination of pregnancy or miscarriages and enable such couples to have an unaffected child<ref name="PMID24907939"><pubmed>24907939</pubmed></ref>. Through major improvements in PGD/S and general laboratory technology, the testing for abnormalities in fetuses has shifted from prenatal diagnosis during the first 2 trimesters <ref> Blackburn, S.L. (2003) '''Maternal, Fetal & Neonatal physiology: a Clinical perspective''' (2nd ed.). Seattle: Saudners </ref>, testing for overall fetal growth, complications of pregnancy, and birth defects<ref> Sadler T.W.(2012) '''Langman's Medical Embryology''' (12th ed.) Philadelphia: Lipincott, Wiliams & Wilkins, a Wolters Kluwer Business </ref>, to an embryonic focus especially in advancements in Artificial Reproductive Technologies (ART)<ref><pubmed>20638568</pubmed></ref>. In 1990 PGD for a recessive X-linked disease resulted in the first live birth<ref><pubmed>2330030</pubmed></ref> and has since been incorporated in clinical routine and applied for a variety of genetic diseases, such as sickle cell anemia, thalassemia, or cystic fibrosis<ref name="PMID24907939"/>.<br />
[[File:Preimplantation Genetic Diagnosis Procedure.jpeg|600px|left|thumb| Simplified steps for PGD<ref name="PMID24907939"/>]]<br />
{|class="wikitable"align="right" <br />
| <html5media height="400" width="533">https://www.youtube.com/watch?v=0e-79qKllqk</html5media><br />
|-<br />
| Preimplantation Genetic Diagnosis<ref>IVF Florida (2011, December 11) IVF Florida - South Florida Fertility Specialists - Pre-Implantation Genetic Diagnosis [Video file]. Retrieved from https://www.youtube.com/watch?v=0e-79qKllqk</ref><br />
|}<br />
==History==<br />
The advances in reproductive technology during the second half of the 20th century, led to PGD's first clinical application in 1990 <ref>Harper, J. (n.d.). The history of PGD. Lecture. UCL Centre for PG&D and CRGH.University College London</ref>.<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
|Year<br />
|<br />
|- bgcolor="FFFAFA"<br />
| '''1967''' <br />
|First PGD on rabbit blastocysts (Gardner& Edwards) <ref name="PMID6036172"><pubmed>6036172</pubmed></ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1986''' <br />
|First Cleavage Biopsy (Wilton & Trounson)<ref>Wilton, L. J., & Trounson, A. O. (1986). Viability of mouse embryos and blastomeres following biopsy of a single cell. In Proceedings of the 18th Annual Conference of the Australian Society for Reproductive Biology, Brisbane, Australia.</ref><br />
|- bgcolor="FFFAFA"<br />
|'''1987''' <br />
|First Blastocyst Biopsy (Muggleton-Harris, Monk, Rawlings, & Whittingham)<ref name="PMID3372699"><pubmed>3372699</pubmed></ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1988''' <br />
|First Polar Body Biopsy (Yury Verlinksy)<ref> Verlinsky, Y., Pergament, E., Andresen, P., Enriquez, G., & Strom, C. (1989). Genetic analysis of polar body DNA: A new approach to preimplantation genetic diagnosis. Am J Hum Genet, 45(4), A272.</ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1990''' <br />
|First Clinical PGD using PCR testing for X-linked (Handyside, Kontogianni, Hardy, & Winston)<ref name="PMID2330030"><pubmed>2330030</pubmed></ref> <br />
|} <br />
==Preimplantation Genetic Diagnosis==<br />
[[File:Pre-PGD workup.jpeg|thumb|400px|Pre-PGD workup for a family with a previous child with spinal muscular atrophy. Panel (a) shows how the study of both parents and grandparents allows the phasing of the SMN mutation relative to polymorphic short tandem repeat (STR) markers; panel (b) shows the maternal and paternal haplotypes M1, M2, P1 and P2 and the distance of the STR markers from the SMN gene; panel (c) shows the four predicted fetal haplotypes. These reflect a Hardy–Weinberg equilibrium of one homozygous non-carrier, two heterozygous carriers and one that is homozygous and affected. Short tandem repeat markers linked with the SMN mutation are shown in red. DEL indicates the presense of the exon 7 (840 C>T) mutation<ref name="PMID26237262"/>.]]<br />
PGD is used to test the genetic makeup of embryos to detect single gene disorders, chromosomal abnormalities and mitochondrial disorders. It also has applications in gender selection for diseases with unequal gender distributions <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Some diseases commonly involved with PGD include cystic fibrosis, spinal muscular atrophy and beta – thalassaemia <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press.">Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press</ref> <ref name="PMID17823145"><pubmed>17823145</pubmed></ref>. It was first used in the United Kingdom in the 1980s, primarily focusing on sex- linked disorders <ref name="PMID17823145"/><ref name="PMID23150080"><pubmed>23150080</pubmed></ref>. PGD is now capable of detecting single cell defects (molecular) and chromosomal disorders resulting from the inversion, translocation or deletion of chromosomes (cytogenic) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/> <ref name="PMID11325751"><pubmed>11325751</pubmed></ref>. PGD can be applied to the embryo at different stages. That is on polar bodies, blastomeres or blastocyst <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>.<br />
Depending on the type of genetic disorder, PGD utilises different methods of genetic testing. These include Fluorescence in situ hybridisation (FISH) which is used for sex – linked disorders and detects chromosomal rearrangements <ref name="PMID11325751"/><ref name="PMID17876073"><pubmed>17876073</pubmed></ref> and Embryo halotyping which allows the identification of chromosomes causing the inherited disorder through knowledge of the pattern of closely linked markers <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. Polymerase chain reaction (PCR) is also widely used to detect molecular abnormalities <ref name="PMID11325751"/>.<br />
PGD is tightly regulated and supported by large organisations namely The American Society for Reproductive Medicine, The European Society for Human Reproduction and Embryology (ESHRE), The European Society of Human Genetics and the Preimplantation Genetic Diagnosis International Society <ref name="PMID25500181><pubmed>25500181</pubmed></ref>.<br />
===Sex-linked disorders===<br />
The determination of a disease as gender specific usually correlates with the presence or absence of specific genes such as SRY on the Y chromosome. It is known that females have two X chromosomes and males have an X and a Y chromosome where abnormalities are more prevalent on the X chromosome. PGD can be used for sex selection where only male embryos are transferred to reduce the chance of inheriting X-linked disorders. However, this does not completely eradicate the problem as male embryos remain susceptible to inheriting an affected X chromosome. Sex determination is only used when the specific mutation is unknown and has yet to be discovered <ref name="PMID24866878"><pubmed>24866878</pubmed></ref>.<br />
===Single gene defects===<br />
Single gene defects can be dominant, recessive, autosomal or X-linked. They are commonly diagnosed using PCR and although the PCR available today is complex and capable of combatting a large range of disease the development of new protocols has been proven to be difficult due to the small DNA sample available <ref name="PMID26168107"><pubmed>26168107</pubmed></ref>.<br />
===Mitochondrial disorders===<br />
Mitochondrial disorders also known as oxidative phosphorylation disorders arise from mutations in the nuclear DNA or mitochondrial DNA <ref name="PMID26312584"><pubmed>26312584</pubmed></ref>. They pose as a problem because they are unrecognisable until the mutations in the cell reach a detrimental level <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Mitochondrial disorders cause miscarriages and stillbirths as well as death in children and young adults. The effects can either be contained in a single organ or more commonly involve multiple organ failure where organs with high energy demands such as the brain, liver muscle and heart and heavily influenced. They are usually occur spontaneously or result from inheritance from the mother. Since mitochondria are solely inherited from the mother oocyte donations have been used as a solution to combat mitochondrial disorders. Additionally, there has been an increasing use in PGD where embryos that stay under the given threshold of 18% gene-mutations are allowed to be transferred and result in normal development. New technology in the areas of nuclear gene transfer and genome editing are also being experimented with <ref name="PMID26312584"/>. <br />
===Chromosomal disorders===<br />
Chromosomal disorders can be reciprocal, Robertsonian translocations, inversions, deletions and insertions <ref name="PMID26168107"/>. Data from ESHRE collected between 2010 and 2011 has shown that the most common chromosomal abnormality confronted in PGD are reciprocal chromosomal abnormalities <ref name"PMID26071418"><pubmed>26071418</pubmed></ref>. PGD has also been used successfully for Robertsonian translocations (RT), a type of structural translocation. Children who carry RT are phenotypically normal, however in their later years it is found that they will suffer from infertility and repeated miscarriages due to the high frequency of abnormal embryos <ref name="PMID22081077"><pubmed>22081077</pubmed></ref>. PCR and FISH are the two main techniques used for chromosomal disorders. To be able to conduct the examinations the cells are required to be at the metaphase stage <ref name="PMID26168107"/>. <br />
[[File:Reasons_for_PGD.jpg|600px|thumb|Reasons for PGD<ref name="PMID24764761"><pubmed><24764761</pubmed></ref>]]<br />
==Preimplantation Genetic Screening==<br />
PGS involves an array of methods or ideas that aim to segregate embryos that have genetic flaws and those that are healthy <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. The occurrence of aneuploidy is high around the stages of early embryonic development and they are the most common cause if miscarriages and congenital birth defects <ref name= "PMID26085841"><pubmed>26085841</pubmed></ref>. They have little effect on the morphology of the embryo making them difficult to identify thus identification heavily relies on genetic testing <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. <br />
Genetic sampling is most commonly conducted using Microarray Comparative Genomic Hybridisation (aCGH) as well as FISH, Quantitative PCR and Single Nucleotide Polymorphism (SNP) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. These methods collectively aim to assess numeral and structural chromosomal errors <ref name= "PMID26085841"/>. Studies have also introduced Next- Generation Sequencing (NGS) <ref name= "PMID26085841"/> and Whole Genome Amplification used to screen imbalances in the complete 24-chromosomes <ref name="PMID25953353"><pubmed>25953353</pubmed></ref>.<br />
Statistics from ESHRE have shown that the most common indications for PGS is advanced age, followed by repeated implantation failure or recurrent miscarriage and male infertility <ref name="PMID26071418"><pubmed>26071418</pubmed></ref>.<br />
===Indications===<br />
A low percentage of structural abnormalities in chromosomes are responsible for the cause of miscarriages. Despite this, they are the most prevalent type of chromosomal abnormality accounted for in PGD <ref name="PMID20638568"/>. The presence of specific gene cycles, initiation of embryonic protein synthesis and evident physiological development are all indicative of a successful in vitro fertilisation procedure <ref name="PMID11576737"><pubmed>11576737</pubmed></ref>. To eliminate further errors from occurring during the PGD procedure it is recommended to undertake further prenatal testing such as amniocentesis in the later stages <ref name="PMID20638568"/>. <br />
====Advanced maternal age====<br />
Data provided by the ESHRE has shown that the mean age of women undergoing PGS is 39 years <ref name="PMID26071418"/>. Women of advanced age have been shown to have a lower rate of pregnancies reaching childbirth <ref name="PMID18583331"><pubmed>18583331</pubmed></ref>. The highlighted concern revolves around the increased occurrence of aneuploidy following maternal age. The optimal age range for the lowest aneuploidy incidence was found to be between 27 to 37 years of age (6%) then progressively higher in women aged up to 42 (33%) and most common in those 44 and above (53%) <ref name="PMID24355045"><pubmed>24355045</pubmed></ref>. <br />
====Recurrent pregnancy loss / IVF failure====<br />
Recurrent pregnancy loss is defined as three or more IVF failures after cumulative transfer of more than 10 good-quality embryos. These are primarily caused by two main factors, reduced endometrium receptivity or embryonic defects. Endometrium receptivity can be negatively influences by instances including uterine pathologies such as thin endometrium, altered expression of adhesive molecules and immunological factors. Additionally, embryonic defects may be due to genetic abnormalities, embryonic aneuploidy or zona hardening. Endometriosis and hydrosalpinx has been known to effect both the endometrium and embryo <ref name="PMID23260857"><pubmed>23260857</pubmed></ref>.<br />
====Human leukocyte antigen matching====<br />
First used in 2001, HLA matching is an option given to parents to save a child with haematological or immunological disease through conceiving another child who would potentially be able to donate cord blood or haematopoietic stem cells from the bone marrow for transplantation. The process namely PGD-HLA has shown to improve haematopoietic stem cell transplant (HSCT). PGD-HLA can only be performed when HSCT is not needed urgently due to the time needed to conceive and delivery the baby <ref name="PMID25500181"><pubmed>25500181</pubmed></ref>. It is most commonly applied to children suffering from relapsed leukaemia <ref name="PMID22524201"><pubmed>22524201</pubmed></ref>. In a case study PGD-HLA was proven to successfully cure 10 diseases including Fanconi anaemia, Diamond-Blackfan anaemia and beta thalassemia <ref name="PMID25066893><pubmed>25066893</pubmed></ref>.<br />
==Biopsy Methods==<br />
Biopsy, the removal of genetic materials, from oocytes or embryos in the preimplantation stage is the primary step in PGD. For the past two decades these biopsies have been performed at three stages, the polar body, blastomere, and blastocyst, and the methodologies optimized to ensure the embryo’s viability. The most common approach involves biopsies at the cleavage stage. However, polar body and blastocyst biopsies are increasingly more often tested and applied. Approached for opening the zona pellucida involve next to the traditional mechanical and chemical means, novel approaches such as noncontact lasers. Their application may simplify and secure the procedure significantly. The most challenging question about PGD procedures remains at what stage biopsies should be taken. Much controversy has developed around this topic, highlighting the varying disadvantages and advantages of temporal biopsies <ref name="PMID22723007"><pubmed>22723007</pubmed></ref>.<br />
[[File:Polar_Body,_Blastomere,_and_Trophectoderm_Biopsy.jpeg|500px|thumb|Polar body (A), blastomere (B) and trophectoderm (C) biopsies<ref name="PMID25625041"><pubmed>25625041</pubmed></ref>.]]<br />
{| class="wikitable"<br />
|- align="center" bgcolor="DDCEF2"<br />
|<br />
| Time of Biopsy<br />
| Prevalence <br />
| Advantages <br />
| Disadvantages<br />
|- bgcolor="FFFAFA"<br />
| Polar Body<br />
| Day 1<br />
| ~16%<br />
| Little to no harm is caused to the oocyte and both PBs can be extracted (more genetic material)<ref name="PMID22723007"/>.<br />
| Only the maternal DNA is tested<ref name="PMID22723007"/>, often PB biopsies need to be coupled to other biopsies, and difficulties arise in distinguishing between the first and second PB<ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. Lower reliability of results compared to other biopsy methods have been reported<ref name="PMID25106935"/>. <br />
|- bgcolor="FFFAFA"<br />
| Blastomere <br />
| Day 3<br />
| ~80%<br />
| Biopsies are safe for good quality embryos and it is performed relatively early, so fresh transfer is possible, yet, it includes both paternal and maternal genetic contributions<ref name="PMID26237262"/>. <br />
| Relatively large decrease in implantation rates for low quality embryos have been reported, embryo mosaicism can influence genetic analysis, and only one to two cells can be safely removed<ref name="PMID26237262"/>. <br />
|- bgcolor="FFFAFA"<br />
| Trophectoderm<br />
| Day 5 and 6 <br />
| ~ 2%<br />
| Little harm to the embryo and large amount of genetic material can be extracted, which allows for more accurate genetic analysis and lessen effects of mosaicism<ref name="PMID26237262"/>. <br />
| The biopsy takes place relatively late and, thus, the time window for procedure is small and embryos often need to be cryopreserved<ref name="PMID22723007"/>. <br />
|}<br />
===Polar Body Analysis===<br />
Day 1<br />
====Description====<br />
[[File:Polar_Body_Biopsy.jpeg|thumb|400px|The presence of a faint but clearly identifiable strand connecting PB2 to the oolemma. The biopsy was performed ∼9 h after ICSI<ref name="PMID21908464"><pubmed>21908464</pubmed></ref>.]] <br />
Polar body (PB) biopsy offers a promising alternative to biopsies performed at the blastomere stage for PGD/S indications on legal and practical grounds<ref name="PMID22723007"/>. The ESHRE calculated the proportion of PB biopsies to be about 16.3%<ref name= "Traeger-Synodinos, J., Coonen, E., Goossens, V., De Mouzon, J., Shenfield, F., Ruiz, A., ... & de Mouzon, J. (2013). Session 09: ESHRE data reporting on PGD cycles and oocyte donation.">Human Reproduction, 28(suppl 1), i18-i19. </ref>. Embryo development does not necessitate the presence of the first and second PB and their removal may not be crucial<ref name="PMID22723007"/>. The idea behind PB biopsies is that each abnormality found in the PB corresponds to an error in the oocyte. On the other hand, in women with known single gene mutations, it is assumed that if the PB contains the mutated allele ,the oocyte will have the normal allele, thus, resulting in a healthy embryo<ref name="PMID26237262"/>. PB biopsy requires precise timing. Keeping track of the meiotic cell cycle is necessary to perform a successful biopsy and, therefore, PB biopsy usually is applied in combination with intracytoplasmic sperm injection (ICSI). During the maturation from the germinal vesicle stage to the metaphase-II stage the first PB is formed. A cytoplasmic bridge containing spindle remnants, that are still in contact with the cellular genetic material, links this PB to the oolemma for about 90 minutes after extrusion. It is possible to visualize these remnants by polarization microscopy and it is crucial to not perform the biopsy until the first PB is no longer firmly attached to the oolemma as this indicates an immature embryo.The oocyte tolerates mechanical zona dissection best during hours four until six after ICSI as the oolemma has stabilized by that time because of the cortical granule reaction. Over time the first PB degenerates stressing a temporal biopsy and its optimal extraction time window is four to 12 hours after ICSI. The second PB forms around two to four hours after ICSI. Its optimal time window for biopsy is set to be eight to 16 hours after ICSI due to the second PB being attached to the oolemma with spindle remnants until six hours after ICSI. Biopsy at this point may cause enucleation of the oocyte. Studies have shown that the amplification efficiency of second PB’s DNA is worse if the PB is extracted prior to eight hours after ICSI. Thus, it is possible to perform sequential and simultaneous biopsies for the first and second PB. If performed, sequentially the first PB may be removed four to 12 hours and the second PB eight to 16 hours after ICSI. The optimal time window for a biopsy for both the first and second PB simultaneously is eight to 12 hours after ICSI. It is highly preferred to analyze both PBs due to potential aneuploidies in either PB and crossing overs during meiosis <ref name="PMID22723007"/>. <br />
====Procedure====<br />
Chemical opening achieved with for example acidic tyrode’s solution of the zona pellucida is not tolerated by the oocyte and may have detrimental effects on the embryo’s development. Therefore, the access to the perivitelline space of the oocyte is provided by mechanical zona dissection or by laser. Both techniques work well if performed by experienced embryologist. However, laser-assisted biopsy is less time consuming when compared to manual dissection. It is critical to consider the size of the introduced opening as it will remain permanent. If it is too large the blastomere may be lost during embryo development and if it is too small it may interfere with hatching of the embryo during blastocyst stage<ref name="PMID22723007"/>.<br />
[[File:Implantation_predictive_value_of_euploid_screening_results.jpeg|thumb|450px|The sustained implantation predictive value (with 95 % confidence interval) of a euploid screening result obtained from the first polar body (PB1), PB1 and the second polar body (PB2), or a direct embryo biopsy for each stage of embryo transfer (cleavage-stage and blastocyst stage)<ref name="PMID25106935"><pubmed>25106935</pubmed></ref>.]]<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JTaQzszVr8o</html5media><br />
|-<br />
| Laser-assisted polar body biopsy<ref>RIUK, R. (2013, June 25) Polar Body Biopsy [Video file]. Retrieved from https://www.youtube.com/watch?v=JTaQzszVr8o</ref><br />
|}<br />
====Advantages & Disadvantages====<br />
PB biopsies can only investigate the maternal contributions to the embryo as they are of maternal origin. Thus, this procedure is appropriate for PGD solely for monogenetic diseases from the maternal side. Recessive diseases may be evaluated with PB biopsies on the basis that the embryo’s outcome will be determined by the paternal contribution. It may still be applied for PGS as it is a fairly safe biopsy option and most aneuploidies either arise during meiosis or origin from the maternal genome. However, diagnosis error has been reported due to the lack of considering paternal contributions<ref name="PMID22723007"/>. About 10% of PB biopsies appear to be wrongfully diagnosed with aneuploidies<ref name="PMID26237262"><pubmed>26237262</pubmed></ref>. Because PB biopsies are performed very early it is not yet known whether the oocyte will develop into a viable embryo. Thus, PBs are commonly frozen or fixed after biopsy and depending on the state of the embryo only chosen PBs will be tested. This is primarily an economic issue as many genetic testing procedures are very cost-intensive<ref name="PMID22723007"/>. Generally the sustained implantation predictive value of screening of PBs is significantly lower than of, for example, biopsies of the blastocyst stage<ref name="PMID25106935"/>. Moreover, it is often difficult to distinguish between the first and the second PB. As the first one degenerates quicker, this may influence diagnostic procedures<ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
===Blastomere biopsy===<br />
Day 3 <br />
====Description====<br />
Blastomere biopsy has been the prevalent method for PGD and PGS in the last two decades. In 2013 the ESHRE reported 79.8% of biopsies to be performed at the cleavage stage<ref name= "Traeger-Synodinos, J., Coonen, E., Goossens, V., De Mouzon, J., Shenfield, F., Ruiz, A., ... & de Mouzon, J. (2013). Session 09: ESHRE data reporting on PGD cycles and oocyte donation."/>. At least one, but up to two, blastomeres are biopsied on day three of the cleavage stage embryo. The right number of blastomeres removed is a controversial topic as two cells allow for more genetic material and more accurate results. However, removing two cells might be too invasive and damaging to the embryo. As PGS tries to improve implantation rates, whereas PGD sets out to avoid known genetic disorders, for the former only one cell is removed, while for the latter often two need to be removed, to ensure results as correct as possible<ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
====Procedure====<br />
Initially a hole was drilled into the zona pellucida using acid Tyrode's solution or by mechanical means. Nowadays the zona pellucida is largely opened using a laser and calcium and magnesium free media have been introduced to decrease junctions between blastomeres, which facilitates the biopsy. This if followed by the consequent aspiration of blastomeres with a pipette.<ref name="PMID21748341"/>. The blastomeres can also be removed by applying pressure on the outside of the zona<ref name="PMID26237262"/>.<br />
[[File:Aspiration_of_a_Blastomere.jpeg|thumb|left|400px|Aspiration of a Blastomere into the biopsy pipette<ref name=" PMID24783200"><pubmed>24783200</pubmed></ref>.]]<br />
{|class="wikitable"align="right" <br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=TbridWVwipI</html5media><br />
|-<br />
| Laser-assisted blastomere biopsy<ref>Sukprasert, M. (2014, March 5) Day 3 Blastomere Biopsy 1 [Video file]. Retrieved from https://www.youtube.com/watch?v=TbridWVwipI</ref><br />
|}<br />
====Advantages & Disadvantages====<br />
Blastomere biopsy is limited by the presence of embryo mosaicism, which can severely influence the interpretation of the genetic analysis. Approximately 15%-80% of all embryos display mosaicism on day three. Thus, any results might be a misrepresentation of the embryo as a whole. However, if good quality embryos are selected, the procedure overall is safe and does not negatively influence the embryos transition to the blastocyst stage. In a typical IVF cycle, however, not all embryos are of good quality, particularly if they have undergone cryopreservation. Studies have found that in these embryos biopsies reduce implantation rates by 12.5%-25%. Furthermore, unlike PB biopsy, the cells at the blastomere stage contain both paternal and maternal contribution, giving the genetic analysis a fuller perspective on the embryo's genetic make up. Since blastomere biopsy is performed at the third day after fertilization, it is possible complete fresh embryo transfer. Thus, no storage procedures, such as cryopreservation, are necessary<ref name="PMID26237262"/>. <br />
===Trophectoderm biopsy===<br />
Day 5 and 6<br />
====Description====<br />
The improvement of embryo culture media allowed the in vitro development of human embryos until the blastocyst stage and opened up the possibility to take blastocyst biopsies. While currently according to ESHRE datasets only about 2.3% of biopsies are performed at the blastomere stage<ref name= "Traeger-Synodinos, J., Coonen, E., Goossens, V., De Mouzon, J., Shenfield, F., Ruiz, A., ... & de Mouzon, J. (2013). Session 09: ESHRE data reporting on PGD cycles and oocyte donation."/>. During day three to day five the haploid maternal and paternal genomes come together for the first time to form the genome of the embryo. The maternal epigenetic control lessens significantly while preparing for implantation with precisely arranged events happening. The first event includes a rapid increase in the number of embryonic cells which are active in mitotic divisions and apoptosis of aberrant cells. This is followed by the formation of blastocoel (cavitation) which results from the flattening of cell located on the outside of the blastomere. Now the blastocyst will expand until the embryo hatches by rupturing the zona pellucida. The cells of the blastocyst will differentiate to form two distinct cell lineages, the outer trophectoderm and the inner cell mass<ref name="PMID22723007"/>. <br />
====Procedure====<br />
Trophectoderm biopsy is usually performed in Hepes buffered biopsy medium and opening approaches include needle cutting which has been replaced by lasers in past years. Different research groups report different timings of the opening to be the most successful. Some open the blastocyst on day three or four by creating a 25 µm which causes the trophectoderm to herniate through this hole and is, thus, accessible for biopsy. Others create this hole about four hours before biopsy which allows sufficient herniation of trophectoderm cells. It is also possible to open the blastocyst immediately before biopsy. This avoids an extra step and the inner cell mass usually is easy to locate. Blastocyst biopsies involve the removal of trophectoderm cells and the ideal time for the procedure is day five. Successful biopsies on day six have been performed, while little is known about the results of biopsies on day seven. However, since the window of implantation in humans is from day eight to ten after ovulation, day seven biopsies appear to be possible<ref name="PMID22723007"/>.<br />
[[File:Microscopic images of human blastocysts for biopsy.jpeg|thumb|400px|left|(A) Some trophectoderm cells in a blastocyst started to hatch and (B) the trophectoderm cells were biopsied with assisted laser cutting. Images in C–D show the blastocysts after vitrification and warming. Blastocysts had been cultured for 2–4 hrs after warming, showing good (ICM and trophectoderm cells) hatched (C) and hatching (D) blastocysts. The hatching blastocyst in (E) has good ICM but fair trophectoderm while the blastocyst in (F) has both fair ICM and trophectoderm. Arrows indicate ICMs and arrow heads indicate trophectoderm cells. Bar = 40 µm<ref name="PMID2190846"><pubmed>2190846</pubmed></ref>.]]<br />
{|class="wikitable"align="right"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JI_TQ8d8tNM</html5media><br />
|-<br />
| Laser-assisted blastocyst biopsy (at 00:50 min)<ref>Coco, R. (2014, April 30) Trophectoderm biopsy in a Hatching blastocyst protruding ICM [Video file]. Retrieved from https://www.youtube.com/watch?v=JI_TQ8d8tNM</ref><br />
|}<br />
====Advantages & Disadvantages====<br />
Blastocyst biopsies are believed to be less damaging to the embryo and appear to be unrelated to implantation rates. In addition, this biopsy method allows for a larger extraction of cells for genetic testing. However, since they are performed late in in vitro development, the time window for genetic testing is relatively small. Fast and accurate genetic testing methods are needed to ensure a successful and safe result from this biopsy. Thus, blastocyst biopsies may gain more popularity in the future when such methods have been developed or improved<ref name="PMID22723007"/>. Furthermore, the extraction of multiple cells may lessen the effects of mosaicism and problems during PCR, such as ADO. Studies comparing the implantation rate and screening accuracy have found that blastocysts are significantly safer. Blastocyst biopsies decrease implantation rates significantly, while biopsies at day five or six do not seem to influence implantation and delivery rates<ref name="PMID26237262"/>.<br />
==Genetic Techniques==<br />
===Polymerase Chain Reaction===<br />
PCR amplifies DNA specific to genetic sequence of interest . PCR was developed by Kay Mullis in the 1980's, for which he was awarded the Nobel prize for chemistry in 1993 <ref> Pubmed Docs (2015) Polymerase Chain Reaction (PCR) Pubmed. Retrieved from [http://www.ncbi.nlm.nih.gov/probe/docs/techpcr/]</ref>. This technique enables clinicians to monitor and diagnose diseases using minute samples such as embryonic cells <ref>Roche (2015) PCR: How We Copy DNA. Roche Molecular Systems Inc. retrieved From [http://molecular.roche.com/pcr/Pages/Process.aspx]</ref>. PCR is used to detect genetic disorders, as a part of PGD, in conjunction with IVF<ref name="PMID24301057"><pubmed>24301057</pubmed></ref>. It is used to detect molecular abnormalities, such as single gene disorders including Tay Sach, Cycstic fibrosis, Duchenne Muscular Dystrophy, Thalassemia, Huntington disease, Spinal muscular atrophy and many more. Molecular and genetic analysis require a significant amount of DNA, which can be delivered by PCR. It revolutionized the study of DNA, replacing all previous recombinant DNA technology and is a significant component of PGD procedures<ref name="PMID24907939"/>.<br />
[[File:PCR.jpg|450px|thumb|PCR amplifies DNA specific to genetic sequence of interest, enabling the monitoring and diagnose molecular abnormalities such as single gene disorders using minute samples such as embryonic cells, blood & tissue <ref name="NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute">NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref>]]<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="7" |'''Advantages'''<br />
|-bgcolor="FFFAFA"<br />
| Fast and inexpensive way of copying a target sequence of DNA.<br />
|-bgcolor="FFFAFA"<br />
| Particularly useful for the diagnosis of single cell defects.<br />
|-bgcolor="FFFAFA"<br />
| Rapid generation of results (within hours).<br />
|-bgcolor="FFFAFA"<br />
| Highly sensitive, a single molecule of DNA is sufficient for reaction.<br />
|-bgcolor="FFFAFA"<br />
| Generates DNA copies exponentially.<br />
|-bgcolor="FFFAFA"<br />
| This enables DNA amplification required for molecular and genetic diagnostic analysis<ref> Dreesen, J., Drusedaul, M., Smeets, H., Die-Smulders, C., Coonen, E., Dumoulin, J., Gielen, M., Evers, J., Herbergers, J. & Geradets, J. (2008) Validation of preimplantation genetic diagnosis by PCR analysis: genotype comparison of the blastomere and corresponding embryo, implications for clinical practice. Mol. Hum. Reprod. 14 (10):573-579.doi: 10.1093/molehr/gan052. Retrieved from [http://molehr.oxfordjournals.org/content/14/10/573.short] </ref> <ref><pubmed>20966460</pubmed></ref>.<br />
|-bgcolor="DDCEF2"<br />
| rowspan="7"|'''Disadvantages'''<br />
|-bgcolor="FFFAFA"<br />
| Only during the exponential DNA replication phase, the starting quantity sequence contained in the original sample (template DNA strand) can be determined.<br />
|-bgcolor="FFFAFA"<br />
| PCR reaction is limited to by presence of inhibitors in the sample.<br />
|-bgcolor="FFFAFA"<br />
| Self annealing due to the accumulation of the product and the stopping exponential amplification for the target sequence and reaching of a plateau<br />
quantification of the end point of reaction of PCR products make real time quantitative RT-PCR necessary<ref name="NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute">NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref>.<br />
|-bgcolor="FFFAFA"<br />
| Not a diagnostic method on its own, but requires further analysis.<br />
|-bgcolor="FFFAFA"<br />
|Low-quantity DNA template may result in amplification failure<ref name="PMID24907939"/>.<br />
|-bgcolor="FFFAFA"<br />
|Allele drop-out (ADO) in heterozygous loci is possible<ref name="PMID24907939"/>.<br />
|}<br />
====Procedure====<br />
Samples are obtained from the the blastocyst, a polar body biopsy or the blastomeres stages of the embryo. <br />
*Stage 1 Denaturing: separating the target strands of DNA <br />
The obtained sample is heated to roughly 90 degrees celcius, this heat breaks the relatively weak bonds between nucleotides that form DNA. The double stranded DNA is split into two single strands of DNA that are used as templates.<br />
*Stage 2 Annealing: Binding the Primers to the target DNA sequence <ref name="PMID25250056"><pubmed>25250056</pubmed></ref><br />
PCR will only copy the target sequence of DNA specified by specific PCR primer. These synthesized primers oligonucleotides are small artificial pieces of DNA. TAQ polymerase enzyme synthesize two new strands of DNA duplicate to the single sample DNA stand template indicated by these primers. During this stage the reaction is cooled to a temperature between 40-60 degrees Celsius. <br />
*Stage 3- Extension- making copies <br />
Each of these two copies are then used again as templates generating two further replications This cycle can occur as many 30 -40 times within a couple hours leading to billions of extra copies of the original DNA segment. Generally the optimal temperature for the further replication is roughly 72 degrees Celsius, although, this may vary according to the analysis machines used. <ref name="PMID26092180"><pubmed>26092180</pubmed></ref><br />
This process mediated by a thermocycler machine that is programmed to alter the temperature of the reaction every couple of minutes, perpetuating the cycle of DNA denaturing and synthesis. <br />
This process, generates exponentially exact copies of the original template DNA sequence, as visible in the expandable table below. <ref> Mullins, K., Francois, F.& Gibbs R.A. (1994 ) The Polymerase Chain Reaction. p3. Springer- Science +Business Media. Birkhauser, Boston<br />
Available at [https://books.google.com.au/books?hl=en&lr=&id=gjrTBwAAQBAJ&oi=fnd&pg=PR5&dq=kary+mullis+PCR&ots=mpzAyRh5ZY&sig=PQ4goNoKJ90tb3-MkPk62zrTGbw#v=onepage&q=kary%20mullis%20PCR&f=false] </ref><br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
!rowspan="2" PCR cycles<br />
|-<br />
| '''PCR Cycle'''<br />
| '''Target Copies'''<br />
|-<br />
| 1<br />
| 2<br />
|-<br />
| 2<br />
| 4<br />
|-<br />
| 3<br />
| 8<br />
|-<br />
| 4<br />
| 16<br />
|-"<br />
| 5 <br />
| 32<br />
|-<br />
| 6 <br />
| 64<br />
|-<br />
| 7 <br />
| 128<br />
|-<br />
| 8<br />
| 256<br />
|- <br />
| 9<br />
| 512 <br />
|-<br />
| 10<br />
| 1024<br />
|-<br />
| 15<br />
| 32,768<br />
|-<br />
| 20 <br />
| 1,048,578<br />
|-<br />
| 25<br />
| 33,554,432<br />
|-<br />
| 30 <br />
| 1,073,741,842<br />
|-<br />
|}<br />
===Fluorescent In Situ Hybridisation===<br />
FISH is the one of the most effective and rapid <ref name="PMID26338801"><pubmed>26338801</pubmed></ref> method as part of PGD. This technique locates a specific DNA sequences within a chromosome. FISH facilitates the clinical diagnosis of chromosomal abnormalities indicated by sequential duplications, deletions and rearrangements of chromosome, that are usually missed with microscopic analysis. This technique is especially relevant for female embryos with X-linked diseases<ref name="PMID20809319"><pubmed>20809319</pubmed></ref>. As part of PGD, it enabled the screening for aneuploidies and increased live birth rates in women with advanced age<ref name="PMID24907939"/> <ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. FISH is 99% effective when used in conjunction with competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities<ref name="PMID26338801"/>. <br />
[[File:Fluorescent In Situ Hybridisation (FISH).jpg|thumb|450px|right|'''FISH''' Specific DNA sequences using probes which have been tagged with fluorescent labels are visualised.This technique enables the clinical diagnosis of chromosomal abnormalities, indicated by sequential duplication, deletions and rearrangements of chromosome <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref>]]<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="5" |'''Advantages''' <br />
|-bgcolor="FFFAFA" <br />
| FISH is 99% effective when used in conjunction with CGH to diagnose chromosomal abnormalities<ref><pubmed>26338801</pubmed></ref>.<br />
|-bgcolor="FFFAFA" <br />
| Results are rapidly generated. <br />
|-bgcolor="FFFAFA"<br />
| Very small translocations and aneuploidies that occur within chromosomes, that would usually be missed under microscopic analysis, can be identified<ref name="Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd)">Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref>.<br />
|-bgcolor="FFFAFA" <br />
| The most common chromosomal abnormalities, such as down syndrome chromosomes 13,16,18,21 and 22<ref><pubmed>21749752</pubmed></ref>, and inheritable X-linked disease or sex chromosome anomalies such as Duchenne's Muscular Dystrophy, hemophilia, ectodermal dysplasia<ref><pubmed>17876073</pubmed></ref> can be identified.<br />
|-bgcolor="DDCEF2"<br />
| rowspan="5"|'''Disadvantages'''<br />
|-bgcolor="FFFAFA" <br />
| FISH destroys all cells tested <ref> O'Connor, C. (2008) Fluorescence in situ hybridization (FISH). Nature Education 1(1):171. retrieved from [http://www.nature.com/scitable/topicpage/fluorescence-in-situ-hybridization-fish-327] </ref>.<br />
|-bgcolor="FFFAFA" <br />
| It does not fully access all chromosomes (only ~ 12)<ref name="PMID24907939"/>.<br />
|-bgcolor="FFFAFA" <br />
| The analysis of results is dependent upon the dot quality impacted by hybridisation efficiency or the camera sensitivity<ref name="PMID17970921"><pubmed>17970921</pubmed></ref>.<br />
|-bgcolor="FFFAFA" <br />
| Some studies indicate that using FISH on a day-3 embryo biopsy decreases the rate of live births<ref><pubmed>26168107</pubmed></ref>.<br />
|}<br />
====Procedure====<br />
Samples collected from the embryo<ref name="PMID21748341"><pubmed>21748341</pubmed></ref> are collected, processed, and its DNA strands are heated and denatured causing their the individual DNA strands to break apart. Then, probes of single complimentary stands of DNA a that have been tagged with small chemical agents that glow brightly in the presence of a specific region on a chromosome are added. These specific probes then hybridize and join to their complementary DNA strand. The fluorescent tags enable the correct identification of the presence or lack thereof and location of specific chromosomes that are tested for<ref name="PMID17876073"><pubmed>17876073</pubmed></ref>. The number and the relative location of the fluorescent dots generated by the FISH images is analysed and gives rise to diagnosis<ref name="PMID17970921"><pubmed>17970921</pubmed></ref>. The probe will not fully hybridise if there has been a duplication or a deletion of the DNA - indicating chromosomal and sex chromosomal anomalies like trisomies and aneuploidies. <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref>. Different probes are used for different purposes <ref>Unique, Rare Chromosome Disorder Support Group (2013) Fluorescence in situ hybridisation (FISH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/Other/FISH%20FTNW.pdf]</ref>:<br />
*'''Locus specific tags''' detect very small imbalances, and locate isolated small portions <br />
of genes within a chromosome<br />
*'''Alphoid/Centomeric Repeat probes''' are developed from the repetitive sequence located in the middle region of each chromosome, useful in determining the number of chromosomes , detecting rearrangement and when used in conjunction with locus probes to determine the absence of genetic material on a chromosome. <br />
*'''Paint Probes''' are collections of smaller probes with their own stains that bind to a different section on the chromosome - allowing the full chromosome too be labeled a unique colour, this "full colour map" can be used to know the spectral karyotype- full chromosomal mapping is useful in examining chromosomal abnormalities. <br />
===Array Comparative Genomic Hybridisation (aCGH)===<br />
[[File:aCGH.jpg|thumb|600px|right|'''aCGH''' checks the entire genome for chromosomal imbalances, by comparing control and a sample slides contatining small segements of DNA sample microarrayed slides small segments of DNA. Illustrated by student z5020317 and adapted from <ref> NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation. retrieved from [http://www.phgfoundation.org/file/5237/]</ref> <ref name="Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45"> Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432] </ref>]]<br />
aCGH also known as Microarray analysis efficiently scans the entire genome for chromosomal imbalances. CGH was initially developed to detect the number of changes in a solid tumor mass. It uses 2 genomes comparing the sample to the control, with each labeled in a different fluorescent dye<ref name="PMID1876176"><pubmed>1876176</pubmed></ref>. Earlier CGH techniques were limited by the resolution of the imaging <ref> Lichter, P., et al. Comparative genomic hybridization: Uses and limitations. Seminars in Hematology 37, 348–357 (2000)</ref>, these initial limitations were overcome by using Microarrays in conjunction with CGh to improve the resolution of the imaging, Array Comparative Genomic Hybridisation (aCGH). This method compares sample and control microarrayed slides containing small segments of DNA (probes). <ref> Lucito, R., et al. Representational oligonucleotide microarray analysis: A high-resolution method to detect genome copy number variation. Genome Research 13, 2291–2305 (2003) </ref> the Probes used will vary according from the small (25-85 base pairs) oligonucleotides manufactured to highlight different target sequences, to the very large genomic clones (80,000- 200,00 base pairs), and as these are significantly smaller than the traditional metaphase chromosomes used for CGH, generating a higher resolution of image. <ref name="PMID22467166"><pubmed>22467166</pubmed></ref>.aCGH is used as a diagnostic tool for prenatal detection f chromosomal abnormalities <ref name="PMID19012303"><pubmed>19012303</pubmed></ref>.<br />
{|class="wikitable" align="center"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="12" |'''Advantages''' <br />
|-bgcolor="FFFAFA"<br />
| Multiple applications: prenatal genetic diagnosis, cancer diagnosis, <ref name="PMID20193845"><pubmed>20193845</pubmed></ref> genetic screening for developmental delay (learning disabilities) <ref name="PMID17309648"><pubmed>17309648</pubmed></ref>. or congenital anomalies that are suspected to be genetic in origin <ref>NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation . retrieved from [http://www.phgfoundation.org/file/5237/]</ref><br />
|-bgcolor="FFFAFA"<br />
| trace represents all chromosomes present in the human genome chromosomes 1-22 and the X & Y chromosomes, and therefore is the most accurate method for testing whole embryo aneuploidy<br />
|-bgcolor="FFFAFA"<br />
| aCGH has been extensively tested, and Validated, and is now used world wide.<br />
|-bgcolor="FFFAFA"<br />
| Detects submicroscopic alterations<br />
|-bgcolor="FFFAFA"<br />
| Detects deletions and additions and rearrangements as well as amplification, of the WHOLE genome, simultaneously.<br />
|-bgcolor="FFFAFA"<br />
| Used as a diagnostic tool for prenatal detection of chromosomal abnormalities <ref name="PMID22034057"><pubmed>22034057</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Provides high resolution genomewide screening of segmental genomic copy number variations<br />
|-bgcolor="FFFAFA"<br />
| Very accurate when used in conjunction with FISH<br />
|-bgcolor="FFFAFA"<br />
| Alone is more reliable and in detecting chromosomal abnormalities, with a higher implantation success rate, than FISH <ref name="PMID20494259"><pubmed>20494259</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Allows an in depth research focus upon specific types of rearrangements within selected chromosomal regions, a recent particular area of interest is subtelomeric and pericentromeric rearrangements<br />
|-bgcolor="FFFAFA"<br />
| Reduces the risk of failed implantation and miscarriage, improving the chance of a healthy baby <ref name="Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd)">Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref>><br />
|-bgcolor="DDCEF2"<br />
| rowspan="9" |'''Disadvantages'''<br />
|-bgcolor="FFFAFA"<br />
| Translocations and inversions of DNA are not detected<br />
|-bgcolor="FFFAFA"<br />
| Limited ability diagnosing specific polyploidies such as triploidy <ref> Unique, Rare Chromosome Disorder Support Group (2013) Microarray-based Comparative Genomic Hybridiation (array CGH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/other/array%20cgh%20ftnw.pdf] </ref><br />
|-bgcolor="FFFAFA"<br />
| Will not detect mosaicism detection <20% (cultures where >1 of 5 cells are trisomy 12)<br />
|-bgcolor="FFFAFA"<br />
| Will not detect balanced chromosomal rearrangement<br />
|-bgcolor="FFFAFA"<br />
| Will not detect duplications or deletions <80kb<br />
|-bgcolor="FFFAFA"<br />
| Will not detect point mutations within genes <ref>Washington department of education (CGH- FAQ for physicians. Signature Genomic LAboratories, LLC. Retrieved from [https://depts.washington.edu/dbpeds/Lab%20Tests/SignatureCGH-physician_FAQ.pdf]</ref><br />
|-bgcolor="FFFAFA"<br />
| will not detect chromosomal position of genomic gains<br />
|-bgcolor="FFFAFA"<br />
| Will not detect loos of heterozygosity (LOH) or Absence of heterozygosity (AOH) <ref>WiCell Research Institute Inc. (2012) Comparative Genomic Hybridization Microarray. <br />
retrieved from [http://www.wicell.org/home/cytogenetic-services/cgh-microarray/array-comparative-genomic-hybridization-acgh.cmsx]</ref><br />
|}<br />
====Procedure==== <br />
As a part of PGD fetal cell samples are collected from; the fertilized egg polar bodies, the blastomere (day 3 embryo) or the blastocyst/tropoectoderm stage (day 5 embryo).<br />
Sample DNA is labeled with one fluorescent dye, and the control DNA is labeled with a different colored fluorescent dye. the control DNA is used as the base point of reference. <br />
heated and denatured single DNA strands then hybridize to their complementary single strand probes, which are then combined and applied to a microarray and the results are run through a computer program and a digital imaging system is used to quantify the results( fluorescent intensities of the labeled probes)<ref name="Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45"> Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432] </ref>. <br />
The fluorescent ratio and the hybridization signal at different locations on the genome of the control DNA are used to identify any variances present in the sample DNA. aCGH facilitates the clinical diagnosis of submicroscopic chromosomal duplication, deletion and rearrangements indicative of chromosomal disorders such as trisomies 1-22 and specific sex linked disorders. <br />
Duplication in the DNA are displayed by the computer program as spikes/ peaks over an established threshold and deletions in DNA are displayed by the computer program as spikes/ toughs beneath this threshold. <br />
===Next Generation Sequencing===<br />
The development and advances within ART in the past 20 years, as well as the increasing popularity of IVF, has lead to an influx of new technologies developed to screen embryos for chromosomal anomalies, which are covered by the umbrella term of Next generation Sequencing (NGS). NGS is a general term used to describe all of the new and emerging screening techniques currently being introduced and used as part of PGD for IVF. NGS screens for single gene disorders as well as conducting extensive and very comprehensive chromosome diagnosis by sequencing, counting, and accurately assembling millions of DNA reads, simultaneously<ref name="PMID23499002"><pubmed>23499002</pubmed></ref>. NGS is expected to replace the other limited and outdated testing techniques and be used as the standard test in the future. <br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="13" |'''Advantages''' <br />
|-bgcolor="FFFAFA" <br />
| Cost effective<br />
|-bgcolor="FFFAFA"<br />
| Accurately tests all 24 chromosomes.<br />
|-bgcolor="FFFAFA"<br />
| Tests for the presence of monogenic diseases of known genetic background.<br />
|-bgcolor="FFFAFA"<br />
| Reduces the number of biopsies required for diagnosis.<br />
|-bgcolor="FFFAFA"<br />
| Higher detection rate of small translocations is possible. <br />
|-bgcolor="FFFAFA"<br />
| Testing for compound point mutations, chromosomal duplication, deletions and insertions is highly accurate<ref name="PMID23312231"><pubmed>23312231</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| It accurately detects chromosomal aneuploidy and unbalanced rearrangement<ref name="PMID25685330"><pubmed>25685330</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| Higher detection rate of small translocations is possible.<br />
|-bgcolor="FFFAFA"<br />
| NGS single gene disorder screenings can be conducted in conjunction with PCR comprehensive chromosomal screening.<br />
|-bgcolor="FFFAFA"<br />
| Human error is reduced.<br />
|-bgcolor="FFFAFA"<br />
| It detects the presence of mosaicism better.<br />
|-bgcolor="FFFAFA"<br />
| Work well in conjunction with CGH and aCGH as part of PGD, improving the chances of IVF. <ref> Morris, R. S. (2015 ) Next generation sequencing for PCG|PGS|CCS. IVF1 retrieved from [http://www.ivf1.com/next-generation-sequencing for-pgd] </ref><br />
|-bgcolor="DDCEF2"<br />
| rowspan'''Disadvantages''' <br />
|-bgcolor="FFFAFA"<br />
| There are limited information available to clinical applications of NGS <ref><pubmed>26100406</pubmed></ref><br />
|}<br />
====Procedure====<br />
Samples are collected from either blastomere or the blastocyst/tropoectoderm and processed for analysis by a computer system. <br />
The methodology of each process is unique to the technique being used. the popularity of the new and emerging techniques is due to the cost effective nature of their testing, their speed and the accuracy of their results. Please see the table above for advantages of NGS.<br />
==Diagnosis==<br />
[[File:ACGH tracing after trophectoderm biopsy.jpeg|thumb|450px|Array comparative genomic hybridization (aCGH) tracing after trophectoderm biopsy: (a) normal male embryo (female embryo control in blue); (b) female embryo with monosomy for chromosome 20 (male control in red); (c) an excellent quality blastocyst showing chaotic chromosome abnormalities. Nearly every chromosome is aneuploidy<ref name="PMID26237262"/>.]]<br />
There are a large amount of diseases that PGD can apply to, below are descriptions of the diseases that PGD are more commonly used for. Upon completion of the genetic testing for the genes of concern the cells the embryos are discarded and priority is given to those that are healthy. <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/><br />
===Cystic Fibrosis===<br />
Cystic fibrosis is a single gene disorder. It is autosomal recessive and involves mutations in the cystic fibrosis transmembrane conductance regulator (CTFR) gene. The CTFR gene is normally responsible for the decrease in chloride and the transport of bicarbonate in epithelial cells thus playing a major physiological role. In PGD procedures, identification of the gene is assisted by microsatellite markers that have similar composition to the CTFR gene itself. Biopsy of two cells at the blastocyst stage is recommended if markers are not available. There are many variations of cystic fibrosis the most common being P.Phe508del <ref name="PMID26014425"><pubmed>26014425</pubmed></ref>.<br />
<br />
===Autosomal Recessive Meckel-Gruber Syndrome===<br />
Autosomal recessive genetic defect caused by the TMEM67 gene. It results in cystic dysplasia of the kidneys with fibrotic change in the liber and occipital encephalocele. Other malformations could also be present in the central nervous system. In PGD whole genome amplification of single blastomeres are taken to identify the gene, this is also coupled with PCR techniques. Maternal plasma can also be extracted for PGS. <ref><pubmed>24039893</pubmed></ref> <br />
===β – Thalassemia=== <br />
β – Thalassemia is known as the most common type of autosomal recessive inherited disorder among haemoglobinopathies. It involves the adult β-globin gene and is associated with the absent or decreased expression of the gene. This is commonly caused by a single nucleotide change in the gene. PGD has been used successfully worldwide to identify the β-globin gene where its application is usually performed on a single blastomere or polar body <ref name="PMID19064120">19064120</pubmed></ref>.<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
! Applicable diseases for PGD <ref>Genoma Group (2014). Retrieved September 18th, 2015, from http://www.preimplantationgeneticdiagnosis.it/genetic-diseases-diagnosed-by-pgd.htm </ref> <ref>Genesis Genetics (2015). Retrieved September 18th, 2015, from http://genesisgenetics.org/pgd/what-we-test-for/</ref> <ref>Human Fertilisation & Embryology Authority (2015). Retrieved Septembr 18th, 2015, from http://guide.hfea.gov.uk/pgd/</ref><br />
|-<br />
| '''Disease'''<br />
| '''Involved Genes'''<br />
|-<br />
| 5 Alpha Reductase Deficiency (5ARD)<br />
| SRD5A2 [http://www.omim.org/entry/607306]<br />
|-<br />
| Achondroplasia<br />
|FGFR3 [http://www.omim.org/entry/134934]<br />
|-<br />
| Acute Intermittent Porphyria <br />
| ALAD [http://www.omim.org/entry/125270] , ALAS2 [http://www.omim.org/entry/612732], CPOX [http://www.omim.org/entry/612386], FECH [http://www.omim.org/entry/612386], HMBS [http://www.omim.org/entry/609806], PPOX [http://www.omim.org/entry/600923], UROD [http://www.omim.org/entry/613521], or UROS [http://www.omim.org/entry/606938]<br />
|-<br />
| Adrenoleukodystrophy (Adrenomyeloneuropathy)<br />
| ABCD1 [http://www.omim.org/entry/300371]<br />
|-<br />
| Agammaglobulinaemia (x-linked) <br />
|BTK [http://www.omim.org/entry/300300]<br />
|-<br />
| Agammaglobulinemia Bruton Tyrosine Kinase (BTK) <br />
|BTK [http://www.omim.org/entry/300300]<br />
|-<br />
| Aicardi Goutieres Syndrome 1 (AGS1) <br />
|TREX1 [http://www.omim.org/entry/606609] , RNASEH2A [http://www.omim.org/entry/606034] , RNASEH2B [http://www.omim.org/entry/610326] , RNASEH2C [http://www.omim.org/entry/610330], SAMHD1 [http://www.omim.org/entry/606754]<br />
|-<br />
| Alagille Syndrome<br />
|JAG1 [http://www.omim.org/entry/601920] or NOTCH2<br />
|- <br />
| Alpers-Huttenlocher Syndrome <br />
|POLG [http://www.omim.org/entry/174763]<br />
|-<br />
| Alpha-1-antitrypsin deficiency <br />
|SERPINA1 [http://www.omim.org/entry/107400]<br />
|-<br />
| Alpha-Mannosidosis<br />
| MAN2B1[http://www.omim.org/entry/609458]<br />
|-<br />
| Alpha Thalassemia <br />
|HBA1[http://www.omim.org/entry/141800]or HBA2 [http://www.omim.org/entry/141850] <br />
|-<br />
| Alports Syndrome<br />
|COL4A3 [http://www.omim.org/entry/120070] , COL4A4 [http://www.omim.org/entry/120131] , COL4A5 [http://www.omim.org/entry/303630]<br />
|-<br />
| Alzheimer's Disease - early onset (Type 3 and 4) <br />
|APP [http://www.omim.org/entry/104760] , PSEN1 [http://www.omim.org/entry/104311], or PSEN2 [http://www.omim.org/entry/600759] <br />
|-<br />
| Amyotrophic Lateral Sclerosis 1 (ALS1) <br />
| C9orf72 [http://www.omim.org/entry/614260], SOD1 [http://www.omim.org/entry/147450], TARDBP [http://www.omim.org/entry/605078], FUS [http://www.omim.org/entry/137070], ANG [http://www.omim.org/entry/105850] , ALS2 [http://www.omim.org/entry/205100], SETX [http://www.omim.org/entry/608465], VAPB [http://www.omim.org/entry/605704]<br />
|-<br />
| Argininosuccinic Aciduria <br />
| ASL [http://www.omim.org/entry/608310]<br />
|-<br />
| Arrhythmogenic Right Ventricular Cardiomyopathy/ Dysplasia (ARVC/D)<br />
| DSG2 [http://www.omim.org/entry/125671]; DSP [http://www.omim.org/entry/125647] ; PKP2 [http://www.omim.org/entry/602861]<br />
|-<br />
| Ataxia Telangiectasia<br />
| ATM [http://www.omim.org/entry/607585]<br />
|-<br />
| Autosomal Recessive Meckel-Gruber Syndrome<br />
| TMEM67 [http://www.omim.org/entry/609884]<br />
|-<br />
| Bardet-Biedl Syndrome (BBS)<br />
| BBS1 [http://www.omim.org/entry/209901]; BBS10 [http://www.omim.org/entry/610148]<br />
|-<br />
| Barth Syndrome<br />
| TAZ [http://www.omim.org/entry/300394]<br />
|-<br />
| Beta Thalassaemia<br />
| HBB [http://www.omim.org/entry/141900]<br />
|-<br />
| Birt-Hogg-Dubé Syndrome<br />
| FLCN<br />
|-<br />
| Breast Ovarian Cancer Familial Susceptibility (BRCA2)<br />
| BRCA1; BRCA2<br />
|-<br />
| Canavan Disease <br />
| ASPA<br />
|-<br />
| Carnitine-Acylcarnitine Translocase Deficiency <br />
| SLC25A20<br />
|-<br />
| Cerebral Arteriopathy with Subcortical Infarcts & Leukoencephalopathy (CADASIL)<br />
| NOTCH3<br />
|-<br />
| Cerebral Cavernous Malformation<br />
| CCM1<br />
|-<br />
| Charcot-Marie-Tooth Disease<br />
| GJB1; MPZ; NEFL; PMP22<br />
|-<br />
| CHARGE Syndrome<br />
| CHD7<br />
|-<br />
| Cherubism<br />
| SH3BP2<br />
|-<br />
| Choroideremia<br />
| CHM<br />
|-<br />
| Chronic Granulomatous Disease<br />
| CYBB; NCF1<br />
|-<br />
| Ciliary Dyskinesia<br />
| DNAH5<br />
|-<br />
| Citrullinemia<br />
| ASS1<br />
|-<br />
| Cleidocranial Dysplasia<br />
| RUNX2<br />
|-<br />
| Cockayne Syndrome<br />
| ERCC6<br />
|-<br />
| Congenital Adrenal Hyperplasia<br />
| CYP21A2<br />
|-<br />
| Congenital Cataracts<br />
| GJA8; VSX2<br />
|-<br />
| Congenital Diarrhea, Syndromic<br />
| SPINT2<br />
|-<br />
| Congenital Disorders of Glycosylation (CDG)<br />
| ALG1; ALG6; CDG1C; DOLK; PMM2<br />
|-<br />
| Cornelia de Lange Syndrome <br />
| NIPBL<br />
|-<br />
| Craniosynostosis<br />
| TWIST1<br />
|-<br />
| Crouzon Syndrome<br />
| FGFR2<br />
|-<br />
| Cysteinyl Leukotriene Receptor 1 Deficiency <br />
| CYSLTR1<br />
|-<br />
| Cystic Fibrosis<br />
| CFTR<br />
|-<br />
| Diamond –Blackfan Anemia <br />
| RPS19<br />
|-<br />
| Duchenne Muscular Dystrophy <br />
| DMD<br />
|-<br />
| Dyskeratosis congenita (Male embryos only)<br />
| DKC1<br />
|-<br />
| Ectodermal dysplasia (Hypohidrotic)<br />
| EDA; EDA1; GJB6; IKBKG<br />
|-<br />
| Familial Adenomatous polyposis coli (FAP)<br />
| APC<br />
|-<br />
| Familial Dysautonomia<br />
| IKBKAP<br />
|-<br />
| Fanconi Anemia <br />
| FANCA; FANCC; FANCD2; FANCF; FANCG; FANCJ<br />
|-<br />
| Fragile X Syndrome (FRAX)<br />
| FMR1<br />
|-<br />
| Galactosemia <br />
| GALT<br />
|-<br />
| Gangliosidosis<br />
| GLB1<br />
|-<br />
| Glanzmann Thrombasthenia <br />
| ITGA2B<br />
|-<br />
| Glutaric Acidemia (aciduria)<br />
| GCDH <br />
|-<br />
| Glycogen Storage Disease <br />
| G6PC; GAA; SLC37A4<br />
|-<br />
| Haemophilia A<br />
| F8<br />
|-<br />
| Haemophilia B<br />
| F9<br />
|-<br />
| Hereditary Nonpolyposis Colorectal Cancer: Lynch Syndrome<br />
| MLH1; MSH2; MSH6<br />
|-<br />
| Holt Oram Syndrome<br />
| TBX5<br />
|-<br />
| Huntington Disease<br />
| HD<br />
|-<br />
| Hydrocephalus<br />
| L1CAM<br />
|-<br />
| Ichthyosis <br />
| ABCA12; STS<br />
|-<br />
| Incontinentia Pigmenti (IP)<br />
| NEMO<br />
|-<br />
| Joubert Syndrome 5<br />
| INPP5E<br />
|-<br />
| Krabbe Disease<br />
| GALC<br />
|-<br />
| Leber Congenital Amaurosis (LCA)<br />
| CEP290; GUCY2D<br />
|-<br />
| Leigh Syndrome (Infantile Subacute Necrotising Encephalopathy)<br />
| LRPPRC<br />
|-<br />
| Lesch Nyan Syndrome<br />
| HPRT1<br />
|-<br />
| Leukocyte Adhesion Deficiency (Type I)<br />
| ITGB2<br />
|-<br />
| Li-Fraumeni Syndrome<br />
| TP53<br />
|-<br />
| Macular Dystrophy Retinal <br />
| VMD2<br />
|-<br />
| Maple Syrup Urine Disorder (MSUD)<br />
| BCKDHB<br />
|-<br />
| Marfan Syndrome <br />
| FBN1<br />
|-<br />
| Menkes Syndrome<br />
| ATP7A<br />
|-<br />
| Mitochondrial DNA Depletion Syndrom <br />
| POLG; RRM2B; SUCLA2; TK2<br />
|-<br />
| Mucolipidosis type II<br />
| GNPTAB<br />
|-<br />
| Multiple Endocrine Neoplasia<br />
| MEN1; MEN2A; MEN2B<br />
|-<br />
| Multiple Exostoses<br />
| EXT1; EXT2 <br />
|-<br />
| Myotubular myopathy<br />
| MTM1 <br />
|-<br />
| Nail-Patella Syndrome<br />
| LMX1B<br />
|-<br />
| Neurofibromatosis Type 1<br />
| NF1<br />
|-<br />
| Neurofibromatosis Type 2 <br />
| NF2<br />
|-<br />
| Noonan Syndrome<br />
| KRAS, PTPN11; SOS1<br />
|-<br />
| Norrie Disease<br />
| NDP<br />
|-<br />
| Ocular Albinism <br />
| GPR143<br />
|-<br />
| Oculocutaneous Albinism <br />
| OCA2; TYR <br />
|-<br />
| Oculodentaldigital Dysplasia<br />
| GJA1<br />
|-<br />
| Optic Atrophy<br />
| OPA1<br />
|-<br />
| Ornithine Transcarbamylase Deficiency <br />
| OTC<br />
|-<br />
| Osteogenesis imperfeca <br />
| COL1A1; COL1A2<br />
|-<br />
| Osteopetrosis <br />
| CLCN7; OSTM1; TCIRG1<br />
|-<br />
| Pachyonychia Congenita <br />
| KRT16; KRT6A<br />
|-<br />
| Pancreatitis, Hereditary<br />
| PRSS1 <br />
|-<br />
| Papillorenal syndrome <br />
| PAX2<br />
|-<br />
| Phenylketonuria <br />
| PAH <br />
|-<br />
| This table does not cover the complete list of diseases that PGD can be applied to.<br />
|}<br />
==Laws & Legal status==<br />
{| class="wikitable" <br />
|-bgcolor="DDCEF2"<br />
|'''Country'''<br />
|'''Legislation'''<br />
|-bgcolor="FFFAFA" <br />
| Australia<br />
| PGD is currently used to detect serious genetic conditions to improve the outcome of Assisted Reproductive Technologies (ART). In very rare cases it may be used to select an embryo with compatible tissue for a sibling who has a life-threatening disease where other means of treatment is unavailable. This is with the conditions that the use of PGD will not affect the welfare and interests of the child to be born. The parents must also receive adequate counselling and have full understanding of the procedures of PGD. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"> National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art</ref><br />
The use of PGD for sex-selection is prohibited with the exception of reducing the risk of the transmission of serious sex-linked genetic conditions. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"/><br />
|-bgcolor="FFFAFA"<br />
| Brazil<br />
| The laws regarding PGD in Brazil are not strictly regulated. They are vague and there is limited information surround the activities of assisted reproduction in general in the country <ref name="PMID25493379"><pubmed>25493379</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| Czech Republic<br />
| The laws in the Czech Republic allow those with a “defined indication in order to exclude risk of serous genetically conditioned disease and defects with embryos before they are implanted into the cavity of the uterus”. Couples that undergo any assisted reproductive treatment including PGD have to be married. Sex-selection is illegal except in regards to serious sex-linked genetic diseases <ref name="PMID24777348"><pubmed>24777348</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| Greece<br />
| In Greece, ART is open to those up to the age of 50 with written consent. It can only be used if a medical necessity is present such as the susceptibility of serious hereditary diseases. Sex selection is banned apart from cases of sex-linked diseases and sexually transmitted diseases <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| India<br />
| In India there is a cultural preference for boys thus the Prenatal Diagnostic Techniques (Regulation and Prevention of Misuse) Act was introduced in 1994. This law limits the use of PGD for sex determination except in cases of specific congenital diseases. These laws however are not strictly enforced. <ref>World Health Organisation (2015) Gender and Genetics Retrieved on October 21st 2015 from:http://www.who.int/genomics/gender/en/index4.html</ref><br />
|-bgcolor="FFFAFA"<br />
| Portugal <br />
| ART is only available to those who are married or have a similar type of relationship for at least two years. The couples cannot be of the same sex and must be at least 18 years of age. Sex selection is illegal except in cases of sex-linked diseases. The use of PGD is illegal if the predictive value of genetic tests are very low <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| Spain<br />
| PGD can be applied to “serious hereditary diseases not amenable to postnatal curative treatment” and “detection of other abnormalities which may compromise the viability of the pre-embryo”. If PGD is to be used for any other purpose authorisation must be acquired <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| Sweden <br />
| The use of PGD is strictly regulated and couples must achieve authorisation of the National Board of Health and Welfare. It can only be used it can only be used if the child is at risk to inheriting a serious chromosomal or monogenetic disease. It cannot be used for selection of specific characteristics <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| United Kingdom<br />
| Those involved with carrying out the IVF treatment must have a license from the Human Fertilisation and Embryology Authority (HFEA). Only embryos that are approved by the HFEA can be implanted where the embryonic nuclear or mitochondrial DNA cannot be altered with the exception of preventing mitochondrial diseases <ref name="PMID24777348"/>. <br />
|}<br />
==Future/Current Research==<br />
In addition to research efforts for improving overall performance of established PGD/S techniques, such as finding the ideal zona pellucida insection site in an fully automatic manner<ref name="PMID26259216"><pubmed>26259216</pubmed></ref>, many research efforts have been spent to find alternative, non-invasive techniques to test for diseases and abnormalities<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
===Non-invasive Preimplantation Genetic Testing without Embryo Biopsy===<br />
Different parameters of gametes, zygotes, embryos (“vacuoles in sperm heads, spindle position in mature oocytes, cleavage intervals of zygote, and embryo developmental dynamics”) may correlate with aneuploidy rates. This knowledge may be applied in potential noninvasive preimplantation diagnostic methods. Several methods have been proposed and are currently further researched<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Sperm Selection====<br />
Intracytoplasmic morphologically selected sperm injection (IMSI) is common procedure in IVF treatment to improve fertilization rates in patients with poor semen quality. In addition, studies have found that IMSI improves embryo development and that spermatozoa with large vacuoles in their heads correlate with increased aneuploidy rates and disturbed chromosomal structures. Thus, selecting spermatozoa based on morphological hallmarks may decrease aneuploidy rates in the fertilized embryos. As with polar body biopsies, however, this approach will solely be applicable if evidence for severe male detrimental contribution is given<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Blastocoel Fluid Extraction====<br />
In addition, a less invasive retrieval of material for diagnosis could include the extraction of the blastocoel fluid. The cavity of the blastocyst, lined by the trophectoderm, is filled with this blastocoel fluid, which contains metabolites of both trophectoderm and inner cell mass origin. The retrieval does not require a biopsy but merely a small opening to extract the fluid and, thus, causes less harm to the embryo. Multiple studies have applied this method<ref name="PMID22020776"><pubmed>22020776</pubmed></ref> <ref name="PMID23148560"><pubmed>23148560</pubmed></ref> <ref name="PMID26006737"><pubmed>26006737</pubmed></ref> and it may in the future become of clinical relevance.[[File:Aspiration_of_the_Blastocoel_Fluid.jpeg|400px|thumb|Aspiration of the Blastocoel Fluid using a ICSI pipette<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.]]Next to metabolites, the blastocoel fluid can contain DNA. Studies have shown that genomic DNA is present in about 90% of the blastocoel fluid samples tested. Typically the fluid is removed with an ICSI pipette from a day five blastocyst through its mural trophectoderm until the blastocyst fully collapses around the embryo. Several concerns regarding this method in a clinical setting have been raised. The collected DNA may be contaminated by the culture media that contains DNA fractions. The DNA may also be least representative of the actual embryos genome as the DNA may originate from abnormal or degenerated cells. Even though labelled noninvasive, the blastocyst still undergoes manipulation to some degree which may affect its viability. Thus, more research is required until this method can evolve from research to clinical use<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
====Proteomics and Medium Based PGD====<br />
The media in which embryos are kept during the early IVF procedures, gives rise to potential non-invasive techniques. For instance, the protein secretome of blastocysts may be representative of its chromosome constitution Recent studies have found biomarkers such as lipocalin-1, interleukin-10, tumor necrosis factor, stem cell factor, and chemokine ligand 13 to be differently secreted by aneuploid blastocyst than by euploid ones. The most significant biomarker appears to be interleukin-10. Paired with novel proteomic technologies and mass spectrometry this knowledge when extended may contribute to a new invasive PGD method<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. In addition, medium based non-invasive PGD has been researched for the diagnose of human α-thalassemia-SEA. Genomic DNA was collected from the media and the study surprisingly resulted in increased diagnosis efficacy compared to biopsy-based methods<ref name="PMID25816038"><pubmed>25816038</pubmed></ref>.<br />
====Embryo Morphology====<br />
Using time lapse imaging the embryo’s morphology can be closely observed and potential aneuploidy characteristics detected. Such characteristics may include the time of division to five cells, the time between the division from three to four cells, and the duration of the division from one to two and subsequently to three. In addition, the morphological quality of ICM an TE has been positively associated with aneuploidy or euploidy prognosis<ref name="PMID26246880"><pubmed>26246880</pubmed></ref>. These may give rise to an embryo quality screening prior to implantation<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
==Glossary==<br />
'''Aberrent Cells'''<br />
<br />
'''Abnormalities:'''<br />
<br />
'''Allele:'''<br />
<br />
'''Anneuploidy:'''<br />
<br />
'''Annelaing:'''<br />
<br />
'''Aspiration:'''<br />
<br />
'''Biopsy:''' sample of tissue taken for examination <br />
<br />
'''Blastocyst:''' Stage of embryo at approximately day 5 consisting of an outer (trophoblast) layer and inner (embryoblast) cell mass. <br />
<br />
'''Blastomere:''' Initial cells formed through mitosis of the zygote<br />
<br />
'''Chromosome'''<br />
<br />
'''CTFR:''' Cystic Fibrosis Transmembrane Conductance Regulator, responsible for transport of chloride across the cell membrane<br />
<br />
'''Cytoplasmic Bridge:'''<br />
<br />
'''Denaturing:'''<br />
<br />
'''DNA:'''<br />
<br />
'''Endometriosis:''<br />
<br />
'''Enucleation:'''<br />
<br />
'''Epigenetic:'''<br />
<br />
'''Extension:'''<br />
<br />
'''Fluorescent In situ hybridisation:''' technique use to locate specific gene sequences using fluorescence tags <br />
<br />
'''Genome:'''<br />
<br />
'''Heterozygosity:'''<br />
<br />
'''Haemotological:'''<br />
<br />
'''Hydrosalphinx:''' <br />
<br />
'''Intracytoplasmic Morphologically Selected Sperm Injection (IMSI):''' IVF technique involving morphological selection of sperm under the microscope to be injected to oocyte<br />
<br />
'''Intracytoplasmic Sperm Injection (ICSI):''' IVF technique used to treat male infertility and involves direct injection of one sperm into an oocyte<br />
<br />
'''In Vitro:'''<br />
<br />
'''IVF:'''<br />
<br />
'''Leukocyte:'''<br />
<br />
'''Leukemia:'''<br />
<br />
'''Locus:''<br />
<br />
'''Micorarray:'''<br />
<br />
'''Mitochondria:'''<br />
<br />
'''Molecular anomalies:'''<br />
<br />
'''Next Generation Sequencing (NGS):''' Term used to describe the collection of recent findings regarding embryo screening<br />
<br />
'''Oolema'''<br />
<br />
'''Phenotype:'''<br />
<br />
'''Polar bodies:''' cell formed during the meiotic stages of the oocyte containing extra genetic material <br />
<br />
'''Polymerase Chain Reaction (PCR):''' Technique used to amplify DNA to study a specific genetic sequence<br />
<br />
'''Polyploidy:'''<br />
<br />
'''Preimplantation Genetic Diagnosis (PGD):''' Involves genetic testing conducted to identify abnormalities in an embryo before implantation.<br />
<br />
'''Preimplantation Genetic Screening (PGS):''' Involves genetic screening for genetic abnormalities using techniques such as FISH and PCR to eliminate unhealthy embryos <br />
<br />
'''Perivitelline Space:''<br />
<br />
'''Primer:'''<br />
<br />
'''Robertsonian Translocations:''' Type of structural chromosomal translocation <br />
<br />
'''Single Gene Disorders:''<br />
<br />
'''Self Annealing:'''<br />
<br />
'''Submicroscopic:'''<br />
<br />
'''Translocations:'''<br />
<br />
'''Trisomies:'''<br />
<br />
'''Trophoectoderm:'''<br />
<br />
'''Zona Pellucida:'''<br />
<br />
<br />
==References==<br />
<br />
<references/><br />
<br />
<br />
{{StudentPage2015}}</div>Z5017878https://embryology.med.unsw.edu.au/embryology/index.php?title=2015_Group_Project_6&diff=2085092015 Group Project 62015-10-23T09:50:28Z<p>Z5017878: </p>
<hr />
<div>{{ANAT2341Project2015header}}<br />
<br />
<br />
=Preimplantation Genetic Diagnosis and Preimplantation Genetic Screening=<br />
==Introduction==<br />
Preimplantation genetic diagnosis (PGD) and preimplantation genetic screening (PGS) are reproductive options for couples with known family histories of genetic disease or couples undergoing IVF procedures due to infertility issues. PGD can diagnose many genetic disorders caused by known chromosomal abnormalities (number and/or structure) or single gene mutations, and, thus decrease the risk of termination of pregnancy or miscarriages and enable such couples to have an unaffected child<ref name="PMID24907939"><pubmed>24907939</pubmed></ref>. Through major improvements in PGD/S and general laboratory technology, the testing for abnormalities in fetuses has shifted from prenatal diagnosis during the first 2 trimesters <ref> Blackburn, S.L. (2003) '''Maternal, Fetal & Neonatal physiology: a Clinical perspective''' (2nd ed.). Seattle: Saudners </ref>, testing for overall fetal growth, complications of pregnancy, and birth defects<ref> Sadler T.W.(2012) '''Langman's Medical Embryology''' (12th ed.) Philadelphia: Lipincott, Wiliams & Wilkins, a Wolters Kluwer Business </ref>, to an embryonic focus especially in advancements in Artificial Reproductive Technologies (ART)<ref><pubmed>20638568</pubmed></ref>. In 1990 PGD for a recessive X-linked disease resulted in the first live birth<ref><pubmed>2330030</pubmed></ref> and has since been incorporated in clinical routine and applied for a variety of genetic diseases, such as sickle cell anemia, thalassemia, or cystic fibrosis<ref name="PMID24907939"/>.<br />
[[File:Preimplantation Genetic Diagnosis Procedure.jpeg|600px|left|thumb| Simplified steps for PGD<ref name="PMID24907939"/>]]<br />
{|class="wikitable"align="right" <br />
| <html5media height="400" width="533">https://www.youtube.com/watch?v=0e-79qKllqk</html5media><br />
|-<br />
| Preimplantation Genetic Diagnosis<ref>IVF Florida (2011, December 11) IVF Florida - South Florida Fertility Specialists - Pre-Implantation Genetic Diagnosis [Video file]. Retrieved from https://www.youtube.com/watch?v=0e-79qKllqk</ref><br />
|}<br />
==History==<br />
The advances in reproductive technology during the second half of the 20th century, led to PGD's first clinical application in 1990 <ref>Harper, J. (n.d.). The history of PGD. Lecture. UCL Centre for PG&D and CRGH.University College London</ref>.<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
|Year<br />
|<br />
|- bgcolor="FFFAFA"<br />
| '''1967''' <br />
|First PGD on rabbit blastocysts (Gardner& Edwards) <ref name="PMID6036172"><pubmed>6036172</pubmed></ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1986''' <br />
|First Cleavage Biopsy (Wilton & Trounson)<ref>Wilton, L. J., & Trounson, A. O. (1986). Viability of mouse embryos and blastomeres following biopsy of a single cell. In Proceedings of the 18th Annual Conference of the Australian Society for Reproductive Biology, Brisbane, Australia.</ref><br />
|- bgcolor="FFFAFA"<br />
|'''1987''' <br />
|First Blastocyst Biopsy (Muggleton-Harris, Monk, Rawlings, & Whittingham)<ref name="PMID3372699"><pubmed>3372699</pubmed></ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1988''' <br />
|First Polar Body Biopsy (Yury Verlinksy)<ref> Verlinsky, Y., Pergament, E., Andresen, P., Enriquez, G., & Strom, C. (1989). Genetic analysis of polar body DNA: A new approach to preimplantation genetic diagnosis. Am J Hum Genet, 45(4), A272.</ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1990''' <br />
|First Clinical PGD using PCR testing for X-linked (Handyside, Kontogianni, Hardy, & Winston)<ref name="PMID2330030"><pubmed>2330030</pubmed></ref> <br />
|} <br />
==Preimplantation Genetic Diagnosis==<br />
[[File:Pre-PGD workup.jpeg|thumb|400px|Pre-PGD workup for a family with a previous child with spinal muscular atrophy. Panel (a) shows how the study of both parents and grandparents allows the phasing of the SMN mutation relative to polymorphic short tandem repeat (STR) markers; panel (b) shows the maternal and paternal haplotypes M1, M2, P1 and P2 and the distance of the STR markers from the SMN gene; panel (c) shows the four predicted fetal haplotypes. These reflect a Hardy–Weinberg equilibrium of one homozygous non-carrier, two heterozygous carriers and one that is homozygous and affected. Short tandem repeat markers linked with the SMN mutation are shown in red. DEL indicates the presense of the exon 7 (840 C>T) mutation<ref name="PMID26237262"/>.]]<br />
PGD is used to test the genetic makeup of embryos to detect single gene disorders, chromosomal abnormalities and mitochondrial disorders. It also has applications in gender selection for diseases with unequal gender distributions <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Some diseases commonly involved with PGD include cystic fibrosis, spinal muscular atrophy and beta – thalassaemia <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press.">Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press</ref> <ref name="PMID17823145"><pubmed>17823145</pubmed></ref>. It was first used in the United Kingdom in the 1980s, primarily focusing on sex- linked disorders <ref name="PMID17823145"/><ref name="PMID23150080"><pubmed>23150080</pubmed></ref>. PGD is now capable of detecting single cell defects (molecular) and chromosomal disorders resulting from the inversion, translocation or deletion of chromosomes (cytogenic) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/> <ref name="PMID11325751"><pubmed>11325751</pubmed></ref>. PGD can be applied to the embryo at different stages. That is on polar bodies, blastomeres or blastocyst <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>.<br />
Depending on the type of genetic disorder, PGD utilises different methods of genetic testing. These include Fluorescence in situ hybridisation (FISH) which is used for sex – linked disorders and detects chromosomal rearrangements <ref name="PMID11325751"/><ref name="PMID17876073"><pubmed>17876073</pubmed></ref> and Embryo halotyping which allows the identification of chromosomes causing the inherited disorder through knowledge of the pattern of closely linked markers <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. Polymerase chain reaction (PCR) is also widely used to detect molecular abnormalities <ref name="PMID11325751"/>.<br />
PGD is tightly regulated and supported by large organisations namely The American Society for Reproductive Medicine, The European Society for Human Reproduction and Embryology (ESHRE), The European Society of Human Genetics and the Preimplantation Genetic Diagnosis International Society <ref name="PMID25500181><pubmed>25500181</pubmed></ref>.<br />
===Sex-linked disorders===<br />
The determination of a disease as gender specific usually correlates with the presence or absence of specific genes such as SRY on the Y chromosome. It is known that females have two X chromosomes and males have an X and a Y chromosome where abnormalities are more prevalent on the X chromosome. PGD can be used for sex selection where only male embryos are transferred to reduce the chance of inheriting X-linked disorders. However, this does not completely eradicate the problem as male embryos remain susceptible to inheriting an affected X chromosome. Sex determination is only used when the specific mutation is unknown and has yet to be discovered <ref name="PMID24866878"><pubmed>24866878</pubmed></ref>.<br />
===Single gene defects===<br />
Single gene defects can be dominant, recessive, autosomal or X-linked. They are commonly diagnosed using PCR and although the PCR available today is complex and capable of combatting a large range of disease the development of new protocols has been proven to be difficult due to the small DNA sample available <ref name="PMID26168107"><pubmed>26168107</pubmed></ref>.<br />
===Mitochondrial disorders===<br />
Mitochondrial disorders also known as oxidative phosphorylation disorders arise from mutations in the nuclear DNA or mitochondrial DNA <ref name="PMID26312584"><pubmed>26312584</pubmed></ref>. They pose as a problem because they are unrecognisable until the mutations in the cell reach a detrimental level <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Mitochondrial disorders cause miscarriages and stillbirths as well as death in children and young adults. The effects can either be contained in a single organ or more commonly involve multiple organ failure where organs with high energy demands such as the brain, liver muscle and heart and heavily influenced. They are usually occur spontaneously or result from inheritance from the mother. Since mitochondria are solely inherited from the mother oocyte donations have been used as a solution to combat mitochondrial disorders. Additionally, there has been an increasing use in PGD where embryos that stay under the given threshold of 18% gene-mutations are allowed to be transferred and result in normal development. New technology in the areas of nuclear gene transfer and genome editing are also being experimented with <ref name="PMID26312584"/>. <br />
===Chromosomal disorders===<br />
Chromosomal disorders can be reciprocal, Robertsonian translocations, inversions, deletions and insertions <ref name="PMID26168107"/>. Data from ESHRE collected between 2010 and 2011 has shown that the most common chromosomal abnormality confronted in PGD are reciprocal chromosomal abnormalities <ref name"PMID26071418"><pubmed>26071418</pubmed></ref>. PGD has also been used successfully for Robertsonian translocations (RT), a type of structural translocation. Children who carry RT are phenotypically normal, however in their later years it is found that they will suffer from infertility and repeated miscarriages due to the high frequency of abnormal embryos <ref name="PMID22081077"><pubmed>22081077</pubmed></ref>. PCR and FISH are the two main techniques used for chromosomal disorders. To be able to conduct the examinations the cells are required to be at the metaphase stage <ref name="PMID26168107"/>. <br />
[[File:Reasons_for_PGD.jpg|600px|thumb|Reasons for PGD<ref name="PMID24764761"><pubmed><24764761</pubmed></ref>]]<br />
==Preimplantation Genetic Screening==<br />
PGS involves an array of methods or ideas that aim to segregate embryos that have genetic flaws and those that are healthy <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. The occurrence of aneuploidy is high around the stages of early embryonic development and they are the most common cause if miscarriages and congenital birth defects <ref name= "PMID26085841"><pubmed>26085841</pubmed></ref>. They have little effect on the morphology of the embryo making them difficult to identify thus identification heavily relies on genetic testing <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. <br />
Genetic sampling is most commonly conducted using Microarray Comparative Genomic Hybridisation (aCGH) as well as FISH, Quantitative PCR and Single Nucleotide Polymorphism (SNP) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. These methods collectively aim to assess numeral and structural chromosomal errors <ref name= "PMID26085841"/>. Studies have also introduced Next- Generation Sequencing (NGS) <ref name= "PMID26085841"/> and Whole Genome Amplification used to screen imbalances in the complete 24-chromosomes <ref name="PMID25953353"><pubmed>25953353</pubmed></ref>.<br />
Statistics from ESHRE have shown that the most common indications for PGS is advanced age, followed by repeated implantation failure or recurrent miscarriage and male infertility <ref name="PMID26071418"><pubmed>26071418</pubmed></ref>.<br />
===Indications===<br />
A low percentage of structural abnormalities in chromosomes are responsible for the cause of miscarriages. Despite this, they are the most prevalent type of chromosomal abnormality accounted for in PGD <ref name="PMID20638568"/>. The presence of specific gene cycles, initiation of embryonic protein synthesis and evident physiological development are all indicative of a successful in vitro fertilisation procedure <ref name="PMID11576737"><pubmed>11576737</pubmed></ref>. To eliminate further errors from occurring during the PGD procedure it is recommended to undertake further prenatal testing such as amniocentesis in the later stages <ref name="PMID20638568"/>. <br />
====Advanced maternal age====<br />
Data provided by the ESHRE has shown that the mean age of women undergoing PGS is 39 years <ref name="PMID26071418"/>. Women of advanced age have been shown to have a lower rate of pregnancies reaching childbirth <ref name="PMID18583331"><pubmed>18583331</pubmed></ref>. The highlighted concern revolves around the increased occurrence of aneuploidy following maternal age. The optimal age range for the lowest aneuploidy incidence was found to be between 27 to 37 years of age (6%) then progressively higher in women aged up to 42 (33%) and most common in those 44 and above (53%) <ref name="PMID24355045"><pubmed>24355045</pubmed></ref>. <br />
====Recurrent pregnancy loss / IVF failure====<br />
Recurrent pregnancy loss is defined as three or more IVF failures after cumulative transfer of more than 10 good-quality embryos. These are primarily caused by two main factors, reduced endometrium receptivity or embryonic defects. Endometrium receptivity can be negatively influences by instances including uterine pathologies such as thin endometrium, altered expression of adhesive molecules and immunological factors. Additionally, embryonic defects may be due to genetic abnormalities, embryonic aneuploidy or zona hardening. Endometriosis and hydrosalpinx has been known to effect both the endometrium and embryo <ref name="PMID23260857"><pubmed>23260857</pubmed></ref>.<br />
====Human leukocyte antigen matching====<br />
First used in 2001, HLA matching is an option given to parents to save a child with haematological or immunological disease through conceiving another child who would potentially be able to donate cord blood or haematopoietic stem cells from the bone marrow for transplantation. The process namely PGD-HLA has shown to improve haematopoietic stem cell transplant (HSCT). PGD-HLA can only be performed when HSCT is not needed urgently due to the time needed to conceive and delivery the baby <ref name="PMID25500181"><pubmed>25500181</pubmed></ref>. It is most commonly applied to children suffering from relapsed leukaemia <ref name="PMID22524201"><pubmed>22524201</pubmed></ref>. In a case study PGD-HLA was proven to successfully cure 10 diseases including Fanconi anaemia, Diamond-Blackfan anaemia and beta thalassemia <ref name="PMID25066893><pubmed>25066893</pubmed></ref>.<br />
==Biopsy Methods==<br />
Biopsy, the removal of genetic materials, from oocytes or embryos in the preimplantation stage is the primary step in PGD. For the past two decades these biopsies have been performed at three stages, the polar body, blastomere, and blastocyst, and the methodologies optimized to ensure the embryo’s viability. The most common approach involves biopsies at the cleavage stage. However, polar body and blastocyst biopsies are increasingly more often tested and applied. Approached for opening the zona pellucida involve next to the traditional mechanical and chemical means, novel approaches such as noncontact lasers. Their application may simplify and secure the procedure significantly. The most challenging question about PGD procedures remains at what stage biopsies should be taken. Much controversy has developed around this topic, highlighting the varying disadvantages and advantages of temporal biopsies <ref name="PMID22723007"><pubmed>22723007</pubmed></ref>.<br />
[[File:Polar_Body,_Blastomere,_and_Trophectoderm_Biopsy.jpeg|500px|thumb|Polar body (A), blastomere (B) and trophectoderm (C) biopsies<ref name="PMID25625041"><pubmed>25625041</pubmed></ref>.]]<br />
{| class="wikitable"<br />
|- align="center" bgcolor="DDCEF2"<br />
|<br />
| Time of Biopsy<br />
| Prevalence <br />
| Advantages <br />
| Disadvantages<br />
|- bgcolor="FFFAFA"<br />
| Polar Body<br />
| Day 1<br />
| ~16%<br />
| Little to no harm is caused to the oocyte and both PBs can be extracted (more genetic material)<ref name="PMID22723007"/>.<br />
| Only the maternal DNA is tested<ref name="PMID22723007"/>, often PB biopsies need to be coupled to other biopsies, and difficulties arise in distinguishing between the first and second PB<ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. Lower reliability of results compared to other biopsy methods have been reported<ref name="PMID25106935"/>. <br />
|- bgcolor="FFFAFA"<br />
| Blastomere <br />
| Day 3<br />
| ~80%<br />
| Biopsies are safe for good quality embryos and it is performed relatively early, so fresh transfer is possible, yet, it includes both paternal and maternal genetic contributions<ref name="PMID26237262"/>. <br />
| Relatively large decrease in implantation rates for low quality embryos have been reported, embryo mosaicism can influence genetic analysis, and only one to two cells can be safely removed<ref name="PMID26237262"/>. <br />
|- bgcolor="FFFAFA"<br />
| Trophectoderm<br />
| Day 5 and 6 <br />
| ~ 2%<br />
| Little harm to the embryo and large amount of genetic material can be extracted, which allows for more accurate genetic analysis and lessen effects of mosaicism<ref name="PMID26237262"/>. <br />
| The biopsy takes place relatively late and, thus, the time window for procedure is small and embryos often need to be cryopreserved<ref name="PMID22723007"/>. <br />
|}<br />
===Polar Body Analysis===<br />
Day 1<br />
====Description====<br />
[[File:Polar_Body_Biopsy.jpeg|thumb|400px|The presence of a faint but clearly identifiable strand connecting PB2 to the oolemma. The biopsy was performed ∼9 h after ICSI<ref name="PMID21908464"><pubmed>21908464</pubmed></ref>.]] <br />
Polar body (PB) biopsy offers a promising alternative to biopsies performed at the blastomere stage for PGD/S indications on legal and practical grounds<ref name="PMID22723007"/>. The ESHRE calculated the proportion of PB biopsies to be about 16.3%<ref name= "Traeger-Synodinos, J., Coonen, E., Goossens, V., De Mouzon, J., Shenfield, F., Ruiz, A., ... & de Mouzon, J. (2013). Session 09: ESHRE data reporting on PGD cycles and oocyte donation.">Human Reproduction, 28(suppl 1), i18-i19. </ref>. Embryo development does not necessitate the presence of the first and second PB and their removal may not be crucial<ref name="PMID22723007"/>. The idea behind PB biopsies is that each abnormality found in the PB corresponds to an error in the oocyte. On the other hand, in women with known single gene mutations, it is assumed that if the PB contains the mutated allele ,the oocyte will have the normal allele, thus, resulting in a healthy embryo<ref name="PMID26237262"/>. PB biopsy requires precise timing. Keeping track of the meiotic cell cycle is necessary to perform a successful biopsy and, therefore, PB biopsy usually is applied in combination with intracytoplasmic sperm injection (ICSI). During the maturation from the germinal vesicle stage to the metaphase-II stage the first PB is formed. A cytoplasmic bridge containing spindle remnants, that are still in contact with the cellular genetic material, links this PB to the oolemma for about 90 minutes after extrusion. It is possible to visualize these remnants by polarization microscopy and it is crucial to not perform the biopsy until the first PB is no longer firmly attached to the oolemma as this indicates an immature embryo.The oocyte tolerates mechanical zona dissection best during hours four until six after ICSI as the oolemma has stabilized by that time because of the cortical granule reaction. Over time the first PB degenerates stressing a temporal biopsy and its optimal extraction time window is four to 12 hours after ICSI. The second PB forms around two to four hours after ICSI. Its optimal time window for biopsy is set to be eight to 16 hours after ICSI due to the second PB being attached to the oolemma with spindle remnants until six hours after ICSI. Biopsy at this point may cause enucleation of the oocyte. Studies have shown that the amplification efficiency of second PB’s DNA is worse if the PB is extracted prior to eight hours after ICSI. Thus, it is possible to perform sequential and simultaneous biopsies for the first and second PB. If performed, sequentially the first PB may be removed four to 12 hours and the second PB eight to 16 hours after ICSI. The optimal time window for a biopsy for both the first and second PB simultaneously is eight to 12 hours after ICSI. It is highly preferred to analyze both PBs due to potential aneuploidies in either PB and crossing overs during meiosis <ref name="PMID22723007"/>. <br />
====Procedure====<br />
Chemical opening achieved with for example acidic tyrode’s solution of the zona pellucida is not tolerated by the oocyte and may have detrimental effects on the embryo’s development. Therefore, the access to the perivitelline space of the oocyte is provided by mechanical zona dissection or by laser. Both techniques work well if performed by experienced embryologist. However, laser-assisted biopsy is less time consuming when compared to manual dissection. It is critical to consider the size of the introduced opening as it will remain permanent. If it is too large the blastomere may be lost during embryo development and if it is too small it may interfere with hatching of the embryo during blastocyst stage<ref name="PMID22723007"/>.<br />
[[File:Implantation_predictive_value_of_euploid_screening_results.jpeg|thumb|450px|The sustained implantation predictive value (with 95 % confidence interval) of a euploid screening result obtained from the first polar body (PB1), PB1 and the second polar body (PB2), or a direct embryo biopsy for each stage of embryo transfer (cleavage-stage and blastocyst stage)<ref name="PMID25106935"><pubmed>25106935</pubmed></ref>.]]<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JTaQzszVr8o</html5media><br />
|-<br />
| Laser-assisted polar body biopsy<ref>RIUK, R. (2013, June 25) Polar Body Biopsy [Video file]. Retrieved from https://www.youtube.com/watch?v=JTaQzszVr8o</ref><br />
|}<br />
====Advantages & Disadvantages====<br />
PB biopsies can only investigate the maternal contributions to the embryo as they are of maternal origin. Thus, this procedure is appropriate for PGD solely for monogenetic diseases from the maternal side. Recessive diseases may be evaluated with PB biopsies on the basis that the embryo’s outcome will be determined by the paternal contribution. It may still be applied for PGS as it is a fairly safe biopsy option and most aneuploidies either arise during meiosis or origin from the maternal genome. However, diagnosis error has been reported due to the lack of considering paternal contributions<ref name="PMID22723007"/>. About 10% of PB biopsies appear to be wrongfully diagnosed with aneuploidies<ref name="PMID26237262"><pubmed>26237262</pubmed></ref>. Because PB biopsies are performed very early it is not yet known whether the oocyte will develop into a viable embryo. Thus, PBs are commonly frozen or fixed after biopsy and depending on the state of the embryo only chosen PBs will be tested. This is primarily an economic issue as many genetic testing procedures are very cost-intensive<ref name="PMID22723007"/>. Generally the sustained implantation predictive value of screening of PBs is significantly lower than of, for example, biopsies of the blastocyst stage<ref name="PMID25106935"/>. Moreover, it is often difficult to distinguish between the first and the second PB. As the first one degenerates quicker, this may influence diagnostic procedures<ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
===Blastomere biopsy===<br />
Day 3 <br />
====Description====<br />
Blastomere biopsy has been the prevalent method for PGD and PGS in the last two decades. In 2013 the ESHRE reported 79.8% of biopsies to be performed at the cleavage stage<ref name= "Traeger-Synodinos, J., Coonen, E., Goossens, V., De Mouzon, J., Shenfield, F., Ruiz, A., ... & de Mouzon, J. (2013). Session 09: ESHRE data reporting on PGD cycles and oocyte donation."/>. At least one, but up to two, blastomeres are biopsied on day three of the cleavage stage embryo. The right number of blastomeres removed is a controversial topic as two cells allow for more genetic material and more accurate results. However, removing two cells might be too invasive and damaging to the embryo. As PGS tries to improve implantation rates, whereas PGD sets out to avoid known genetic disorders, for the former only one cell is removed, while for the latter often two need to be removed, to ensure results as correct as possible<ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
====Procedure====<br />
Initially a hole was drilled into the zona pellucida using acid Tyrode's solution or by mechanical means. Nowadays the zona pellucida is largely opened using a laser and calcium and magnesium free media have been introduced to decrease junctions between blastomeres, which facilitates the biopsy. This if followed by the consequent aspiration of blastomeres with a pipette.<ref name="PMID21748341"/>. The blastomeres can also be removed by applying pressure on the outside of the zona<ref name="PMID26237262"/>.<br />
[[File:Aspiration_of_a_Blastomere.jpeg|thumb|left|400px|Aspiration of a Blastomere into the biopsy pipette<ref name=" PMID24783200"><pubmed>24783200</pubmed></ref>.]]<br />
{|class="wikitable"align="right" <br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=TbridWVwipI</html5media><br />
|-<br />
| Laser-assisted blastomere biopsy<ref>Sukprasert, M. (2014, March 5) Day 3 Blastomere Biopsy 1 [Video file]. Retrieved from https://www.youtube.com/watch?v=TbridWVwipI</ref><br />
|}<br />
====Advantages & Disadvantages====<br />
Blastomere biopsy is limited by the presence of embryo mosaicism, which can severely influence the interpretation of the genetic analysis. Approximately 15%-80% of all embryos display mosaicism on day three. Thus, any results might be a misrepresentation of the embryo as a whole. However, if good quality embryos are selected, the procedure overall is safe and does not negatively influence the embryos transition to the blastocyst stage. In a typical IVF cycle, however, not all embryos are of good quality, particularly if they have undergone cryopreservation. Studies have found that in these embryos biopsies reduce implantation rates by 12.5%-25%. Furthermore, unlike PB biopsy, the cells at the blastomere stage contain both paternal and maternal contribution, giving the genetic analysis a fuller perspective on the embryo's genetic make up. Since blastomere biopsy is performed at the third day after fertilization, it is possible complete fresh embryo transfer. Thus, no storage procedures, such as cryopreservation, are necessary<ref name="PMID26237262"/>. <br />
===Trophectoderm biopsy===<br />
Day 5 and 6<br />
====Description====<br />
The improvement of embryo culture media allowed the in vitro development of human embryos until the blastocyst stage and opened up the possibility to take blastocyst biopsies. While currently according to ESHRE datasets only about 2.3% of biopsies are performed at the blastomere stage<ref name= "Traeger-Synodinos, J., Coonen, E., Goossens, V., De Mouzon, J., Shenfield, F., Ruiz, A., ... & de Mouzon, J. (2013). Session 09: ESHRE data reporting on PGD cycles and oocyte donation."/>. During day three to day five the haploid maternal and paternal genomes come together for the first time to form the genome of the embryo. The maternal epigenetic control lessens significantly while preparing for implantation with precisely arranged events happening. The first event includes a rapid increase in the number of embryonic cells which are active in mitotic divisions and apoptosis of aberrant cells. This is followed by the formation of blastocoel (cavitation) which results from the flattening of cell located on the outside of the blastomere. Now the blastocyst will expand until the embryo hatches by rupturing the zona pellucida. The cells of the blastocyst will differentiate to form two distinct cell lineages, the outer trophectoderm and the inner cell mass<ref name="PMID22723007"/>. <br />
====Procedure====<br />
Trophectoderm biopsy is usually performed in Hepes buffered biopsy medium and opening approaches include needle cutting which has been replaced by lasers in past years. Different research groups report different timings of the opening to be the most successful. Some open the blastocyst on day three or four by creating a 25 µm which causes the trophectoderm to herniate through this hole and is, thus, accessible for biopsy. Others create this hole about four hours before biopsy which allows sufficient herniation of trophectoderm cells. It is also possible to open the blastocyst immediately before biopsy. This avoids an extra step and the inner cell mass usually is easy to locate. Blastocyst biopsies involve the removal of trophectoderm cells and the ideal time for the procedure is day five. Successful biopsies on day six have been performed, while little is known about the results of biopsies on day seven. However, since the window of implantation in humans is from day eight to ten after ovulation, day seven biopsies appear to be possible<ref name="PMID22723007"/>.<br />
[[File:Microscopic images of human blastocysts for biopsy.jpeg|thumb|400px|left|(A) Some trophectoderm cells in a blastocyst started to hatch and (B) the trophectoderm cells were biopsied with assisted laser cutting. Images in C–D show the blastocysts after vitrification and warming. Blastocysts had been cultured for 2–4 hrs after warming, showing good (ICM and trophectoderm cells) hatched (C) and hatching (D) blastocysts. The hatching blastocyst in (E) has good ICM but fair trophectoderm while the blastocyst in (F) has both fair ICM and trophectoderm. Arrows indicate ICMs and arrow heads indicate trophectoderm cells. Bar = 40 µm<ref name="PMID2190846"><pubmed>2190846</pubmed></ref>.]]<br />
{|class="wikitable"align="right"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JI_TQ8d8tNM</html5media><br />
|-<br />
| Laser-assisted blastocyst biopsy (at 00:50 min)<ref>Coco, R. (2014, April 30) Trophectoderm biopsy in a Hatching blastocyst protruding ICM [Video file]. Retrieved from https://www.youtube.com/watch?v=JI_TQ8d8tNM</ref><br />
|}<br />
====Advantages & Disadvantages====<br />
Blastocyst biopsies are believed to be less damaging to the embryo and appear to be unrelated to implantation rates. In addition, this biopsy method allows for a larger extraction of cells for genetic testing. However, since they are performed late in in vitro development, the time window for genetic testing is relatively small. Fast and accurate genetic testing methods are needed to ensure a successful and safe result from this biopsy. Thus, blastocyst biopsies may gain more popularity in the future when such methods have been developed or improved<ref name="PMID22723007"/>. Furthermore, the extraction of multiple cells may lessen the effects of mosaicism and problems during PCR, such as ADO. Studies comparing the implantation rate and screening accuracy have found that blastocysts are significantly safer. Blastocyst biopsies decrease implantation rates significantly, while biopsies at day five or six do not seem to influence implantation and delivery rates<ref name="PMID26237262"/>.<br />
==Genetic Techniques==<br />
===Polymerase Chain Reaction===<br />
PCR amplifies DNA specific to genetic sequence of interest . PCR was developed by Kay Mullis in the 1980's, for which he was awarded the Nobel prize for chemistry in 1993 <ref> Pubmed Docs (2015) Polymerase Chain Reaction (PCR) Pubmed. Retrieved from [http://www.ncbi.nlm.nih.gov/probe/docs/techpcr/]</ref>. This technique enables clinicians to monitor and diagnose diseases using minute samples such as embryonic cells <ref>Roche (2015) PCR: How We Copy DNA. Roche Molecular Systems Inc. retrieved From [http://molecular.roche.com/pcr/Pages/Process.aspx]</ref>. PCR is used to detect genetic disorders, as a part of PGD, in conjunction with IVF<ref name="PMID24301057"><pubmed>24301057</pubmed></ref>. It is used to detect molecular abnormalities, such as single gene disorders including Tay Sach, Cycstic fibrosis, Duchenne Muscular Dystrophy, Thalassemia, Huntington disease, Spinal muscular atrophy and many more. Molecular and genetic analysis require a significant amount of DNA, which can be delivered by PCR. It revolutionized the study of DNA, replacing all previous recombinant DNA technology and is a significant component of PGD procedures<ref name="PMID24907939"/>.<br />
[[File:PCR.jpg|450px|thumb|PCR amplifies DNA specific to genetic sequence of interest, enabling the monitoring and diagnose molecular abnormalities such as single gene disorders using minute samples such as embryonic cells, blood & tissue <ref name="NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute">NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref>]]<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="7" |'''Advantages'''<br />
|-bgcolor="FFFAFA"<br />
| Fast and inexpensive way of copying a target sequence of DNA.<br />
|-bgcolor="FFFAFA"<br />
| Particularly useful for the diagnosis of single cell defects.<br />
|-bgcolor="FFFAFA"<br />
| Rapid generation of results (within hours).<br />
|-bgcolor="FFFAFA"<br />
| Highly sensitive, a single molecule of DNA is sufficient for reaction.<br />
|-bgcolor="FFFAFA"<br />
| Generates DNA copies exponentially.<br />
|-bgcolor="FFFAFA"<br />
| This enables DNA amplification required for molecular and genetic diagnostic analysis<ref> Dreesen, J., Drusedaul, M., Smeets, H., Die-Smulders, C., Coonen, E., Dumoulin, J., Gielen, M., Evers, J., Herbergers, J. & Geradets, J. (2008) Validation of preimplantation genetic diagnosis by PCR analysis: genotype comparison of the blastomere and corresponding embryo, implications for clinical practice. Mol. Hum. Reprod. 14 (10):573-579.doi: 10.1093/molehr/gan052. Retrieved from [http://molehr.oxfordjournals.org/content/14/10/573.short] </ref> <ref><pubmed>20966460</pubmed></ref>.<br />
|-bgcolor="DDCEF2"<br />
| rowspan="7"|'''Disadvantages'''<br />
|-bgcolor="FFFAFA"<br />
| Only during the exponential DNA replication phase, the starting quantity sequence contained in the original sample (template DNA strand) can be determined.<br />
|-bgcolor="FFFAFA"<br />
| PCR reaction is limited to by presence of inhibitors in the sample.<br />
|-bgcolor="FFFAFA"<br />
| Self annealing due to the accumulation of the product and the stopping exponential amplification for the target sequence and reaching of a plateau<br />
quantification of the end point of reaction of PCR products make real time quantitative RT-PCR necessary<ref name="NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute">NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref>.<br />
|-bgcolor="FFFAFA"<br />
| Not a diagnostic method on its own, but requires further analysis.<br />
|-bgcolor="FFFAFA"<br />
|Low-quantity DNA template may result in amplification failure<ref name="PMID24907939"/>.<br />
|-bgcolor="FFFAFA"<br />
|Allele drop-out (ADO) in heterozygous loci is possible<ref name="PMID24907939"/>.<br />
|}<br />
====Procedure====<br />
Samples are obtained from the the blastocyst, a polar body biopsy or the blastomeres stages of the embryo. <br />
*Stage 1 Denaturing: separating the target strands of DNA <br />
The obtained sample is heated to roughly 90 degrees celcius, this heat breaks the relatively weak bonds between nucleotides that form DNA. The double stranded DNA is split into two single strands of DNA that are used as templates.<br />
*Stage 2 Annealing: Binding the Primers to the target DNA sequence <ref name="PMID25250056"><pubmed>25250056</pubmed></ref><br />
PCR will only copy the target sequence of DNA specified by specific PCR primer. These synthesized primers oligonucleotides are small artificial pieces of DNA. TAQ polymerase enzyme synthesize two new strands of DNA duplicate to the single sample DNA stand template indicated by these primers. During this stage the reaction is cooled to a temperature between 40-60 degrees Celsius. <br />
*Stage 3- Extension- making copies <br />
Each of these two copies are then used again as templates generating two further replications This cycle can occur as many 30 -40 times within a couple hours leading to billions of extra copies of the original DNA segment. Generally the optimal temperature for the further replication is roughly 72 degrees Celsius, although, this may vary according to the analysis machines used. <ref name="PMID26092180"><pubmed>26092180</pubmed></ref><br />
This process mediated by a thermocycler machine that is programmed to alter the temperature of the reaction every couple of minutes, perpetuating the cycle of DNA denaturing and synthesis. <br />
This process, generates exponentially exact copies of the original template DNA sequence, as visible in the expandable table below. <ref> Mullins, K., Francois, F.& Gibbs R.A. (1994 ) The Polymerase Chain Reaction. p3. Springer- Science +Business Media. Birkhauser, Boston<br />
Available at [https://books.google.com.au/books?hl=en&lr=&id=gjrTBwAAQBAJ&oi=fnd&pg=PR5&dq=kary+mullis+PCR&ots=mpzAyRh5ZY&sig=PQ4goNoKJ90tb3-MkPk62zrTGbw#v=onepage&q=kary%20mullis%20PCR&f=false] </ref><br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
!rowspan="2" PCR cycles<br />
|-<br />
| '''PCR Cycle'''<br />
| '''Target Copies'''<br />
|-<br />
| 1<br />
| 2<br />
|-<br />
| 2<br />
| 4<br />
|-<br />
| 3<br />
| 8<br />
|-<br />
| 4<br />
| 16<br />
|-"<br />
| 5 <br />
| 32<br />
|-<br />
| 6 <br />
| 64<br />
|-<br />
| 7 <br />
| 128<br />
|-<br />
| 8<br />
| 256<br />
|- <br />
| 9<br />
| 512 <br />
|-<br />
| 10<br />
| 1024<br />
|-<br />
| 15<br />
| 32,768<br />
|-<br />
| 20 <br />
| 1,048,578<br />
|-<br />
| 25<br />
| 33,554,432<br />
|-<br />
| 30 <br />
| 1,073,741,842<br />
|-<br />
|}<br />
===Fluorescent In Situ Hybridisation===<br />
FISH is the one of the most effective and rapid <ref name="PMID26338801"><pubmed>26338801</pubmed></ref> method as part of PGD. This technique locates a specific DNA sequences within a chromosome. FISH facilitates the clinical diagnosis of chromosomal abnormalities indicated by sequential duplications, deletions and rearrangements of chromosome, that are usually missed with microscopic analysis. This technique is especially relevant for female embryos with X-linked diseases<ref name="PMID20809319"><pubmed>20809319</pubmed></ref>. As part of PGD, it enabled the screening for aneuploidies and increased live birth rates in women with advanced age<ref name="PMID24907939"/> <ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. FISH is 99% effective when used in conjunction with competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities<ref name="PMID26338801"/>. <br />
[[File:Fluorescent In Situ Hybridisation (FISH).jpg|thumb|450px|right|'''FISH''' Specific DNA sequences using probes which have been tagged with fluorescent labels are visualised.This technique enables the clinical diagnosis of chromosomal abnormalities, indicated by sequential duplication, deletions and rearrangements of chromosome <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref>]]<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="5" |'''Advantages''' <br />
|-bgcolor="FFFAFA" <br />
| FISH is 99% effective when used in conjunction with CGH to diagnose chromosomal abnormalities<ref><pubmed>26338801</pubmed></ref>.<br />
|-bgcolor="FFFAFA" <br />
| Results are rapidly generated. <br />
|-bgcolor="FFFAFA"<br />
| Very small translocations and aneuploidies that occur within chromosomes, that would usually be missed under microscopic analysis, can be identified<ref name="Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd)">Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref>.<br />
|-bgcolor="FFFAFA" <br />
| The most common chromosomal abnormalities, such as down syndrome chromosomes 13,16,18,21 and 22<ref><pubmed>21749752</pubmed></ref>, and inheritable X-linked disease or sex chromosome anomalies such as Duchenne's Muscular Dystrophy, hemophilia, ectodermal dysplasia<ref><pubmed>17876073</pubmed></ref> can be identified.<br />
|-bgcolor="DDCEF2"<br />
| rowspan="5"|'''Disadvantages'''<br />
|-bgcolor="FFFAFA" <br />
| FISH destroys all cells tested <ref> O'Connor, C. (2008) Fluorescence in situ hybridization (FISH). Nature Education 1(1):171. retrieved from [http://www.nature.com/scitable/topicpage/fluorescence-in-situ-hybridization-fish-327] </ref>.<br />
|-bgcolor="FFFAFA" <br />
| It does not fully access all chromosomes (only ~ 12)<ref name="PMID24907939"/>.<br />
|-bgcolor="FFFAFA" <br />
| The analysis of results is dependent upon the dot quality impacted by hybridisation efficiency or the camera sensitivity<ref name="PMID17970921"><pubmed>17970921</pubmed></ref>.<br />
|-bgcolor="FFFAFA" <br />
| Some studies indicate that using FISH on a day-3 embryo biopsy decreases the rate of live births<ref><pubmed>26168107</pubmed></ref>.<br />
|}<br />
====Procedure====<br />
Samples collected from the embryo<ref name="PMID21748341"><pubmed>21748341</pubmed></ref> are collected, processed, and its DNA strands are heated and denatured causing their the individual DNA strands to break apart. Then, probes of single complimentary stands of DNA a that have been tagged with small chemical agents that glow brightly in the presence of a specific region on a chromosome are added. These specific probes then hybridize and join to their complementary DNA strand. The fluorescent tags enable the correct identification of the presence or lack thereof and location of specific chromosomes that are tested for<ref name="PMID17876073"><pubmed>17876073</pubmed></ref>. The number and the relative location of the fluorescent dots generated by the FISH images is analysed and gives rise to diagnosis<ref name="PMID17970921"><pubmed>17970921</pubmed></ref>. The probe will not fully hybridise if there has been a duplication or a deletion of the DNA - indicating chromosomal and sex chromosomal anomalies like trisomies and aneuploidies. <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref>. Different probes are used for different purposes <ref>Unique, Rare Chromosome Disorder Support Group (2013) Fluorescence in situ hybridisation (FISH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/Other/FISH%20FTNW.pdf]</ref>:<br />
*'''Locus specific tags''' detect very small imbalances, and locate isolated small portions <br />
of genes within a chromosome<br />
*'''Alphoid/Centomeric Repeat probes''' are developed from the repetitive sequence located in the middle region of each chromosome, useful in determining the number of chromosomes , detecting rearrangement and when used in conjunction with locus probes to determine the absence of genetic material on a chromosome. <br />
*'''Paint Probes''' are collections of smaller probes with their own stains that bind to a different section on the chromosome - allowing the full chromosome too be labeled a unique colour, this "full colour map" can be used to know the spectral karyotype- full chromosomal mapping is useful in examining chromosomal abnormalities. <br />
===Array Comparative Genomic Hybridisation (aCGH)===<br />
[[File:aCGH.jpg|thumb|600px|right|'''aCGH''' checks the entire genome for chromosomal imbalances, by comparing control and a sample slides contatining small segements of DNA sample microarrayed slides small segments of DNA. Illustrated by student z5020317 and adapted from <ref> NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation. retrieved from [http://www.phgfoundation.org/file/5237/]</ref> <ref name="Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45"> Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432] </ref>]]<br />
aCGH also known as Microarray analysis efficiently scans the entire genome for chromosomal imbalances. CGH was initially developed to detect the number of changes in a solid tumor mass. It uses 2 genomes comparing the sample to the control, with each labeled in a different fluorescent dye<ref name="PMID1876176"><pubmed>1876176</pubmed></ref>. Earlier CGH techniques were limited by the resolution of the imaging <ref> Lichter, P., et al. Comparative genomic hybridization: Uses and limitations. Seminars in Hematology 37, 348–357 (2000)</ref>, these initial limitations were overcome by using Microarrays in conjunction with CGh to improve the resolution of the imaging, Array Comparative Genomic Hybridisation (aCGH). This method compares sample and control microarrayed slides containing small segments of DNA (probes). <ref> Lucito, R., et al. Representational oligonucleotide microarray analysis: A high-resolution method to detect genome copy number variation. Genome Research 13, 2291–2305 (2003) </ref> the Probes used will vary according from the small (25-85 base pairs) oligonucleotides manufactured to highlight different target sequences, to the very large genomic clones (80,000- 200,00 base pairs), and as these are significantly smaller than the traditional metaphase chromosomes used for CGH, generating a higher resolution of image. <ref name="PMID22467166"><pubmed>22467166</pubmed></ref>.aCGH is used as a diagnostic tool for prenatal detection f chromosomal abnormalities <ref name="PMID19012303"><pubmed>19012303</pubmed></ref>.<br />
{|class="wikitable" align="center"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="12" |'''Advantages''' <br />
|-bgcolor="FFFAFA"<br />
| Multiple applications: prenatal genetic diagnosis, cancer diagnosis, <ref name="PMID20193845"><pubmed>20193845</pubmed></ref> genetic screening for developmental delay (learning disabilities) <ref name="PMID17309648"><pubmed>17309648</pubmed></ref>. or congenital anomalies that are suspected to be genetic in origin <ref>NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation . retrieved from [http://www.phgfoundation.org/file/5237/]</ref><br />
|-bgcolor="FFFAFA"<br />
| trace represents all chromosomes present in the human genome chromosomes 1-22 and the X & Y chromosomes, and therefore is the most accurate method for testing whole embryo aneuploidy<br />
|-bgcolor="FFFAFA"<br />
| aCGH has been extensively tested, and Validated, and is now used world wide.<br />
|-bgcolor="FFFAFA"<br />
| Detects submicroscopic alterations<br />
|-bgcolor="FFFAFA"<br />
| Detects deletions and additions and rearrangements as well as amplification, of the WHOLE genome, simultaneously.<br />
|-bgcolor="FFFAFA"<br />
| Used as a diagnostic tool for prenatal detection of chromosomal abnormalities <ref name="PMID22034057"><pubmed>22034057</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Provides high resolution genomewide screening of segmental genomic copy number variations<br />
|-bgcolor="FFFAFA"<br />
| Very accurate when used in conjunction with FISH<br />
|-bgcolor="FFFAFA"<br />
| Alone is more reliable and in detecting chromosomal abnormalities, with a higher implantation success rate, than FISH <ref name="PMID20494259"><pubmed>20494259</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Allows an in depth research focus upon specific types of rearrangements within selected chromosomal regions, a recent particular area of interest is subtelomeric and pericentromeric rearrangements<br />
|-bgcolor="FFFAFA"<br />
| Reduces the risk of failed implantation and miscarriage, improving the chance of a healthy baby <ref name="Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd)">Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref>><br />
|-bgcolor="DDCEF2"<br />
| rowspan="9" |'''Disadvantages'''<br />
|-bgcolor="FFFAFA"<br />
| Translocations and inversions of DNA are not detected<br />
|-bgcolor="FFFAFA"<br />
| Limited ability diagnosing specific polyploidies such as triploidy <ref> Unique, Rare Chromosome Disorder Support Group (2013) Microarray-based Comparative Genomic Hybridiation (array CGH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/other/array%20cgh%20ftnw.pdf] </ref><br />
|-bgcolor="FFFAFA"<br />
| Will not detect mosaicism detection <20% (cultures where >1 of 5 cells are trisomy 12)<br />
|-bgcolor="FFFAFA"<br />
| Will not detect balanced chromosomal rearrangement<br />
|-bgcolor="FFFAFA"<br />
| Will not detect duplications or deletions <80kb<br />
|-bgcolor="FFFAFA"<br />
| Will not detect point mutations within genes <ref>Washington department of education (CGH- FAQ for physicians. Signature Genomic LAboratories, LLC. Retrieved from [https://depts.washington.edu/dbpeds/Lab%20Tests/SignatureCGH-physician_FAQ.pdf]</ref><br />
|-bgcolor="FFFAFA"<br />
| will not detect chromosomal position of genomic gains<br />
|-bgcolor="FFFAFA"<br />
| Will not detect loos of heterozygosity (LOH) or Absence of heterozygosity (AOH) <ref>WiCell Research Institute Inc. (2012) Comparative Genomic Hybridization Microarray. <br />
retrieved from [http://www.wicell.org/home/cytogenetic-services/cgh-microarray/array-comparative-genomic-hybridization-acgh.cmsx]</ref><br />
|}<br />
====Procedure==== <br />
As a part of PGD fetal cell samples are collected from; the fertilized egg polar bodies, the blastomere (day 3 embryo) or the blastocyst/tropoectoderm stage (day 5 embryo).<br />
Sample DNA is labeled with one fluorescent dye, and the control DNA is labeled with a different colored fluorescent dye. the control DNA is used as the base point of reference. <br />
heated and denatured single DNA strands then hybridize to their complementary single strand probes, which are then combined and applied to a microarray and the results are run through a computer program and a digital imaging system is used to quantify the results( fluorescent intensities of the labeled probes)<ref name="Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45"> Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432] </ref>. <br />
The fluorescent ratio and the hybridization signal at different locations on the genome of the control DNA are used to identify any variances present in the sample DNA. aCGH facilitates the clinical diagnosis of submicroscopic chromosomal duplication, deletion and rearrangements indicative of chromosomal disorders such as trisomies 1-22 and specific sex linked disorders. <br />
Duplication in the DNA are displayed by the computer program as spikes/ peaks over an established threshold and deletions in DNA are displayed by the computer program as spikes/ toughs beneath this threshold. <br />
===Next Generation Sequencing===<br />
The development and advances within ART in the past 20 years, as well as the increasing popularity of IVF, has lead to an influx of new technologies developed to screen embryos for chromosomal anomalies, which are covered by the umbrella term of Next generation Sequencing (NGS). NGS is a general term used to describe all of the new and emerging screening techniques currently being introduced and used as part of PGD for IVF. NGS screens for single gene disorders as well as conducting extensive and very comprehensive chromosome diagnosis by sequencing, counting, and accurately assembling millions of DNA reads, simultaneously<ref name="PMID23499002"><pubmed>23499002</pubmed></ref>. NGS is expected to replace the other limited and outdated testing techniques and be used as the standard test in the future. <br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="13" |'''Advantages''' <br />
|-bgcolor="FFFAFA" <br />
| Cost effective<br />
|-bgcolor="FFFAFA"<br />
| Accurately tests all 24 chromosomes.<br />
|-bgcolor="FFFAFA"<br />
| Tests for the presence of monogenic diseases of known genetic background.<br />
|-bgcolor="FFFAFA"<br />
| Reduces the number of biopsies required for diagnosis.<br />
|-bgcolor="FFFAFA"<br />
| Higher detection rate of small translocations is possible. <br />
|-bgcolor="FFFAFA"<br />
| Testing for compound point mutations, chromosomal duplication, deletions and insertions is highly accurate<ref name="PMID23312231"><pubmed>23312231</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| It accurately detects chromosomal aneuploidy and unbalanced rearrangement<ref name="PMID25685330"><pubmed>25685330</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| Higher detection rate of small translocations is possible.<br />
|-bgcolor="FFFAFA"<br />
| NGS single gene disorder screenings can be conducted in conjunction with PCR comprehensive chromosomal screening.<br />
|-bgcolor="FFFAFA"<br />
| Human error is reduced.<br />
|-bgcolor="FFFAFA"<br />
| It detects the presence of mosaicism better.<br />
|-bgcolor="FFFAFA"<br />
| Work well in conjunction with CGH and aCGH as part of PGD, improving the chances of IVF. <ref> Morris, R. S. (2015 ) Next generation sequencing for PCG|PGS|CCS. IVF1 retrieved from [http://www.ivf1.com/next-generation-sequencing for-pgd] </ref><br />
|-bgcolor="DDCEF2"<br />
| rowspan'''Disadvantages''' <br />
|-bgcolor="FFFAFA"<br />
| There are limited information available to clinical applications of NGS <ref><pubmed>26100406</pubmed></ref><br />
|}<br />
====Procedure====<br />
Samples are collected from either blastomere or the blastocyst/tropoectoderm and processed for analysis by a computer system. <br />
The methodology of each process is unique to the technique being used. the popularity of the new and emerging techniques is due to the cost effective nature of their testing, their speed and the accuracy of their results. Please see the table above for advantages of NGS.<br />
==Diagnosis==<br />
[[File:ACGH tracing after trophectoderm biopsy.jpeg|thumb|450px|Array comparative genomic hybridization (aCGH) tracing after trophectoderm biopsy: (a) normal male embryo (female embryo control in blue); (b) female embryo with monosomy for chromosome 20 (male control in red); (c) an excellent quality blastocyst showing chaotic chromosome abnormalities. Nearly every chromosome is aneuploidy<ref name="PMID26237262"/>.]]<br />
There are a large amount of diseases that PGD can apply to, below are descriptions of the diseases that PGD are more commonly used for. Upon completion of the genetic testing for the genes of concern the cells the embryos are discarded and priority is given to those that are healthy. <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/><br />
===Cystic Fibrosis===<br />
Cystic fibrosis is a single gene disorder. It is autosomal recessive and involves mutations in the cystic fibrosis transmembrane conductance regulator (CTFR) gene. The CTFR gene is normally responsible for the decrease in chloride and the transport of bicarbonate in epithelial cells thus playing a major physiological role. In PGD procedures, identification of the gene is assisted by microsatellite markers that have similar composition to the CTFR gene itself. Biopsy of two cells at the blastocyst stage is recommended if markers are not available. There are many variations of cystic fibrosis the most common being P.Phe508del <ref name="PMID26014425"><pubmed>26014425</pubmed></ref>.<br />
<br />
===Autosomal Recessive Meckel-Gruber Syndrome===<br />
Autosomal recessive genetic defect caused by the TMEM67 gene. It results in cystic dysplasia of the kidneys with fibrotic change in the liber and occipital encephalocele. Other malformations could also be present in the central nervous system. In PGD whole genome amplification of single blastomeres are taken to identify the gene, this is also coupled with PCR techniques. Maternal plasma can also be extracted for PGS. <ref><pubmed>24039893</pubmed></ref> <br />
===β – Thalassemia=== <br />
β – Thalassemia is known as the most common type of autosomal recessive inherited disorder among haemoglobinopathies. It involves the adult β-globin gene and is associated with the absent or decreased expression of the gene. This is commonly caused by a single nucleotide change in the gene. PGD has been used successfully worldwide to identify the β-globin gene where its application is usually performed on a single blastomere or polar body <ref name="PMID19064120">19064120</pubmed></ref>.<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
! Applicable diseases for PGD <ref>Genoma Group (2014). Retrieved September 18th, 2015, from http://www.preimplantationgeneticdiagnosis.it/genetic-diseases-diagnosed-by-pgd.htm </ref> <ref>Genesis Genetics (2015). Retrieved September 18th, 2015, from http://genesisgenetics.org/pgd/what-we-test-for/</ref> <ref>Human Fertilisation & Embryology Authority (2015). Retrieved Septembr 18th, 2015, from http://guide.hfea.gov.uk/pgd/</ref><br />
|-<br />
| '''Disease'''<br />
| '''Involved Genes'''<br />
|-<br />
| 5 Alpha Reductase Deficiency (5ARD)<br />
| SRD5A2 [http://www.omim.org/entry/607306]<br />
|-<br />
| Achondroplasia<br />
|FGFR3 [http://www.omim.org/entry/134934]<br />
|-<br />
| Acute Intermittent Porphyria <br />
| ALAD [http://www.omim.org/entry/125270] , ALAS2 [http://www.omim.org/entry/612732], CPOX [http://www.omim.org/entry/612386], FECH [http://www.omim.org/entry/612386], HMBS [http://www.omim.org/entry/609806], PPOX [http://www.omim.org/entry/600923], UROD [http://www.omim.org/entry/613521], or UROS [http://www.omim.org/entry/606938]<br />
|-<br />
| Adrenoleukodystrophy (Adrenomyeloneuropathy)<br />
| ABCD1 [http://www.omim.org/entry/300371]<br />
|-<br />
| Agammaglobulinaemia (x-linked) <br />
|BTK [http://www.omim.org/entry/300300]<br />
|-<br />
| Agammaglobulinemia Bruton Tyrosine Kinase (BTK) <br />
|BTK [http://www.omim.org/entry/300300]<br />
|-<br />
| Aicardi Goutieres Syndrome 1 (AGS1) <br />
|TREX1 [http://www.omim.org/entry/606609] , RNASEH2A [http://www.omim.org/entry/606034] , RNASEH2B [http://www.omim.org/entry/610326] , RNASEH2C [http://www.omim.org/entry/610330], SAMHD1 [http://www.omim.org/entry/606754]<br />
|-<br />
| Alagille Syndrome<br />
|JAG1 [http://www.omim.org/entry/601920] or NOTCH2<br />
|- <br />
| Alpers-Huttenlocher Syndrome <br />
|POLG [http://www.omim.org/entry/174763]<br />
|-<br />
| Alpha-1-antitrypsin deficiency <br />
|SERPINA1 [http://www.omim.org/entry/107400]<br />
|-<br />
| Alpha-Mannosidosis<br />
| MAN2B1[http://www.omim.org/entry/609458]<br />
|-<br />
| Alpha Thalassemia <br />
|HBA1[http://www.omim.org/entry/141800]or HBA2 [http://www.omim.org/entry/141850] <br />
|-<br />
| Alports Syndrome<br />
|COL4A3 [http://www.omim.org/entry/120070] , COL4A4 [http://www.omim.org/entry/120131] , COL4A5 [http://www.omim.org/entry/303630]<br />
|-<br />
| Alzheimer's Disease - early onset (Type 3 and 4) <br />
|APP, PSEN1, or PSEN2<br />
|-<br />
| Amyotrophic Lateral Sclerosis 1 (ALS1) <br />
|C9orf72, SOD1, TARDBP, FUS, ANG, ALS2, SETX, VAPB <br />
|-<br />
| Argininosuccinic Aciduria <br />
| ASL<br />
|-<br />
| Arrhythmogenic Right Ventricular Cardiomyopathy/ Dysplasia (ARVC/D)<br />
| DSG2; DSP; PKP2<br />
|-<br />
| Ataxia Telangiectasia<br />
| ATM<br />
|-<br />
| Autosomal Recessive Meckel-Gruber Syndrome<br />
| TMEM67<br />
|-<br />
| Bardet-Biedl Syndrome (BBS)<br />
| BBS1; BBS10<br />
|-<br />
| Barth Syndrome<br />
| TAZ<br />
|-<br />
| Beta Thalassaemia<br />
| HBB<br />
|-<br />
| Birt-Hogg-Dubé Syndrome<br />
| FLCN<br />
|-<br />
| Breast Ovarian Cancer Familial Susceptibility (BRCA2)<br />
| BRCA1; BRCA2<br />
|-<br />
| Canavan Disease <br />
| ASPA<br />
|-<br />
| Carnitine-Acylcarnitine Translocase Deficiency <br />
| SLC25A20<br />
|-<br />
| Cerebral Arteriopathy with Subcortical Infarcts & Leukoencephalopathy (CADASIL)<br />
| NOTCH3<br />
|-<br />
| Cerebral Cavernous Malformation<br />
| CCM1<br />
|-<br />
| Charcot-Marie-Tooth Disease<br />
| GJB1; MPZ; NEFL; PMP22<br />
|-<br />
| CHARGE Syndrome<br />
| CHD7<br />
|-<br />
| Cherubism<br />
| SH3BP2<br />
|-<br />
| Choroideremia<br />
| CHM<br />
|-<br />
| Chronic Granulomatous Disease<br />
| CYBB; NCF1<br />
|-<br />
| Ciliary Dyskinesia<br />
| DNAH5<br />
|-<br />
| Citrullinemia<br />
| ASS1<br />
|-<br />
| Cleidocranial Dysplasia<br />
| RUNX2<br />
|-<br />
| Cockayne Syndrome<br />
| ERCC6<br />
|-<br />
| Congenital Adrenal Hyperplasia<br />
| CYP21A2<br />
|-<br />
| Congenital Cataracts<br />
| GJA8; VSX2<br />
|-<br />
| Congenital Diarrhea, Syndromic<br />
| SPINT2<br />
|-<br />
| Congenital Disorders of Glycosylation (CDG)<br />
| ALG1; ALG6; CDG1C; DOLK; PMM2<br />
|-<br />
| Cornelia de Lange Syndrome <br />
| NIPBL<br />
|-<br />
| Craniosynostosis<br />
| TWIST1<br />
|-<br />
| Crouzon Syndrome<br />
| FGFR2<br />
|-<br />
| Cysteinyl Leukotriene Receptor 1 Deficiency <br />
| CYSLTR1<br />
|-<br />
| Cystic Fibrosis<br />
| CFTR<br />
|-<br />
| Diamond –Blackfan Anemia <br />
| RPS19<br />
|-<br />
| Duchenne Muscular Dystrophy <br />
| DMD<br />
|-<br />
| Dyskeratosis congenita (Male embryos only)<br />
| DKC1<br />
|-<br />
| Ectodermal dysplasia (Hypohidrotic)<br />
| EDA; EDA1; GJB6; IKBKG<br />
|-<br />
| Familial Adenomatous polyposis coli (FAP)<br />
| APC<br />
|-<br />
| Familial Dysautonomia<br />
| IKBKAP<br />
|-<br />
| Fanconi Anemia <br />
| FANCA; FANCC; FANCD2; FANCF; FANCG; FANCJ<br />
|-<br />
| Fragile X Syndrome (FRAX)<br />
| FMR1<br />
|-<br />
| Galactosemia <br />
| GALT<br />
|-<br />
| Gangliosidosis<br />
| GLB1<br />
|-<br />
| Glanzmann Thrombasthenia <br />
| ITGA2B<br />
|-<br />
| Glutaric Acidemia (aciduria)<br />
| GCDH <br />
|-<br />
| Glycogen Storage Disease <br />
| G6PC; GAA; SLC37A4<br />
|-<br />
| Haemophilia A<br />
| F8<br />
|-<br />
| Haemophilia B<br />
| F9<br />
|-<br />
| Hereditary Nonpolyposis Colorectal Cancer: Lynch Syndrome<br />
| MLH1; MSH2; MSH6<br />
|-<br />
| Holt Oram Syndrome<br />
| TBX5<br />
|-<br />
| Huntington Disease<br />
| HD<br />
|-<br />
| Hydrocephalus<br />
| L1CAM<br />
|-<br />
| Ichthyosis <br />
| ABCA12; STS<br />
|-<br />
| Incontinentia Pigmenti (IP)<br />
| NEMO<br />
|-<br />
| Joubert Syndrome 5<br />
| INPP5E<br />
|-<br />
| Krabbe Disease<br />
| GALC<br />
|-<br />
| Leber Congenital Amaurosis (LCA)<br />
| CEP290; GUCY2D<br />
|-<br />
| Leigh Syndrome (Infantile Subacute Necrotising Encephalopathy)<br />
| LRPPRC<br />
|-<br />
| Lesch Nyan Syndrome<br />
| HPRT1<br />
|-<br />
| Leukocyte Adhesion Deficiency (Type I)<br />
| ITGB2<br />
|-<br />
| Li-Fraumeni Syndrome<br />
| TP53<br />
|-<br />
| Macular Dystrophy Retinal <br />
| VMD2<br />
|-<br />
| Maple Syrup Urine Disorder (MSUD)<br />
| BCKDHB<br />
|-<br />
| Marfan Syndrome <br />
| FBN1<br />
|-<br />
| Menkes Syndrome<br />
| ATP7A<br />
|-<br />
| Mitochondrial DNA Depletion Syndrom <br />
| POLG; RRM2B; SUCLA2; TK2<br />
|-<br />
| Mucolipidosis type II<br />
| GNPTAB<br />
|-<br />
| Multiple Endocrine Neoplasia<br />
| MEN1; MEN2A; MEN2B<br />
|-<br />
| Multiple Exostoses<br />
| EXT1; EXT2 <br />
|-<br />
| Myotubular myopathy<br />
| MTM1 <br />
|-<br />
| Nail-Patella Syndrome<br />
| LMX1B<br />
|-<br />
| Neurofibromatosis Type 1<br />
| NF1<br />
|-<br />
| Neurofibromatosis Type 2 <br />
| NF2<br />
|-<br />
| Noonan Syndrome<br />
| KRAS, PTPN11; SOS1<br />
|-<br />
| Norrie Disease<br />
| NDP<br />
|-<br />
| Ocular Albinism <br />
| GPR143<br />
|-<br />
| Oculocutaneous Albinism <br />
| OCA2; TYR <br />
|-<br />
| Oculodentaldigital Dysplasia<br />
| GJA1<br />
|-<br />
| Optic Atrophy<br />
| OPA1<br />
|-<br />
| Ornithine Transcarbamylase Deficiency <br />
| OTC<br />
|-<br />
| Osteogenesis imperfeca <br />
| COL1A1; COL1A2<br />
|-<br />
| Osteopetrosis <br />
| CLCN7; OSTM1; TCIRG1<br />
|-<br />
| Pachyonychia Congenita <br />
| KRT16; KRT6A<br />
|-<br />
| Pancreatitis, Hereditary<br />
| PRSS1 <br />
|-<br />
| Papillorenal syndrome <br />
| PAX2<br />
|-<br />
| Phenylketonuria <br />
| PAH <br />
|-<br />
| This table does not cover the complete list of diseases that PGD can be applied to.<br />
|}<br />
==Laws & Legal status==<br />
{| class="wikitable" <br />
|-bgcolor="DDCEF2"<br />
|'''Country'''<br />
|'''Legislation'''<br />
|-bgcolor="FFFAFA" <br />
| Australia<br />
| PGD is currently used to detect serious genetic conditions to improve the outcome of Assisted Reproductive Technologies (ART). In very rare cases it may be used to select an embryo with compatible tissue for a sibling who has a life-threatening disease where other means of treatment is unavailable. This is with the conditions that the use of PGD will not affect the welfare and interests of the child to be born. The parents must also receive adequate counselling and have full understanding of the procedures of PGD. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"> National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art</ref><br />
The use of PGD for sex-selection is prohibited with the exception of reducing the risk of the transmission of serious sex-linked genetic conditions. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"/><br />
|-bgcolor="FFFAFA"<br />
| Brazil<br />
| The laws regarding PGD in Brazil are not strictly regulated. They are vague and there is limited information surround the activities of assisted reproduction in general in the country <ref name="PMID25493379"><pubmed>25493379</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| Czech Republic<br />
| The laws in the Czech Republic allow those with a “defined indication in order to exclude risk of serous genetically conditioned disease and defects with embryos before they are implanted into the cavity of the uterus”. Couples that undergo any assisted reproductive treatment including PGD have to be married. Sex-selection is illegal except in regards to serious sex-linked genetic diseases <ref name="PMID24777348"><pubmed>24777348</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| Greece<br />
| In Greece, ART is open to those up to the age of 50 with written consent. It can only be used if a medical necessity is present such as the susceptibility of serious hereditary diseases. Sex selection is banned apart from cases of sex-linked diseases and sexually transmitted diseases <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| India<br />
| In India there is a cultural preference for boys thus the Prenatal Diagnostic Techniques (Regulation and Prevention of Misuse) Act was introduced in 1994. This law limits the use of PGD for sex determination except in cases of specific congenital diseases. These laws however are not strictly enforced. <ref>World Health Organisation (2015) Gender and Genetics Retrieved on October 21st 2015 from:http://www.who.int/genomics/gender/en/index4.html</ref><br />
|-bgcolor="FFFAFA"<br />
| Portugal <br />
| ART is only available to those who are married or have a similar type of relationship for at least two years. The couples cannot be of the same sex and must be at least 18 years of age. Sex selection is illegal except in cases of sex-linked diseases. The use of PGD is illegal if the predictive value of genetic tests are very low <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| Spain<br />
| PGD can be applied to “serious hereditary diseases not amenable to postnatal curative treatment” and “detection of other abnormalities which may compromise the viability of the pre-embryo”. If PGD is to be used for any other purpose authorisation must be acquired <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| Sweden <br />
| The use of PGD is strictly regulated and couples must achieve authorisation of the National Board of Health and Welfare. It can only be used it can only be used if the child is at risk to inheriting a serious chromosomal or monogenetic disease. It cannot be used for selection of specific characteristics <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| United Kingdom<br />
| Those involved with carrying out the IVF treatment must have a license from the Human Fertilisation and Embryology Authority (HFEA). Only embryos that are approved by the HFEA can be implanted where the embryonic nuclear or mitochondrial DNA cannot be altered with the exception of preventing mitochondrial diseases <ref name="PMID24777348"/>. <br />
|}<br />
==Future/Current Research==<br />
In addition to research efforts for improving overall performance of established PGD/S techniques, such as finding the ideal zona pellucida insection site in an fully automatic manner<ref name="PMID26259216"><pubmed>26259216</pubmed></ref>, many research efforts have been spent to find alternative, non-invasive techniques to test for diseases and abnormalities<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
===Non-invasive Preimplantation Genetic Testing without Embryo Biopsy===<br />
Different parameters of gametes, zygotes, embryos (“vacuoles in sperm heads, spindle position in mature oocytes, cleavage intervals of zygote, and embryo developmental dynamics”) may correlate with aneuploidy rates. This knowledge may be applied in potential noninvasive preimplantation diagnostic methods. Several methods have been proposed and are currently further researched<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Sperm Selection====<br />
Intracytoplasmic morphologically selected sperm injection (IMSI) is common procedure in IVF treatment to improve fertilization rates in patients with poor semen quality. In addition, studies have found that IMSI improves embryo development and that spermatozoa with large vacuoles in their heads correlate with increased aneuploidy rates and disturbed chromosomal structures. Thus, selecting spermatozoa based on morphological hallmarks may decrease aneuploidy rates in the fertilized embryos. As with polar body biopsies, however, this approach will solely be applicable if evidence for severe male detrimental contribution is given<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Blastocoel Fluid Extraction====<br />
In addition, a less invasive retrieval of material for diagnosis could include the extraction of the blastocoel fluid. The cavity of the blastocyst, lined by the trophectoderm, is filled with this blastocoel fluid, which contains metabolites of both trophectoderm and inner cell mass origin. The retrieval does not require a biopsy but merely a small opening to extract the fluid and, thus, causes less harm to the embryo. Multiple studies have applied this method<ref name="PMID22020776"><pubmed>22020776</pubmed></ref> <ref name="PMID23148560"><pubmed>23148560</pubmed></ref> <ref name="PMID26006737"><pubmed>26006737</pubmed></ref> and it may in the future become of clinical relevance.[[File:Aspiration_of_the_Blastocoel_Fluid.jpeg|400px|thumb|Aspiration of the Blastocoel Fluid using a ICSI pipette<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.]]Next to metabolites, the blastocoel fluid can contain DNA. Studies have shown that genomic DNA is present in about 90% of the blastocoel fluid samples tested. Typically the fluid is removed with an ICSI pipette from a day five blastocyst through its mural trophectoderm until the blastocyst fully collapses around the embryo. Several concerns regarding this method in a clinical setting have been raised. The collected DNA may be contaminated by the culture media that contains DNA fractions. The DNA may also be least representative of the actual embryos genome as the DNA may originate from abnormal or degenerated cells. Even though labelled noninvasive, the blastocyst still undergoes manipulation to some degree which may affect its viability. Thus, more research is required until this method can evolve from research to clinical use<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
====Proteomics and Medium Based PGD====<br />
The media in which embryos are kept during the early IVF procedures, gives rise to potential non-invasive techniques. For instance, the protein secretome of blastocysts may be representative of its chromosome constitution Recent studies have found biomarkers such as lipocalin-1, interleukin-10, tumor necrosis factor, stem cell factor, and chemokine ligand 13 to be differently secreted by aneuploid blastocyst than by euploid ones. The most significant biomarker appears to be interleukin-10. Paired with novel proteomic technologies and mass spectrometry this knowledge when extended may contribute to a new invasive PGD method<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. In addition, medium based non-invasive PGD has been researched for the diagnose of human α-thalassemia-SEA. Genomic DNA was collected from the media and the study surprisingly resulted in increased diagnosis efficacy compared to biopsy-based methods<ref name="PMID25816038"><pubmed>25816038</pubmed></ref>.<br />
====Embryo Morphology====<br />
Using time lapse imaging the embryo’s morphology can be closely observed and potential aneuploidy characteristics detected. Such characteristics may include the time of division to five cells, the time between the division from three to four cells, and the duration of the division from one to two and subsequently to three. In addition, the morphological quality of ICM an TE has been positively associated with aneuploidy or euploidy prognosis<ref name="PMID26246880"><pubmed>26246880</pubmed></ref>. These may give rise to an embryo quality screening prior to implantation<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
==Glossary==<br />
'''Aberrent Cells'''<br />
<br />
'''Abnormalities:'''<br />
<br />
'''Allele:'''<br />
<br />
'''Anneuploidy:'''<br />
<br />
'''Annelaing:'''<br />
<br />
'''Aspiration:'''<br />
<br />
'''Biopsy:''' sample of tissue taken for examination <br />
<br />
'''Blastocyst:''' Stage of embryo at approximately day 5 consisting of an outer (trophoblast) layer and inner (embryoblast) cell mass. <br />
<br />
'''Blastomere:''' Initial cells formed through mitosis of the zygote<br />
<br />
'''Chromosome'''<br />
<br />
'''CTFR:''' Cystic Fibrosis Transmembrane Conductance Regulator, responsible for transport of chloride across the cell membrane<br />
<br />
'''Cytoplasmic Bridge:'''<br />
<br />
'''Denaturing:'''<br />
<br />
'''DNA:'''<br />
<br />
'''Endometriosis:''<br />
<br />
'''Enucleation:'''<br />
<br />
'''Epigenetic:'''<br />
<br />
'''Extension:'''<br />
<br />
'''Fluorescent In situ hybridisation:''' technique use to locate specific gene sequences using fluorescence tags <br />
<br />
'''Genome:'''<br />
<br />
'''Heterozygosity:'''<br />
<br />
'''Haemotological:'''<br />
<br />
'''Hydrosalphinx:''' <br />
<br />
'''Intracytoplasmic Morphologically Selected Sperm Injection (IMSI):''' IVF technique involving morphological selection of sperm under the microscope to be injected to oocyte<br />
<br />
'''Intracytoplasmic Sperm Injection (ICSI):''' IVF technique used to treat male infertility and involves direct injection of one sperm into an oocyte<br />
<br />
'''In Vitro:'''<br />
<br />
'''IVF:'''<br />
<br />
'''Leukocyte:'''<br />
<br />
'''Leukemia:'''<br />
<br />
'''Locus:''<br />
<br />
'''Micorarray:'''<br />
<br />
'''Mitochondria:'''<br />
<br />
'''Molecular anomalies:'''<br />
<br />
'''Next Generation Sequencing (NGS):''' Term used to describe the collection of recent findings regarding embryo screening<br />
<br />
'''Oolema'''<br />
<br />
'''Phenotype:'''<br />
<br />
'''Polar bodies:''' cell formed during the meiotic stages of the oocyte containing extra genetic material <br />
<br />
'''Polymerase Chain Reaction (PCR):''' Technique used to amplify DNA to study a specific genetic sequence<br />
<br />
'''Polyploidy:'''<br />
<br />
'''Preimplantation Genetic Diagnosis (PGD):''' Involves genetic testing conducted to identify abnormalities in an embryo before implantation.<br />
<br />
'''Preimplantation Genetic Screening (PGS):''' Involves genetic screening for genetic abnormalities using techniques such as FISH and PCR to eliminate unhealthy embryos <br />
<br />
'''Perivitelline Space:''<br />
<br />
'''Primer:'''<br />
<br />
'''Robertsonian Translocations:''' Type of structural chromosomal translocation <br />
<br />
'''Single Gene Disorders:''<br />
<br />
'''Self Annealing:'''<br />
<br />
'''Submicroscopic:'''<br />
<br />
'''Translocations:'''<br />
<br />
'''Trisomies:'''<br />
<br />
'''Trophoectoderm:'''<br />
<br />
'''Zona Pellucida:'''<br />
<br />
<br />
==References==<br />
<br />
<references/><br />
<br />
<br />
{{StudentPage2015}}</div>Z5017878https://embryology.med.unsw.edu.au/embryology/index.php?title=2015_Group_Project_6&diff=2085072015 Group Project 62015-10-23T09:36:58Z<p>Z5017878: </p>
<hr />
<div>{{ANAT2341Project2015header}}<br />
<br />
<br />
=Preimplantation Genetic Diagnosis and Preimplantation Genetic Screening=<br />
==Introduction==<br />
Preimplantation genetic diagnosis (PGD) and preimplantation genetic screening (PGS) are reproductive options for couples with known family histories of genetic disease or couples undergoing IVF procedures due to infertility issues. PGD can diagnose many genetic disorders caused by known chromosomal abnormalities (number and/or structure) or single gene mutations, and, thus decrease the risk of termination of pregnancy or miscarriages and enable such couples to have an unaffected child<ref name="PMID24907939"><pubmed>24907939</pubmed></ref>. Through major improvements in PGD/S and general laboratory technology, the testing for abnormalities in fetuses has shifted from prenatal diagnosis during the first 2 trimesters <ref> Blackburn, S.L. (2003) '''Maternal, Fetal & Neonatal physiology: a Clinical perspective''' (2nd ed.). Seattle: Saudners </ref>, testing for overall fetal growth, complications of pregnancy, and birth defects<ref> Sadler T.W.(2012) '''Langman's Medical Embryology''' (12th ed.) Philadelphia: Lipincott, Wiliams & Wilkins, a Wolters Kluwer Business </ref>, to an embryonic focus especially in advancements in Artificial Reproductive Technologies (ART)<ref><pubmed>20638568</pubmed></ref>. In 1990 PGD for a recessive X-linked disease resulted in the first live birth<ref><pubmed>2330030</pubmed></ref> and has since been incorporated in clinical routine and applied for a variety of genetic diseases, such as sickle cell anemia, thalassemia, or cystic fibrosis<ref name="PMID24907939"/>.<br />
[[File:Preimplantation Genetic Diagnosis Procedure.jpeg|600px|left|thumb| Simplified steps for PGD<ref name="PMID24907939"/>]]<br />
{|class="wikitable"align="right" <br />
| <html5media height="400" width="533">https://www.youtube.com/watch?v=0e-79qKllqk</html5media><br />
|-<br />
| Preimplantation Genetic Diagnosis<ref>IVF Florida (2011, December 11) IVF Florida - South Florida Fertility Specialists - Pre-Implantation Genetic Diagnosis [Video file]. Retrieved from https://www.youtube.com/watch?v=0e-79qKllqk</ref><br />
|}<br />
==History==<br />
The advances in reproductive technology during the second half of the 20th century, led to PGD's first clinical application in 1990 <ref>Harper, J. (n.d.). The history of PGD. Lecture. UCL Centre for PG&D and CRGH.University College London</ref>.<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
|Year<br />
|<br />
|- bgcolor="FFFAFA"<br />
| '''1967''' <br />
|First PGD on rabbit blastocysts (Gardner& Edwards) <ref name="PMID6036172"><pubmed>6036172</pubmed></ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1986''' <br />
|First Cleavage Biopsy (Wilton & Trounson)<ref>Wilton, L. J., & Trounson, A. O. (1986). Viability of mouse embryos and blastomeres following biopsy of a single cell. In Proceedings of the 18th Annual Conference of the Australian Society for Reproductive Biology, Brisbane, Australia.</ref><br />
|- bgcolor="FFFAFA"<br />
|'''1987''' <br />
|First Blastocyst Biopsy (Muggleton-Harris, Monk, Rawlings, & Whittingham)<ref name="PMID3372699"><pubmed>3372699</pubmed></ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1988''' <br />
|First Polar Body Biopsy (Yury Verlinksy)<ref> Verlinsky, Y., Pergament, E., Andresen, P., Enriquez, G., & Strom, C. (1989). Genetic analysis of polar body DNA: A new approach to preimplantation genetic diagnosis. Am J Hum Genet, 45(4), A272.</ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1990''' <br />
|First Clinical PGD using PCR testing for X-linked (Handyside, Kontogianni, Hardy, & Winston)<ref name="PMID2330030"><pubmed>2330030</pubmed></ref> <br />
|} <br />
==Preimplantation Genetic Diagnosis==<br />
[[File:Pre-PGD workup.jpeg|thumb|400px|Pre-PGD workup for a family with a previous child with spinal muscular atrophy. Panel (a) shows how the study of both parents and grandparents allows the phasing of the SMN mutation relative to polymorphic short tandem repeat (STR) markers; panel (b) shows the maternal and paternal haplotypes M1, M2, P1 and P2 and the distance of the STR markers from the SMN gene; panel (c) shows the four predicted fetal haplotypes. These reflect a Hardy–Weinberg equilibrium of one homozygous non-carrier, two heterozygous carriers and one that is homozygous and affected. Short tandem repeat markers linked with the SMN mutation are shown in red. DEL indicates the presense of the exon 7 (840 C>T) mutation<ref name="PMID26237262"/>.]]<br />
PGD is used to test the genetic makeup of embryos to detect single gene disorders, chromosomal abnormalities and mitochondrial disorders. It also has applications in gender selection for diseases with unequal gender distributions <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Some diseases commonly involved with PGD include cystic fibrosis, spinal muscular atrophy and beta – thalassaemia <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press.">Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press</ref> <ref name="PMID17823145"><pubmed>17823145</pubmed></ref>. It was first used in the United Kingdom in the 1980s, primarily focusing on sex- linked disorders <ref name="PMID17823145"/><ref name="PMID23150080"><pubmed>23150080</pubmed></ref>. PGD is now capable of detecting single cell defects (molecular) and chromosomal disorders resulting from the inversion, translocation or deletion of chromosomes (cytogenic) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/> <ref name="PMID11325751"><pubmed>11325751</pubmed></ref>. PGD can be applied to the embryo at different stages. That is on polar bodies, blastomeres or blastocyst <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>.<br />
Depending on the type of genetic disorder, PGD utilises different methods of genetic testing. These include Fluorescence in situ hybridisation (FISH) which is used for sex – linked disorders and detects chromosomal rearrangements <ref name="PMID11325751"/><ref name="PMID17876073"><pubmed>17876073</pubmed></ref> and Embryo halotyping which allows the identification of chromosomes causing the inherited disorder through knowledge of the pattern of closely linked markers <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. Polymerase chain reaction (PCR) is also widely used to detect molecular abnormalities <ref name="PMID11325751"/>.<br />
PGD is tightly regulated and supported by large organisations namely The American Society for Reproductive Medicine, The European Society for Human Reproduction and Embryology (ESHRE), The European Society of Human Genetics and the Preimplantation Genetic Diagnosis International Society <ref name="PMID25500181><pubmed>25500181</pubmed></ref>.<br />
===Sex-linked disorders===<br />
The determination of a disease as gender specific usually correlates with the presence or absence of specific genes such as SRY on the Y chromosome. It is known that females have two X chromosomes and males have an X and a Y chromosome where abnormalities are more prevalent on the X chromosome. PGD can be used for sex selection where only male embryos are transferred to reduce the chance of inheriting X-linked disorders. However, this does not completely eradicate the problem as male embryos remain susceptible to inheriting an affected X chromosome. Sex determination is only used when the specific mutation is unknown and has yet to be discovered <ref name="PMID24866878"><pubmed>24866878</pubmed></ref>.<br />
===Single gene defects===<br />
Single gene defects can be dominant, recessive, autosomal or X-linked. They are commonly diagnosed using PCR and although the PCR available today is complex and capable of combatting a large range of disease the development of new protocols has been proven to be difficult due to the small DNA sample available <ref name="PMID26168107"><pubmed>26168107</pubmed></ref>.<br />
===Mitochondrial disorders===<br />
Mitochondrial disorders also known as oxidative phosphorylation disorders arise from mutations in the nuclear DNA or mitochondrial DNA <ref name="PMID26312584"><pubmed>26312584</pubmed></ref>. They pose as a problem because they are unrecognisable until the mutations in the cell reach a detrimental level <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Mitochondrial disorders cause miscarriages and stillbirths as well as death in children and young adults. The effects can either be contained in a single organ or more commonly involve multiple organ failure where organs with high energy demands such as the brain, liver muscle and heart and heavily influenced. They are usually occur spontaneously or result from inheritance from the mother. Since mitochondria are solely inherited from the mother oocyte donations have been used as a solution to combat mitochondrial disorders. Additionally, there has been an increasing use in PGD where embryos that stay under the given threshold of 18% gene-mutations are allowed to be transferred and result in normal development. New technology in the areas of nuclear gene transfer and genome editing are also being experimented with <ref name="PMID26312584"/>. <br />
===Chromosomal disorders===<br />
Chromosomal disorders can be reciprocal, Robertsonian translocations, inversions, deletions and insertions <ref name="PMID26168107"/>. Data from ESHRE collected between 2010 and 2011 has shown that the most common chromosomal abnormality confronted in PGD are reciprocal chromosomal abnormalities <ref name"PMID26071418"><pubmed>26071418</pubmed></ref>. PGD has also been used successfully for Robertsonian translocations (RT), a type of structural translocation. Children who carry RT are phenotypically normal, however in their later years it is found that they will suffer from infertility and repeated miscarriages due to the high frequency of abnormal embryos <ref name="PMID22081077"><pubmed>22081077</pubmed></ref>. PCR and FISH are the two main techniques used for chromosomal disorders. To be able to conduct the examinations the cells are required to be at the metaphase stage <ref name="PMID26168107"/>. <br />
[[File:Reasons_for_PGD.jpg|600px|thumb|Reasons for PGD<ref name="PMID24764761"><pubmed><24764761</pubmed></ref>]]<br />
==Preimplantation Genetic Screening==<br />
PGS involves an array of methods or ideas that aim to segregate embryos that have genetic flaws and those that are healthy <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. The occurrence of aneuploidy is high around the stages of early embryonic development and they are the most common cause if miscarriages and congenital birth defects <ref name= "PMID26085841"><pubmed>26085841</pubmed></ref>. They have little effect on the morphology of the embryo making them difficult to identify thus identification heavily relies on genetic testing <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. <br />
Genetic sampling is most commonly conducted using Microarray Comparative Genomic Hybridisation (aCGH) as well as FISH, Quantitative PCR and Single Nucleotide Polymorphism (SNP) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. These methods collectively aim to assess numeral and structural chromosomal errors <ref name= "PMID26085841"/>. Studies have also introduced Next- Generation Sequencing (NGS) <ref name= "PMID26085841"/> and Whole Genome Amplification used to screen imbalances in the complete 24-chromosomes <ref name="PMID25953353"><pubmed>25953353</pubmed></ref>.<br />
Statistics from ESHRE have shown that the most common indications for PGS is advanced age, followed by repeated implantation failure or recurrent miscarriage and male infertility <ref name="PMID26071418"><pubmed>26071418</pubmed></ref>.<br />
===Indications===<br />
A low percentage of structural abnormalities in chromosomes are responsible for the cause of miscarriages. Despite this, they are the most prevalent type of chromosomal abnormality accounted for in PGD <ref name="PMID20638568"/>. The presence of specific gene cycles, initiation of embryonic protein synthesis and evident physiological development are all indicative of a successful in vitro fertilisation procedure <ref name="PMID11576737"><pubmed>11576737</pubmed></ref>. To eliminate further errors from occurring during the PGD procedure it is recommended to undertake further prenatal testing such as amniocentesis in the later stages <ref name="PMID20638568"/>. <br />
====Advanced maternal age====<br />
Data provided by the ESHRE has shown that the mean age of women undergoing PGS is 39 years <ref name="PMID26071418"/>. Women of advanced age have been shown to have a lower rate of pregnancies reaching childbirth <ref name="PMID18583331"><pubmed>18583331</pubmed></ref>. The highlighted concern revolves around the increased occurrence of aneuploidy following maternal age. The optimal age range for the lowest aneuploidy incidence was found to be between 27 to 37 years of age (6%) then progressively higher in women aged up to 42 (33%) and most common in those 44 and above (53%) <ref name="PMID24355045"><pubmed>24355045</pubmed></ref>. <br />
====Recurrent pregnancy loss / IVF failure====<br />
Recurrent pregnancy loss is defined as three or more IVF failures after cumulative transfer of more than 10 good-quality embryos. These are primarily caused by two main factors, reduced endometrium receptivity or embryonic defects. Endometrium receptivity can be negatively influences by instances including uterine pathologies such as thin endometrium, altered expression of adhesive molecules and immunological factors. Additionally, embryonic defects may be due to genetic abnormalities, embryonic aneuploidy or zona hardening. Endometriosis and hydrosalpinx has been known to effect both the endometrium and embryo <ref name="PMID23260857"><pubmed>23260857</pubmed></ref>.<br />
====Human leukocyte antigen matching====<br />
First used in 2001, HLA matching is an option given to parents to save a child with haematological or immunological disease through conceiving another child who would potentially be able to donate cord blood or haematopoietic stem cells from the bone marrow for transplantation. The process namely PGD-HLA has shown to improve haematopoietic stem cell transplant (HSCT). PGD-HLA can only be performed when HSCT is not needed urgently due to the time needed to conceive and delivery the baby <ref name="PMID25500181"><pubmed>25500181</pubmed></ref>. It is most commonly applied to children suffering from relapsed leukaemia <ref name="PMID22524201"><pubmed>22524201</pubmed></ref>. In a case study PGD-HLA was proven to successfully cure 10 diseases including Fanconi anaemia, Diamond-Blackfan anaemia and beta thalassemia <ref name="PMID25066893><pubmed>25066893</pubmed></ref>.<br />
==Biopsy Methods==<br />
Biopsy, the removal of genetic materials, from oocytes or embryos in the preimplantation stage is the primary step in PGD. For the past two decades these biopsies have been performed at three stages, the polar body, blastomere, and blastocyst, and the methodologies optimized to ensure the embryo’s viability. The most common approach involves biopsies at the cleavage stage. However, polar body and blastocyst biopsies are increasingly more often tested and applied. Approached for opening the zona pellucida involve next to the traditional mechanical and chemical means, novel approaches such as noncontact lasers. Their application may simplify and secure the procedure significantly. The most challenging question about PGD procedures remains at what stage biopsies should be taken. Much controversy has developed around this topic, highlighting the varying disadvantages and advantages of temporal biopsies <ref name="PMID22723007"><pubmed>22723007</pubmed></ref>.<br />
[[File:Polar_Body,_Blastomere,_and_Trophectoderm_Biopsy.jpeg|500px|thumb|Polar body (A), blastomere (B) and trophectoderm (C) biopsies<ref name="PMID25625041"><pubmed>25625041</pubmed></ref>.]]<br />
{| class="wikitable"<br />
|- align="center" bgcolor="DDCEF2"<br />
|<br />
| Time of Biopsy<br />
| Prevalence <br />
| Advantages <br />
| Disadvantages<br />
|- bgcolor="FFFAFA"<br />
| Polar Body<br />
| Day 1<br />
| ~16%<br />
| Little to no harm is caused to the oocyte and both PBs can be extracted (more genetic material)<ref name="PMID22723007"/>.<br />
| Only the maternal DNA is tested<ref name="PMID22723007"/>, often PB biopsies need to be coupled to other biopsies, and difficulties arise in distinguishing between the first and second PB<ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. Lower reliability of results compared to other biopsy methods have been reported<ref name="PMID25106935"/>. <br />
|- bgcolor="FFFAFA"<br />
| Blastomere <br />
| Day 3<br />
| ~80%<br />
| Biopsies are safe for good quality embryos and it is performed relatively early, so fresh transfer is possible, yet, it includes both paternal and maternal genetic contributions<ref name="PMID26237262"/>. <br />
| Relatively large decrease in implantation rates for low quality embryos have been reported, embryo mosaicism can influence genetic analysis, and only one to two cells can be safely removed<ref name="PMID26237262"/>. <br />
|- bgcolor="FFFAFA"<br />
| Trophectoderm<br />
| Day 5 and 6 <br />
| ~ 2%<br />
| Little harm to the embryo and large amount of genetic material can be extracted, which allows for more accurate genetic analysis and lessen effects of mosaicism<ref name="PMID26237262"/>. <br />
| The biopsy takes place relatively late and, thus, the time window for procedure is small and embryos often need to be cryopreserved<ref name="PMID22723007"/>. <br />
|}<br />
===Polar Body Analysis===<br />
Day 1<br />
====Description====<br />
[[File:Polar_Body_Biopsy.jpeg|thumb|400px|The presence of a faint but clearly identifiable strand connecting PB2 to the oolemma. The biopsy was performed ∼9 h after ICSI<ref name="PMID21908464"><pubmed>21908464</pubmed></ref>.]] <br />
Polar body (PB) biopsy offers a promising alternative to biopsies performed at the blastomere stage for PGD/S indications on legal and practical grounds<ref name="PMID22723007"/>. The ESHRE calculated the proportion of PB biopsies to be about 16.3%<ref name= "Traeger-Synodinos, J., Coonen, E., Goossens, V., De Mouzon, J., Shenfield, F., Ruiz, A., ... & de Mouzon, J. (2013). Session 09: ESHRE data reporting on PGD cycles and oocyte donation.">Human Reproduction, 28(suppl 1), i18-i19. </ref>. Embryo development does not necessitate the presence of the first and second PB and their removal may not be crucial<ref name="PMID22723007"/>. The idea behind PB biopsies is that each abnormality found in the PB corresponds to an error in the oocyte. On the other hand, in women with known single gene mutations, it is assumed that if the PB contains the mutated allele ,the oocyte will have the normal allele, thus, resulting in a healthy embryo<ref name="PMID26237262"/>. PB biopsy requires precise timing. Keeping track of the meiotic cell cycle is necessary to perform a successful biopsy and, therefore, PB biopsy usually is applied in combination with intracytoplasmic sperm injection (ICSI). During the maturation from the germinal vesicle stage to the metaphase-II stage the first PB is formed. A cytoplasmic bridge containing spindle remnants, that are still in contact with the cellular genetic material, links this PB to the oolemma for about 90 minutes after extrusion. It is possible to visualize these remnants by polarization microscopy and it is crucial to not perform the biopsy until the first PB is no longer firmly attached to the oolemma as this indicates an immature embryo.The oocyte tolerates mechanical zona dissection best during hours four until six after ICSI as the oolemma has stabilized by that time because of the cortical granule reaction. Over time the first PB degenerates stressing a temporal biopsy and its optimal extraction time window is four to 12 hours after ICSI. The second PB forms around two to four hours after ICSI. Its optimal time window for biopsy is set to be eight to 16 hours after ICSI due to the second PB being attached to the oolemma with spindle remnants until six hours after ICSI. Biopsy at this point may cause enucleation of the oocyte. Studies have shown that the amplification efficiency of second PB’s DNA is worse if the PB is extracted prior to eight hours after ICSI. Thus, it is possible to perform sequential and simultaneous biopsies for the first and second PB. If performed, sequentially the first PB may be removed four to 12 hours and the second PB eight to 16 hours after ICSI. The optimal time window for a biopsy for both the first and second PB simultaneously is eight to 12 hours after ICSI. It is highly preferred to analyze both PBs due to potential aneuploidies in either PB and crossing overs during meiosis <ref name="PMID22723007"/>. <br />
====Procedure====<br />
Chemical opening achieved with for example acidic tyrode’s solution of the zona pellucida is not tolerated by the oocyte and may have detrimental effects on the embryo’s development. Therefore, the access to the perivitelline space of the oocyte is provided by mechanical zona dissection or by laser. Both techniques work well if performed by experienced embryologist. However, laser-assisted biopsy is less time consuming when compared to manual dissection. It is critical to consider the size of the introduced opening as it will remain permanent. If it is too large the blastomere may be lost during embryo development and if it is too small it may interfere with hatching of the embryo during blastocyst stage<ref name="PMID22723007"/>.<br />
[[File:Implantation_predictive_value_of_euploid_screening_results.jpeg|thumb|450px|The sustained implantation predictive value (with 95 % confidence interval) of a euploid screening result obtained from the first polar body (PB1), PB1 and the second polar body (PB2), or a direct embryo biopsy for each stage of embryo transfer (cleavage-stage and blastocyst stage)<ref name="PMID25106935"><pubmed>25106935</pubmed></ref>.]]<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JTaQzszVr8o</html5media><br />
|-<br />
| Laser-assisted polar body biopsy<ref>RIUK, R. (2013, June 25) Polar Body Biopsy [Video file]. Retrieved from https://www.youtube.com/watch?v=JTaQzszVr8o</ref><br />
|}<br />
====Advantages & Disadvantages====<br />
PB biopsies can only investigate the maternal contributions to the embryo as they are of maternal origin. Thus, this procedure is appropriate for PGD solely for monogenetic diseases from the maternal side. Recessive diseases may be evaluated with PB biopsies on the basis that the embryo’s outcome will be determined by the paternal contribution. It may still be applied for PGS as it is a fairly safe biopsy option and most aneuploidies either arise during meiosis or origin from the maternal genome. However, diagnosis error has been reported due to the lack of considering paternal contributions<ref name="PMID22723007"/>. About 10% of PB biopsies appear to be wrongfully diagnosed with aneuploidies<ref name="PMID26237262"><pubmed>26237262</pubmed></ref>. Because PB biopsies are performed very early it is not yet known whether the oocyte will develop into a viable embryo. Thus, PBs are commonly frozen or fixed after biopsy and depending on the state of the embryo only chosen PBs will be tested. This is primarily an economic issue as many genetic testing procedures are very cost-intensive<ref name="PMID22723007"/>. Generally the sustained implantation predictive value of screening of PBs is significantly lower than of, for example, biopsies of the blastocyst stage<ref name="PMID25106935"/>. Moreover, it is often difficult to distinguish between the first and the second PB. As the first one degenerates quicker, this may influence diagnostic procedures<ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
===Blastomere biopsy===<br />
Day 3 <br />
====Description====<br />
Blastomere biopsy has been the prevalent method for PGD and PGS in the last two decades. In 2013 the ESHRE reported 79.8% of biopsies to be performed at the cleavage stage<ref name= "Traeger-Synodinos, J., Coonen, E., Goossens, V., De Mouzon, J., Shenfield, F., Ruiz, A., ... & de Mouzon, J. (2013). Session 09: ESHRE data reporting on PGD cycles and oocyte donation."/>. At least one, but up to two, blastomeres are biopsied on day three of the cleavage stage embryo. The right number of blastomeres removed is a controversial topic as two cells allow for more genetic material and more accurate results. However, removing two cells might be too invasive and damaging to the embryo. As PGS tries to improve implantation rates, whereas PGD sets out to avoid known genetic disorders, for the former only one cell is removed, while for the latter often two need to be removed, to ensure results as correct as possible<ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
====Procedure====<br />
Initially a hole was drilled into the zona pellucida using acid Tyrode's solution or by mechanical means. Nowadays the zona pellucida is largely opened using a laser and calcium and magnesium free media have been introduced to decrease junctions between blastomeres, which facilitates the biopsy. This if followed by the consequent aspiration of blastomeres with a pipette.<ref name="PMID21748341"/>. The blastomeres can also be removed by applying pressure on the outside of the zona<ref name="PMID26237262"/>.<br />
[[File:Aspiration_of_a_Blastomere.jpeg|thumb|left|400px|Aspiration of a Blastomere into the biopsy pipette<ref name=" PMID24783200"><pubmed>24783200</pubmed></ref>.]]<br />
{|class="wikitable"align="right" <br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=TbridWVwipI</html5media><br />
|-<br />
| Laser-assisted blastomere biopsy<ref>Sukprasert, M. (2014, March 5) Day 3 Blastomere Biopsy 1 [Video file]. Retrieved from https://www.youtube.com/watch?v=TbridWVwipI</ref><br />
|}<br />
====Advantages & Disadvantages====<br />
Blastomere biopsy is limited by the presence of embryo mosaicism, which can severely influence the interpretation of the genetic analysis. Approximately 15%-80% of all embryos display mosaicism on day three. Thus, any results might be a misrepresentation of the embryo as a whole. However, if good quality embryos are selected, the procedure overall is safe and does not negatively influence the embryos transition to the blastocyst stage. In a typical IVF cycle, however, not all embryos are of good quality, particularly if they have undergone cryopreservation. Studies have found that in these embryos biopsies reduce implantation rates by 12.5%-25%. Furthermore, unlike PB biopsy, the cells at the blastomere stage contain both paternal and maternal contribution, giving the genetic analysis a fuller perspective on the embryo's genetic make up. Since blastomere biopsy is performed at the third day after fertilization, it is possible complete fresh embryo transfer. Thus, no storage procedures, such as cryopreservation, are necessary<ref name="PMID26237262"/>. <br />
===Trophectoderm biopsy===<br />
Day 5 and 6<br />
====Description====<br />
The improvement of embryo culture media allowed the in vitro development of human embryos until the blastocyst stage and opened up the possibility to take blastocyst biopsies. While currently according to ESHRE datasets only about 2.3% of biopsies are performed at the blastomere stage<ref name= "Traeger-Synodinos, J., Coonen, E., Goossens, V., De Mouzon, J., Shenfield, F., Ruiz, A., ... & de Mouzon, J. (2013). Session 09: ESHRE data reporting on PGD cycles and oocyte donation."/>. During day three to day five the haploid maternal and paternal genomes come together for the first time to form the genome of the embryo. The maternal epigenetic control lessens significantly while preparing for implantation with precisely arranged events happening. The first event includes a rapid increase in the number of embryonic cells which are active in mitotic divisions and apoptosis of aberrant cells. This is followed by the formation of blastocoel (cavitation) which results from the flattening of cell located on the outside of the blastomere. Now the blastocyst will expand until the embryo hatches by rupturing the zona pellucida. The cells of the blastocyst will differentiate to form two distinct cell lineages, the outer trophectoderm and the inner cell mass<ref name="PMID22723007"/>. <br />
====Procedure====<br />
Trophectoderm biopsy is usually performed in Hepes buffered biopsy medium and opening approaches include needle cutting which has been replaced by lasers in past years. Different research groups report different timings of the opening to be the most successful. Some open the blastocyst on day three or four by creating a 25 µm which causes the trophectoderm to herniate through this hole and is, thus, accessible for biopsy. Others create this hole about four hours before biopsy which allows sufficient herniation of trophectoderm cells. It is also possible to open the blastocyst immediately before biopsy. This avoids an extra step and the inner cell mass usually is easy to locate. Blastocyst biopsies involve the removal of trophectoderm cells and the ideal time for the procedure is day five. Successful biopsies on day six have been performed, while little is known about the results of biopsies on day seven. However, since the window of implantation in humans is from day eight to ten after ovulation, day seven biopsies appear to be possible<ref name="PMID22723007"/>.<br />
[[File:Microscopic images of human blastocysts for biopsy.jpeg|thumb|400px|left|(A) Some trophectoderm cells in a blastocyst started to hatch and (B) the trophectoderm cells were biopsied with assisted laser cutting. Images in C–D show the blastocysts after vitrification and warming. Blastocysts had been cultured for 2–4 hrs after warming, showing good (ICM and trophectoderm cells) hatched (C) and hatching (D) blastocysts. The hatching blastocyst in (E) has good ICM but fair trophectoderm while the blastocyst in (F) has both fair ICM and trophectoderm. Arrows indicate ICMs and arrow heads indicate trophectoderm cells. Bar = 40 µm<ref name="PMID2190846"><pubmed>2190846</pubmed></ref>.]]<br />
{|class="wikitable"align="right"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JI_TQ8d8tNM</html5media><br />
|-<br />
| Laser-assisted blastocyst biopsy (at 00:50 min)<ref>Coco, R. (2014, April 30) Trophectoderm biopsy in a Hatching blastocyst protruding ICM [Video file]. Retrieved from https://www.youtube.com/watch?v=JI_TQ8d8tNM</ref><br />
|}<br />
====Advantages & Disadvantages====<br />
Blastocyst biopsies are believed to be less damaging to the embryo and appear to be unrelated to implantation rates. In addition, this biopsy method allows for a larger extraction of cells for genetic testing. However, since they are performed late in in vitro development, the time window for genetic testing is relatively small. Fast and accurate genetic testing methods are needed to ensure a successful and safe result from this biopsy. Thus, blastocyst biopsies may gain more popularity in the future when such methods have been developed or improved<ref name="PMID22723007"/>. Furthermore, the extraction of multiple cells may lessen the effects of mosaicism and problems during PCR, such as ADO. Studies comparing the implantation rate and screening accuracy have found that blastocysts are significantly safer. Blastocyst biopsies decrease implantation rates significantly, while biopsies at day five or six do not seem to influence implantation and delivery rates<ref name="PMID26237262"/>.<br />
==Genetic Techniques==<br />
===Polymerase Chain Reaction===<br />
PCR amplifies DNA specific to genetic sequence of interest . PCR was developed by Kay Mullis in the 1980's, for which he was awarded the Nobel prize for chemistry in 1993 <ref> Pubmed Docs (2015) Polymerase Chain Reaction (PCR) Pubmed. Retrieved from [http://www.ncbi.nlm.nih.gov/probe/docs/techpcr/]</ref>. This technique enables clinicians to monitor and diagnose diseases using minute samples such as embryonic cells <ref>Roche (2015) PCR: How We Copy DNA. Roche Molecular Systems Inc. retrieved From [http://molecular.roche.com/pcr/Pages/Process.aspx]</ref>. PCR is used to detect genetic disorders, as a part of PGD, in conjunction with IVF<ref name="PMID24301057"><pubmed>24301057</pubmed></ref>. It is used to detect molecular abnormalities, such as single gene disorders including Tay Sach, Cycstic fibrosis, Duchenne Muscular Dystrophy, Thalassemia, Huntington disease, Spinal muscular atrophy and many more. Molecular and genetic analysis require a significant amount of DNA, which can be delivered by PCR. It revolutionized the study of DNA, replacing all previous recombinant DNA technology and is a significant component of PGD procedures<ref name="PMID24907939"/>.<br />
[[File:PCR.jpg|450px|thumb|PCR amplifies DNA specific to genetic sequence of interest, enabling the monitoring and diagnose molecular abnormalities such as single gene disorders using minute samples such as embryonic cells, blood & tissue <ref name="NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute">NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref>]]<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="7" |'''Advantages'''<br />
|-bgcolor="FFFAFA"<br />
| Fast and inexpensive way of copying a target sequence of DNA.<br />
|-bgcolor="FFFAFA"<br />
| Particularly useful for the diagnosis of single cell defects.<br />
|-bgcolor="FFFAFA"<br />
| Rapid generation of results (within hours).<br />
|-bgcolor="FFFAFA"<br />
| Highly sensitive, a single molecule of DNA is sufficient for reaction.<br />
|-bgcolor="FFFAFA"<br />
| Generates DNA copies exponentially.<br />
|-bgcolor="FFFAFA"<br />
| This enables DNA amplification required for molecular and genetic diagnostic analysis<ref> Dreesen, J., Drusedaul, M., Smeets, H., Die-Smulders, C., Coonen, E., Dumoulin, J., Gielen, M., Evers, J., Herbergers, J. & Geradets, J. (2008) Validation of preimplantation genetic diagnosis by PCR analysis: genotype comparison of the blastomere and corresponding embryo, implications for clinical practice. Mol. Hum. Reprod. 14 (10):573-579.doi: 10.1093/molehr/gan052. Retrieved from [http://molehr.oxfordjournals.org/content/14/10/573.short] </ref> <ref><pubmed>20966460</pubmed></ref>.<br />
|-bgcolor="DDCEF2"<br />
| rowspan="7"|'''Disadvantages'''<br />
|-bgcolor="FFFAFA"<br />
| Only during the exponential DNA replication phase, the starting quantity sequence contained in the original sample (template DNA strand) can be determined.<br />
|-bgcolor="FFFAFA"<br />
| PCR reaction is limited to by presence of inhibitors in the sample.<br />
|-bgcolor="FFFAFA"<br />
| Self annealing due to the accumulation of the product and the stopping exponential amplification for the target sequence and reaching of a plateau<br />
quantification of the end point of reaction of PCR products make real time quantitative RT-PCR necessary<ref name="NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute">NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref>.<br />
|-bgcolor="FFFAFA"<br />
| Not a diagnostic method on its own, but requires further analysis.<br />
|-bgcolor="FFFAFA"<br />
|Low-quantity DNA template may result in amplification failure<ref name="PMID24907939"/>.<br />
|-bgcolor="FFFAFA"<br />
|Allele drop-out (ADO) in heterozygous loci is possible<ref name="PMID24907939"/>.<br />
|}<br />
====Procedure====<br />
Samples are obtained from the the blastocyst, a polar body biopsy or the blastomeres stages of the embryo. <br />
*Stage 1 Denaturing: separating the target strands of DNA <br />
The obtained sample is heated to roughly 90 degrees celcius, this heat breaks the relatively weak bonds between nucleotides that form DNA. The double stranded DNA is split into two single strands of DNA that are used as templates.<br />
*Stage 2 Annealing: Binding the Primers to the target DNA sequence <ref name="PMID25250056"><pubmed>25250056</pubmed></ref><br />
PCR will only copy the target sequence of DNA specified by specific PCR primer. These synthesized primers oligonucleotides are small artificial pieces of DNA. TAQ polymerase enzyme synthesize two new strands of DNA duplicate to the single sample DNA stand template indicated by these primers. During this stage the reaction is cooled to a temperature between 40-60 degrees Celsius. <br />
*Stage 3- Extension- making copies <br />
Each of these two copies are then used again as templates generating two further replications This cycle can occur as many 30 -40 times within a couple hours leading to billions of extra copies of the original DNA segment. Generally the optimal temperature for the further replication is roughly 72 degrees Celsius, although, this may vary according to the analysis machines used. <ref name="PMID26092180"><pubmed>26092180</pubmed></ref><br />
This process mediated by a thermocycler machine that is programmed to alter the temperature of the reaction every couple of minutes, perpetuating the cycle of DNA denaturing and synthesis. <br />
This process, generates exponentially exact copies of the original template DNA sequence, as visible in the expandable table below. <ref> Mullins, K., Francois, F.& Gibbs R.A. (1994 ) The Polymerase Chain Reaction. p3. Springer- Science +Business Media. Birkhauser, Boston<br />
Available at [https://books.google.com.au/books?hl=en&lr=&id=gjrTBwAAQBAJ&oi=fnd&pg=PR5&dq=kary+mullis+PCR&ots=mpzAyRh5ZY&sig=PQ4goNoKJ90tb3-MkPk62zrTGbw#v=onepage&q=kary%20mullis%20PCR&f=false] </ref><br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
!rowspan="2" PCR cycles<br />
|-<br />
| '''PCR Cycle'''<br />
| '''Target Copies'''<br />
|-<br />
| 1<br />
| 2<br />
|-<br />
| 2<br />
| 4<br />
|-<br />
| 3<br />
| 8<br />
|-<br />
| 4<br />
| 16<br />
|-"<br />
| 5 <br />
| 32<br />
|-<br />
| 6 <br />
| 64<br />
|-<br />
| 7 <br />
| 128<br />
|-<br />
| 8<br />
| 256<br />
|- <br />
| 9<br />
| 512 <br />
|-<br />
| 10<br />
| 1024<br />
|-<br />
| 15<br />
| 32,768<br />
|-<br />
| 20 <br />
| 1,048,578<br />
|-<br />
| 25<br />
| 33,554,432<br />
|-<br />
| 30 <br />
| 1,073,741,842<br />
|-<br />
|}<br />
===Fluorescent In Situ Hybridisation===<br />
FISH is the one of the most effective and rapid <ref name="PMID26338801"><pubmed>26338801</pubmed></ref> method as part of PGD. This technique locates a specific DNA sequences within a chromosome. FISH facilitates the clinical diagnosis of chromosomal abnormalities indicated by sequential duplications, deletions and rearrangements of chromosome, that are usually missed with microscopic analysis. This technique is especially relevant for female embryos with X-linked diseases<ref name="PMID20809319"><pubmed>20809319</pubmed></ref>. As part of PGD, it enabled the screening for aneuploidies and increased live birth rates in women with advanced age<ref name="PMID24907939"/> <ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. FISH is 99% effective when used in conjunction with competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities<ref name="PMID26338801"/>. <br />
[[File:Fluorescent In Situ Hybridisation (FISH).jpg|thumb|450px|right|'''FISH''' Specific DNA sequences using probes which have been tagged with fluorescent labels are visualised.This technique enables the clinical diagnosis of chromosomal abnormalities, indicated by sequential duplication, deletions and rearrangements of chromosome <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref>]]<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="5" |'''Advantages''' <br />
|-bgcolor="FFFAFA" <br />
| FISH is 99% effective when used in conjunction with CGH to diagnose chromosomal abnormalities<ref><pubmed>26338801</pubmed></ref>.<br />
|-bgcolor="FFFAFA" <br />
| Results are rapidly generated. <br />
|-bgcolor="FFFAFA"<br />
| Very small translocations and aneuploidies that occur within chromosomes, that would usually be missed under microscopic analysis, can be identified<ref name="Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd)">Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref>.<br />
|-bgcolor="FFFAFA" <br />
| The most common chromosomal abnormalities, such as down syndrome chromosomes 13,16,18,21 and 22<ref><pubmed>21749752</pubmed></ref>, and inheritable X-linked disease or sex chromosome anomalies such as Duchenne's Muscular Dystrophy, hemophilia, ectodermal dysplasia<ref><pubmed>17876073</pubmed></ref> can be identified.<br />
|-bgcolor="DDCEF2"<br />
| rowspan="5"|'''Disadvantages'''<br />
|-bgcolor="FFFAFA" <br />
| FISH destroys all cells tested <ref> O'Connor, C. (2008) Fluorescence in situ hybridization (FISH). Nature Education 1(1):171. retrieved from [http://www.nature.com/scitable/topicpage/fluorescence-in-situ-hybridization-fish-327] </ref>.<br />
|-bgcolor="FFFAFA" <br />
| It does not fully access all chromosomes (only ~ 12)<ref name="PMID24907939"/>.<br />
|-bgcolor="FFFAFA" <br />
| The analysis of results is dependent upon the dot quality impacted by hybridisation efficiency or the camera sensitivity<ref name="PMID17970921"><pubmed>17970921</pubmed></ref>.<br />
|-bgcolor="FFFAFA" <br />
| Some studies indicate that using FISH on a day-3 embryo biopsy decreases the rate of live births<ref><pubmed>26168107</pubmed></ref>.<br />
|}<br />
====Procedure====<br />
Samples collected from the embryo<ref name="PMID21748341"><pubmed>21748341</pubmed></ref> are collected, processed, and its DNA strands are heated and denatured causing their the individual DNA strands to break apart. Then, probes of single complimentary stands of DNA a that have been tagged with small chemical agents that glow brightly in the presence of a specific region on a chromosome are added. These specific probes then hybridize and join to their complementary DNA strand. The fluorescent tags enable the correct identification of the presence or lack thereof and location of specific chromosomes that are tested for<ref name="PMID17876073"><pubmed>17876073</pubmed></ref>. The number and the relative location of the fluorescent dots generated by the FISH images is analysed and gives rise to diagnosis<ref name="PMID17970921"><pubmed>17970921</pubmed></ref>. The probe will not fully hybridise if there has been a duplication or a deletion of the DNA - indicating chromosomal and sex chromosomal anomalies like trisomies and aneuploidies. <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref>. Different probes are used for different purposes <ref>Unique, Rare Chromosome Disorder Support Group (2013) Fluorescence in situ hybridisation (FISH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/Other/FISH%20FTNW.pdf]</ref>:<br />
*'''Locus specific tags''' detect very small imbalances, and locate isolated small portions <br />
of genes within a chromosome<br />
*'''Alphoid/Centomeric Repeat probes''' are developed from the repetitive sequence located in the middle region of each chromosome, useful in determining the number of chromosomes , detecting rearrangement and when used in conjunction with locus probes to determine the absence of genetic material on a chromosome. <br />
*'''Paint Probes''' are collections of smaller probes with their own stains that bind to a different section on the chromosome - allowing the full chromosome too be labeled a unique colour, this "full colour map" can be used to know the spectral karyotype- full chromosomal mapping is useful in examining chromosomal abnormalities. <br />
===Array Comparative Genomic Hybridisation (aCGH)===<br />
[[File:aCGH.jpg|thumb|600px|right|'''aCGH''' checks the entire genome for chromosomal imbalances, by comparing control and a sample slides contatining small segements of DNA sample microarrayed slides small segments of DNA. Illustrated by student z5020317 and adapted from <ref> NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation. retrieved from [http://www.phgfoundation.org/file/5237/]</ref> <ref name="Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45"> Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432] </ref>]]<br />
aCGH also known as Microarray analysis efficiently scans the entire genome for chromosomal imbalances. CGH was initially developed to detect the number of changes in a solid tumor mass. It uses 2 genomes comparing the sample to the control, with each labeled in a different fluorescent dye<ref name="PMID1876176"><pubmed>1876176</pubmed></ref>. Earlier CGH techniques were limited by the resolution of the imaging <ref> Lichter, P., et al. Comparative genomic hybridization: Uses and limitations. Seminars in Hematology 37, 348–357 (2000)</ref>, these initial limitations were overcome by using Microarrays in conjunction with CGh to improve the resolution of the imaging, Array Comparative Genomic Hybridisation (aCGH). This method compares sample and control microarrayed slides containing small segments of DNA (probes). <ref> Lucito, R., et al. Representational oligonucleotide microarray analysis: A high-resolution method to detect genome copy number variation. Genome Research 13, 2291–2305 (2003) </ref> the Probes used will vary according from the small (25-85 base pairs) oligonucleotides manufactured to highlight different target sequences, to the very large genomic clones (80,000- 200,00 base pairs), and as these are significantly smaller than the traditional metaphase chromosomes used for CGH, generating a higher resolution of image. <ref name="PMID22467166"><pubmed>22467166</pubmed></ref>.aCGH is used as a diagnostic tool for prenatal detection f chromosomal abnormalities <ref name="PMID19012303"><pubmed>19012303</pubmed></ref>.<br />
{|class="wikitable" align="center"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="12" |'''Advantages''' <br />
|-bgcolor="FFFAFA"<br />
| Multiple applications: prenatal genetic diagnosis, cancer diagnosis, <ref name="PMID20193845"><pubmed>20193845</pubmed></ref> genetic screening for developmental delay (learning disabilities) <ref name="PMID17309648"><pubmed>17309648</pubmed></ref>. or congenital anomalies that are suspected to be genetic in origin <ref>NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation . retrieved from [http://www.phgfoundation.org/file/5237/]</ref><br />
|-bgcolor="FFFAFA"<br />
| trace represents all chromosomes present in the human genome chromosomes 1-22 and the X & Y chromosomes, and therefore is the most accurate method for testing whole embryo aneuploidy<br />
|-bgcolor="FFFAFA"<br />
| aCGH has been extensively tested, and Validated, and is now used world wide.<br />
|-bgcolor="FFFAFA"<br />
| Detects submicroscopic alterations<br />
|-bgcolor="FFFAFA"<br />
| Detects deletions and additions and rearrangements as well as amplification, of the WHOLE genome, simultaneously.<br />
|-bgcolor="FFFAFA"<br />
| Used as a diagnostic tool for prenatal detection of chromosomal abnormalities <ref name="PMID22034057"><pubmed>22034057</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Provides high resolution genomewide screening of segmental genomic copy number variations<br />
|-bgcolor="FFFAFA"<br />
| Very accurate when used in conjunction with FISH<br />
|-bgcolor="FFFAFA"<br />
| Alone is more reliable and in detecting chromosomal abnormalities, with a higher implantation success rate, than FISH <ref name="PMID20494259"><pubmed>20494259</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Allows an in depth research focus upon specific types of rearrangements within selected chromosomal regions, a recent particular area of interest is subtelomeric and pericentromeric rearrangements<br />
|-bgcolor="FFFAFA"<br />
| Reduces the risk of failed implantation and miscarriage, improving the chance of a healthy baby <ref name="Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd)">Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref>><br />
|-bgcolor="DDCEF2"<br />
| rowspan="9" |'''Disadvantages'''<br />
|-bgcolor="FFFAFA"<br />
| Translocations and inversions of DNA are not detected<br />
|-bgcolor="FFFAFA"<br />
| Limited ability diagnosing specific polyploidies such as triploidy <ref> Unique, Rare Chromosome Disorder Support Group (2013) Microarray-based Comparative Genomic Hybridiation (array CGH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/other/array%20cgh%20ftnw.pdf] </ref><br />
|-bgcolor="FFFAFA"<br />
| Will not detect mosaicism detection <20% (cultures where >1 of 5 cells are trisomy 12)<br />
|-bgcolor="FFFAFA"<br />
| Will not detect balanced chromosomal rearrangement<br />
|-bgcolor="FFFAFA"<br />
| Will not detect duplications or deletions <80kb<br />
|-bgcolor="FFFAFA"<br />
| Will not detect point mutations within genes <ref>Washington department of education (CGH- FAQ for physicians. Signature Genomic LAboratories, LLC. Retrieved from [https://depts.washington.edu/dbpeds/Lab%20Tests/SignatureCGH-physician_FAQ.pdf]</ref><br />
|-bgcolor="FFFAFA"<br />
| will not detect chromosomal position of genomic gains<br />
|-bgcolor="FFFAFA"<br />
| Will not detect loos of heterozygosity (LOH) or Absence of heterozygosity (AOH) <ref>WiCell Research Institute Inc. (2012) Comparative Genomic Hybridization Microarray. <br />
retrieved from [http://www.wicell.org/home/cytogenetic-services/cgh-microarray/array-comparative-genomic-hybridization-acgh.cmsx]</ref><br />
|}<br />
====Procedure==== <br />
As a part of PGD fetal cell samples are collected from; the fertilized egg polar bodies, the blastomere (day 3 embryo) or the blastocyst/tropoectoderm stage (day 5 embryo).<br />
Sample DNA is labeled with one fluorescent dye, and the control DNA is labeled with a different colored fluorescent dye. the control DNA is used as the base point of reference. <br />
heated and denatured single DNA strands then hybridize to their complementary single strand probes, which are then combined and applied to a microarray and the results are run through a computer program and a digital imaging system is used to quantify the results( fluorescent intensities of the labeled probes)<ref name="Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45"> Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432] </ref>. <br />
The fluorescent ratio and the hybridization signal at different locations on the genome of the control DNA are used to identify any variances present in the sample DNA. aCGH facilitates the clinical diagnosis of submicroscopic chromosomal duplication, deletion and rearrangements indicative of chromosomal disorders such as trisomies 1-22 and specific sex linked disorders. <br />
Duplication in the DNA are displayed by the computer program as spikes/ peaks over an established threshold and deletions in DNA are displayed by the computer program as spikes/ toughs beneath this threshold. <br />
===Next Generation Sequencing===<br />
The development and advances within ART in the past 20 years, as well as the increasing popularity of IVF, has lead to an influx of new technologies developed to screen embryos for chromosomal anomalies, which are covered by the umbrella term of Next generation Sequencing (NGS). NGS is a general term used to describe all of the new and emerging screening techniques currently being introduced and used as part of PGD for IVF. NGS screens for single gene disorders as well as conducting extensive and very comprehensive chromosome diagnosis by sequencing, counting, and accurately assembling millions of DNA reads, simultaneously<ref name="PMID23499002"><pubmed>23499002</pubmed></ref>. NGS is expected to replace the other limited and outdated testing techniques and be used as the standard test in the future. <br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="13" |'''Advantages''' <br />
|-bgcolor="FFFAFA" <br />
| Cost effective<br />
|-bgcolor="FFFAFA"<br />
| Accurately tests all 24 chromosomes.<br />
|-bgcolor="FFFAFA"<br />
| Tests for the presence of monogenic diseases of known genetic background.<br />
|-bgcolor="FFFAFA"<br />
| Reduces the number of biopsies required for diagnosis.<br />
|-bgcolor="FFFAFA"<br />
| Higher detection rate of small translocations is possible. <br />
|-bgcolor="FFFAFA"<br />
| Testing for compound point mutations, chromosomal duplication, deletions and insertions is highly accurate<ref name="PMID23312231"><pubmed>23312231</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| It accurately detects chromosomal aneuploidy and unbalanced rearrangement<ref name="PMID25685330"><pubmed>25685330</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| Higher detection rate of small translocations is possible.<br />
|-bgcolor="FFFAFA"<br />
| NGS single gene disorder screenings can be conducted in conjunction with PCR comprehensive chromosomal screening.<br />
|-bgcolor="FFFAFA"<br />
| Human error is reduced.<br />
|-bgcolor="FFFAFA"<br />
| It detects the presence of mosaicism better.<br />
|-bgcolor="FFFAFA"<br />
| Work well in conjunction with CGH and aCGH as part of PGD, improving the chances of IVF. <ref> Morris, R. S. (2015 ) Next generation sequencing for PCG|PGS|CCS. IVF1 retrieved from [http://www.ivf1.com/next-generation-sequencing for-pgd] </ref><br />
|-bgcolor="DDCEF2"<br />
| rowspan'''Disadvantages''' <br />
|-bgcolor="FFFAFA"<br />
| There are limited information available to clinical applications of NGS <ref><pubmed>26100406</pubmed></ref><br />
|}<br />
====Procedure====<br />
Samples are collected from either blastomere or the blastocyst/tropoectoderm and processed for analysis by a computer system. <br />
The methodology of each process is unique to the technique being used. the popularity of the new and emerging techniques is due to the cost effective nature of their testing, their speed and the accuracy of their results. Please see the table above for advantages of NGS.<br />
==Diagnosis==<br />
[[File:ACGH tracing after trophectoderm biopsy.jpeg|thumb|450px|Array comparative genomic hybridization (aCGH) tracing after trophectoderm biopsy: (a) normal male embryo (female embryo control in blue); (b) female embryo with monosomy for chromosome 20 (male control in red); (c) an excellent quality blastocyst showing chaotic chromosome abnormalities. Nearly every chromosome is aneuploidy<ref name="PMID26237262"/>.]]<br />
There are a large amount of diseases that PGD can apply to, below are descriptions of the diseases that PGD are more commonly used for. Upon completion of the genetic testing for the genes of concern the cells the embryos are discarded and priority is given to those that are healthy. <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/><br />
===Cystic Fibrosis===<br />
Cystic fibrosis is a single gene disorder. It is autosomal recessive and involves mutations in the cystic fibrosis transmembrane conductance regulator (CTFR) gene. The CTFR gene is normally responsible for the decrease in chloride and the transport of bicarbonate in epithelial cells thus playing a major physiological role. In PGD procedures, identification of the gene is assisted by microsatellite markers that have similar composition to the CTFR gene itself. Biopsy of two cells at the blastocyst stage is recommended if markers are not available. There are many variations of cystic fibrosis the most common being P.Phe508del <ref name="PMID26014425"><pubmed>26014425</pubmed></ref>.<br />
===Duchenne Muscular Dystrophy ===<br />
Duchenne Muscular Dystrophy is an X-linked recessive disease. It involves the Xp21 gene where majority of the mutations are chromosomal deletions with a smaller percentage resulting from duplications <ref name="PMID18359022"><pubmed>18359022</pubmed></ref>.<br />
===Autosomal Recessive Meckel-Gruber Syndrome===<br />
Autosomal recessive genetic defect caused by the TMEM67 gene. It results in cystic dysplasia of the kidneys with fibrotic change in the liber and occipital encephalocele. Other malformations could also be present in the central nervous system. In PGD whole genome amplification of single blastomeres are taken to identify the gene, this is also coupled with PCR techniques. Maternal plasma can also be extracted for PGS. <ref><pubmed>24039893</pubmed></ref> <br />
===β – Thalassemia=== <br />
β – Thalassemia is known as the most common type of autosomal recessive inherited disorder among haemoglobinopathies. It involves the adult β-globin gene and is associated with the absent or decreased expression of the gene. This is commonly caused by a single nucleotide change in the gene. PGD has been used successfully worldwide to identify the β-globin gene where its application is usually performed on a single blastomere or polar body <ref name="PMID19064120">19064120</pubmed></ref>.<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
! Applicable diseases for PGD <ref>Genoma Group (2014). Retrieved September 18th, 2015, from http://www.preimplantationgeneticdiagnosis.it/genetic-diseases-diagnosed-by-pgd.htm </ref> <ref>Genesis Genetics (2015). Retrieved September 18th, 2015, from http://genesisgenetics.org/pgd/what-we-test-for/</ref> <ref>Human Fertilisation & Embryology Authority (2015). Retrieved Septembr 18th, 2015, from http://guide.hfea.gov.uk/pgd/</ref><br />
|-<br />
| '''Disease'''<br />
| '''Involved Genes'''<br />
|-<br />
| 5 Alpha Reductase Deficiency (5ARD)<br />
| SRD5A2 [http://www.omim.org/entry/607306]<br />
|-<br />
| Achondroplasia<br />
|FGFR3 [http://www.omim.org/entry/134934]<br />
|-<br />
| Acute Intermittent Porphyria <br />
| ALAD [http://www.omim.org/entry/125270] , ALAS2 [http://www.omim.org/entry/612732], CPOX [http://www.omim.org/entry/612386], FECH [http://www.omim.org/entry/612386], HMBS [http://www.omim.org/entry/609806], PPOX [http://www.omim.org/entry/600923], UROD [http://www.omim.org/entry/613521], or UROS [http://www.omim.org/entry/606938]<br />
|-<br />
| Adrenoleukodystrophy (Adrenomyeloneuropathy)<br />
| ABCD1 [http://www.omim.org/entry/300371]<br />
|-<br />
| Agammaglobulinaemia (x-linked) <br />
|BTK [http://www.omim.org/entry/300300]<br />
|-<br />
| Agammaglobulinemia Bruton Tyrosine Kinase (BTK) <br />
|BTK [http://www.omim.org/entry/300300]<br />
|-<br />
| Aicardi Goutieres Syndrome 1 (AGS1) <br />
|TREX1 [http://www.omim.org/entry/606609] , RNASEH2A [http://www.omim.org/entry/606034] , RNASEH2B [http://www.omim.org/entry/610326] , RNASEH2C [http://www.omim.org/entry/610330], SAMHD1 [http://www.omim.org/entry/606754]<br />
|-<br />
| Alagille Syndrome<br />
|JAG1 or NOTCH2<br />
|- <br />
| Alpers-Huttenlocher Syndrome <br />
|POLG <br />
|-<br />
| Alpha-1-antitrypsin deficiency <br />
|SERPINA1 <br />
|-<br />
| Alpha-Mannosidosis<br />
| MAN2B1 <br />
|-<br />
| Alpha Thalassemia <br />
|HBA1 or HBA2 <br />
|-<br />
| Alports Syndrome<br />
|COL4A3, COL4A4, COL4A5<br />
|-<br />
| Alzheimer's Disease - early onset (Type 3 and 4) <br />
|APP, PSEN1, or PSEN2<br />
|-<br />
| Amyotrophic Lateral Sclerosis 1 (ALS1) <br />
|C9orf72, SOD1, TARDBP, FUS, ANG, ALS2, SETX, VAPB <br />
|-<br />
| Argininosuccinic Aciduria <br />
| ASL<br />
|-<br />
| Arrhythmogenic Right Ventricular Cardiomyopathy/ Dysplasia (ARVC/D)<br />
| DSG2; DSP; PKP2<br />
|-<br />
| Ataxia Telangiectasia<br />
| ATM<br />
|-<br />
| Autosomal Recessive Meckel-Gruber Syndrome<br />
| TMEM67<br />
|-<br />
| Bardet-Biedl Syndrome (BBS)<br />
| BBS1; BBS10<br />
|-<br />
| Barth Syndrome<br />
| TAZ<br />
|-<br />
| Beta Thalassaemia<br />
| HBB<br />
|-<br />
| Birt-Hogg-Dubé Syndrome<br />
| FLCN<br />
|-<br />
| Breast Ovarian Cancer Familial Susceptibility (BRCA2)<br />
| BRCA1; BRCA2<br />
|-<br />
| Canavan Disease <br />
| ASPA<br />
|-<br />
| Carnitine-Acylcarnitine Translocase Deficiency <br />
| SLC25A20<br />
|-<br />
| Cerebral Arteriopathy with Subcortical Infarcts & Leukoencephalopathy (CADASIL)<br />
| NOTCH3<br />
|-<br />
| Cerebral Cavernous Malformation<br />
| CCM1<br />
|-<br />
| Charcot-Marie-Tooth Disease<br />
| GJB1; MPZ; NEFL; PMP22<br />
|-<br />
| CHARGE Syndrome<br />
| CHD7<br />
|-<br />
| Cherubism<br />
| SH3BP2<br />
|-<br />
| Choroideremia<br />
| CHM<br />
|-<br />
| Chronic Granulomatous Disease<br />
| CYBB; NCF1<br />
|-<br />
| Ciliary Dyskinesia<br />
| DNAH5<br />
|-<br />
| Citrullinemia<br />
| ASS1<br />
|-<br />
| Cleidocranial Dysplasia<br />
| RUNX2<br />
|-<br />
| Cockayne Syndrome<br />
| ERCC6<br />
|-<br />
| Congenital Adrenal Hyperplasia<br />
| CYP21A2<br />
|-<br />
| Congenital Cataracts<br />
| GJA8; VSX2<br />
|-<br />
| Congenital Diarrhea, Syndromic<br />
| SPINT2<br />
|-<br />
| Congenital Disorders of Glycosylation (CDG)<br />
| ALG1; ALG6; CDG1C; DOLK; PMM2<br />
|-<br />
| Cornelia de Lange Syndrome <br />
| NIPBL<br />
|-<br />
| Craniosynostosis<br />
| TWIST1<br />
|-<br />
| Crouzon Syndrome<br />
| FGFR2<br />
|-<br />
| Cysteinyl Leukotriene Receptor 1 Deficiency <br />
| CYSLTR1<br />
|-<br />
| Cystic Fibrosis<br />
| CFTR<br />
|-<br />
| Diamond –Blackfan Anemia <br />
| RPS19<br />
|-<br />
| Duchenne Muscular Dystrophy <br />
| DMD<br />
|-<br />
| Dyskeratosis congenita (Male embryos only)<br />
| DKC1<br />
|-<br />
| Ectodermal dysplasia (Hypohidrotic)<br />
| EDA; EDA1; GJB6; IKBKG<br />
|-<br />
| Familial Adenomatous polyposis coli (FAP)<br />
| APC<br />
|-<br />
| Familial Dysautonomia<br />
| IKBKAP<br />
|-<br />
| Fanconi Anemia <br />
| FANCA; FANCC; FANCD2; FANCF; FANCG; FANCJ<br />
|-<br />
| Fragile X Syndrome (FRAX)<br />
| FMR1<br />
|-<br />
| Galactosemia <br />
| GALT<br />
|-<br />
| Gangliosidosis<br />
| GLB1<br />
|-<br />
| Glanzmann Thrombasthenia <br />
| ITGA2B<br />
|-<br />
| Glutaric Acidemia (aciduria)<br />
| GCDH <br />
|-<br />
| Glycogen Storage Disease <br />
| G6PC; GAA; SLC37A4<br />
|-<br />
| Haemophilia A<br />
| F8<br />
|-<br />
| Haemophilia B<br />
| F9<br />
|-<br />
| Hereditary Nonpolyposis Colorectal Cancer: Lynch Syndrome<br />
| MLH1; MSH2; MSH6<br />
|-<br />
| Holt Oram Syndrome<br />
| TBX5<br />
|-<br />
| Huntington Disease<br />
| HD<br />
|-<br />
| Hydrocephalus<br />
| L1CAM<br />
|-<br />
| Ichthyosis <br />
| ABCA12; STS<br />
|-<br />
| Incontinentia Pigmenti (IP)<br />
| NEMO<br />
|-<br />
| Joubert Syndrome 5<br />
| INPP5E<br />
|-<br />
| Krabbe Disease<br />
| GALC<br />
|-<br />
| Leber Congenital Amaurosis (LCA)<br />
| CEP290; GUCY2D<br />
|-<br />
| Leigh Syndrome (Infantile Subacute Necrotising Encephalopathy)<br />
| LRPPRC<br />
|-<br />
| Lesch Nyan Syndrome<br />
| HPRT1<br />
|-<br />
| Leukocyte Adhesion Deficiency (Type I)<br />
| ITGB2<br />
|-<br />
| Li-Fraumeni Syndrome<br />
| TP53<br />
|-<br />
| Macular Dystrophy Retinal <br />
| VMD2<br />
|-<br />
| Maple Syrup Urine Disorder (MSUD)<br />
| BCKDHB<br />
|-<br />
| Marfan Syndrome <br />
| FBN1<br />
|-<br />
| Menkes Syndrome<br />
| ATP7A<br />
|-<br />
| Mitochondrial DNA Depletion Syndrom <br />
| POLG; RRM2B; SUCLA2; TK2<br />
|-<br />
| Mucolipidosis type II<br />
| GNPTAB<br />
|-<br />
| Multiple Endocrine Neoplasia<br />
| MEN1; MEN2A; MEN2B<br />
|-<br />
| Multiple Exostoses<br />
| EXT1; EXT2 <br />
|-<br />
| Myotubular myopathy<br />
| MTM1 <br />
|-<br />
| Nail-Patella Syndrome<br />
| LMX1B<br />
|-<br />
| Neurofibromatosis Type 1<br />
| NF1<br />
|-<br />
| Neurofibromatosis Type 2 <br />
| NF2<br />
|-<br />
| Noonan Syndrome<br />
| KRAS, PTPN11; SOS1<br />
|-<br />
| Norrie Disease<br />
| NDP<br />
|-<br />
| Ocular Albinism <br />
| GPR143<br />
|-<br />
| Oculocutaneous Albinism <br />
| OCA2; TYR <br />
|-<br />
| Oculodentaldigital Dysplasia<br />
| GJA1<br />
|-<br />
| Optic Atrophy<br />
| OPA1<br />
|-<br />
| Ornithine Transcarbamylase Deficiency <br />
| OTC<br />
|-<br />
| Osteogenesis imperfeca <br />
| COL1A1; COL1A2<br />
|-<br />
| Osteopetrosis <br />
| CLCN7; OSTM1; TCIRG1<br />
|-<br />
| Pachyonychia Congenita <br />
| KRT16; KRT6A<br />
|-<br />
| Pancreatitis, Hereditary<br />
| PRSS1 <br />
|-<br />
| Papillorenal syndrome <br />
| PAX2<br />
|-<br />
| Phenylketonuria <br />
| PAH <br />
|-<br />
| This table does not cover the complete list of diseases that PGD can be applied to.<br />
|}<br />
==Laws & Legal status==<br />
{| class="wikitable" <br />
|-bgcolor="DDCEF2"<br />
|'''Country'''<br />
|'''Legislation'''<br />
|-bgcolor="FFFAFA" <br />
| Australia<br />
| PGD is currently used to detect serious genetic conditions to improve the outcome of Assisted Reproductive Technologies (ART). In very rare cases it may be used to select an embryo with compatible tissue for a sibling who has a life-threatening disease where other means of treatment is unavailable. This is with the conditions that the use of PGD will not affect the welfare and interests of the child to be born. The parents must also receive adequate counselling and have full understanding of the procedures of PGD. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"> National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art</ref><br />
The use of PGD for sex-selection is prohibited with the exception of reducing the risk of the transmission of serious sex-linked genetic conditions. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"/><br />
|-bgcolor="FFFAFA"<br />
| Brazil<br />
| The laws regarding PGD in Brazil are not strictly regulated. They are vague and there is limited information surround the activities of assisted reproduction in general in the country <ref name="PMID25493379"><pubmed>25493379</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| Czech Republic<br />
| The laws in the Czech Republic allow those with a “defined indication in order to exclude risk of serous genetically conditioned disease and defects with embryos before they are implanted into the cavity of the uterus”. Couples that undergo any assisted reproductive treatment including PGD have to be married. Sex-selection is illegal except in regards to serious sex-linked genetic diseases <ref name="PMID24777348"><pubmed>24777348</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| Greece<br />
| In Greece, ART is open to those up to the age of 50 with written consent. It can only be used if a medical necessity is present such as the susceptibility of serious hereditary diseases. Sex selection is banned apart from cases of sex-linked diseases and sexually transmitted diseases <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| India<br />
| In India there is a cultural preference for boys thus the Prenatal Diagnostic Techniques (Regulation and Prevention of Misuse) Act was introduced in 1994. This law limits the use of PGD for sex determination except in cases of specific congenital diseases. These laws however are not strictly enforced. <ref>World Health Organisation (2015) Gender and Genetics Retrieved on October 21st 2015 from:http://www.who.int/genomics/gender/en/index4.html</ref><br />
|-bgcolor="FFFAFA"<br />
| Portugal <br />
| ART is only available to those who are married or have a similar type of relationship for at least two years. The couples cannot be of the same sex and must be at least 18 years of age. Sex selection is illegal except in cases of sex-linked diseases. The use of PGD is illegal if the predictive value of genetic tests are very low <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| Spain<br />
| PGD can be applied to “serious hereditary diseases not amenable to postnatal curative treatment” and “detection of other abnormalities which may compromise the viability of the pre-embryo”. If PGD is to be used for any other purpose authorisation must be acquired <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| Sweden <br />
| The use of PGD is strictly regulated and couples must achieve authorisation of the National Board of Health and Welfare. It can only be used it can only be used if the child is at risk to inheriting a serious chromosomal or monogenetic disease. It cannot be used for selection of specific characteristics <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| United Kingdom<br />
| Those involved with carrying out the IVF treatment must have a license from the Human Fertilisation and Embryology Authority (HFEA). Only embryos that are approved by the HFEA can be implanted where the embryonic nuclear or mitochondrial DNA cannot be altered with the exception of preventing mitochondrial diseases <ref name="PMID24777348"/>. <br />
|}<br />
==Future/Current Research==<br />
In addition to research efforts for improving overall performance of established PGD/S techniques, such as finding the ideal zona pellucida insection site in an fully automatic manner<ref name="PMID26259216"><pubmed>26259216</pubmed></ref>, many research efforts have been spent to find alternative, non-invasive techniques to test for diseases and abnormalities<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
===Non-invasive Preimplantation Genetic Testing without Embryo Biopsy===<br />
Different parameters of gametes, zygotes, embryos (“vacuoles in sperm heads, spindle position in mature oocytes, cleavage intervals of zygote, and embryo developmental dynamics”) may correlate with aneuploidy rates. This knowledge may be applied in potential noninvasive preimplantation diagnostic methods. Several methods have been proposed and are currently further researched<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Sperm Selection====<br />
Intracytoplasmic morphologically selected sperm injection (IMSI) is common procedure in IVF treatment to improve fertilization rates in patients with poor semen quality. In addition, studies have found that IMSI improves embryo development and that spermatozoa with large vacuoles in their heads correlate with increased aneuploidy rates and disturbed chromosomal structures. Thus, selecting spermatozoa based on morphological hallmarks may decrease aneuploidy rates in the fertilized embryos. As with polar body biopsies, however, this approach will solely be applicable if evidence for severe male detrimental contribution is given<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Blastocoel Fluid Extraction====<br />
In addition, a less invasive retrieval of material for diagnosis could include the extraction of the blastocoel fluid. The cavity of the blastocyst, lined by the trophectoderm, is filled with this blastocoel fluid, which contains metabolites of both trophectoderm and inner cell mass origin. The retrieval does not require a biopsy but merely a small opening to extract the fluid and, thus, causes less harm to the embryo. Multiple studies have applied this method<ref name="PMID22020776"><pubmed>22020776</pubmed></ref> <ref name="PMID23148560"><pubmed>23148560</pubmed></ref> <ref name="PMID26006737"><pubmed>26006737</pubmed></ref> and it may in the future become of clinical relevance.[[File:Aspiration_of_the_Blastocoel_Fluid.jpeg|400px|thumb|Aspiration of the Blastocoel Fluid using a ICSI pipette<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.]]Next to metabolites, the blastocoel fluid can contain DNA. Studies have shown that genomic DNA is present in about 90% of the blastocoel fluid samples tested. Typically the fluid is removed with an ICSI pipette from a day five blastocyst through its mural trophectoderm until the blastocyst fully collapses around the embryo. Several concerns regarding this method in a clinical setting have been raised. The collected DNA may be contaminated by the culture media that contains DNA fractions. The DNA may also be least representative of the actual embryos genome as the DNA may originate from abnormal or degenerated cells. Even though labelled noninvasive, the blastocyst still undergoes manipulation to some degree which may affect its viability. Thus, more research is required until this method can evolve from research to clinical use<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
====Proteomics and Medium Based PGD====<br />
The media in which embryos are kept during the early IVF procedures, gives rise to potential non-invasive techniques. For instance, the protein secretome of blastocysts may be representative of its chromosome constitution Recent studies have found biomarkers such as lipocalin-1, interleukin-10, tumor necrosis factor, stem cell factor, and chemokine ligand 13 to be differently secreted by aneuploid blastocyst than by euploid ones. The most significant biomarker appears to be interleukin-10. Paired with novel proteomic technologies and mass spectrometry this knowledge when extended may contribute to a new invasive PGD method<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. In addition, medium based non-invasive PGD has been researched for the diagnose of human α-thalassemia-SEA. Genomic DNA was collected from the media and the study surprisingly resulted in increased diagnosis efficacy compared to biopsy-based methods<ref name="PMID25816038"><pubmed>25816038</pubmed></ref>.<br />
====Embryo Morphology====<br />
Using time lapse imaging the embryo’s morphology can be closely observed and potential aneuploidy characteristics detected. Such characteristics may include the time of division to five cells, the time between the division from three to four cells, and the duration of the division from one to two and subsequently to three. In addition, the morphological quality of ICM an TE has been positively associated with aneuploidy or euploidy prognosis<ref name="PMID26246880"><pubmed>26246880</pubmed></ref>. These may give rise to an embryo quality screening prior to implantation<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
==Glossary==<br />
'''Aberrent Cells'''<br />
<br />
'''Abnormalities:'''<br />
<br />
'''Allele:'''<br />
<br />
'''Anneuploidy:'''<br />
<br />
'''Annelaing:'''<br />
<br />
'''Aspiration:'''<br />
<br />
'''Biopsy:''' sample of tissue taken for examination <br />
<br />
'''Blastocyst:''' Stage of embryo at approximately day 5 consisting of an outer (trophoblast) layer and inner (embryoblast) cell mass. <br />
<br />
'''Blastomere:''' Initial cells formed through mitosis of the zygote<br />
<br />
'''Chromosome'''<br />
<br />
'''CTFR:''' Cystic Fibrosis Transmembrane Conductance Regulator, responsible for transport of chloride across the cell membrane<br />
<br />
'''Cytoplasmic Bridge:'''<br />
<br />
'''Denaturing:'''<br />
<br />
'''DNA:'''<br />
<br />
'''Endometriosis:''<br />
<br />
'''Enucleation:'''<br />
<br />
'''Epigenetic:'''<br />
<br />
'''Extension:'''<br />
<br />
'''Fluorescent In situ hybridisation:''' technique use to locate specific gene sequences using fluorescence tags <br />
<br />
'''Genome:'''<br />
<br />
'''Heterozygosity:'''<br />
<br />
'''Haemotological:'''<br />
<br />
'''Hydrosalphinx:''' <br />
<br />
'''Intracytoplasmic Morphologically Selected Sperm Injection (IMSI):''' IVF technique involving morphological selection of sperm under the microscope to be injected to oocyte<br />
<br />
'''Intracytoplasmic Sperm Injection (ICSI):''' IVF technique used to treat male infertility and involves direct injection of one sperm into an oocyte<br />
<br />
'''In Vitro:'''<br />
<br />
'''IVF:'''<br />
<br />
'''Leukocyte:'''<br />
<br />
'''Leukemia:'''<br />
<br />
'''Locus:''<br />
<br />
'''Micorarray:'''<br />
<br />
'''Mitochondria:'''<br />
<br />
'''Molecular anomalies:'''<br />
<br />
'''Next Generation Sequencing (NGS):''' Term used to describe the collection of recent findings regarding embryo screening<br />
<br />
'''Oolema'''<br />
<br />
'''Phenotype:'''<br />
<br />
'''Polar bodies:''' cell formed during the meiotic stages of the oocyte containing extra genetic material <br />
<br />
'''Polymerase Chain Reaction (PCR):''' Technique used to amplify DNA to study a specific genetic sequence<br />
<br />
'''Polyploidy:'''<br />
<br />
'''Preimplantation Genetic Diagnosis (PGD):''' Involves genetic testing conducted to identify abnormalities in an embryo before implantation.<br />
<br />
'''Preimplantation Genetic Screening (PGS):''' Involves genetic screening for genetic abnormalities using techniques such as FISH and PCR to eliminate unhealthy embryos <br />
<br />
'''Perivitelline Space:''<br />
<br />
'''Primer:'''<br />
<br />
'''Robertsonian Translocations:''' Type of structural chromosomal translocation <br />
<br />
'''Single Gene Disorders:''<br />
<br />
'''Self Annealing:'''<br />
<br />
'''Submicroscopic:'''<br />
<br />
'''Translocations:'''<br />
<br />
'''Trisomies:'''<br />
<br />
'''Trophoectoderm:'''<br />
<br />
'''Zona Pellucida:'''<br />
<br />
<br />
==References==<br />
<br />
<references/><br />
<br />
<br />
{{StudentPage2015}}</div>Z5017878https://embryology.med.unsw.edu.au/embryology/index.php?title=File:Reasons_for_PGD.jpg&diff=208229File:Reasons for PGD.jpg2015-10-23T03:10:21Z<p>Z5017878: /* Reference */</p>
<hr />
<div>This image is a pie chart representation reproduced by student z5088434 from the data of Table 3 of 'Reprogenetics: Preimplantational genetics diagnosis' by Coco, R. <br />
PMID 24764761<br />
===Reference===<br />
<pubmed>24764761</pubmed><br />
<br />
===Copyright===<br />
License information: This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.</div>Z5017878https://embryology.med.unsw.edu.au/embryology/index.php?title=2015_Group_Project_6&diff=2082132015 Group Project 62015-10-23T03:06:02Z<p>Z5017878: </p>
<hr />
<div>{{ANAT2341Project2015header}}<br />
<br />
<br />
=Preimplantation Genetic Diagnosis and Preimplantation Genetic Screening=<br />
==Introduction==<br />
Preimplantation genetic diagnosis (PGD) and preimplantation genetic screening (PGS) are reproductive options for couples with known family histories of genetic disease or couples undergoing IVF procedures due to infertility issues. PGD can diagnose many genetic disorders caused by known chromosomal abnormalities (number and/or structure) or single gene mutations, and, thus decrease the risk of termination of pregnancy or miscarriages and enable such couples to have an unaffected child<ref name="PMID24907939"><pubmed>24907939</pubmed></ref>. Through major improvements in PGD/S and general laboratory technology, the testing for abnormalities in fetuses has shifted from prenatal diagnosis during the first 2 trimesters <ref> Blackburn, S.L. (2003) '''Maternal, Fetal & Neonatal physiology: a Clinical perspective''' (2nd ed.). Seattle: Saudners </ref>, testing for overall fetal growth, complications of pregnancy, and birth defects<ref> Sadler T.W.(2012) '''Langman's Medical Embryology''' (12th ed.) Philadelphia: Lipincott, Wiliams & Wilkins, a Wolters Kluwer Business </ref>, to an embryonic focus especially in advancements in Artificial Reproductive Technologies (ART)<ref><pubmed>20638568</pubmed></ref>. In 1990 PGD for a recessive X-linked disease resulted in the first live birth<ref><pubmed>2330030</pubmed></ref> and has since been incorporated in clinical routine and applied for a variety of genetic diseases, such as sickle cell anemia, thalassemia, or cystic fibrosis<ref name="PMID24907939"/>.<br />
[[File:Preimplantation Genetic Diagnosis Procedure.jpeg|600px|left|thumb| Simplified steps for PGD<ref name="PMID24907939"/>]]<br />
{|class="wikitable"align="right" <br />
| <html5media height="400" width="533">https://www.youtube.com/watch?v=0e-79qKllqk</html5media><br />
|-<br />
| Preimplantation Genetic Diagnosis<ref>IVF Florida (2011, December 11) IVF Florida - South Florida Fertility Specialists - Pre-Implantation Genetic Diagnosis [Video file]. Retrieved from https://www.youtube.com/watch?v=0e-79qKllqk</ref><br />
|}<br />
<br />
==History==<br />
The advances in reproductive technology during the second half of the 20th century, led to PGD's first clinical application in 1990 <ref>Harper, J. (n.d.). The history of PGD. Lecture. UCL Centre for PG&D and CRGH.University College London</ref>.<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
|Year<br />
|<br />
|- bgcolor="FFFAFA"<br />
| '''1967''' <br />
|First PGD on rabbit blastocysts (Gardner& Edwards) <ref name="PMID6036172"><pubmed>6036172</pubmed></ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1986''' <br />
|First Cleavage Biopsy (Wilton & Trounson)<ref>Wilton, L. J., & Trounson, A. O. (1986). Viability of mouse embryos and blastomeres following biopsy of a single cell. In Proceedings of the 18th Annual Conference of the Australian Society for Reproductive Biology, Brisbane, Australia.</ref><br />
|- bgcolor="FFFAFA"<br />
|'''1987''' <br />
|First Blastocyst Biopsy (Muggleton-Harris, Monk, Rawlings, & Whittingham)<ref name="PMID3372699"><pubmed>3372699</pubmed></ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1988''' <br />
|First Polar Body Biopsy (Yury Verlinksy)<ref> Verlinsky, Y., Pergament, E., Andresen, P., Enriquez, G., & Strom, C. (1989). Genetic analysis of polar body DNA: A new approach to preimplantation genetic diagnosis. Am J Hum Genet, 45(4), A272.</ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1990''' <br />
|First Clinical PGD using PCR testing for X-linked (Handyside, Kontogianni, Hardy, & Winston)<ref name="PMID2330030"><pubmed>2330030</pubmed></ref> <br />
|} <br />
==Preimplantation Genetic Diagnosis==<br />
PGD is used to test the genetic makeup of embryos to detect single gene disorders, chromosomal abnormalities and mitochondrial disorders. It also has applications in gender selection for diseases with unequal gender distributions <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Some diseases commonly involved with PGD include cystic fibrosis, spinal muscular atrophy and beta – thalassaemia <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press.">Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press</ref> <ref name="PMID17823145"><pubmed>17823145</pubmed></ref>. It was first used in the United Kingdom in the 1980s, primarily focusing on sex- linked disorders <ref name="PMID17823145"/><ref name="PMID23150080"><pubmed>23150080</pubmed></ref>. PGD is now capable of detecting single cell defects (molecular) and chromosomal disorders resulting from the inversion, translocation or deletion of chromosomes (cytogenic) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/> <ref name="PMID11325751"><pubmed>11325751</pubmed></ref>. PGD can be applied to the embryo at different stages. That is on polar bodies, blastomeres or blastocyst <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>.<br />
Depending on the type of genetic disorder, PGD utilises different methods of genetic testing. These include Fluorescence in situ hybridisation (FISH) which is used for sex – linked disorders and detects chromosomal rearrangements <ref name="PMID11325751"/><ref name="PMID17876073"><pubmed>17876073</pubmed></ref> and Embryo halotyping which allows the identification of chromosomes causing the inherited disorder through knowledge of the pattern of closely linked markers <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. Polymerase chain reaction (PCR) is also widely used to detect molecular abnormalities <ref name="PMID11325751"/>.<br />
PGD is tightly regulated and supported by large organisations namely The American Society for Reproductive Medicine, The European Society for Human Reproduction and Embryology (ESHRE), The European Society of Human Genetics and the Preimplantation Genetic Diagnosis International Society <ref name="PMID25500181><pubmed>25500181</pubmed></ref>.<br />
===Sex-linked disorders===<br />
The determination of a disease as gender specific usually correlates with the presence or absence of specific genes such as SRY on the Y chromosome. It is known that females have two X chromosomes and males have an X and a Y chromosome where abnormalities are more prevalent on the X chromosome. PGD can be used for sex selection where only male embryos are transferred to reduce the chance of inheriting X-linked disorders. However, this does not completely eradicate the problem as male embryos remain susceptible to inheriting an affected X chromosome. Sex determination is only used when the specific mutation is unknown and has yet to be discovered <ref name="PMID24866878"><pubmed>24866878</pubmed></ref>.<br />
===Single gene defects===<br />
Single gene defects can be dominant, recessive, autosomal or X-linked. They are commonly diagnosed using PCR and although the PCR available today is complex and capable of combatting a large range of disease the development of new protocols has been proven to be difficult due to the small DNA sample available <ref name="PMID26168107"><pubmed>26168107</pubmed></ref>.<br />
===Mitochondrial disorders===<br />
Mitochondrial disorders also known as oxidative phosphorylation disorders arise from mutations in the nuclear DNA or mitochondrial DNA <ref name="PMID26312584"><pubmed>26312584</pubmed></ref>. They pose as a problem because they are unrecognisable until the mutations in the cell reach a detrimental level <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Mitochondrial disorders cause miscarriages and stillbirths as well as death in children and young adults. The effects can either be contained in a single organ or more commonly involve multiple organ failure where organs with high energy demands such as the brain, liver muscle and heart and heavily influenced. They are usually occur spontaneously or result from inheritance from the mother. Since mitochondria are solely inherited from the mother oocyte donations have been used as a solution to combat mitochondrial disorders. Additionally, there has been an increasing use in PGD where embryos that stay under the given threshold of 18% gene-mutations are allowed to be transferred and result in normal development. New technology in the areas of nuclear gene transfer and genome editing are also being experimented with <ref name="PMID26312584"/>. <br />
===Chromosomal disorders===<br />
Chromosomal disorders can be reciprocal, Robertsonian translocations, inversions, deletions and insertions <ref name="PMID26168107"/>. Data from ESHRE collected between 2010 and 2011 has shown that the most common chromosomal abnormality confronted in PGD are reciprocal chromosomal abnormalities <ref name"PMID26071418"><pubmed>26071418</pubmed></ref>. PGD has also been used successfully for Robertsonian translocations (RT), a type of structural translocation. Children who carry RT are phenotypically normal, however in their later years it is found that they will suffer from infertility and repeated miscarriages due to the high frequency of abnormal embryos <ref name="PMID22081077"><pubmed>22081077</pubmed></ref>. PCR and FISH are the two main techniques used for chromosomal disorders. To be able to conduct the examinations the cells are required to be at the metaphase stage <ref name="PMID26168107"/>. <br />
[[File:Reasons_for_PGD.jpg|600px|thumb|Reasons for PGD<ref name= "PMID24764761"><pubmed><24764761</pubmed></ref>]]<br />
==Preimplantation Genetic Screening==<br />
PGS involves an array of methods or ideas that aim to segregate embryos that have genetic flaws and those that are healthy <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. The occurrence of aneuploidy is high around the stages of early embryonic development and they are the most common cause if miscarriages and congenital birth defects <ref name= "PMID26085841"><pubmed>26085841</pubmed></ref>. They have little effect on the morphology of the embryo making them difficult to identify thus identification heavily relies on genetic testing <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. <br />
Genetic sampling is most commonly conducted using Microarray Comparative Genomic Hybridisation (aCGH) as well as FISH, Quantitative PCR and Single Nucleotide Polymorphism (SNP) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. These methods collectively aim to assess numeral and structural chromosomal errors <ref name= "PMID26085841"/>. Studies have also introduced Next- Generation Sequencing (NGS) <ref name= "PMID26085841"/> and Whole Genome Amplification used to screen imbalances in the complete 24-chromosomes <ref name="PMID25953353"><pubmed>25953353</pubmed></ref>.<br />
Statistics from ESHRE have shown that the most common indications for PGS is advanced age, followed by repeated implantation failure or recurrent miscarriage and male infertility <ref name="PMID26071418"><pubmed>26071418</pubmed></ref>.<br />
===Indications===<br />
A low percentage of structural abnormalities in chromosomes are responsible for the cause of miscarriages. Despite this, they are the most prevalent type of chromosomal abnormality accounted for in PGD <ref name="PMID20638568"/>. The presence of specific gene cycles, initiation of embryonic protein synthesis and evident physiological development are all indicative of a successful in vitro fertilisation procedure <ref name="PMID11576737"><pubmed>11576737</pubmed></ref>. To eliminate further errors from occurring during the PGD procedure it is recommended to undertake further prenatal testing such as amniocentesis in the later stages <ref name="PMID20638568"/>. <br />
====Advanced maternal age====<br />
Data provided by the ESHRE has shown that the mean age of women undergoing PGS is 39 years <ref name="PMID26071418"/>. Women of advanced age have been shown to have a lower rate of pregnancies reaching childbirth <ref name="PMID18583331"><pubmed>18583331</pubmed></ref>. The highlighted concern revolves around the increased occurrence of aneuploidy following maternal age. The optimal age range for the lowest aneuploidy incidence was found to be between 27 to 37 years of age (6%) then progressively higher in women aged up to 42 (33%) and most common in those 44 and above (53%) <ref name="PMID24355045"><pubmed>24355045</pubmed></ref>. <br />
====Recurrent pregnancy loss / IVF failure====<br />
Recurrent pregnancy loss is defined as three or more IVF failures after cumulative transfer of more than 10 good-quality embryos. These are primarily caused by two main factors, reduced endometrium receptivity or embryonic defects. Endometrium receptivity can be negatively influences by instances including uterine pathologies such as thin endometrium, altered expression of adhesive molecules and immunological factors. Additionally, embryonic defects may be due to genetic abnormalities, embryonic aneuploidy or zona hardening. Endometriosis and hydrosalpinx has been known to effect both the endometrium and embryo <ref name="PMID23260857"><pubmed>23260857</pubmed></ref>.<br />
====Human leukocyte antigen matching====<br />
First used in 2001, HLA matching is an option given to parents to save a child with haematological or immunological disease through conceiving another child who would potentially be able to donate cord blood or haematopoietic stem cells from the bone marrow for transplantation. The process namely PGD-HLA has shown to improve haematopoietic stem cell transplant (HSCT). PGD-HLA can only be performed when HSCT is not needed urgently due to the time needed to conceive and delivery the baby <ref name="PMID25500181"><pubmed>25500181</pubmed></ref>. It is most commonly applied to children suffering from relapsed leukaemia <ref name="PMID22524201"><pubmed>22524201</pubmed></ref>. In a case study PGD-HLA was proven to successfully cure 10 diseases including Fanconi anaemia, Diamond-Blackfan anaemia and beta thalassemia <ref name="PMID25066893><pubmed>25066893</pubmed></ref>.<br />
==Biopsy Methods==<br />
Biopsy, the removal of genetic materials, from oocytes or embryos in the preimplantation stage is the primary step in PGD. For the past two decades these biopsies have been performed at three stages, the polar body, blastomere, and blastocyst, and the methodologies optimized to ensure the embryo’s viability. The most common approach involves biopsies at the cleavage stage. However, polar body and blastocyst biopsies are increasingly more often tested and applied. Approached for opening the zona pellucida involve next to the traditional mechanical and chemical means, novel approaches such as noncontact lasers. Their application may simplify and secure the procedure significantly. The most challenging question about PGD procedures remains at what stage biopsies should be taken. Much controversy has developed around this topic, highlighting the varying disadvantages and advantages of temporal biopsies <ref name="PMID22723007"><pubmed>22723007</pubmed></ref>.<br />
<br />
[[File:Polar_Body,_Blastomere,_and_Trophectoderm_Biopsy.jpeg|400px|thumb|Polar body (A), blastomere (B) and trophectoderm (C) biopsies<ref name="PMID25625041"><pubmed>25625041</pubmed></ref>.]]<br />
{| class="wikitable"<br />
|- align="center" bgcolor="DDCEF2"<br />
|<br />
| Time of Biopsy<br />
| Advantages <br />
| Disadvantages<br />
|- bgcolor="FFFAFA"<br />
| Polar Body<br />
| Day 1<br />
| No harm to oocyte<br />
| Only maternal DNA is tested, often needs to be coupled with other biopsies, and there are difficulties distinguishing between the first and second PB.<br />
|- bgcolor="FFFAFA"<br />
| Blastomere<br />
| Day 3<br />
| …<br />
| … <br />
|- bgcolor="FFFAFA"<br />
| Trophectoderm<br />
| Day 5 and 6 <br />
| Little harm to the embryo and large amount of genetic material is extracted. <br />
| Opening of blastocyst necessary, small time window for procedure<br />
|}<br />
===Polar Body Analysis===<br />
Day 1<br />
====Description====<br />
Polar body (PB) biopsy offers a promising alternative to biopsies performed at the blastomere stage for PGD/S indications on legal and practical grounds. Consequent embryo development does not necessitate the presence of the first and second PB and their removal may not be crucial. PB biopsy requires precise timing. Keeping track of the meiotic cell cycle is necessary to perform a successful biopsy and, therefore, PB biopsy usually is applied in combination with intracytoplasmic sperm injection (ICSI). During the maturation from the germinal vesicle stage to the metaphase-II stage the first PB is formed. A cytoplasmic bridge containing spindle remnants, that are still in contact with the cellular genetic material, links this PB to the oolemma for about 90 minutes after extrusion. It is possible to visualize these remnants by polarization microscopy and it is crucial to not perform the biopsy until the first PB is no longer firmly attached to the oolemma as this indicates an immature embryo.The oocyte tolerates mechanical zona dissection best during hours four until six after ICSI as the oolemma has stabilized by that time because of the cortical granule reaction. Over time the first PB degenerates stressing a temporal biopsy and its optimal extraction time window is four to 12 hours after ICSI.>.[[File:Polar_Body_Biopsy.jpeg|thumb|The presence of a faint but clearly identifiable strand connecting PB2 to the oolemma. The biopsy was performed ∼9 h after ICSI<ref name="PMID21908464"><pubmed>21908464</pubmed></ref>.]] The second PB forms around two to four hours after ICSI. Its optimal time window for biopsy is set to be eight to 16 hours after ICSI due to the second PB being attached to the oolemma with spindle remnants until six hours after ICSI. Biopsy at this point may cause enucleation of the oocyte. Studies have shown that the amplification efficiency of second PB’s DNA is worse if the PB is extracted prior to eight hours after ICSI. Thus, it is possible to perform sequential and simultaneous biopsies for the first and second PB. If performed, sequentially the first PB may be removed four to 12 hours and the second PB eight to 16 hours after ICSI. The optimal time window for a biopsy for both the first and second PB simultaneously is eight to 12 hours after ICSI. It is highly preferred to analyze both PBs due to potential aneuploidies in either PB and crossing overs during meiosis <ref name="PMID22723007"/>. <br />
====Procedure====<br />
Chemical opening achieved with for example acidic tyrode’s solution of the zona pellucida is not tolerated by the oocyte and may have detrimental effects on the embryo’s development. Therefore, the access to the perivitelline space of the oocyte is provided by mechanical zona dissection or by laser. Both techniques work well if performed by experienced embryologist. However, laser-assisted biopsy is less time consuming when compared to manual dissection. It is critical to consider the size of the introduced opening as it will remain permanent. If it is too large the blastomere may be lost during embryo development and if it is too small it may interfere with hatching of the embryo during blastocyst stage<ref name="PMID22723007"/>.<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JTaQzszVr8o</html5media><br />
|-<br />
| Laser-assisted polar body biopsy<ref>RIUK, R. (2013, June 25) Polar Body Biopsy [Video file]. Retrieved from https://www.youtube.com/watch?v=JTaQzszVr8o</ref><br />
|}<br />
====Advantages & Disadvantages====<br />
PB biopsies can only investigate the maternal contributions to the embryo as they are of maternal origin. Thus, this procedure is appropriate for PGD solely for monogenetic diseases from the maternal side. Recessive diseases may be evaluated with PB biopsies on the basis that the embryo’s outcome will be determined by the paternal contribution. It may still be applied for PGS as it is a fairly safe biopsy option and most aneuploidies either arise during meiosis or origin from the maternal genome. However, diagnosis error has been reported due to the lack of considering paternal contributions.Because PB biopsies are performed very early it is not yet known whether the oocyte will develop into a viable embryo. Thus, PBs are commonly frozen or fixed after biopsy and depending on the state of the embryo only chosen PBs will be tested. This is primarily an economic issue as many genetic testing procedures are very cost-intensive<ref name="PMID22723007"/>.[[File:Implantation_predictive_value_of_euploid_screening_results.jpeg|thumb|The sustained implantation predictive value (with 95 % confidence interval) of a euploid screening result obtained from the first polar body (PB1), PB1 and the second polar body (PB2), or a direct embryo biopsy for each stage of embryo transfer (cleavage-stage and blastocyst stage)<ref name="PMID25106935"><pubmed>25106935</pubmed></ref>.]] Generally the sustained implantation predictive value of screening of PBs is significantly lower than of for example biopsies of the blastocyst stage<ref name="PMID25106935"/>. Moreover, it is often difficult to distinguish between the first and the second PB. As the first one degenerates quicker, this may influence diagnostic procedures<ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
===Blastomere biopsy===<br />
Day 3 <br />
====Description====<br />
Blastomere biopsy has been the prevalent method for PGD and PGS in the last two decades. At least one, but up to two, blastomeres are biopsied on day three of the cleavage stage embryo. The right number of blastomeres removed is a controversial topic as two cells allow for more genetic material and more accurate results.[[File:Aspiration_of_a_Blastomere.jpeg|thumb|Aspiration of a Blastomere into the biopsy pipette<ref name=" PMID24783200"><pubmed>24783200</pubmed></ref>.]]However, removing two cells might be too invasive and damaging to the embryo. As PGS tries to improve implantation rates, whereas PGD sets out to avoid known genetic disorders, for the former only one cell is removed, while for the latter often two need to be removed, to ensure results as correct as possible<ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
====Procedure====<br />
Initially a hole was drilled into the zona pellucida using acid tyrodes with the consequent aspiration of blastomeres with a pipette. Nowadays the zona pellucida is largely opened using a laser and calcium and magnesium free media have been introduced to decrease junctions between blastomeres, which facilitates the biopsy<ref name="PMID21748341"/>. <br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=TbridWVwipI</html5media><br />
|-<br />
| Laser-assisted blastomere biopsy<ref>Sukprasert, M. (2014, March 5) Day 3 Blastomere Biopsy 1 [Video file]. Retrieved from https://www.youtube.com/watch?v=TbridWVwipI</ref><br />
|}<br />
====Advantages & Disadvantages====<br />
===Trophectoderm biopsy===<br />
Day 5 and 6<br />
====Description====<br />
The improvement of embryo culture media allowed the in vitro development of human embryos until the blastocyst stage and opened up the possibility to take blastocyst biopsies. During day three to day five the haploid maternal and paternal genomes work together for the first time to form the genome of the embryo. The maternal epigenetic control lessens significantly while preparing for implantation with precisely arranged events happening. [[File:Microscopic images of human blastocysts for biopsy.jpeg|thumb|(A) Some trophectoderm cells in a blastocyst started to hatch and (B) the trophectoderm cells were biopsied with assisted laser cutting. Images in C–D show the blastocysts after vitrification and warming. Blastocysts had been cultured for 2–4 hrs after warming, showing good (ICM and trophectoderm cells) hatched (C) and hatching (D) blastocysts. The hatching blastocyst in (E) has good ICM but fair trophectoderm while the blastocyst in (F) has both fair ICM and trophectoderm. Arrows indicate ICMs and arrow heads indicate trophectoderm cells. Bar = 40 µm<ref name="PMID2190846"><pubmed>2190846</pubmed></ref>.]] The first event includes a rapid increase in the number of embryonic cells which are active in mitotic divisions and apoptosis of aberrant cells. This is followed by the formation of blastocoel (cavitation) which results from the flattening of cell located on the outside of the blastomere. Now the blastocyst will expand until the embryo hatches by rupturing the zona pellucida. The cells of the blastocyst will differentiate to form two distinct cell lineages, the outer trophectoderm and the inner cell mass<ref name="PMID22723007"/>. <br />
====Procedure====<br />
Trophectoderm biopsy is usually performed in Hepes buffered biopsy medium and opening approaches include needle cutting which has been replaced by lasers in past years. Different research groups report different timings of the opening to be the most successful. Some open the blastocyst on day three or four by creating a 25 µm which causes the trophectoderm to herniate through this hole and is, thus, accessible for biopsy. Others create this hole about four hours before biopsy which allows sufficient herniation of trophectoderm cells. It is also possible to open the blastocyst immediately before biopsy. This avoids an extra step and the inner cell mass usually is easy to locate. Blastocyst biopsies involve the removal of trophectoderm cells and the ideal time for the procedure is day five. Successful biopsies on day six have been performed, while little is known about the results of biopsies on day seven. However, since the window of implantation in humans is from day eight to ten after ovulation, day seven biopsies appear to be possible<ref name="PMID22723007"/>.<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JI_TQ8d8tNM</html5media><br />
|-<br />
| Laser-assisted blastocyst biopsy (at 00:50 min)<ref>Coco, R. (2014, April 30) Trophectoderm biopsy in a Hatching blastocyst protruding ICM [Video file]. Retrieved from https://www.youtube.com/watch?v=JI_TQ8d8tNM</ref><br />
|}<br />
====Advantages & Disadvantages====<br />
Blastocyst biopsies are believed to be less damaging to the embryo and appear to be unrelated to implantation rates. In addition, this biopsy method allows for a larger extraction of cells for genetic testing. However, since they are performed late in in vitro development, the time window for genetic testing is relatively small. Fast and accurate genetic testing methods are needed to ensure a successful and safe result from this biopsy. Thus, blastocyst biopsies may gain more popularity in the future when such methods have been developed or improved<ref name="PMID22723007"/>. <br />
==Genetic Techniques==<br />
===Polymerase Chain Reaction===<br />
PCR amplifies DNA specific to genetic sequence of interest . PCR was developed by Kay Mullis in the 1980's, for which he was awarded the Nobel prize for chemistry in 1993. <ref> Pubmed Docs (2015) Polymerase Chain Reaction (PCR) Pubmed. Retrieved from [http://www.ncbi.nlm.nih.gov/probe/docs/techpcr/]</ref> This technique enables clinicians to monitor and diagnose diseases using minute samples such as embryonic cells. <ref>Roche (2015) PCR: How We Copy DNA. Roche Molecular Systems Inc. retrieved From [http://molecular.roche.com/pcr/Pages/Process.aspx]</ref>. PCR is used to detect genetic disorders, as a part of PGD, in conjunction with IVF<ref name="PMID24301057"><pubmed>24301057</pubmed></ref>. It is used to detect molecular abnormalities, such as single gene disorders including Tay Sach, Cycstic fibrosis, Duchenne Muscular Dystrophy, Thalassemia, Huntington disease, Spinal muscular atrophy and many more. Molecular and genetic analysis require a significant amount of DNA, which can be delivered by PCR. It revolutionized the study of DNA, replacing all previous recombinant DNA technology and is a significant component of PGD procedures<ref name="PMID24907939"/>.<br />
<br />
[[File:PCR.jpg|thumb|PCR amplifies DNA specific to genetic sequence of interest, enabling the monitoring and diagnose molecular abnormalities such as single gene disorders using minute samples such as embryonic cells, blood & tissue <ref name="NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute">NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref>]]<br />
<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="7" |'''Advantages'''<br />
|-bgcolor="FFFAFA"<br />
| Fast and inexpensive way of copying a target sequence of DNA.<br />
|-bgcolor="FFFAFA"<br />
| Particularly useful for the diagnosis of single cell defects.<br />
|-bgcolor="FFFAFA"<br />
| Rapid generation of results (within hours).<br />
|-bgcolor="FFFAFA"<br />
| Highly sensitive, a single molecule of DNA is sufficient for reaction.<br />
|-bgcolor="FFFAFA"<br />
| Generates DNA copies exponentially.<br />
|-bgcolor="FFFAFA"<br />
| This enables DNA amplification required for molecular and genetic diagnostic analysis<ref> Dreesen, J., Drusedaul, M., Smeets, H., Die-Smulders, C., Coonen, E., Dumoulin, J., Gielen, M., Evers, J., Herbergers, J. & Geradets, J. (2008) Validation of preimplantation genetic diagnosis by PCR analysis: genotype comparison of the blastomere and corresponding embryo, implications for clinical practice. Mol. Hum. Reprod. 14 (10):573-579.doi: 10.1093/molehr/gan052. Retrieved from [http://molehr.oxfordjournals.org/content/14/10/573.short] </ref> <ref><pubmed>20966460</pubmed></ref>.<br />
|-bgcolor="DDCEF2"<br />
| rowspan="7"|'''Disadvantages'''<br />
|-bgcolor="FFFAFA"<br />
| Only during the exponential DNA replication phase, the starting quantity sequence contained in the original sample (template DNA strand) can be determined.<br />
|-bgcolor="FFFAFA"<br />
| PCR reaction is limited to by presence of inhibitors in the sample.<br />
|-bgcolor="FFFAFA"<br />
| Self annealing due to the accumulation of the product and the stopping exponential amplification for the target sequence and reaching of a plateau<br />
quantification of the end point of reaction of PCR products make real time quantitative RT-PCR necessary<ref name="NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute">NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref>.<br />
|-bgcolor="FFFAFA"<br />
| Not a diagnostic method on its own, but requires further analysis.<br />
|-bgcolor="FFFAFA"<br />
|Low-quantity DNA template may result in amplification failure<ref name="PMID24907939"/>.<br />
|-bgcolor="FFFAFA"<br />
|Allele drop-out (ADO) in heterozygous loci is possible<ref name="PMID24907939"/>.<br />
|}<br />
====Procedure====<br />
Samples are obtained from the the blastocyst, a polar body biopsy or the blastomeres stages of the embryo. <br />
*Stage 1 Denaturing: separating the target strands of DNA <br />
The obtained sample is heated to roughly 90 degrees celcius, this heat breaks the relatively weak bonds between nucleotides that form DNA. The double stranded DNA is split into two single strands of DNA that are used as templates.<br />
*Stage 2 Annealing: Binding the Primers to the target DNA sequence <ref name="PMID25250056"><pubmed>25250056</pubmed></ref><br />
PCR will only copy the target sequence of DNA specified by specific PCR primer. These synthesized primers oligonucleotides are small artificial pieces of DNA. TAQ polymerase enzyme synthesize two new strands of DNA duplicate to the single sample DNA stand template indicated by these primers. During this stage the reaction is cooled to a temperature between 40-60 degrees Celsius. <br />
*Stage 3- Extension- making copies <br />
Each of these two copies are then used again as templates generating two further replications This cycle can occur as many 30 -40 times within a couple hours leading to billions of extra copies of the original DNA segment. Generally the optimal temperature for the further replication is roughly 72 degrees Celsius, although, this may vary according to the analysis machines used. <ref name="PMID26092180"><pubmed>26092180</pubmed></ref><br />
This process mediated by a thermocycler machine that is programmed to alter the temperature of the reaction every couple of minutes, perpetuating the cycle of DNA denaturing and synthesis. <br />
This process, generates exponentially exact copies of the original template DNA sequence. <ref> Mullins, K., Francois, F.& Gibbs R.A. (1994 ) The Polymerase Chain Reaction. p3. Springer- Science +Business Media. Birkhauser, Boston<br />
Available at [https://books.google.com.au/books?hl=en&lr=&id=gjrTBwAAQBAJ&oi=fnd&pg=PR5&dq=kary+mullis+PCR&ots=mpzAyRh5ZY&sig=PQ4goNoKJ90tb3-MkPk62zrTGbw#v=onepage&q=kary%20mullis%20PCR&f=false] </ref><br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
!PCR cycles<br />
|-<br />
| '''PCR Cycle'''<br />
| '''Target Copies'''<br />
|-<br />
| 1<br />
| 2<br />
|-<br />
| 2<br />
| 4<br />
|-<br />
| 3<br />
| 8<br />
|-<br />
| 4<br />
| 16<br />
|-"<br />
| 5 <br />
| 32<br />
|-<br />
| 6 <br />
| 64<br />
|-<br />
| 7 <br />
| 128<br />
|-<br />
| 8<br />
| 256<br />
|- <br />
| 9<br />
| 512 <br />
|-<br />
| 10<br />
| 1024<br />
|-<br />
| 15<br />
| 32,768<br />
|-<br />
| 20 <br />
| 1,048,578<br />
|-<br />
| 25<br />
| 33,554,432<br />
|-<br />
| 30 <br />
| 1,073,741,842<br />
|-<br />
|}<br />
===Fluorescent In Situ Hybridisation===<br />
FISH is the one of the most effective and rapid <ref name="PMID26338801"><pubmed>26338801</pubmed></ref> method as part of PGD. This technique locates a specific DNA sequences within a chromosome. FISH facilitates the clinical diagnosis of chromosomal abnormalities indicated by sequential duplications, deletions and rearrangements of chromosome, that are usually missed with microscopic analysis. This technique is especially relevant for female embryos with X-linked diseases<ref name="PMID20809319"><pubmed>20809319</pubmed></ref>.[http://www.ncbi.nlm.nih.gov/pubmed/20809319] As part of PGD, it enabled the screening for aneuploidies and increased live birth rates in women with advanced age<ref name="PMID24907939"/> <ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. FISH is 99% effective when used in conjunction with competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities<ref name="PMID26338801"/>. [[File:Fluorescent In Situ Hybridisation (FISH).jpg|thumb|right|'''FISH''' Specific DNA sequences using probes which have been tagged with fluorescent labels are visualised.This technique enables the clinical diagnosis of chromosomal abnormalities, indicated by sequential duplication, deletions and rearrangements of chromosome <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref>]]<br />
<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="5" |'''Advantages''' <br />
|-bgcolor="FFFAFA" <br />
| FISH is 99% effective when used in conjunction with CGH to diagnose chromosomal abnormalities<ref><pubmed>26338801</pubmed></ref>.<br />
|-bgcolor="FFFAFA" <br />
| Results are rapidly generated. <br />
|-bgcolor="FFFAFA"<br />
| Very small translocations and aneuploidies that occur within chromosomes, that would usually be missed under microscopic analysis, can be identified<ref name="Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd)">Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref>.<br />
|-bgcolor="FFFAFA" <br />
| The most common chromosomal abnormalities, such as down syndrome chromosomes 13,16,18,21 and 22<ref><pubmed>21749752</pubmed></ref>, and inheritable X-linked disease or sex chromosome anomalies such as Duchenne's Muscular Dystrophy, hemophilia, ectodermal dysplasia<ref><pubmed>17876073</pubmed></ref> can be identified.<br />
|-bgcolor="DDCEF2"<br />
| rowspan="5"|'''Disadvantages'''<br />
|-bgcolor="FFFAFA" <br />
| FISH destroys all cells tested <ref> O'Connor, C. (2008) Fluorescence in situ hybridization (FISH). Nature Education 1(1):171. retrieved from [http://www.nature.com/scitable/topicpage/fluorescence-in-situ-hybridization-fish-327] </ref>.<br />
|-bgcolor="FFFAFA" <br />
| It does not fully access all chromosomes (only ~ 12)<ref name="PMID24907939"/>.<br />
|-bgcolor="FFFAFA" <br />
| The analysis of results is dependent upon the dot quality impacted by hybridisation efficiency or the camera sensitivity<ref name="PMID17970921"><pubmed>17970921</pubmed></ref>.<br />
|-bgcolor="FFFAFA" <br />
| Some studies indicate that using FISH on a day-3 embryo biopsy decreases the rate of live births<ref><pubmed>26168107</pubmed></ref>.<br />
|}<br />
====Procedure====<br />
Samples collected from the embryo<ref name="PMID21748341"><pubmed>21748341</pubmed></ref> are collected, processed, and its DNA strands are heated and denatured causing their the individual DNA strands to break apart. Then, probes of single complimentary stands of DNA a that have been tagged with small chemical agents that glow brightly in the presence of a specific region on a chromosome are added. These specific probes then hybridize and join to their complementary DNA strand. The fluorescent tags enable the correct identification of the presence or lack thereof and location of specific chromosomes that are tested for<ref name="PMID17876073"><pubmed>17876073</pubmed></ref>. The number and the relative location of the fluorescent dots generated by the FISH images is analysed and gives rise to diagnosis<ref name="PMID17970921"><pubmed>17970921</pubmed></ref>. The probe will not fully hybridise if there has been a duplication or a deletion of the DNA - indicating chromosomal and sex chromosomal anomalies like trisomies and aneuploidies. <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref>. Different probes are used for different purposes: <ref>Unique, Rare Chromosome Disorder Support Group (2013) Fluorescence in situ hybridisation (FISH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/Other/FISH%20FTNW.pdf]</ref><br />
*'''Locus specific tags''' detect very small imbalances, and locate isolated small portions <br />
of genes within a chromosome<br />
*'''Alphoid/Centomeric Repeat probes''' are developed from the repetitive sequence located in the middle region of each chromosome, useful in determining the number of chromosomes , detecting rearrangement and when used in conjunction with locus probes to determine the absence of genetic material on a chromosome. <br />
*'''Paint Probes''' are collections of smaller probes with their own stains that bind to a different section on the chromosome - allowing the full chromosome too be labeled a unique colour, this "full colour map" can be used to know the spectral karyotype- full chromosomal mapping is useful in examining chromosomal abnormalities. <br />
===Array Comparative Genomic Hybridisation (aCGH)===<br />
aCGH also known as Microarray analysis efficiently scans the entire genome for chromosomal imbalances. CGH was initially developed to detect the number of changes in a solid tumor mass. It uses 2 genomes comparing the sample to the control, with each labeled in a different fluorescent dye<ref name="PMID1876176"><pubmed>1876176</pubmed></ref>. Earlier CGH techniques were limited by the resolution of the imaging <ref> Lichter, P., et al. Comparative genomic hybridization: Uses and limitations. Seminars in Hematology 37, 348–357 (2000)</ref> , these initial limitations were overcome by using Microarrays in conjunction with CGh to improve the resolution of the imaging, Array Comparative Genomic Hybridisation (aCGH). This method compares sample and control microarrayed slides containing small segments of DNA (probes). <ref> Lucito, R., et al. Representational oligonucleotide microarray analysis: A high-resolution method to detect genome copy number variation. Genome Research 13, 2291–2305 (2003) </ref> the Probes used will vary according from the small (25-85 base pairs) oligonucleotides manufactured to highlight different target sequences, to the very large genomic clones (80,000- 200,00 base pairs), and as these are significantly smaller than the traditional metaphase chromosomes used for CGH, generating a higher resolution of image. <ref name="PMID22467166"><pubmed>22467166</pubmed></ref>.aCGH is used as a diagnostic tool for prenatal detection f chromosomal abnormalities <ref name="PMID19012303"><pubmed>19012303</pubmed></ref>.<br />
{|class="wikitable" align="center"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="12" |'''Advantages''' <br />
|-bgcolor="FFFAFA"<br />
| Multiple applications: prenatal genetic diagnosis, cancer diagnosis, <ref name="PMID20193845"><pubmed>20193845</pubmed></ref> genetic screening for developmental delay (learning disabilities) <ref name="PMID17309648"><pubmed>17309648</pubmed></ref>. or congenital anomalies that are suspected to be genetic in origin <ref>NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation . retrieved from [http://www.phgfoundation.org/file/5237/]</ref><br />
|-bgcolor="FFFAFA"<br />
| trace represents all chromosomes present in the human genome chromosomes 1-22 and the X & Y chromosomes, and therefore is the most accurate method for testing whole embryo aneuploidy<br />
|-bgcolor="FFFAFA"<br />
| aCGH has been extensively tested, and Validated, and is now used world wide.<br />
|-bgcolor="FFFAFA"<br />
| Detects submicroscopic alterations<br />
|-bgcolor="FFFAFA"<br />
| Detects deletions and additions and rearrangements as well as amplification, of the WHOLE genome, simultaneously.<br />
|-bgcolor="FFFAFA"<br />
| Used as a diagnostic tool for prenatal detection of chromosomal abnormalities <ref name="PMID22034057"><pubmed>22034057</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Provides high resolution genomewide screening of segmental genomic copy number variations<br />
|-bgcolor="FFFAFA"<br />
| Very accurate when used in conjunction with FISH<br />
|-bgcolor="FFFAFA"<br />
| Alone is more reliable and in detecting chromosomal abnormalities, with a higher implantation success rate, than FISH <ref name="PMID20494259"><pubmed>20494259</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Allows an in depth research focus upon specific types of rearrangements within selected chromosomal regions, a recent particular area of interest is subtelomeric and pericentromeric rearrangements<br />
|-bgcolor="FFFAFA"<br />
| Reduces the risk of failed implantation and miscarriage, improving the chance of a healthy baby <ref name="Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd)">Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref>><br />
|-bgcolor="DDCEF2"<br />
| rowspan="9" |'''Disadvantages'''<br />
|-bgcolor="FFFAFA"<br />
| Translocations and inversions of DNA are not detected<br />
|-bgcolor="FFFAFA"<br />
| Limited ability diagnosing specific polyploidies such as triploidy <ref> Unique, Rare Chromosome Disorder Support Group (2013) Microarray-based Comparative Genomic Hybridiation (array CGH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/other/array%20cgh%20ftnw.pdf] </ref><br />
|-bgcolor="FFFAFA"<br />
| Will not detect mosaicism detection <20% (cultures where >1 of 5 cells are trisomy 12)<br />
|-bgcolor="FFFAFA"<br />
| Will not detect balanced chromosomal rearrangement<br />
|-bgcolor="FFFAFA"<br />
| Will not detect duplications or deletions <80kb<br />
|-bgcolor="FFFAFA"<br />
| Will not detect point mutations within genes <ref>Washington department of education (CGH- FAQ for physicians. Signature Genomic LAboratories, LLC. Retrieved from [https://depts.washington.edu/dbpeds/Lab%20Tests/SignatureCGH-physician_FAQ.pdf]</ref><br />
|-bgcolor="FFFAFA"<br />
| will not detect chromosomal position of genomic gains<br />
|-bgcolor="FFFAFA"<br />
| Will not detect loos of heterozygosity (LOH) or Absence of heterozygosity (AOH) <ref>WiCell Research Institute Inc. (2012) Comparative Genomic Hybridization Microarray. <br />
retrieved from [http://www.wicell.org/home/cytogenetic-services/cgh-microarray/array-comparative-genomic-hybridization-acgh.cmsx]</ref><br />
|}<br />
====Procedure====<br />
<br />
The sample is obtained (skin, blood or fetal cells) and DNA is obtained. <br />
As a part of PGD fetal cell samples are collected from; the fertilized egg polar bodies, the blastomere (day 3 embryo) or the blastocyst/tropoectoderm stage (day 5 embryo).<br />
Sample DNA is labeled with one fluorescent dye, and the control DNA is labeled with a different colored fluorescent dye. the control DNA is used as the base point of reference. <br />
heated and denatured single DNA strands then hybridize to their complementary single strand probes, which are then combined and applied to a microarray and the results are run through a computer program and a digital imaging system is used to quantify the results( fluorescent intensities of the labeled probes)<ref name="Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45"> Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432] </ref>. <br />
<br />
[[File:aCGH.jpg|thumb|right|'''aCGH''' checks the entire genome for chromosomal imbalances, by comparing control and a sample slides contatining small segements of DNA sample microarrayed slides small segments of DNA. Illustrated by student z5020317 and adapted from <ref> NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation. retrieved from [http://www.phgfoundation.org/file/5237/]</ref> <ref name="Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45"> Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432] </ref>]]<br />
<br />
The fluorescent ratio and the hybridization signal at different locations on the genome of the control DNA are used to identify any variances present in the sample DNA. aCGH facilitates the clinical diagnosis of submicroscopic chromosomal duplication, deletion and rearrangements indicative of chromosomal disorders such as trisomies 1-22and specific sex linked disorders. <br />
Duplications in the DNA are displayed by the computer program as spikes/ peaks over an established threshold and deletions in DNA are displayed by the computer program as spikes/ toughs beneath this threshold <br />
<br />
<br />
===Next Generation Sequencing===<br />
The development and advances within ART in the past 20 years, as well as the increasing popularity of IV, has lead to an influx of new technologies developed to screen embryos for chromosomal anomalies, which are covered by the umbrella term of Next generation Sequencing (NGS). NGS is a general term used to describe all of the new and emerging screening techniques currently being introduced and used as part of PGD for IVF . NGS screens for single gene disorders as well as conducting extensive and very comprehensive chromosome diagnosis by sequencing, counting, and accurately assembling millions of DNA reads, simultaneously. <ref name="PMID23499002"><pubmed>23499002</pubmed></ref> There is a movement for NGS to replace the other limited testing techniques and be used as the standard. <br />
<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="14" |'''Advantages''' <br />
|-bgcolor="FFFAFA" <br />
| Cost effective<br />
|-bgcolor="FFFAFA"<br />
| Opens new diagnostic possibilities<br />
|-bgcolor="FFFAFA"<br />
| Accurately tests all 24 chromosomes<br />
|-bgcolor="FFFAFA"<br />
| Tests for the presence of monogenic diseases of known genetic background<br />
|-bgcolor="FFFAFA"<br />
| Reduces the number of biopsies required for diagnosis<br />
|-bgcolor="FFFAFA"<br />
| Higher detection rate of small translocations<br />
|-bgcolor="FFFAFA"<br />
| Highly accurate is testing for compound point mutations, chromosomal duplication, deletions and insertions <ref name="PMID23312231"><pubmed>23312231</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| It accurately detects chromosomal aneuploidy and unbalanced rearrangement <ref name="PMID25685330"><pubmed>25685330</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Higher detection rate of small translocations<br />
|-bgcolor="FFFAFA"<br />
| NGS single gene disorder screenings can conducted in conjunction with PCR comprehensive chromosomal screening<br />
|-bgcolor="FFFAFA"<br />
| Reduces human error <br />
|-bgcolor="FFFAFA"<br />
| Better detects the presence of mosaicism<br />
|-bgcolor="FFFAFA"<br />
| Work well in conjunction with CGH and aCGH as part of PGD, improving the chances of IVF. <ref> Morris, R. S. (2015 ) Next generation sequencing for PCG|PGS|CCS. IVF1 retrieved from [http://www.ivf1.com/next-generation-sequencing for-pgd] </ref><br />
|-bgcolor="DDCEF2"<br />
| '''Disadvantages''' <br />
|-bgcolor="FFFAFA"<br />
| There are limited information available to clinical applications of NGS <ref><pubmed>26100406</pubmed></ref><br />
|}<br />
<br />
====Procedure====<br />
Samples are collected from either blastomere or the blastocyst/tropoectoderm and processed for analysis by a computer system. <br />
The methodology of each process is unique to the technique being used. <br />
<br />
==Diagnosis==<br />
There are a large amount of diseases that PGD can apply to, below are descriptions of the diseases that PGD are more commonly used for. Upon completion of the genetic testing for the genes of concern the cells the embryos are discarded and priority is given to those that are healthy. <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/><br />
===Cystic Fibrosis===<br />
Cystic fibrosis is a single gene disorder. It is autosomal recessive and involves mutations in the cystic fibrosis transmembrane conductance regulator (CTFR) gene. The CTFR gene is normally responsible for the decrease in chloride and the transport of bicarbonate in epithelial cells thus playing a major physiological role. In PGD procedures, identification of the gene is assisted by microsatellite markers that have similar composition to the CTFR gene itself. Biopsy of two cells at the blastocyst stage is recommended if markers are not available. There are many variations of cystic fibrosis the most common being P.Phe508del <ref name="PMID26014425"><pubmed>26014425</pubmed></ref>.<br />
===Duchenne Muscular Dystrophy ===<br />
Duchenne Muscular Dystrophy is an X-linked recessive disease. It involves the Xp21 gene where majority of the mutations are chromosomal deletions with a smaller percentage resulting from duplications <ref name="PMID18359022"><pubmed>18359022</pubmed></ref>.<br />
<br />
===Autosomal Recessive Meckel-Gruber Syndrome===<br />
Autosomal recessive genetic defect caused by the TMEM67 gene. It results in cystic dysplasia of the kidneys with fibrotic change in the liber and occipital encephalocele. Other malformations could also be present in the central nervous system. In PGD whole genome amplification of single blastomeres are taken to identify the gene, this is also coupled with PCR techniques. Maternal plasma can also be extracted for PGS. <ref><pubmed>24039893</pubmed></ref> <br />
===β – Thalassemia=== <br />
β – Thalassemia is known as the most common type of autosomal recessive inherited disorder among haemoglobinopathies. It involves the adult β-globin gene and is associated with the absent or decreased expression of the gene. This is commonly caused by a single nucleotide change in the gene. PGD has been used successfully worldwide to identify the β-globin gene where its application is usually performed on a single blastomere or polar body <ref name="PMID19064120">19064120</pubmed></ref>.<br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
! Applicable diseases for PGD <ref>Genoma Group (2014). Retrieved September 18th, 2015, from http://www.preimplantationgeneticdiagnosis.it/genetic-diseases-diagnosed-by-pgd.htm </ref> <ref>Genesis Genetics (2015). Retrieved September 18th, 2015, from http://genesisgenetics.org/pgd/what-we-test-for/</ref> <ref>Human Fertilisation & Embryology Authority (2015). Retrieved Septembr 18th, 2015, from http://guide.hfea.gov.uk/pgd/</ref><br />
|-<br />
| '''Disease'''<br />
| '''Involved Genes'''<br />
|-<br />
| 5 Alpha Reductase Deficiency (5ARD)<br />
| SRD5A2 <br />
|-<br />
| Achondroplasia<br />
|FGFR3 <br />
|-<br />
| Acute Intermittent Porphyria <br />
| ALAD, ALAS2, CPOX, FECH, HMBS, PPOX, UROD, or UROS<br />
|-<br />
| Adrenoleukodystrophy (Adrenomyeloneuropathy)<br />
| ABCD1 <br />
|-<br />
| Agammaglobulinaemia (x-linked) <br />
|BTK <br />
|-<br />
| Agammaglobulinemia Bruton Tyrosine Kinase (BTK) <br />
|BTK <br />
|-<br />
| Aicardi Goutieres Syndrome 1 (AGS1) <br />
|TREX1, RNASEH2A, RNASEH2B, RNASEH2C, SAMHD1<br />
|-<br />
| Alagille Syndrome<br />
|JAG1 or NOTCH2<br />
|- <br />
| Alpers-Huttenlocher Syndrome <br />
|POLG <br />
|-<br />
| Alpha-1-antitrypsin deficiency <br />
|SERPINA1 <br />
|-<br />
| Alpha-Mannosidosis<br />
| MAN2B1 <br />
|-<br />
| Alpha Thalassemia <br />
|HBA1 or HBA2 <br />
|-<br />
| Alports Syndrome<br />
|COL4A3, COL4A4, COL4A5<br />
|-<br />
| Alzheimer's Disease - early onset (Type 3 and 4) <br />
|APP, PSEN1, or PSEN2<br />
|-<br />
| Amyotrophic Lateral Sclerosis 1 (ALS1) <br />
|C9orf72, SOD1, TARDBP, FUS, ANG, ALS2, SETX, VAPB <br />
|-<br />
| Argininosuccinic Aciduria <br />
| ASL<br />
|-<br />
| Arrhythmogenic Right Ventricular Cardiomyopathy/ Dysplasia (ARVC/D)<br />
| DSG2; DSP; PKP2<br />
|-<br />
| Ataxia Telangiectasia<br />
| ATM<br />
|-<br />
| Autosomal Recessive Meckel-Gruber Syndrome<br />
| TMEM67<br />
|-<br />
| Bardet-Biedl Syndrome (BBS)<br />
| BBS1; BBS10<br />
|-<br />
| Barth Syndrome<br />
| TAZ<br />
|-<br />
| Beta Thalassaemia<br />
| HBB<br />
|-<br />
| Birt-Hogg-Dubé Syndrome<br />
| FLCN<br />
|-<br />
| Breast Ovarian Cancer Familial Susceptibility (BRCA2)<br />
| BRCA1; BRCA2<br />
|-<br />
| Canavan Disease <br />
| ASPA<br />
|-<br />
| Carnitine-Acylcarnitine Translocase Deficiency <br />
| SLC25A20<br />
|-<br />
| Cerebral Arteriopathy with Subcortical Infarcts & Leukoencephalopathy (CADASIL)<br />
| NOTCH3<br />
|-<br />
| Cerebral Cavernous Malformation<br />
| CCM1<br />
|-<br />
| Charcot-Marie-Tooth Disease<br />
| GJB1; MPZ; NEFL; PMP22<br />
|-<br />
| CHARGE Syndrome<br />
| CHD7<br />
|-<br />
| Cherubism<br />
| SH3BP2<br />
|-<br />
| Choroideremia<br />
| CHM<br />
|-<br />
| Chronic Granulomatous Disease<br />
| CYBB; NCF1<br />
|-<br />
| Ciliary Dyskinesia<br />
| DNAH5<br />
|-<br />
| Citrullinemia<br />
| ASS1<br />
|-<br />
| Cleidocranial Dysplasia<br />
| RUNX2<br />
|-<br />
| Cockayne Syndrome<br />
| ERCC6<br />
|-<br />
| Congenital Adrenal Hyperplasia<br />
| CYP21A2<br />
|-<br />
| Congenital Cataracts<br />
| GJA8; VSX2<br />
|-<br />
| Congenital Diarrhea, Syndromic<br />
| SPINT2<br />
|-<br />
| Congenital Disorders of Glycosylation (CDG)<br />
| ALG1; ALG6; CDG1C; DOLK; PMM2<br />
|-<br />
| Cornelia de Lange Syndrome <br />
| NIPBL<br />
|-<br />
| Craniosynostosis<br />
| TWIST1<br />
|-<br />
| Crouzon Syndrome<br />
| FGFR2<br />
|-<br />
| Cysteinyl Leukotriene Receptor 1 Deficiency <br />
| CYSLTR1<br />
|-<br />
| Cystic Fibrosis<br />
| CFTR<br />
|-<br />
| Diamond –Blackfan Anemia <br />
| RPS19<br />
|-<br />
| Duchenne Muscular Dystrophy <br />
| DMD<br />
|-<br />
| Dyskeratosis congenita (Male embryos only)<br />
| DKC1<br />
|-<br />
| Ectodermal dysplasia (Hypohidrotic)<br />
| EDA; EDA1; GJB6; IKBKG<br />
|-<br />
| Familial Adenomatous polyposis coli (FAP)<br />
| APC<br />
|-<br />
| Familial Dysautonomia<br />
| IKBKAP<br />
|-<br />
| Fanconi Anemia <br />
| FANCA; FANCC; FANCD2; FANCF; FANCG; FANCJ<br />
|-<br />
| Fragile X Syndrome (FRAX)<br />
| FMR1<br />
|-<br />
| Galactosemia <br />
| GALT<br />
|-<br />
| Gangliosidosis<br />
| GLB1<br />
|-<br />
| Glanzmann Thrombasthenia <br />
| ITGA2B<br />
|-<br />
| Glutaric Acidemia (aciduria)<br />
| GCDH <br />
|-<br />
| Glycogen Storage Disease <br />
| G6PC; GAA; SLC37A4<br />
|-<br />
| Haemophilia A<br />
| F8<br />
|-<br />
| Haemophilia B<br />
| F9<br />
|-<br />
| Hereditary Nonpolyposis Colorectal Cancer: Lynch Syndrome<br />
| MLH1; MSH2; MSH6<br />
|-<br />
| Holt Oram Syndrome<br />
| TBX5<br />
|-<br />
| Huntington Disease<br />
| HD<br />
|-<br />
| Hydrocephalus<br />
| L1CAM<br />
|-<br />
| Ichthyosis <br />
| ABCA12; STS<br />
|-<br />
| Incontinentia Pigmenti (IP)<br />
| NEMO<br />
|-<br />
| Joubert Syndrome 5<br />
| INPP5E<br />
|-<br />
| Krabbe Disease<br />
| GALC<br />
|-<br />
| Leber Congenital Amaurosis (LCA)<br />
| CEP290; GUCY2D<br />
|-<br />
| Leigh Syndrome (Infantile Subacute Necrotising Encephalopathy)<br />
| LRPPRC<br />
|-<br />
| Lesch Nyan Syndrome<br />
| HPRT1<br />
|-<br />
| Leukocyte Adhesion Deficiency (Type I)<br />
| ITGB2<br />
|-<br />
| Li-Fraumeni Syndrome<br />
| TP53<br />
|-<br />
| Macular Dystrophy Retinal <br />
| VMD2<br />
|-<br />
| Maple Syrup Urine Disorder (MSUD)<br />
| BCKDHB<br />
|-<br />
| Marfan Syndrome <br />
| FBN1<br />
|-<br />
| Menkes Syndrome<br />
| ATP7A<br />
|-<br />
| Mitochondrial DNA Depletion Syndrom <br />
| POLG; RRM2B; SUCLA2; TK2<br />
|-<br />
| Mucolipidosis type II<br />
| GNPTAB<br />
|-<br />
| Multiple Endocrine Neoplasia<br />
| MEN1; MEN2A; MEN2B<br />
|-<br />
| Multiple Exostoses<br />
| EXT1; EXT2 <br />
|-<br />
| Myotubular myopathy<br />
| MTM1 <br />
|-<br />
| Nail-Patella Syndrome<br />
| LMX1B<br />
|-<br />
| Neurofibromatosis Type 1<br />
| NF1<br />
|-<br />
| Neurofibromatosis Type 2 <br />
| NF2<br />
|-<br />
| Noonan Syndrome<br />
| KRAS, PTPN11; SOS1<br />
|-<br />
| Norrie Disease<br />
| NDP<br />
|-<br />
| Ocular Albinism <br />
| GPR143<br />
|-<br />
| Oculocutaneous Albinism <br />
| OCA2; TYR <br />
|-<br />
| Oculodentaldigital Dysplasia<br />
| GJA1<br />
|-<br />
| Optic Atrophy<br />
| OPA1<br />
|-<br />
| Ornithine Transcarbamylase Deficiency <br />
| OTC<br />
|-<br />
| Osteogenesis imperfeca <br />
| COL1A1; COL1A2<br />
|-<br />
| Osteopetrosis <br />
| CLCN7; OSTM1; TCIRG1<br />
|-<br />
| Pachyonychia Congenita <br />
| KRT16; KRT6A<br />
|-<br />
| Pancreatitis, Hereditary<br />
| PRSS1 <br />
|-<br />
| Papillorenal syndrome <br />
| PAX2<br />
|-<br />
| Phenylketonuria <br />
| PAH <br />
|-<br />
| This table does not cover the complete list of diseases that PGD can be applied to.<br />
|}<br />
<br />
==Laws & Legal status==<br />
<br />
{| class="wikitable" <br />
|-bgcolor="DDCEF2"<br />
|'''Country'''<br />
|'''Legislation'''<br />
|-bgcolor="FFFAFA" <br />
| Australia<br />
| PGD is currently used to detect serious genetic conditions to improve the outcome of Assisted Reproductive Technologies (ART). In very rare cases it may be used to select an embryo with compatible tissue for a sibling who has a life-threatening disease where other means of treatment is unavailable. This is with the conditions that the use of PGD will not affect the welfare and interests of the child to be born. The parents must also receive adequate counselling and have full understanding of the procedures of PGD. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"> National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art</ref><br />
The use of PGD for sex-selection is prohibited with the exception of reducing the risk of the transmission of serious sex-linked genetic conditions. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"/><br />
|-bgcolor="FFFAFA"<br />
| Brazil<br />
| The laws regarding PGD in Brazil are not strictly regulated. They are vague and there is limited information surround the activities of assisted reproduction in general in the country <ref name="PMID25493379"><pubmed>25493379</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| Czech Republic<br />
| The laws in the Czech Republic allow those with a “defined indication in order to exclude risk of serous genetically conditioned disease and defects with embryos before they are implanted into the cavity of the uterus”. Couples that undergo any assisted reproductive treatment including PGD have to be married. Sex-selection is illegal except in regards to serious sex-linked genetic diseases <ref name="PMID24777348"><pubmed>24777348</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| Greece<br />
| In Greece, ART is open to those up to the age of 50 with written consent. It can only be used if a medical necessity is present such as the susceptibility of serious hereditary diseases. Sex selection is banned apart from cases of sex-linked diseases and sexually transmitted diseases <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| India<br />
| In India there is a cultural preference for boys thus the Prenatal Diagnostic Techniques (Regulation and Prevention of Misuse) Act was introduced in 1994. This law limits the use of PGD for sex determination except in cases of specific congenital diseases. These laws however are not strictly enforced. <ref>World Health Organisation (2015) Gender and Genetics Retrieved on October 21st 2015 from:http://www.who.int/genomics/gender/en/index4.html</ref><br />
|-bgcolor="FFFAFA"<br />
| Portugal <br />
| ART is only available to those who are married or have a similar type of relationship for at least two years. The couples cannot be of the same sex and must be at least 18 years of age. Sex selection is illegal except in cases of sex-linked diseases. The use of PGD is illegal if the predictive value of genetic tests are very low <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| Spain<br />
| PGD can be applied to “serious hereditary diseases not amenable to postnatal curative treatment” and “detection of other abnormalities which may compromise the viability of the pre-embryo”. If PGD is to be used for any other purpose authorisation must be acquired <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| Sweden <br />
| The use of PGD is strictly regulated and couples must achieve authorisation of the National Board of Health and Welfare. It can only be used it can only be used if the child is at risk to inheriting a serious chromosomal or monogenetic disease. It cannot be used for selection of specific characteristics <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| United Kingdom<br />
| Those involved with carrying out the IVF treatment must have a license from the Human Fertilisation and Embryology Authority (HFEA). Only embryos that are approved by the HFEA can be implanted where the embryonic nuclear or mitochondrial DNA cannot be altered with the exception of preventing mitochondrial diseases <ref name="PMID24777348"/>. <br />
|}<br />
<br />
==Future/Current Research==<br />
In addition to research efforts for improving overall performance of established PGD/S techniques, such as finding the ideal zona pellucida insection site in an fully automatic manner<ref name="PMID26259216"><pubmed>26259216</pubmed></ref>, many research efforts have been spent to find alternative, non-invasive techniques to test for diseases and abnormalities<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
===Non-invasive Preimplantation Genetic Testing without Embryo Biopsy===<br />
Different parameters of gametes, zygotes, embryos (“vacuoles in sperm heads, spindle position in mature oocytes, cleavage intervals of zygote, and embryo developmental dynamics”) may correlate with aneuploidy rates. This knowledge may be applied in potential noninvasive preimplantation diagnostic methods. Several methods have been proposed and are currently further researched<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Sperm Selection====<br />
Intracytoplasmic morphologically selected sperm injection (IMSI) is common procedure in IVF treatment to improve fertilization rates in patients with poor semen quality. In addition, studies have found that IMSI improves embryo development and that spermatozoa with large vacuoles in their heads correlate with increased aneuploidy rates and disturbed chromosomal structures. Thus, selecting spermatozoa based on morphological hallmarks may decrease aneuploidy rates in the fertilized embryos. As with polar body biopsies, however, this approach will solely be applicable if evidence for severe male detrimental contribution is given<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Blastocoel Fluid Extraction====<br />
In addition, a less invasive retrieval of material for diagnosis could include the extraction of the blastocoel fluid. The cavity of the blastocyst, lined by the trophectoderm, is filled with this blastocoel fluid, which contains metabolites of both trophectoderm and inner cell mass origin. The retrieval does not require a biopsy but merely a small opening to extract the fluid and, thus, causes less harm to the embryo. Multiple studies have applied this method<ref name="PMID22020776"><pubmed>22020776</pubmed></ref> <ref name="PMID23148560"><pubmed>23148560</pubmed></ref> <ref name="PMID26006737"><pubmed>26006737</pubmed></ref> and it may in the future become of clinical relevance.[[File:Aspiration_of_the_Blastocoel_Fluid.jpeg|400px|thumb|Aspiration of the Blastocoel Fluid using a ICSI pipette<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.]]Next to metabolites, the blastocoel fluid can contain DNA. Studies have shown that genomic DNA is present in about 90% of the blastocoel fluid samples tested. Typically the fluid is removed with an ICSI pipette from a day five blastocyst through its mural trophectoderm until the blastocyst fully collapses around the embryo. Several concerns regarding this method in a clinical setting have been raised. The collected DNA may be contaminated by the culture media that contains DNA fractions. The DNA may also be least representative of the actual embryos genome as the DNA may originate from abnormal or degenerated cells. Even though labelled noninvasive, the blastocyst still undergoes manipulation to some degree which may affect its viability. Thus, more research is required until this method can evolve from research to clinical use<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
====Proteomics and Medium Based PGD====<br />
The media in which embryos are kept during the early IVF procedures, gives rise to potential non-invasive techniques. For instance, the protein secretome of blastocysts may be representative of its chromosome constitution Recent studies have found biomarkers such as lipocalin-1, interleukin-10, tumor necrosis factor, stem cell factor, and chemokine ligand 13 to be differently secreted by aneuploid blastocyst than by euploid ones. The most significant biomarker appears to be interleukin-10. Paired with novel proteomic technologies and mass spectrometry this knowledge when extended may contribute to a new invasive PGD method<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. In addition, medium based non-invasive PGD has been researched for the diagnose of human α-thalassemia-SEA. Genomic DNA was collected from the media and the study surprisingly resulted in increased diagnosis efficacy compared to biopsy-based methods<ref name="PMID25816038"><pubmed>25816038</pubmed></ref>.<br />
====Embryo Morphology====<br />
Using time lapse imaging the embryo’s morphology can be closely observed and potential aneuploidy characteristics detected. Such characteristics may include the time of division to five cells, the time between the division from three to four cells, and the duration of the division from one to two and subsequently to three. In addition, the morphological quality of ICM an TE has been positively associated with aneuploidy or euploidy prognosis<ref name="PMID26246880"><pubmed>26246880</pubmed></ref>. These may give rise to an embryo quality screening prior to implantation<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
==Glossary==<br />
'''Biopsy:''' sample of tissue taken for examination <br />
<br />
'''Blastocyst:''' Stage of embryo at approximately day 5 consisting of an outer (trophoblast) layer and inner (embryoblast) cell mass. <br />
<br />
'''Blastomere:''' Initial cells formed through mitosis of the zygote<br />
<br />
'''CTFR''' Cystic Fibrosis Transmembrane Conductance Regulator, responsible for transport of chloride across the cell membrane<br />
<br />
'''Fluorescent In situ hybridisation:''' technique use to locate specific gene sequences using fluorescence tags <br />
<br />
'''Intracytoplasmic Morphologically Selected Sperm Injection (IMSI):''' IVF technique involving morphological selection of sperm under the microscope to be injected to oocyte<br />
<br />
'''Intracytoplasmic Sperm Injection (ICSI):''' IVF technique used to treat male infertility and involves direct injection of one sperm into an oocyte<br />
<br />
'''Next Generation Sequencing (NGS):''' Term used to describe the collection of recent findings regarding embryo screening<br />
<br />
'''Polar bodies:''' cell formed during the meiotic stages of the oocyte containing extra genetic material <br />
<br />
'''Polymerase Chain Reaction (PCR):''' Technique used to amplify DNA to study a specific genetic sequence<br />
<br />
'''Preimplantation Genetic Diagnosis (PGD):''' Involves genetic testing conducted to identify abnormalities in an embryo before implantation.<br />
<br />
'''Preimplantation Genetic Screening (PGS):''' Involves genetic screening for genetic abnormalities using techniques such as FISH and PCR to eliminate unhealthy embryos <br />
<br />
'''Robertsonian Translocations:''' Type of structural chromosomal translocation <br />
<br />
<br />
<br />
==References==<br />
<br />
<references/><br />
<br />
<br />
{{StudentPage2015}}</div>Z5017878https://embryology.med.unsw.edu.au/embryology/index.php?title=2015_Group_Project_6&diff=2081452015 Group Project 62015-10-23T02:46:37Z<p>Z5017878: </p>
<hr />
<div>{{ANAT2341Project2015header}}<br />
<br />
<br />
=Preimplantation Genetic Diagnosis and Preimplantation Genetic Screening=<br />
==Introduction==<br />
Preimplantation genetic diagnosis (PGD) and preimplantation genetic screening (PGS) are reproductive options for couples with known family histories of genetic disease or couples undergoing IVF procedures due to infertility issues. PGD can diagnose many genetic disorders caused by known chromosomal abnormalities (number and/or structure) or single gene mutations, and, thus decrease the risk of termination of pregnancy or miscarriages and enable such couples to have an unaffected child<ref name="PMID24907939"><pubmed>24907939</pubmed></ref>. Through major improvements in PGD/S and general laboratory technology, the testing for abnormalities in fetuses has shifted from prenatal diagnosis during the first 2 trimesters <ref> Blackburn, S.L. (2003) '''Maternal, Fetal & Neonatal physiology: a Clinical perspective''' (2nd ed.). Seattle: Saudners </ref>, testing for overall fetal growth, complications of pregnancy, and birth defects<ref> Sadler T.W.(2012) '''Langman's Medical Embryology''' (12th ed.) Philadelphia: Lipincott, Wiliams & Wilkins, a Wolters Kluwer Business </ref>, to an embryonic focus especially in advancements in Artificial Reproductive Technologies (ART)<ref><pubmed>20638568</pubmed></ref>. In 1990 PGD for a recessive X-linked disease resulted in the first live birth<ref><pubmed>2330030</pubmed></ref> and has since been incorporated in clinical routine and applied for a variety of genetic diseases, such as sickle cell anemia, thalassemia, or cystic fibrosis<ref name="PMID24907939"/>.<br />
[[File:Preimplantation Genetic Diagnosis Procedure.jpeg|600px|left|thumb| Simplified steps for PGD<ref name="PMID24907939"/>]]<br />
{|class="wikitable"align="right" <br />
| <html5media height="400" width="533">https://www.youtube.com/watch?v=0e-79qKllqk</html5media><br />
|-<br />
| Preimplantation Genetic Diagnosis<ref>IVF Florida (2011, December 11) IVF Florida - South Florida Fertility Specialists - Pre-Implantation Genetic Diagnosis [Video file]. Retrieved from https://www.youtube.com/watch?v=0e-79qKllqk</ref><br />
|}<br />
<br />
==History==<br />
The advances in reproductive technology during the second half of the 20th century, led to PGD's first clinical application in 1990 <ref>Harper, J. (n.d.). The history of PGD. Lecture. UCL Centre for PG&D and CRGH.University College London</ref>.<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
|Year<br />
|<br />
|- bgcolor="FFFAFA"<br />
| '''1967''' <br />
|First PGD on rabbit blastocysts (Gardner& Edwards) <ref name="PMID6036172"><pubmed>6036172</pubmed></ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1986''' <br />
|First Cleavage Biopsy (Wilton & Trounson)<ref>Wilton, L. J., & Trounson, A. O. (1986). Viability of mouse embryos and blastomeres following biopsy of a single cell. In Proceedings of the 18th Annual Conference of the Australian Society for Reproductive Biology, Brisbane, Australia.</ref><br />
|- bgcolor="FFFAFA"<br />
|'''1987''' <br />
|First Blastocyst Biopsy (Muggleton-Harris, Monk, Rawlings, & Whittingham)<ref name="PMID3372699"><pubmed>3372699</pubmed></ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1988''' <br />
|First Polar Body Biopsy (Yury Verlinksy)<ref> Verlinsky, Y., Pergament, E., Andresen, P., Enriquez, G., & Strom, C. (1989). Genetic analysis of polar body DNA: A new approach to preimplantation genetic diagnosis. Am J Hum Genet, 45(4), A272.</ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1990''' <br />
|First Clinical PGD using PCR testing for X-linked (Handyside, Kontogianni, Hardy, & Winston)<ref name="PMID2330030"><pubmed>2330030</pubmed></ref> <br />
|} <br />
==Preimplantation Genetic Diagnosis==<br />
PGD is used to test the genetic makeup of embryos to detect single gene disorders, chromosomal abnormalities and mitochondrial disorders. It also has applications in gender selection for diseases with unequal gender distributions <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Some diseases commonly involved with PGD include cystic fibrosis, spinal muscular atrophy and beta – thalassaemia <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press.">Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press</ref> <ref name="PMID17823145"><pubmed>17823145</pubmed></ref>. It was first used in the United Kingdom in the 1980s, primarily focusing on sex- linked disorders <ref name="PMID17823145"/><ref name="PMID23150080"><pubmed>23150080</pubmed></ref>. PGD is now capable of detecting single cell defects (molecular) and chromosomal disorders resulting from the inversion, translocation or deletion of chromosomes (cytogenic) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/> <ref name="PMID11325751"><pubmed>11325751</pubmed></ref>. PGD can be applied to the embryo at different stages. That is on polar bodies, blastomeres or blastocyst <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>.<br />
Depending on the type of genetic disorder, PGD utilises different methods of genetic testing. These include Fluorescence in situ hybridisation (FISH) which is used for sex – linked disorders and detects chromosomal rearrangements <ref name="PMID11325751"/><ref name="PMID17876073"><pubmed>17876073</pubmed></ref> and Embryo halotyping which allows the identification of chromosomes causing the inherited disorder through knowledge of the pattern of closely linked markers <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. Polymerase chain reaction (PCR) is also widely used to detect molecular abnormalities <ref name="PMID11325751"/>.<br />
PGD is tightly regulated and supported by large organisations namely The American Society for Reproductive Medicine, The European Society for Human Reproduction and Embryology (ESHRE), The European Society of Human Genetics and the Preimplantation Genetic Diagnosis International Society <ref name="PMID25500181><pubmed>25500181</pubmed></ref>.<br />
===Sex-linked disorders===<br />
The determination of a disease as gender specific usually correlates with the presence or absence of specific genes such as SRY on the Y chromosome. It is known that females have two X chromosomes and males have an X and a Y chromosome where abnormalities are more prevalent on the X chromosome. PGD can be used for sex selection where only male embryos are transferred to reduce the chance of inheriting X-linked disorders. However, this does not completely eradicate the problem as male embryos remain susceptible to inheriting an affected X chromosome. Sex determination is only used when the specific mutation is unknown and has yet to be discovered <ref name="PMID24866878"><pubmed>24866878</pubmed></ref>.<br />
===Single gene defects===<br />
Single gene defects can be dominant, recessive, autosomal or X-linked. They are commonly diagnosed using PCR and although the PCR available today is complex and capable of combatting a large range of disease the development of new protocols has been proven to be difficult due to the small DNA sample available <ref name="PMID26168107"><pubmed>26168107</pubmed></ref>.<br />
===Mitochondrial disorders===<br />
Mitochondrial disorders also known as oxidative phosphorylation disorders arise from mutations in the nuclear DNA or mitochondrial DNA <ref name="PMID26312584"><pubmed>26312584</pubmed></ref>. They pose as a problem because they are unrecognisable until the mutations in the cell reach a detrimental level <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Mitochondrial disorders cause miscarriages and stillbirths as well as death in children and young adults. The effects can either be contained in a single organ or more commonly involve multiple organ failure where organs with high energy demands such as the brain, liver muscle and heart and heavily influenced. They are usually occur spontaneously or result from inheritance from the mother. Since mitochondria are solely inherited from the mother oocyte donations have been used as a solution to combat mitochondrial disorders. Additionally, there has been an increasing use in PGD where embryos that stay under the given threshold of 18% gene-mutations are allowed to be transferred and result in normal development. New technology in the areas of nuclear gene transfer and genome editing are also being experimented with <ref name="PMID26312584"/>. <br />
===Chromosomal disorders===<br />
Chromosomal disorders can be reciprocal, Robertsonian translocations, inversions, deletions and insertions <ref name="PMID26168107"/>. Data from ESHRE collected between 2010 and 2011 has shown that the most common chromosomal abnormality confronted in PGD are reciprocal chromosomal abnormalities <ref name"PMID26071418"><pubmed>26071418</pubmed></ref>. PGD has also been used successfully for Robertsonian translocations (RT), a type of structural translocation. Children who carry RT are phenotypically normal, however in their later years it is found that they will suffer from infertility and repeated miscarriages due to the high frequency of abnormal embryos <ref name="PMID22081077"><pubmed>22081077</pubmed></ref>. PCR and FISH are the two main techniques used for chromosomal disorders. To be able to conduct the examinations the cells are required to be at the metaphase stage <ref name="PMID26168107"/>. <br />
[[File:Reasons_for_PGD.jpg|600px|thumb|Reasons for PGD<ref name= "PMID24764761"><pubmed><24764761</pubmed></ref>]]<br />
==Preimplantation Genetic Screening==<br />
PGS involves an array of methods or ideas that aim to segregate embryos that have genetic flaws and those that are healthy <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. The occurrence of aneuploidy is high around the stages of early embryonic development and they are the most common cause if miscarriages and congenital birth defects <ref name= "PMID26085841"><pubmed>26085841</pubmed></ref>. They have little effect on the morphology of the embryo making them difficult to identify thus identification heavily relies on genetic testing <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. <br />
Genetic sampling is most commonly conducted using Microarray Comparative Genomic Hybridisation (aCGH) as well as FISH, Quantitative PCR and Single Nucleotide Polymorphism (SNP) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. These methods collectively aim to assess numeral and structural chromosomal errors <ref name= "PMID26085841"/>. Studies have also introduced Next- Generation Sequencing (NGS) <ref name= "PMID26085841"/> and Whole Genome Amplification used to screen imbalances in the complete 24-chromosomes <ref name="PMID25953353"><pubmed>25953353</pubmed></ref>.<br />
Statistics from ESHRE have shown that the most common indications for PGS is advanced age, followed by repeated implantation failure or recurrent miscarriage and male infertility <ref name="PMID26071418"><pubmed>26071418</pubmed></ref>.<br />
===Indications===<br />
A low percentage of structural abnormalities in chromosomes are responsible for the cause of miscarriages. Despite this, they are the most prevalent type of chromosomal abnormality accounted for in PGD <ref name="PMID20638568"/>. The presence of specific gene cycles, initiation of embryonic protein synthesis and evident physiological development are all indicative of a successful in vitro fertilisation procedure <ref name="PMID11576737"><pubmed>11576737</pubmed></ref>. To eliminate further errors from occurring during the PGD procedure it is recommended to undertake further prenatal testing such as amniocentesis in the later stages <ref name="PMID20638568"/>. <br />
====Advanced maternal age====<br />
Data provided by the ESHRE has shown that the mean age of women undergoing PGS is 39 years <ref name="PMID26071418"/>. Women of advanced age have been shown to have a lower rate of pregnancies reaching childbirth <ref name="PMID18583331"><pubmed>18583331</pubmed></ref>. The highlighted concern revolves around the increased occurrence of aneuploidy following maternal age. The optimal age range for the lowest aneuploidy incidence was found to be between 27 to 37 years of age (6%) then progressively higher in women aged up to 42 (33%) and most common in those 44 and above (53%) <ref name="PMID24355045"><pubmed>24355045</pubmed></ref>. <br />
====Recurrent pregnancy loss / IVF failure====<br />
Recurrent pregnancy loss is defined as three or more IVF failures after cumulative transfer of more than 10 good-quality embryos. These are primarily caused by two main factors, reduced endometrium receptivity or embryonic defects. Endometrium receptivity can be negatively influences by instances including uterine pathologies such as thin endometrium, altered expression of adhesive molecules and immunological factors. Additionally, embryonic defects may be due to genetic abnormalities, embryonic aneuploidy or zona hardening. Endometriosis and hydrosalpinx has been known to effect both the endometrium and embryo <ref name="PMID23260857"><pubmed>23260857</pubmed></ref>.<br />
====Human leukocyte antigen matching====<br />
First used in 2001, HLA matching is an option given to parents to save a child with haematological or immunological disease through conceiving another child who would potentially be able to donate cord blood or haematopoietic stem cells from the bone marrow for transplantation. The process namely PGD-HLA has shown to improve haematopoietic stem cell transplant (HSCT). PGD-HLA can only be performed when HSCT is not needed urgently due to the time needed to conceive and delivery the baby <ref name="PMID25500181"><pubmed>25500181</pubmed></ref>. It is most commonly applied to children suffering from relapsed leukaemia <ref name="PMID22524201"><pubmed>22524201</pubmed></ref>. In a case study PGD-HLA was proven to successfully cure 10 diseases including Fanconi anaemia, Diamond-Blackfan anaemia and beta thalassemia <ref name="PMID25066893><pubmed>25066893</pubmed></ref>.<br />
==Biopsy Methods==<br />
Biopsy, the removal of genetic materials, from oocytes or embryos in the preimplantation stage is the primary step in PGD. For the past two decades these biopsies have been performed at three stages, the polar body, blastomere, and blastocyst, and the methodologies optimized to ensure the embryo’s viability. The most common approach involves biopsies at the cleavage stage. However, polar body and blastocyst biopsies are increasingly more often tested and applied. Approached for opening the zona pellucida involve next to the traditional mechanical and chemical means, novel approaches such as noncontact lasers. Their application may simplify and secure the procedure significantly. The most challenging question about PGD procedures remains at what stage biopsies should be taken. Much controversy has developed around this topic, highlighting the varying disadvantages and advantages of temporal biopsies. <ref name="PMID22723007"><pubmed>22723007</pubmed></ref><br />
<br />
[[File:Polar_Body,_Blastomere,_and_Trophectoderm_Biopsy.jpeg|400px|thumb|Polar body (A), blastomere (B) and trophectoderm (C) biopsies<ref name="PMID25625041"><pubmed>25625041</pubmed></ref>.]]<br />
{| class="wikitable"<br />
|- align="center" bgcolor="DDCEF2"<br />
|<br />
| Time of Biopsy<br />
| Advantages <br />
| Disadvantages<br />
|- bgcolor="FFFAFA"<br />
| Polar Body<br />
| Day 1<br />
| No harm to oocyte<br />
| Only maternal DNA is tested, often needs to be coupled with other biopsies, and there are difficulties distinguishing between the first and second PB.<br />
|- bgcolor="FFFAFA"<br />
| Blastomere<br />
| Day 3<br />
| …<br />
| … <br />
|- bgcolor="FFFAFA"<br />
| Trophectoderm<br />
| Day 5 and 6 <br />
| Little harm to the embryo and large amount of genetic material is extracted. <br />
| Opening of blastocyst necessary, small time window for procedure<br />
|}<br />
===Polar Body Analysis===<br />
Day 1<br />
====Description====<br />
Polar body (PB) biopsy offers a promising alternative to biopsies performed at the blastomere stage for PGD/S indications on legal and practical grounds. Consequent embryo development does not necessitate the presence of the first and second PB and their removal may not be crucial. PB biopsy requires precise timing. Keeping track of the meiotic cell cycle is necessary to perform a successful biopsy and, therefore, PB biopsy usually is applied in combination with intracytoplasmic sperm injection (ICSI). During the maturation from the germinal vesicle stage to the metaphase-II stage the first PB is formed. A cytoplasmic bridge containing spindle remnants, that are still in contact with the cellular genetic material, links this PB to the oolemma for about 90 minutes after extrusion. It is possible to visualize these remnants by polarization microscopy and it is crucial to not perform the biopsy until the first PB is no longer firmly attached to the oolemma as this indicates an immature embryo.The oocyte tolerates mechanical zona dissection best during hours four until six after ICSI as the oolemma has stabilized by that time because of the cortical granule reaction. Over time the first PB degenerates stressing a temporal biopsy and its optimal extraction time window is four to 12 hours after ICSI. The second PB forms around two to four hours after ICSI. Its optimal time window for biopsy is set to be eight to 16 hours after ICSI due to the second PB being attached to the oolemma with spindle remnants until six hours after ICSI. Biopsy at this point may cause enucleation of the oocyte. Studies have shown that the amplification efficiency of second PB’s DNA is worse if the PB is extracted prior to eight hours after ICSI. Thus, it is possible to perform sequential and simultaneous biopsies for the first and second PB. If performed, sequentially the first PB may be removed four to 12 hours and the second PB eight to 16 hours after ICSI. The optimal time window for a biopsy for both the first and second PB simultaneously is eight to 12 hours after ICSI. It is highly preferred to analyze both PBs due to potential aneuploidies in either PB and crossing overs during meiosis<ref name="PMID22723007"/>. <br />
====Procedure====<br />
Chemical opening achieved with for example acidic tyrode’s solution of the zona pellucida is not tolerated by the oocyte and may have detrimental effects on the embryo’s development. Therefore, the access to the perivitelline space of the oocyte is provided by mechanical zona dissection or by laser. Both techniques work well if performed by experienced embryologist. However, laser-assisted biopsy is less time consuming when compared to manual dissection. It is critical to consider the size of the introduced opening as it will remain permanent. If it is too large the blastomere may be lost during embryo development and if it is too small it may interfere with hatching of the embryo during blastocyst stage<ref name="PMID22723007"/>.<br />
[[File:Polar_Body_Biopsy.jpeg|left|thumb|The presence of a faint but clearly identifiable strand connecting PB2 to the oolemma. The biopsy was performed ∼9 h after ICSI<ref name="PMID21908464"><pubmed>21908464</pubmed></ref>.]]<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JTaQzszVr8o</html5media><br />
|-<br />
| Laser-assisted polar body biopsy<ref>RIUK, R. (2013, June 25) Polar Body Biopsy [Video file]. Retrieved from https://www.youtube.com/watch?v=JTaQzszVr8o</ref><br />
|}<br />
====Advantages & Disadvantages====<br />
PB biopsies can only investigate the maternal contributions to the embryo as they are of maternal origin. Thus, this procedure is appropriate for PGD solely for monogenetic diseases from the maternal side. Recessive diseases may be evaluated with PB biopsies on the basis that the embryo’s outcome will be determined by the paternal contribution. It may still be applied for PGS as it is a fairly safe biopsy option and most aneuploidies either arise during meiosis or origin from the maternal genome. However, diagnosis error has been reported due to the lack of considering paternal contributions.Because PB biopsies are performed very early it is not yet known whether the oocyte will develop into a viable embryo. Thus, PBs are commonly frozen or fixed after biopsy and depending on the state of the embryo only chosen PBs will be tested. This is primarily an economic issue as many genetic testing procedures are very cost-intensive<ref name="PMID22723007"/>[[File:Implantation_predictive_value_of_euploid_screening_results.jpeg|thumb|The sustained implantation predictive value (with 95 % confidence interval) of a euploid screening result obtained from the first polar body (PB1), PB1 and the second polar body (PB2), or a direct embryo biopsy for each stage of embryo transfer (cleavage-stage and blastocyst stage)<ref name="PMID25106935"><pubmed>25106935</pubmed></ref>.]] Generally the sustained implantation predictive value of screening of PBs is significantly lower than of for example biopsies of the blastocyst stage<ref name="PMID25106935"/>. Moreover, it is often difficult to distinguish between the first and the second PB. As the first one degenerates quicker, this may influence diagnostic procedures<ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
===Blastomere biopsy===<br />
Day 3 <br />
====Description====<br />
Blastomere biopsy has been the prevalent method for PGD and PGS in the last two decades. At least one, but up to two, blastomeres are biopsied on day three of the cleavage stage embryo. The right number of blastomeres removed is a controversial topic as two cells allow for more genetic material and more accurate results. However, removing two cells might be too invasive and damaging to the embryo. As PGS tries to improve implantation rates, whereas PGD sets out to avoid known genetic disorders, for the former only one cell is removed, while for the latter often two need to be removed, to ensure results as correct as possible<ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
====Procedure====<br />
Initially a hole was drilled into the zona pellucida using acid tyrodes with the consequent aspiration of blastomeres with a pipette. Nowadays the zona pellucida is largely opened using a laser and calcium and magnesium free media have been introduced to decrease junctions between blastomeres, which facilitates the biopsy<ref name="PMID21748341"/>.[[File:Aspiration_of_a_Blastomere.jpeg|thumb|Aspiration of a Blastomere into the biopsy pipette<ref name=" PMID24783200"><pubmed>24783200</pubmed></ref>.]]<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=TbridWVwipI</html5media><br />
|-<br />
| Laser-assisted blastomere biopsy<ref>Sukprasert, M. (2014, March 5) Day 3 Blastomere Biopsy 1 [Video file]. Retrieved from https://www.youtube.com/watch?v=TbridWVwipI</ref><br />
|}<br />
====Advantages & Disadvantages====<br />
===Trophectoderm biopsy===<br />
Day 5 and 6<br />
====Description====<br />
The improvement of embryo culture media allowed the in vitro development of human embryos until the blastocyst stage and opened up the possibility to take blastocyst biopsies. During day three to day five the haploid maternal and paternal genomes work together for the first time to form the genome of the embryo. The maternal epigenetic control lessens significantly while preparing for implantation with precisely arranged events happening. The first event includes a rapid increase in the number of embryonic cells which are active in mitotic divisions and apoptosis of aberrant cells. This is followed by the formation of blastocoel (cavitation) which results from the flattening of cell located on the outside of the blastomere. Now the blastocyst will expand until the embryo hatches by rupturing the zona pellucida. The cells of the blastocyst will differentiate to form two distinct cell lineages, the outer trophectoderm and the inner cell mass<ref name="PMID22723007"/>.<br />
====Procedure====<br />
Trophectoderm biopsy is usually performed in Hepes buffered biopsy medium and opening approaches include needle cutting which has been replaced by lasers in past years. Different research groups report different timings of the opening to be the most successful. Some open the blastocyst on day three or four by creating a 25 µm which causes the trophectoderm to herniate through this hole and is, thus, accessible for biopsy. Others create this hole about four hours before biopsy which allows sufficient herniation of trophectoderm cells. It is also possible to open the blastocyst immediately before biopsy. This avoids an extra step and the inner cell mass usually is easy to locate. Blastocyst biopsies involve the removal of trophectoderm cells and the ideal time for the procedure is day five. Successful biopsies on day six have been performed, while little is known about the results of biopsies on day seven. However, since the window of implantation in humans is from day eight to ten after ovulation, day seven biopsies appear to be possible<ref name="PMID22723007"/>.<br />
[[File:Microscopic images of human blastocysts for biopsy.jpeg|thumb|(A) Some trophectoderm cells in a blastocyst started to hatch and (B) the trophectoderm cells were biopsied with assisted laser cutting. Images in C–D show the blastocysts after vitrification and warming. Blastocysts had been cultured for 2–4 hrs after warming, showing good (ICM and trophectoderm cells) hatched (C) and hatching (D) blastocysts. The hatching blastocyst in (E) has good ICM but fair trophectoderm while the blastocyst in (F) has both fair ICM and trophectoderm. Arrows indicate ICMs and arrow heads indicate trophectoderm cells. Bar = 40 µm<ref name="PMID2190846"><pubmed>2190846</pubmed></ref>.]]<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JI_TQ8d8tNM</html5media><br />
|-<br />
| Laser-assisted blastocyst biopsy (at 00:50 min)<ref>Coco, R. (2014, April 30) Trophectoderm biopsy in a Hatching blastocyst protruding ICM [Video file]. Retrieved from https://www.youtube.com/watch?v=JI_TQ8d8tNM</ref><br />
|}<br />
====Advantages & Disadvantages====<br />
Blastocyst biopsies are believed to be less damaging to the embryo and appear to be unrelated to implantation rates. In addition, this biopsy method allows for a larger extraction of cells for genetic testing. However, since they are performed late in in vitro development, the time window for genetic testing is relatively small. Fast and accurate genetic testing methods are needed to ensure a successful and safe result from this biopsy. Thus, blastocyst biopsies may gain more popularity in the future when such methods have been developed or improved<ref name="PMID22723007"/>. <br />
==Genetic Techniques==<br />
===Polymerase Chain Reaction===<br />
PCR amplifies DNA specific to genetic sequence of interest . PCR was developed by Kay Mullis in the 1980's, for which he was awarded the Nobel prize for chemistry in 1993. <ref> Pubmed Docs (2015) Polymerase Chain Reaction (PCR) Pubmed. Retrieved from [http://www.ncbi.nlm.nih.gov/probe/docs/techpcr/]</ref> This technique enables clinicians to monitor and diagnose diseases using minute samples such as embryonic cells. <ref>Roche (2015) PCR: How We Copy DNA. Roche Molecular Systems Inc. retrieved From [http://molecular.roche.com/pcr/Pages/Process.aspx]</ref>. PCR is used to detect genetic disorders, as a part of PGD, in conjunction with IVF<ref name="PMID24301057"><pubmed>24301057</pubmed></ref>. It is used to detect molecular abnormalities, such as single gene disorders including Tay Sach, Cycstic fibrosis, Duchenne Muscular Dystrophy, Thalassemia, Huntington disease, Spinal muscular atrophy and many more. Molecular and genetic analysis require a significant amount of DNA, which can be delivered by PCR. It revolutionized the study of DNA, replacing all previous recombinant DNA technology and is a significant component of PGD procedures<ref name="PMID24907939"/>.<br />
<br />
[[File:PCR.jpg|thumb|PCR amplifies DNA specific to genetic sequence of interest, enabling the monitoring and diagnose molecular abnormalities such as single gene disorders using minute samples such as embryonic cells, blood & tissue <ref name="NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute">NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref>]]<br />
<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="7" |'''Advantages'''<br />
|-bgcolor="FFFAFA"<br />
| Fast and inexpensive way of copying a target sequence of DNA.<br />
|-bgcolor="FFFAFA"<br />
| Particularly useful for the diagnosis of single cell defects.<br />
|-bgcolor="FFFAFA"<br />
| Rapid generation of results (within hours).<br />
|-bgcolor="FFFAFA"<br />
| Highly sensitive, a single molecule of DNA is sufficient for reaction.<br />
|-bgcolor="FFFAFA"<br />
| Generates DNA copies exponentially.<br />
|-bgcolor="FFFAFA"<br />
| This enables DNA amplification required for molecular and genetic diagnostic analysis<ref> Dreesen, J., Drusedaul, M., Smeets, H., Die-Smulders, C., Coonen, E., Dumoulin, J., Gielen, M., Evers, J., Herbergers, J. & Geradets, J. (2008) Validation of preimplantation genetic diagnosis by PCR analysis: genotype comparison of the blastomere and corresponding embryo, implications for clinical practice. Mol. Hum. Reprod. 14 (10):573-579.doi: 10.1093/molehr/gan052. Retrieved from [http://molehr.oxfordjournals.org/content/14/10/573.short] </ref> <ref><pubmed>20966460</pubmed></ref>.<br />
|-bgcolor="DDCEF2"<br />
| rowspan="7"|'''Disadvantages'''<br />
|-bgcolor="FFFAFA"<br />
| Only during the exponential DNA replication phase, the starting quantity sequence contained in the original sample (template DNA strand) can be determined.<br />
|-bgcolor="FFFAFA"<br />
| PCR reaction is limited to by presence of inhibitors in the sample.<br />
|-bgcolor="FFFAFA"<br />
| Self annealing due to the accumulation of the product and the stopping exponential amplification for the target sequence and reaching of a plateau<br />
quantification of the end point of reaction of PCR products make real time quantitative RT-PCR necessary<ref name="NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute">NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref>.<br />
|-bgcolor="FFFAFA"<br />
| Not a diagnostic method on its own, but requires further analysis.<br />
|-bgcolor="FFFAFA"<br />
|Low-quantity DNA template may result in amplification failure<ref name="PMID24907939"/>.<br />
|-bgcolor="FFFAFA"<br />
|Allele drop-out (ADO) in heterozygous loci is possible<ref name="PMID24907939"/>.<br />
|}<br />
====Procedure====<br />
Samples are obtained from the the blastocyst, a polar body biopsy or the blastomeres stages of the embryo. <br />
*Stage 1 Denaturing: separating the target strands of DNA <br />
The obtained sample is heated to roughly 90 degrees celcius, this heat breaks the relatively weak bonds between nucleotides that form DNA. The double stranded DNA is split into two single strands of DNA that are used as templates.<br />
*Stage 2 Annealing: Binding the Primers to the target DNA sequence <ref name="PMID25250056"><pubmed>25250056</pubmed></ref><br />
PCR will only copy the target sequence of DNA specified by specific PCR primer. These synthesized primers oligonucleotides are small artificial pieces of DNA. TAQ polymerase enzyme synthesize two new strands of DNA duplicate to the single sample DNA stand template indicated by these primers. During this stage the reaction is cooled to a temperature between 40-60 degrees Celsius. <br />
*Stage 3- Extension- making copies <br />
Each of these two copies are then used again as templates generating two further replications This cycle can occur as many 30 -40 times within a couple hours leading to billions of extra copies of the original DNA segment. Generally the optimal temperature for the further replication is roughly 72 degrees Celsius, although, this may vary according to the analysis machines used. <ref name="PMID26092180"><pubmed>26092180</pubmed></ref><br />
This process mediated by a thermocycler machine that is programmed to alter the temperature of the reaction every couple of minutes, perpetuating the cycle of DNA denaturing and synthesis. <br />
This process, generates exponentially exact copies of the original template DNA sequence. <ref> Mullins, K., Francois, F.& Gibbs R.A. (1994 ) The Polymerase Chain Reaction. p3. Springer- Science +Business Media. Birkhauser, Boston<br />
Available at [https://books.google.com.au/books?hl=en&lr=&id=gjrTBwAAQBAJ&oi=fnd&pg=PR5&dq=kary+mullis+PCR&ots=mpzAyRh5ZY&sig=PQ4goNoKJ90tb3-MkPk62zrTGbw#v=onepage&q=kary%20mullis%20PCR&f=false] </ref><br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
!PCR cycles<br />
|-<br />
| '''PCR Cycle'''<br />
| '''Target Copies'''<br />
|-<br />
| 1<br />
| 2<br />
|-<br />
| 2<br />
| 4<br />
|-<br />
| 3<br />
| 8<br />
|-<br />
| 4<br />
| 16<br />
|-"<br />
| 5 <br />
| 32<br />
|-<br />
| 6 <br />
| 64<br />
|-<br />
| 7 <br />
| 128<br />
|-<br />
| 8<br />
| 256<br />
|- <br />
| 9<br />
| 512 <br />
|-<br />
| 10<br />
| 1024<br />
|-<br />
| 15<br />
| 32,768<br />
|-<br />
| 20 <br />
| 1,048,578<br />
|-<br />
| 25<br />
| 33,554,432<br />
|-<br />
| 30 <br />
| 1,073,741,842<br />
|-<br />
|}<br />
===Fluorescent In Situ Hybridisation===<br />
FISH is the one of the most effective and rapid <ref name="PMID26338801"><pubmed>26338801</pubmed></ref> method as part of PGD. This technique locates a specific DNA sequences within a chromosome. FISH facilitates the clinical diagnosis of chromosomal abnormalities indicated by sequential duplications, deletions and rearrangements of chromosome, that are usually missed with microscopic analysis. This technique is especially relevant for female embryos with X-linked diseases<ref name="PMID20809319"><pubmed>20809319</pubmed></ref>.[http://www.ncbi.nlm.nih.gov/pubmed/20809319] As part of PGD, it enabled the screening for aneuploidies and increased live birth rates in women with advanced age<ref name="PMID24907939"/> <ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. FISH is 99% effective when used in conjunction with competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities<ref name="PMID26338801"/>. [[File:Fluorescent In Situ Hybridisation (FISH).jpg|thumb|right|'''FISH''' Specific DNA sequences using probes which have been tagged with fluorescent labels are visualised.This technique enables the clinical diagnosis of chromosomal abnormalities, indicated by sequential duplication, deletions and rearrangements of chromosome <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref>]]<br />
<br />
{|class="wikitable" align="center"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="5" |'''Advantages''' <br />
|-bgcolor="FFFAFA" <br />
| FISH is 99% effective when used in conjunction with CGH to diagnose chromosomal abnormalities<ref><pubmed>26338801</pubmed></ref>.<br />
|-bgcolor="FFFAFA" <br />
| Results are rapidly generated. <br />
|-bgcolor="FFFAFA"<br />
| Very small translocations and aneuploidies that occur within chromosomes, that would usually be missed under microscopic analysis, can be identified<ref name="Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd)">Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref>.<br />
|-bgcolor="FFFAFA" <br />
| The most common chromosomal abnormalities, such as down syndrome chromosomes 13,16,18,21 and 22<ref><pubmed>21749752</pubmed></ref>, and inheritable X-linked disease or sex chromosome anomalies such as Duchenne's Muscular Dystrophy, hemophilia, ectodermal dysplasia<ref><pubmed>17876073</pubmed></ref> can be identified.<br />
|-bgcolor="DDCEF2"<br />
| rowspan="5"|'''Disadvantages'''<br />
|-bgcolor="FFFAFA" <br />
| FISH destroys all cells tested <ref> O'Connor, C. (2008) Fluorescence in situ hybridization (FISH). Nature Education 1(1):171. retrieved from [http://www.nature.com/scitable/topicpage/fluorescence-in-situ-hybridization-fish-327] </ref>.<br />
|-bgcolor="FFFAFA" <br />
| It does not fully access all chromosomes (only ~ 12)<ref name="PMID24907939"/>.<br />
|-bgcolor="FFFAFA" <br />
| The analysis of results is dependent upon the dot quality impacted by hybridisation efficiency or the camera sensitivity<ref name="PMID17970921"><pubmed>17970921</pubmed></ref>.<br />
|-bgcolor="FFFAFA" <br />
| Some studies indicate that using FISH on a day-3 embryo biopsy decreases the rate of live births<ref><pubmed>26168107</pubmed></ref>.<br />
|}<br />
====Procedure====<br />
Samples collected from the embryo<ref name="PMID21748341"><pubmed>21748341</pubmed></ref> are collected, processed, and its DNA strands are heated and denatured causing their the individual DNA strands to break apart. Then, probes of single complimentary stands of DNA a that have been tagged with small chemical agents that glow brightly in the presence of a specific region on a chromosome are added. These specific probes then hybridize and join to their complementary DNA strand. The fluorescent tags enable the correct identification of the presence or lack thereof and location of specific chromosomes that are tested for<ref name="PMID17876073"><pubmed>17876073</pubmed></ref>. The number and the relative location of the fluorescent dots generated by the FISH images is analysed and gives rise to diagnosis<ref name="PMID17970921"><pubmed>17970921</pubmed></ref>. The probe will not fully hybridise if there has been a duplication or a deletion of the DNA - indicating chromosomal and sex chromosomal anomalies like trisomies and aneuploidies. <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref>. Different probes are used for different purposes: <ref>Unique, Rare Chromosome Disorder Support Group (2013) Fluorescence in situ hybridisation (FISH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/Other/FISH%20FTNW.pdf]</ref><br />
*'''Locus specific tags''' detect very small imbalances, and locate isolated small portions <br />
of genes within a chromosome<br />
*'''Alphoid/Centomeric Repeat probes''' are developed from the repetitive sequence located in the middle region of each chromosome, useful in determining the number of chromosomes , detecting rearrangement and when used in conjunction with locus probes to determine the absence of genetic material on a chromosome. <br />
*'''Paint Probes''' are collections of smaller probes with their own stains that bind to a different section on the chromosome - allowing the full chromosome too be labeled a unique colour, this "full colour map" can be used to know the spectral karyotype- full chromosomal mapping is useful in examining chromosomal abnormalities. <br />
===Array Comparative Genomic Hybridisation (aCGH)===<br />
aCGH also known as Microarray analysis efficiently scans the entire genome for chromosomal imbalances. CGH was initially developed to detect the number of changes in a solid tumor mass. It uses 2 genomes comparing the sample to the control, with each labeled in a different fluorescent dye<ref name="PMID1876176"><pubmed>1876176</pubmed></ref>. Earlier CGH techniques were limited by the resolution of the imaging <ref> Lichter, P., et al. Comparative genomic hybridization: Uses and limitations. Seminars in Hematology 37, 348–357 (2000)</ref> , these initial limitations were overcome by using Microarrays in conjunction with CGh to improve the resolution of the imaging, Array Comparative Genomic Hybridisation (aCGH). This method compares sample and control microarrayed slides containing small segments of DNA (probes). <ref> Lucito, R., et al. Representational oligonucleotide microarray analysis: A high-resolution method to detect genome copy number variation. Genome Research 13, 2291–2305 (2003) </ref> the Probes used will vary according from the small (25-85 base pairs) oligonucleotides manufactured to highlight different target sequences, to the very large genomic clones (80,000- 200,00 base pairs), and as these are significantly smaller than the traditional metaphase chromosomes used for CGH, generating a higher resolution of image. <ref name="PMID22467166"><pubmed>22467166</pubmed></ref>.aCGH is used as a diagnostic tool for prenatal detection f chromosomal abnormalities <ref name="PMID19012303"><pubmed>19012303</pubmed></ref>.<br />
{|class="wikitable" align="center"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="12" |'''Advantages''' <br />
|-bgcolor="FFFAFA"<br />
| Multiple applications: prenatal genetic diagnosis, cancer diagnosis, <ref name="PMID20193845"><pubmed>20193845</pubmed></ref> genetic screening for developmental delay (learning disabilities) <ref name="PMID17309648"><pubmed>17309648</pubmed></ref>. or congenital anomalies that are suspected to be genetic in origin <ref>NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation . retrieved from [http://www.phgfoundation.org/file/5237/]</ref><br />
|-bgcolor="FFFAFA"<br />
| trace represents all chromosomes present in the human genome chromosomes 1-22 and the X & Y chromosomes, and therefore is the most accurate method for testing whole embryo aneuploidy<br />
|-bgcolor="FFFAFA"<br />
| aCGH has been extensively tested, and Validated, and is now used world wide.<br />
|-bgcolor="FFFAFA"<br />
| Detects submicroscopic alterations<br />
|-bgcolor="FFFAFA"<br />
| Detects deletions and additions and rearrangements as well as amplification, of the WHOLE genome, simultaneously.<br />
|-bgcolor="FFFAFA"<br />
| Used as a diagnostic tool for prenatal detection of chromosomal abnormalities <ref name="PMID22034057"><pubmed>22034057</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Provides high resolution genomewide screening of segmental genomic copy number variations<br />
|-bgcolor="FFFAFA"<br />
| Very accurate when used in conjunction with FISH<br />
|-bgcolor="FFFAFA"<br />
| Alone is more reliable and in detecting chromosomal abnormalities, with a higher implantation success rate, than FISH <ref name="PMID20494259"><pubmed>20494259</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Allows an in depth research focus upon specific types of rearrangements within selected chromosomal regions, a recent particular area of interest is subtelomeric and pericentromeric rearrangements<br />
|-bgcolor="FFFAFA"<br />
| Reduces the risk of failed implantation and miscarriage, improving the chance of a healthy baby <ref name="Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd)">Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref>><br />
|-bgcolor="DDCEF2"<br />
| rowspan="9" |'''Disadvantages'''<br />
|-bgcolor="FFFAFA"<br />
| Translocations and inversions of DNA are not detected<br />
|-bgcolor="FFFAFA"<br />
| Limited ability diagnosing specific polyploidies such as triploidy <ref> Unique, Rare Chromosome Disorder Support Group (2013) Microarray-based Comparative Genomic Hybridiation (array CGH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/other/array%20cgh%20ftnw.pdf] </ref><br />
|-bgcolor="FFFAFA"<br />
| Will not detect mosaicism detection <20% (cultures where >1 of 5 cells are trisomy 12)<br />
|-bgcolor="FFFAFA"<br />
| Will not detect balanced chromosomal rearrangement<br />
|-bgcolor="FFFAFA"<br />
| Will not detect duplications or deletions <80kb<br />
|-bgcolor="FFFAFA"<br />
| Will not detect point mutations within genes <ref>Washington department of education (CGH- FAQ for physicians. Signature Genomic LAboratories, LLC. Retrieved from [https://depts.washington.edu/dbpeds/Lab%20Tests/SignatureCGH-physician_FAQ.pdf]</ref><br />
|-bgcolor="FFFAFA"<br />
| will not detect chromosomal position of genomic gains<br />
|-bgcolor="FFFAFA"<br />
| Will not detect loos of heterozygosity (LOH) or Absence of heterozygosity (AOH) <ref>WiCell Research Institute Inc. (2012) Comparative Genomic Hybridization Microarray. <br />
retrieved from [http://www.wicell.org/home/cytogenetic-services/cgh-microarray/array-comparative-genomic-hybridization-acgh.cmsx]</ref><br />
|}<br />
====Procedure====<br />
<br />
The sample is obtained (skin, blood or fetal cells) and DNA is obtained. <br />
As a part of PGD fetal cell samples are collected from; the fertilized egg polar bodies, the blastomere (day 3 embryo) or the blastocyst/tropoectoderm stage (day 5 embryo).<br />
Sample DNA is labeled with one fluorescent dye, and the control DNA is labeled with a different colored fluorescent dye. the control DNA is used as the base point of reference. <br />
heated and denatured single DNA strands then hybridize to their complementary single strand probes, which are then combined and applied to a microarray and the results are run through a computer program and a digital imaging system is used to quantify the results( fluorescent intensities of the labeled probes)<ref name="Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45"> Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432] </ref>. <br />
<br />
[[File:aCGH.jpg|thumb|right|'''aCGH''' checks the entire genome for chromosomal imbalances, by comparing control and a sample slides contatining small segements of DNA sample microarrayed slides small segments of DNA. Illustrated by student z5020317 and adapted from <ref> NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation. retrieved from [http://www.phgfoundation.org/file/5237/]</ref> <ref name="Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45"> Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432] </ref>]]<br />
<br />
The fluorescent ratio and the hybridization signal at different locations on the genome of the control DNA are used to identify any variances present in the sample DNA. aCGH facilitates the clinical diagnosis of submicroscopic chromosomal duplication, deletion and rearrangements indicative of chromosomal disorders such as trisomies 1-22and specific sex linked disorders. <br />
Duplications in the DNA are displayed by the computer program as spikes/ peaks over an established threshold and deletions in DNA are displayed by the computer program as spikes/ toughs beneath this threshold <br />
<br />
<br />
===Next Generation Sequencing===<br />
The development and advances within ART in the past 20 years, as well as the increasing popularity of IV, has lead to an influx of new technologies developed to screen embryos for chromosomal anomalies, which are covered by the umbrella term of Next generation Sequencing (NGS). NGS is a general term used to describe all of the new and emerging screening techniques currently being introduced and used as part of PGD for IVF . NGS screens for single gene disorders as well as conducting extensive and very comprehensive chromosome diagnosis by sequencing, counting, and accurately assembling millions of DNA reads, simultaneously. <ref name="PMID23499002"><pubmed>23499002</pubmed></ref> There is a movement for NGS to replace the other limited testing techniques and be used as the standard. <br />
<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="14" |'''Advantages''' <br />
|-bgcolor="FFFAFA" <br />
| Cost effective<br />
|-bgcolor="FFFAFA"<br />
| Opens new diagnostic possibilities<br />
|-bgcolor="FFFAFA"<br />
| Accurately tests all 24 chromosomes<br />
|-bgcolor="FFFAFA"<br />
| Tests for the presence of monogenic diseases of known genetic background<br />
|-bgcolor="FFFAFA"<br />
| Reduces the number of biopsies required for diagnosis<br />
|-bgcolor="FFFAFA"<br />
| Higher detection rate of small translocations<br />
|-bgcolor="FFFAFA"<br />
| Highly accurate is testing for compound point mutations, chromosomal duplication, deletions and insertions <ref name="PMID23312231"><pubmed>23312231</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| It accurately detects chromosomal aneuploidy and unbalanced rearrangement <ref name="PMID25685330"><pubmed>25685330</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Higher detection rate of small translocations<br />
|-bgcolor="FFFAFA"<br />
| NGS single gene disorder screenings can conducted in conjunction with PCR comprehensive chromosomal screening<br />
|-bgcolor="FFFAFA"<br />
| Reduces human error <br />
|-bgcolor="FFFAFA"<br />
| Better detects the presence of mosaicism<br />
|-bgcolor="FFFAFA"<br />
| Work well in conjunction with CGH and aCGH as part of PGD, improving the chances of IVF. <ref> Morris, R. S. (2015 ) Next generation sequencing for PCG|PGS|CCS. IVF1 retrieved from [http://www.ivf1.com/next-generation-sequencing for-pgd] </ref><br />
|-bgcolor="DDCEF2"<br />
| '''Disadvantages''' <br />
|-bgcolor="FFFAFA"<br />
| There are limited information available to clinical applications of NGS <ref><pubmed>26100406</pubmed></ref><br />
|}<br />
<br />
====Procedure====<br />
Samples are collected from either blastomere or the blastocyst/tropoectoderm and processed for analysis by a computer system. <br />
The methodology of each process is unique to the technique being used. <br />
<br />
==Diagnosis==<br />
There are a large amount of diseases that PGD can apply to, below are descriptions of the diseases that PGD are more commonly used for. Upon completion of the genetic testing for the genes of concern the cells the embryos are discarded and priority is given to those that are healthy. <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/><br />
===Cystic Fibrosis===<br />
Cystic fibrosis is a single gene disorder. It is autosomal recessive and involves mutations in the cystic fibrosis transmembrane conductance regulator (CTFR) gene. The CTFR gene is normally responsible for the decrease in chloride and the transport of bicarbonate in epithelial cells thus playing a major physiological role. In PGD procedures, identification of the gene is assisted by microsatellite markers that have similar composition to the CTFR gene itself. Biopsy of two cells at the blastocyst stage is recommended if markers are not available. There are many variations of cystic fibrosis the most common being P.Phe508del <ref name="PMID26014425"><pubmed>26014425</pubmed></ref>.<br />
===Duchenne Muscular Dystrophy ===<br />
Duchenne Muscular Dystrophy is an X-linked recessive disease. It involves the Xp21 gene where majority of the mutations are chromosomal deletions with a smaller percentage resulting from duplications <ref name="PMID18359022"><pubmed>18359022</pubmed></ref>.<br />
<br />
===Autosomal Recessive Meckel-Gruber Syndrome===<br />
Autosomal recessive genetic defect caused by the TMEM67 gene. It results in cystic dysplasia of the kidneys with fibrotic change in the liber and occipital encephalocele. Other malformations could also be present in the central nervous system. In PGD whole genome amplification of single blastomeres are taken to identify the gene, this is also coupled with PCR techniques. Maternal plasma can also be extracted for PGS. <ref><pubmed>24039893</pubmed></ref> <br />
===β – Thalassemia=== <br />
β – Thalassemia is known as the most common type of autosomal recessive inherited disorder among haemoglobinopathies. It involves the adult β-globin gene and is associated with the absent or decreased expression of the gene. This is commonly caused by a single nucleotide change in the gene. PGD has been used successfully worldwide to identify the β-globin gene where its application is usually performed on a single blastomere or polar body <ref name="PMID19064120">19064120</pubmed></ref>.<br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
! Applicable diseases for PGD <ref>Genoma Group (2014). Retrieved September 18th, 2015, from http://www.preimplantationgeneticdiagnosis.it/genetic-diseases-diagnosed-by-pgd.htm </ref> <ref>Genesis Genetics (2015). Retrieved September 18th, 2015, from http://genesisgenetics.org/pgd/what-we-test-for/</ref> <ref>Human Fertilisation & Embryology Authority (2015). Retrieved Septembr 18th, 2015, from http://guide.hfea.gov.uk/pgd/</ref><br />
|-<br />
| '''Disease'''<br />
| '''Involved Genes'''<br />
|-<br />
| 5 Alpha Reductase Deficiency (5ARD)<br />
| SRD5A2 <br />
|-<br />
| Achondroplasia<br />
|FGFR3 <br />
|-<br />
| Acute Intermittent Porphyria <br />
| ALAD, ALAS2, CPOX, FECH, HMBS, PPOX, UROD, or UROS<br />
|-<br />
| Adrenoleukodystrophy (Adrenomyeloneuropathy)<br />
| ABCD1 <br />
|-<br />
| Agammaglobulinaemia (x-linked) <br />
|BTK <br />
|-<br />
| Agammaglobulinemia Bruton Tyrosine Kinase (BTK) <br />
|BTK <br />
|-<br />
| Aicardi Goutieres Syndrome 1 (AGS1) <br />
|TREX1, RNASEH2A, RNASEH2B, RNASEH2C, SAMHD1<br />
|-<br />
| Alagille Syndrome<br />
|JAG1 or NOTCH2<br />
|- <br />
| Alpers-Huttenlocher Syndrome <br />
|POLG <br />
|-<br />
| Alpha-1-antitrypsin deficiency <br />
|SERPINA1 <br />
|-<br />
| Alpha-Mannosidosis<br />
| MAN2B1 <br />
|-<br />
| Alpha Thalassemia <br />
|HBA1 or HBA2 <br />
|-<br />
| Alports Syndrome<br />
|COL4A3, COL4A4, COL4A5<br />
|-<br />
| Alzheimer's Disease - early onset (Type 3 and 4) <br />
|APP, PSEN1, or PSEN2<br />
|-<br />
| Amyotrophic Lateral Sclerosis 1 (ALS1) <br />
|C9orf72, SOD1, TARDBP, FUS, ANG, ALS2, SETX, VAPB <br />
|-<br />
| Argininosuccinic Aciduria <br />
| ASL<br />
|-<br />
| Arrhythmogenic Right Ventricular Cardiomyopathy/ Dysplasia (ARVC/D)<br />
| DSG2; DSP; PKP2<br />
|-<br />
| Ataxia Telangiectasia<br />
| ATM<br />
|-<br />
| Autosomal Recessive Meckel-Gruber Syndrome<br />
| TMEM67<br />
|-<br />
| Bardet-Biedl Syndrome (BBS)<br />
| BBS1; BBS10<br />
|-<br />
| Barth Syndrome<br />
| TAZ<br />
|-<br />
| Beta Thalassaemia<br />
| HBB<br />
|-<br />
| Birt-Hogg-Dubé Syndrome<br />
| FLCN<br />
|-<br />
| Breast Ovarian Cancer Familial Susceptibility (BRCA2)<br />
| BRCA1; BRCA2<br />
|-<br />
| Canavan Disease <br />
| ASPA<br />
|-<br />
| Carnitine-Acylcarnitine Translocase Deficiency <br />
| SLC25A20<br />
|-<br />
| Cerebral Arteriopathy with Subcortical Infarcts & Leukoencephalopathy (CADASIL)<br />
| NOTCH3<br />
|-<br />
| Cerebral Cavernous Malformation<br />
| CCM1<br />
|-<br />
| Charcot-Marie-Tooth Disease<br />
| GJB1; MPZ; NEFL; PMP22<br />
|-<br />
| CHARGE Syndrome<br />
| CHD7<br />
|-<br />
| Cherubism<br />
| SH3BP2<br />
|-<br />
| Choroideremia<br />
| CHM<br />
|-<br />
| Chronic Granulomatous Disease<br />
| CYBB; NCF1<br />
|-<br />
| Ciliary Dyskinesia<br />
| DNAH5<br />
|-<br />
| Citrullinemia<br />
| ASS1<br />
|-<br />
| Cleidocranial Dysplasia<br />
| RUNX2<br />
|-<br />
| Cockayne Syndrome<br />
| ERCC6<br />
|-<br />
| Congenital Adrenal Hyperplasia<br />
| CYP21A2<br />
|-<br />
| Congenital Cataracts<br />
| GJA8; VSX2<br />
|-<br />
| Congenital Diarrhea, Syndromic<br />
| SPINT2<br />
|-<br />
| Congenital Disorders of Glycosylation (CDG)<br />
| ALG1; ALG6; CDG1C; DOLK; PMM2<br />
|-<br />
| Cornelia de Lange Syndrome <br />
| NIPBL<br />
|-<br />
| Craniosynostosis<br />
| TWIST1<br />
|-<br />
| Crouzon Syndrome<br />
| FGFR2<br />
|-<br />
| Cysteinyl Leukotriene Receptor 1 Deficiency <br />
| CYSLTR1<br />
|-<br />
| Cystic Fibrosis<br />
| CFTR<br />
|-<br />
| Diamond –Blackfan Anemia <br />
| RPS19<br />
|-<br />
| Duchenne Muscular Dystrophy <br />
| DMD<br />
|-<br />
| Dyskeratosis congenita (Male embryos only)<br />
| DKC1<br />
|-<br />
| Ectodermal dysplasia (Hypohidrotic)<br />
| EDA; EDA1; GJB6; IKBKG<br />
|-<br />
| Familial Adenomatous polyposis coli (FAP)<br />
| APC<br />
|-<br />
| Familial Dysautonomia<br />
| IKBKAP<br />
|-<br />
| Fanconi Anemia <br />
| FANCA; FANCC; FANCD2; FANCF; FANCG; FANCJ<br />
|-<br />
| Fragile X Syndrome (FRAX)<br />
| FMR1<br />
|-<br />
| Galactosemia <br />
| GALT<br />
|-<br />
| Gangliosidosis<br />
| GLB1<br />
|-<br />
| Glanzmann Thrombasthenia <br />
| ITGA2B<br />
|-<br />
| Glutaric Acidemia (aciduria)<br />
| GCDH <br />
|-<br />
| Glycogen Storage Disease <br />
| G6PC; GAA; SLC37A4<br />
|-<br />
| Haemophilia A<br />
| F8<br />
|-<br />
| Haemophilia B<br />
| F9<br />
|-<br />
| Hereditary Nonpolyposis Colorectal Cancer: Lynch Syndrome<br />
| MLH1; MSH2; MSH6<br />
|-<br />
| Holt Oram Syndrome<br />
| TBX5<br />
|-<br />
| Huntington Disease<br />
| HD<br />
|-<br />
| Hydrocephalus<br />
| L1CAM<br />
|-<br />
| Ichthyosis <br />
| ABCA12; STS<br />
|-<br />
| Incontinentia Pigmenti (IP)<br />
| NEMO<br />
|-<br />
| Joubert Syndrome 5<br />
| INPP5E<br />
|-<br />
| Krabbe Disease<br />
| GALC<br />
|-<br />
| Leber Congenital Amaurosis (LCA)<br />
| CEP290; GUCY2D<br />
|-<br />
| Leigh Syndrome (Infantile Subacute Necrotising Encephalopathy)<br />
| LRPPRC<br />
|-<br />
| Lesch Nyan Syndrome<br />
| HPRT1<br />
|-<br />
| Leukocyte Adhesion Deficiency (Type I)<br />
| ITGB2<br />
|-<br />
| Li-Fraumeni Syndrome<br />
| TP53<br />
|-<br />
| Macular Dystrophy Retinal <br />
| VMD2<br />
|-<br />
| Maple Syrup Urine Disorder (MSUD)<br />
| BCKDHB<br />
|-<br />
| Marfan Syndrome <br />
| FBN1<br />
|-<br />
| Menkes Syndrome<br />
| ATP7A<br />
|-<br />
| Mitochondrial DNA Depletion Syndrom <br />
| POLG; RRM2B; SUCLA2; TK2<br />
|-<br />
| Mucolipidosis type II<br />
| GNPTAB<br />
|-<br />
| Multiple Endocrine Neoplasia<br />
| MEN1; MEN2A; MEN2B<br />
|-<br />
| Multiple Exostoses<br />
| EXT1; EXT2 <br />
|-<br />
| Myotubular myopathy<br />
| MTM1 <br />
|-<br />
| Nail-Patella Syndrome<br />
| LMX1B<br />
|-<br />
| Neurofibromatosis Type 1<br />
| NF1<br />
|-<br />
| Neurofibromatosis Type 2 <br />
| NF2<br />
|-<br />
| Noonan Syndrome<br />
| KRAS, PTPN11; SOS1<br />
|-<br />
| Norrie Disease<br />
| NDP<br />
|-<br />
| Ocular Albinism <br />
| GPR143<br />
|-<br />
| Oculocutaneous Albinism <br />
| OCA2; TYR <br />
|-<br />
| Oculodentaldigital Dysplasia<br />
| GJA1<br />
|-<br />
| Optic Atrophy<br />
| OPA1<br />
|-<br />
| Ornithine Transcarbamylase Deficiency <br />
| OTC<br />
|-<br />
| Osteogenesis imperfeca <br />
| COL1A1; COL1A2<br />
|-<br />
| Osteopetrosis <br />
| CLCN7; OSTM1; TCIRG1<br />
|-<br />
| Pachyonychia Congenita <br />
| KRT16; KRT6A<br />
|-<br />
| Pancreatitis, Hereditary<br />
| PRSS1 <br />
|-<br />
| Papillorenal syndrome <br />
| PAX2<br />
|-<br />
| Phenylketonuria <br />
| PAH <br />
|-<br />
| This table does not cover the complete list of diseases that PGD can be applied to.<br />
|}<br />
<br />
==Laws & Legal status==<br />
<br />
{| class="wikitable" <br />
|-bgcolor="DDCEF2"<br />
|'''Country'''<br />
|'''Legislation'''<br />
|-bgcolor="FFFAFA" <br />
| Australia<br />
| PGD is currently used to detect serious genetic conditions to improve the outcome of Assisted Reproductive Technologies (ART). In very rare cases it may be used to select an embryo with compatible tissue for a sibling who has a life-threatening disease where other means of treatment is unavailable. This is with the conditions that the use of PGD will not affect the welfare and interests of the child to be born. The parents must also receive adequate counselling and have full understanding of the procedures of PGD. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"> National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art</ref><br />
The use of PGD for sex-selection is prohibited with the exception of reducing the risk of the transmission of serious sex-linked genetic conditions. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"/><br />
|-bgcolor="FFFAFA"<br />
| Brazil<br />
| The laws regarding PGD in Brazil are not strictly regulated. They are vague and there is limited information surround the activities of assisted reproduction in general in the country <ref name="PMID25493379"><pubmed>25493379</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| Czech Republic<br />
| The laws in the Czech Republic allow those with a “defined indication in order to exclude risk of serous genetically conditioned disease and defects with embryos before they are implanted into the cavity of the uterus”. Couples that undergo any assisted reproductive treatment including PGD have to be married. Sex-selection is illegal except in regards to serious sex-linked genetic diseases <ref name="PMID24777348"><pubmed>24777348</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| Greece<br />
| In Greece, ART is open to those up to the age of 50 with written consent. It can only be used if a medical necessity is present such as the susceptibility of serious hereditary diseases. Sex selection is banned apart from cases of sex-linked diseases and sexually transmitted diseases <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| India<br />
| In India there is a cultural preference for boys thus the Prenatal Diagnostic Techniques (Regulation and Prevention of Misuse) Act was introduced in 1994. This law limits the use of PGD for sex determination except in cases of specific congenital diseases. These laws however are not strictly enforced. <ref>World Health Organisation (2015) Gender and Genetics Retrieved on October 21st 2015 from:http://www.who.int/genomics/gender/en/index4.html</ref><br />
|-bgcolor="FFFAFA"<br />
| Portugal <br />
| ART is only available to those who are married or have a similar type of relationship for at least two years. The couples cannot be of the same sex and must be at least 18 years of age. Sex selection is illegal except in cases of sex-linked diseases. The use of PGD is illegal if the predictive value of genetic tests are very low <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| Spain<br />
| PGD can be applied to “serious hereditary diseases not amenable to postnatal curative treatment” and “detection of other abnormalities which may compromise the viability of the pre-embryo”. If PGD is to be used for any other purpose authorisation must be acquired <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| Sweden <br />
| The use of PGD is strictly regulated and couples must achieve authorisation of the National Board of Health and Welfare. It can only be used it can only be used if the child is at risk to inheriting a serious chromosomal or monogenetic disease. It cannot be used for selection of specific characteristics <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| United Kingdom<br />
| Those involved with carrying out the IVF treatment must have a license from the Human Fertilisation and Embryology Authority (HFEA). Only embryos that are approved by the HFEA can be implanted where the embryonic nuclear or mitochondrial DNA cannot be altered with the exception of preventing mitochondrial diseases <ref name="PMID24777348"/>. <br />
|}<br />
<br />
==Future/Current Research==<br />
In addition to research efforts for improving overall performance of established PGD/S techniques, such as finding the ideal zona pellucida insection site in an fully automatic manner<ref name="PMID26259216"><pubmed>26259216</pubmed></ref>, many research efforts have been spent to find alternative, non-invasive techniques to test for diseases and abnormalities<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
===Non-invasive Preimplantation Genetic Testing without Embryo Biopsy===<br />
Different parameters of gametes, zygotes, embryos (“vacuoles in sperm heads, spindle position in mature oocytes, cleavage intervals of zygote, and embryo developmental dynamics”) may correlate with aneuploidy rates. This knowledge may be applied in potential noninvasive preimplantation diagnostic methods. Several methods have been proposed and are currently further researched<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Sperm Selection====<br />
Intracytoplasmic morphologically selected sperm injection (IMSI) is common procedure in IVF treatment to improve fertilization rates in patients with poor semen quality. In addition, studies have found that IMSI improves embryo development and that spermatozoa with large vacuoles in their heads correlate with increased aneuploidy rates and disturbed chromosomal structures. Thus, selecting spermatozoa based on morphological hallmarks may decrease aneuploidy rates in the fertilized embryos. As with polar body biopsies, however, this approach will solely be applicable if evidence for severe male detrimental contribution is given<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Blastocoel Fluid Extraction====<br />
In addition, a less invasive retrieval of material for diagnosis could include the extraction of the blastocoel fluid. The cavity of the blastocyst, lined by the trophectoderm, is filled with this blastocoel fluid, which contains metabolites of both trophectoderm and inner cell mass origin. The retrieval does not require a biopsy but merely a small opening to extract the fluid and, thus, causes less harm to the embryo. Multiple studies have applied this method<ref name="PMID22020776"><pubmed>22020776</pubmed></ref> <ref name="PMID23148560"><pubmed>23148560</pubmed></ref> <ref name="PMID26006737"><pubmed>26006737</pubmed></ref> and it may in the future become of clinical relevance.[[File:Aspiration_of_the_Blastocoel_Fluid.jpeg|400px|thumb|Aspiration of the Blastocoel Fluid using a ICSI pipette<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.]]Next to metabolites, the blastocoel fluid can contain DNA. Studies have shown that genomic DNA is present in about 90% of the blastocoel fluid samples tested. Typically the fluid is removed with an ICSI pipette from a day five blastocyst through its mural trophectoderm until the blastocyst fully collapses around the embryo. Several concerns regarding this method in a clinical setting have been raised. The collected DNA may be contaminated by the culture media that contains DNA fractions. The DNA may also be least representative of the actual embryos genome as the DNA may originate from abnormal or degenerated cells. Even though labelled noninvasive, the blastocyst still undergoes manipulation to some degree which may affect its viability. Thus, more research is required until this method can evolve from research to clinical use<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
====Proteomics and Medium Based PGD====<br />
The media in which embryos are kept during the early IVF procedures, gives rise to potential non-invasive techniques. For instance, the protein secretome of blastocysts may be representative of its chromosome constitution Recent studies have found biomarkers such as lipocalin-1, interleukin-10, tumor necrosis factor, stem cell factor, and chemokine ligand 13 to be differently secreted by aneuploid blastocyst than by euploid ones. The most significant biomarker appears to be interleukin-10. Paired with novel proteomic technologies and mass spectrometry this knowledge when extended may contribute to a new invasive PGD method<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. In addition, medium based non-invasive PGD has been researched for the diagnose of human α-thalassemia-SEA. Genomic DNA was collected from the media and the study surprisingly resulted in increased diagnosis efficacy compared to biopsy-based methods<ref name="PMID25816038"><pubmed>25816038</pubmed></ref>.<br />
====Embryo Morphology====<br />
Using time lapse imaging the embryo’s morphology can be closely observed and potential aneuploidy characteristics detected. Such characteristics may include the time of division to five cells, the time between the division from three to four cells, and the duration of the division from one to two and subsequently to three. In addition, the morphological quality of ICM an TE has been positively associated with aneuploidy or euploidy prognosis<ref name="PMID26246880"><pubmed>26246880</pubmed></ref>. These may give rise to an embryo quality screening prior to implantation<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
==Glossary==<br />
'''Biopsy:''' sample of tissue taken for examination <br />
<br />
'''Blastocyst:''' Stage of embryo at approximately day 5 consisting of an outer (trophoblast) layer and inner (embryoblast) cell mass. <br />
<br />
'''Blastomere:''' Initial cells formed through mitosis of the zygote<br />
<br />
'''CTFR''' Cystic Fibrosis Transmembrane Conductance Regulator, responsible for transport of chloride across the cell membrane<br />
<br />
'''Fluorescent In situ hybridisation:''' technique use to locate specific gene sequences using fluorescence tags <br />
<br />
'''Intracytoplasmic Morphologically Selected Sperm Injection (IMSI):''' IVF technique involving morphological selection of sperm under the microscope to be injected to oocyte<br />
<br />
'''Intracytoplasmic Sperm Injection (ICSI):''' IVF technique used to treat male infertility and involves direct injection of one sperm into an oocyte<br />
<br />
'''Next Generation Sequencing (NGS):''' Term used to describe the collection of recent findings regarding embryo screening<br />
<br />
'''Polar bodies:''' cell formed during the meiotic stages of the oocyte containing extra genetic material <br />
<br />
'''Polymerase Chain Reaction (PCR):''' Technique used to amplify DNA to study a specific genetic sequence<br />
<br />
'''Preimplantation Genetic Diagnosis (PGD):''' Involves genetic testing conducted to identify abnormalities in an embryo before implantation.<br />
<br />
'''Preimplantation Genetic Screening (PGS):''' Involves genetic screening for genetic abnormalities using techniques such as FISH and PCR to eliminate unhealthy embryos <br />
<br />
'''Robertsonian Translocations:''' Type of structural chromosomal translocation <br />
<br />
<br />
<br />
==References==<br />
<br />
<references/><br />
<br />
<br />
{{StudentPage2015}}</div>Z5017878https://embryology.med.unsw.edu.au/embryology/index.php?title=2015_Group_Project_6&diff=2080592015 Group Project 62015-10-23T02:26:01Z<p>Z5017878: </p>
<hr />
<div>{{ANAT2341Project2015header}}<br />
<br />
<br />
=Preimplantation Genetic Diagnosis and Preimplantation Genetic Screening=<br />
==Introduction==<br />
Preimplantation genetic diagnosis (PGD) and preimplantation genetic screening (PGS) are reproductive options for couples with known family histories of genetic disease or couples undergoing IVF procedures due to infertility issues. PGD can diagnose many genetic disorders caused by known chromosomal abnormalities (number and/or structure) or single gene mutations, and, thus decrease the risk of termination of pregnancy or miscarriages and enable such couples to have an unaffected child<ref name="PMID24907939"><pubmed>24907939</pubmed></ref>. Through major improvements in PGD/S and general laboratory technology, the testing for abnormalities in fetuses has shifted from prenatal diagnosis during the first 2 trimesters <ref> Blackburn, S.L. (2003) '''Maternal, Fetal & Neonatal physiology: a Clinical perspective''' (2nd ed.). Seattle: Saudners </ref>, testing for overall fetal growth, complications of pregnancy, and birth defects<ref> Sadler T.W.(2012) '''Langman's Medical Embryology''' (12th ed.) Philadelphia: Lipincott, Wiliams & Wilkins, a Wolters Kluwer Business </ref>, to an embryonic focus especially in advancements in Artificial Reproductive Technologies (ART)<ref><pubmed>20638568</pubmed></ref>. In 1990 PGD for a recessive X-linked disease resulted in the first live birth<ref><pubmed>2330030</pubmed></ref> and has since been incorporated in clinical routine and applied for a variety of genetic diseases, such as sickle cell anemia, thalassemia, or cystic fibrosis<ref name="PMID24907939"/>.<br />
[[File:Preimplantation Genetic Diagnosis Procedure.jpeg|600px|left|thumb| Simplified steps for PGD<ref name="PMID24907939"/>]]<br />
{|class="wikitable"align="right" <br />
| <html5media height="400" width="533">https://www.youtube.com/watch?v=0e-79qKllqk</html5media><br />
|-<br />
| Preimplantation Genetic Diagnosis<ref>IVF Florida (2011, December 11) IVF Florida - South Florida Fertility Specialists - Pre-Implantation Genetic Diagnosis [Video file]. Retrieved from https://www.youtube.com/watch?v=0e-79qKllqk</ref><br />
|}<br />
<br />
==History==<br />
The advances in reproductive technology during the second half of the 20th century, led to PGD's first clinical application in 1990 <ref>Harper, J. (n.d.). The history of PGD. Lecture. UCL Centre for PG&D and CRGH.University College London</ref>.<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
|Year<br />
|<br />
|- bgcolor="FFFAFA"<br />
| '''1967''' <br />
|First PGD on rabbit blastocysts (Gardner& Edwards) <ref name="PMID6036172"><pubmed>6036172</pubmed></ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1986''' <br />
|First Cleavage Biopsy (Wilton & Trounson)<ref>Wilton, L. J., & Trounson, A. O. (1986). Viability of mouse embryos and blastomeres following biopsy of a single cell. In Proceedings of the 18th Annual Conference of the Australian Society for Reproductive Biology, Brisbane, Australia.</ref><br />
|- bgcolor="FFFAFA"<br />
|'''1987''' <br />
|First Blastocyst Biopsy (Muggleton-Harris, Monk, Rawlings, & Whittingham)<ref name="PMID3372699"><pubmed>3372699</pubmed></ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1988''' <br />
|First Polar Body Biopsy (Yury Verlinksy)<ref> Verlinsky, Y., Pergament, E., Andresen, P., Enriquez, G., & Strom, C. (1989). Genetic analysis of polar body DNA: A new approach to preimplantation genetic diagnosis. Am J Hum Genet, 45(4), A272.</ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1990''' <br />
|First Clinical PGD using PCR testing for X-linked (Handyside, Kontogianni, Hardy, & Winston)<ref name="PMID2330030"><pubmed>2330030</pubmed></ref> <br />
|} <br />
==Preimplantation Genetic Diagnosis==<br />
PGD is used to test the genetic makeup of embryos to detect single gene disorders, chromosomal abnormalities and mitochondrial disorders. It also has applications in gender selection for diseases with unequal gender distributions <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Some diseases commonly involved with PGD include cystic fibrosis, spinal muscular atrophy and beta – thalassaemia <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press.">Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press</ref> <ref name="PMID17823145"><pubmed>17823145</pubmed></ref>. It was first used in the United Kingdom in the 1980s of arenoleucodystrophy and primarily focusing on sex- linked disorders <ref name="PMID17823145"/><ref name="PMID23150080"><pubmed>23150080</pubmed></ref>. PGD is now capable of detecting single cell defects (molecular) and chromosomal disorders resulting from the inversion, translocation or deletion of chromosomes (cytogenic) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>,<ref name="PMID11325751"><pubmed>11325751</pubmed></ref>. PGD can be applied to the embryo at different stages. That is on polar bodies, blastomeres or blastocyst <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>.<br />
Depending on the type of genetic disorder, PGD utilises different methods of genetic testing. These include Fluorescence in situ hybridisation (FISH) which is used for sex – linked disorders and detects chromosomal rearrangements <ref name="PMID11325751"/><ref name="PMID17876073"><pubmed>17876073</pubmed></ref> and Embryo halotyping which allows the identification of chromosomes causing the inherited disorder through knowledge of the pattern of closely linked markers <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. Polymerase chain reaction (PCR) is also widely used to detect molecular abnormalities <ref name="PMID11325751"/>.<br />
PGD is tightly regulated and supported by large organisations namely The American Society for Reproductive Medicine, The European Society for Human Reproduction and Embryology (ESHRE), The European Society of Human Genetics and the Preimplantation Genetic Diagnosis International Society <ref name="PMID25500181><pubmed>25500181</pubmed></ref>.<br />
===Sex-linked disorders===<br />
The determination of a disease as gender specific usually correlates with the presence or absence of specific genes such as SRY on the Y chromosome. It is known that females have two X chromosomes and males have an X and a Y chromosome where abnormalities are more prevalent on the X chromosome. PGD can be used for sex selection where only male embryos are transferred to reduce the chance of inheriting X-linked disorders. However, this does not completely eradicate the problem as male embryos remain susceptible to inheriting an affected X chromosome. Sex determination is only used when the specific mutation is unknown and has yet to be discovered <ref name="PMID24866878"><pubmed>24866878</pubmed></ref>.<br />
===Single gene defects===<br />
Single gene defects can be dominant, recessive, autosomal or X-linked. They are commonly diagnosed using PCR and although the PCR available today is complex and capable of combatting a large range of disease the development of new protocols has been proven to be difficult due to the small DNA sample available <ref name="PMID26168107"><pubmed>26168107</pubmed></ref><br />
===Mitochondrial disorders===<br />
Mitochondrial disorders also known as oxidative phosphorylation disorders arise from mutations in the nuclear DNA or mitochondrial DNA <ref name="PMID26312584"><pubmed>26312584</pubmed></ref>. They pose as a problem because they are unrecognisable until the mutations in the cell reach a detrimental level <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Mitochondrial disorders cause miscarriages and stillbirths as well as death in children and young adults. The effects can either be contained in a single organ or more commonly involve multiple organ failure where organs with high energy demands such as the brain, liver muscle and heart and heavily influenced. They are usually occur spontaneously or result from inheritance from the mother. Since mitochondria are solely inherited from the mother oocyte donations have been used as a solution to combat mitochondrial disorders. Additionally, there has been an increasing use in PGD where embryos that stay under the given threshold of 18% gene-mutations are allowed to be transferred and result in normal development. New technology in the areas of nuclear gene transfer and genome editing are also being experimented with <ref name="PMID26312584"/>. <br />
===Chromosomal disorders===<br />
Chromosomal disorders can be reciprocal, Robertsonian translocations, inversions, deletions and insertions <ref name="PMID26168107"/>. . Data from ESHRE collected between 2010 and 2011 has shown that the most common chromosomal abnormality confronted in PGD are reciprocal chromosomal abnormalities <ref name"PMID26071418"><pubmed>26071418</pubmed></ref>. PGD has also been used successfully for Robertsonian translocations (RT), a type of structural translocation. Children who carry RT are phenotypically normal, however in their later years it is found that they will suffer from infertility and repeated miscarriages due to the high frequency of abnormal embryos <ref name="PMID22081077"><pubmed>22081077</pubmed></ref>. PCR and FISH are the two main techniques used for chromosomal disorders. To be able to conduct the examinations the cells are required to be at the metaphase stage <ref name="PMID26168107"/>. <br />
[[File:Reasons_for_PGD.jpg|600px|thumb|Reasons for PGD<ref name= "PMID24764761"><pubmed><24764761</pubmed></ref>]]<br />
==Preimplantation Genetic Screening==<br />
PGS involves an array of methods or ideas that aim to segregate embryos that have genetic flaws and those that are healthy <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. The occurrence of aneuploidy is high around the stages of early embryonic development and they are the most common cause if miscarriages and congenital birth defects <ref name= "PMID26085841"><pubmed>26085841</pubmed></ref>. They have little effect on the morphology of the embryo making them difficult to identify thus identification heavily relies on genetic testing <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. <br />
Genetic sampling is most commonly conducted using Microarray Comparative Genomic Hybridisation (aCGH) as well as FISH, Quantitative PCR and Single Nucleotide Polymorphism (SNP) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. These methods collectively aim to assess numeral and structural chromosomal errors <ref name= "PMID26085841"/>. Studies have also introduced Next- Generation Sequencing (NGS) <ref name= "PMID26085841"/> and Whole Genome Amplification used to screen imbalances in the complete 24-chromosomes <ref name="PMID25953353"><pubmed>25953353</pubmed></ref><br />
Statistics from ESHRE have shown that the most common indications for PGS is advanced age, followed by repeated implantation failure or recurrent miscarriage and male infertility <ref name="PMID26071418"><pubmed>26071418</pubmed></ref>.<br />
===Indications===<br />
A low percentage of structural abnormalities in chromosomes are responsible for the cause of miscarriages. Despite this, they are the most prevalent type of chromosomal abnormality accounted for in PGD <ref name="PMID20638568"/>. The presence of specific gene cycles, initiation of embryonic protein synthesis and evident physiological development are all indicative of a successful in vitro fertilisation procedure <ref name="PMID11576737"><pubmed>11576737</pubmed></ref>. To eliminate further errors from occurring during the PGD procedure it is recommended to undertake further prenatal testing such as amniocentesis in the later stages <ref name="PMID20638568"/>. <br />
====Advanced maternal age====<br />
Data provided by the ESHRE has shown that the mean age of women undergoing PGS is 39 years <ref name="PMID26071418"/>. Women of advanced age have been shown to have a lower rate of pregnancies reaching childbirth <ref name="PMID18583331"><pubmed>18583331</pubmed></ref>. The highlighted concern revolves around the increased occurrence of aneuploidy following maternal age. The optimal age range for the lowest aneuploidy incidence was found to be between 27 to 37 years of age (6%) then progressively higher in women aged up to 42 (33%) and most common in those 44 and above (53%) <ref name="PMID24355045"><pubmed>24355045</pubmed></ref>. <br />
====Recurrent pregnancy loss / IVF failure====<br />
Recurrent pregnancy loss is defined as three or more IVF failures after cumulative transfer of more than 10 good-quality embryos. These are primarily caused by two main factors, reduced endometrium receptivity or embryonic defects. Endometrium receptivity can be negatively influences by instances including uterine pathologies such as thin endometrium, altered expression of adhesive molecules and immunological factors. Additionally, embryonic defects may be due to genetic abnormalities, embryonic aneuploidy or zona hardening. Endometriosis and hydrosalpinx has been known to effect both the endometrium and embryo <ref name="PMID23260857"><pubmed>23260857</pubmed></ref>.<br />
====Human leukocyte antigen matching====<br />
First used in 2001, HLA matching is an option given to parents to save a child with haematological or immunological disease through conceiving another child who would potentially be able to donate cord blood or haematopoietic stem cells from the bone marrow for transplantation. The process namely PGD-HLA has shown to improve haematopoietic stem cell transplant (HSCT). PGD-HLA can only be performed when HSCT is not needed urgently due to the time needed to conceive and delivery the baby <ref name="PMID25500181"><pubmed>25500181</pubmed></ref>. It is most commonly applied to children suffering from relapsed leukaemia <ref name="PMID22524201"><pubmed>22524201</pubmed></ref>. In a case study PGD-HLA was proven to successfully cure 10 diseases including Fanconi anaemia, Diamond-Blackfan anaemia and beta thalassemia <ref name="PMID25066893><pubmed>25066893</pubmed></ref>.<br />
==Biopsy Methods==<br />
Biopsy, the removal of genetic materials, from oocytes or embryos in the preimplantation stage is the primary step in PGD. For the past two decades these biopsies have been performed at three stages, the polar body, blastomere, and blastocyst, and the methodologies optimized to ensure the embryo’s viability. The most common approach involves biopsies at the cleavage stage. However, polar body and blastocyst biopsies are increasingly more often tested and applied. Approached for opening the zona pellucida involve next to the traditional mechanical and chemical means, novel approaches such as noncontact lasers. Their application may simplify and secure the procedure significantly. The most challenging question about PGD procedures remains at what stage biopsies should be taken. Much controversy has developed around this topic, highlighting the varying disadvantages and advantages of temporal biopsies. <ref name="PMID22723007"><pubmed>22723007</pubmed></ref><br />
<br />
[[File:Polar_Body,_Blastomere,_and_Trophectoderm_Biopsy.jpeg|400px|thumb|Polar body (A), blastomere (B) and trophectoderm (C) biopsies<ref name="PMID25625041"><pubmed>25625041</pubmed></ref>.]]<br />
{| class="wikitable"<br />
|- align="center" bgcolor="DDCEF2"<br />
|<br />
| Time of Biopsy<br />
| Advantages <br />
| Disadvantages<br />
|- bgcolor="FFFAFA"<br />
| Polar Body<br />
| Day 1<br />
| No harm to oocyte<br />
| Only maternal DNA is tested, often needs to be coupled with other biopsies, and there are difficulties distinguishing between the first and second PB.<br />
|- bgcolor="FFFAFA"<br />
| Blastomere<br />
| Day 3<br />
| …<br />
| … <br />
|- bgcolor="FFFAFA"<br />
| Trophectoderm<br />
| Day 5 and 6 <br />
| Little harm to the embryo and large amount of genetic material is extracted. <br />
| Opening of blastocyst necessary, small time window for procedure<br />
|}<br />
===Polar Body Analysis===<br />
Day 1<br />
====Description====<br />
Polar body (PB) biopsy offers a promising alternative to biopsies performed at the blastomere stage for PGD/S indications on legal and practical grounds. Consequent embryo development does not necessitate the presence of the first and second PB and their removal may not be crucial. PB biopsy requires precise timing. Keeping track of the meiotic cell cycle is necessary to perform a successful biopsy and, therefore, PB biopsy usually is applied in combination with intracytoplasmic sperm injection (ICSI). During the maturation from the germinal vesicle stage to the metaphase-II stage the first PB is formed. A cytoplasmic bridge containing spindle remnants, that are still in contact with the cellular genetic material, links this PB to the oolemma for about 90 minutes after extrusion. It is possible to visualize these remnants by polarization microscopy and it is crucial to not perform the biopsy until the first PB is no longer firmly attached to the oolemma as this indicates an immature embryo.The oocyte tolerates mechanical zona dissection best during hours four until six after ICSI as the oolemma has stabilized by that time because of the cortical granule reaction. Over time the first PB degenerates stressing a temporal biopsy and its optimal extraction time window is four to 12 hours after ICSI. The second PB forms around two to four hours after ICSI. Its optimal time window for biopsy is set to be eight to 16 hours after ICSI due to the second PB being attached to the oolemma with spindle remnants until six hours after ICSI. Biopsy at this point may cause enucleation of the oocyte. Studies have shown that the amplification efficiency of second PB’s DNA is worse if the PB is extracted prior to eight hours after ICSI. Thus, it is possible to perform sequential and simultaneous biopsies for the first and second PB. If performed, sequentially the first PB may be removed four to 12 hours and the second PB eight to 16 hours after ICSI. The optimal time window for a biopsy for both the first and second PB simultaneously is eight to 12 hours after ICSI. It is highly preferred to analyze both PBs due to potential aneuploidies in either PB and crossing overs during meiosis<ref name="PMID22723007"/>. <br />
====Procedure====<br />
Chemical opening achieved with for example acidic tyrode’s solution of the zona pellucida is not tolerated by the oocyte and may have detrimental effects on the embryo’s development. Therefore, the access to the perivitelline space of the oocyte is provided by mechanical zona dissection or by laser. Both techniques work well if performed by experienced embryologist. However, laser-assisted biopsy is less time consuming when compared to manual dissection. It is critical to consider the size of the introduced opening as it will remain permanent. If it is too large the blastomere may be lost during embryo development and if it is too small it may interfere with hatching of the embryo during blastocyst stage<ref name="PMID22723007"/>.<br />
[[File:Polar_Body_Biopsy.jpeg|left|thumb|The presence of a faint but clearly identifiable strand connecting PB2 to the oolemma. The biopsy was performed ∼9 h after ICSI<ref name="PMID21908464"><pubmed>21908464</pubmed></ref>.]]<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JTaQzszVr8o</html5media><br />
|-<br />
| Laser-assisted polar body biopsy<ref>RIUK, R. (2013, June 25) Polar Body Biopsy [Video file]. Retrieved from https://www.youtube.com/watch?v=JTaQzszVr8o</ref><br />
|}<br />
====Advantages & Disadvantages====<br />
PB biopsies can only investigate the maternal contributions to the embryo as they are of maternal origin. Thus, this procedure is appropriate for PGD solely for monogenetic diseases from the maternal side. Recessive diseases may be evaluated with PB biopsies on the basis that the embryo’s outcome will be determined by the paternal contribution. It may still be applied for PGS as it is a fairly safe biopsy option and most aneuploidies either arise during meiosis or origin from the maternal genome. However, diagnosis error has been reported due to the lack of considering paternal contributions.Because PB biopsies are performed very early it is not yet known whether the oocyte will develop into a viable embryo. Thus, PBs are commonly frozen or fixed after biopsy and depending on the state of the embryo only chosen PBs will be tested. This is primarily an economic issue as many genetic testing procedures are very cost-intensive<ref name="PMID22723007"/>[[File:Implantation_predictive_value_of_euploid_screening_results.jpeg|thumb|The sustained implantation predictive value (with 95 % confidence interval) of a euploid screening result obtained from the first polar body (PB1), PB1 and the second polar body (PB2), or a direct embryo biopsy for each stage of embryo transfer (cleavage-stage and blastocyst stage)<ref name="PMID25106935"><pubmed>25106935</pubmed></ref>.]] Generally the sustained implantation predictive value of screening of PBs is significantly lower than of for example biopsies of the blastocyst stage<ref name="PMID25106935"/>. Moreover, it is often difficult to distinguish between the first and the second PB. As the first one degenerates quicker, this may influence diagnostic procedures<ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
===Blastomere biopsy===<br />
Day 3 <br />
====Description====<br />
Blastomere biopsy has been the prevalent method for PGD and PGS in the last two decades. At least one, but up to two, blastomeres are biopsied on day three of the cleavage stage embryo. The right number of blastomeres removed is a controversial topic as two cells allow for more genetic material and more accurate results. However, removing two cells might be too invasive and damaging to the embryo. As PGS tries to improve implantation rates, whereas PGD sets out to avoid known genetic disorders, for the former only one cell is removed, while for the latter often two need to be removed, to ensure results as correct as possible<ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
====Procedure====<br />
Initially a hole was drilled into the zona pellucida using acid tyrodes with the consequent aspiration of blastomeres with a pipette. Nowadays the zona pellucida is largely opened using a laser and calcium and magnesium free media have been introduced to decrease junctions between blastomeres, which facilitates the biopsy<ref name="PMID21748341"/>.<br />
[[File:Aspiration_of_a_Blastomere.jpeg|thumb|Aspiration of a Blastomere into the biopsy pipette<ref name=" PMID24783200"><pubmed>24783200</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=TbridWVwipI</html5media><br />
|-<br />
| Laser-assisted blastomere biopsy<ref>Sukprasert, M. (2014, March 5) Day 3 Blastomere Biopsy 1 [Video file]. Retrieved from https://www.youtube.com/watch?v=TbridWVwipI</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
===Trophectoderm biopsy===<br />
Day 5 and 6<br />
====Description====<br />
The improvement of embryo culture media allowed the in vitro development of human embryos until the blastocyst stage and opened up the possibility to take blastocyst biopsies. During day three to day five the haploid maternal and paternal genomes work together for the first time to form the genome of the embryo. The maternal epigenetic control lessens significantly while preparing for implantation with precisely arranged events happening. The first event includes a rapid increase in the number of embryonic cells which are active in mitotic divisions and apoptosis of aberrant cells. This is followed by the formation of blastocoel (cavitation) which results from the flattening of cell located on the outside of the blastomere. Now the blastocyst will expand until the embryo hatches by rupturing the zona pellucida. The cells of the blastocyst will differentiate to form two distinct cell lineages, the outer trophectoderm and the inner cell mass<ref name="PMID22723007"/>.<br />
====Procedure====<br />
Trophectoderm biopsy is usually performed in Hepes buffered biopsy medium and opening approaches include needle cutting which has been replaced by lasers in past years. Different research groups report different timings of the opening to be the most successful. Some open the blastocyst on day three or four by creating a 25 µm which causes the trophectoderm to herniate through this hole and is, thus, accessible for biopsy. Others create this hole about four hours before biopsy which allows sufficient herniation of trophectoderm cells. It is also possible to open the blastocyst immediately before biopsy. This avoids an extra step and the inner cell mass usually is easy to locate. Blastocyst biopsies involve the removal of trophectoderm cells and the ideal time for the procedure is day five. Successful biopsies on day six have been performed, while little is known about the results of biopsies on day seven. However, since the window of implantation in humans is from day eight to ten after ovulation, day seven biopsies appear to be possible<ref name="PMID22723007"/>.<br />
-collapse of trophoblasts<br />
-possible: biopsy of hatched blastocyst, holding pipette careful mild suction force to hold embryo near ICM <br />
-Cryopreservation<br />
<br />
<br />
[[File:Microscopic images of human blastocysts for biopsy.jpeg|thumb|(A) Some trophectoderm cells in a blastocyst started to hatch and (B) the trophectoderm cells were biopsied with assisted laser cutting. Images in C–D show the blastocysts after vitrification and warming. Blastocysts had been cultured for 2–4 hrs after warming, showing good (ICM and trophectoderm cells) hatched (C) and hatching (D) blastocysts. The hatching blastocyst in (E) has good ICM but fair trophectoderm while the blastocyst in (F) has both fair ICM and trophectoderm. Arrows indicate ICMs and arrow heads indicate trophectoderm cells. Bar = 40 µm<ref name="PMID2190846"><pubmed>2190846</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JI_TQ8d8tNM</html5media><br />
|-<br />
| Laser-assisted blastocyst biopsy (at 00:50 min)<ref>Coco, R. (2014, April 30) Trophectoderm biopsy in a Hatching blastocyst protruding ICM [Video file]. Retrieved from https://www.youtube.com/watch?v=JI_TQ8d8tNM</ref><br />
|}<br />
<br />
====Advantages & Disadvantages====<br />
Blastocyst biopsies are believed to be less damaging to the embryo and appear to be unrelated to implantation rates. In addition, this biopsy method allows for a larger extraction of cells for genetic testing. However, since they are performed late in in vitro development, the time window for genetic testing is relatively small. Fast and accurate genetic testing methods are needed to ensure a successful and safe result from this biopsy. Thus, blastocyst biopsies may gain more popularity in the future when such methods have been developed or improved<ref name="PMID22723007"/>. <br />
==Genetic Techniques==<br />
===Polymerase Chain Reaction===<br />
PCR amplifies DNA specific to genetic sequence of interest . PCR was developed by Kay Mullis in the 1980's, for which he was awarded the Nobel prize for chemistry in 1993. <ref> Pubmed Docs (2015) Polymerase Chain Reaction (PCR) Pubmed. Retrieved from [http://www.ncbi.nlm.nih.gov/probe/docs/techpcr/]</ref> This technique enables clinicians to monitor and diagnose diseases using minute samples such as embryonic cells. <ref>Roche (2015) PCR: How We Copy DNA. Roche Molecular Systems Inc. retrieved From [http://molecular.roche.com/pcr/Pages/Process.aspx]</ref>. PCR is used to detect genetic disorders, as a part of PGD, in conjunction with IVF<ref name="PMID24301057"><pubmed>24301057</pubmed></ref>. It is used to detect molecular abnormalities, such as single gene disorders including Tay Sach, Cycstic fibrosis, Duchenne Muscular Dystrophy, Thalassemia, Huntington disease, Spinal muscular atrophy and many more. Molecular and genetic analysis require a significant amount of DNA, which can be delivered by PCR. It revolutionized the study of DNA, replacing all previous recombinant DNA technology and is a significant component of PGD procedures<ref name="PMID24907939"/>.<br />
<br />
[[File:PCR.jpg|thumb|PCR amplifies DNA specific to genetic sequence of interest, enabling the monitoring and diagnose molecular abnormalities such as single gene disorders using minute samples such as embryonic cells, blood & tissue <ref name="NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute">NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref>]]<br />
{|<br />
|- align="left" bgcolor="DDCEF2"<br />
|'''Procedure'''<br />
|}<br />
Samples are obtained from the the blastocyst, a polar body biopsy or the blastomeres stages of the embryo. <br />
*Stage 1 Denaturing: separating the target strands of DNA <br />
The obtained sample is heated to roughly 90 degrees celcius, this heat breaks the relatively weak bonds between nucleotides that form DNA. The double stranded DNA is split into two single strands of DNA that are used as templates.<br />
*Stage 2 Annealing: Binding the Primers to the target DNA sequence <ref name="PMID25250056"><pubmed>25250056</pubmed></ref><br />
PCR will only copy the target sequence of DNA specified by specific PCR primer. These synthesized primers oligonucleotides are small artificial pieces of DNA. TAQ polymerase enzyme synthesize two new strands of DNA duplicate to the single sample DNA stand template indicated by these primers. During this stage the reaction is cooled to a temperature between 40-60 degrees Celsius. <br />
*Stage 3- Extension- making copies <br />
Each of these two copies are then used again as templates generating two further replications This cycle can occur as many 30 -40 times within a couple hours leading to billions of extra copies of the original DNA segment. Generally the optimal temperature for the further replication is roughly 72 degrees Celsius, although, this may vary according to the analysis machines used. <ref name="PMID26092180"><pubmed>26092180</pubmed></ref><br />
This process mediated by a thermocycler machine that is programmed to alter the temperature of the reaction every couple of minutes, perpetuating the cycle of DNA denaturing and synthesis. <br />
This process, generates exponentially exact copies of the original template DNA sequence. <ref> Mullins, K., Francois, F.& Gibbs R.A. (1994 ) The Polymerase Chain Reaction. p3. Springer- Science +Business Media. Birkhauser, Boston<br />
Available at [https://books.google.com.au/books?hl=en&lr=&id=gjrTBwAAQBAJ&oi=fnd&pg=PR5&dq=kary+mullis+PCR&ots=mpzAyRh5ZY&sig=PQ4goNoKJ90tb3-MkPk62zrTGbw#v=onepage&q=kary%20mullis%20PCR&f=false] </ref><br />
<br />
<br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
!PCR cycles<br />
|-<br />
| '''PCR Cycle'''<br />
| '''Target Copies'''<br />
|-<br />
| 1<br />
| 2<br />
|-<br />
| 2<br />
| 4<br />
|-<br />
| 3<br />
| 8<br />
|-<br />
| 4<br />
| 16<br />
|-"<br />
| 5 <br />
| 32<br />
|-<br />
| 6 <br />
| 64<br />
|-<br />
| 7 <br />
| 128<br />
|-<br />
| 8<br />
| 256<br />
|- <br />
| 9<br />
| 512 <br />
|-<br />
| 10<br />
| 1024<br />
|-<br />
| 15<br />
| 32,768<br />
|-<br />
| 20 <br />
| 1,048,578<br />
|-<br />
| 25<br />
| 33,554,432<br />
|-<br />
| 30 <br />
| 1,073,741,842<br />
|-<br />
|}<br />
<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="7" |'''Advantages'''<br />
|-bgcolor="FFFAFA"<br />
| Fast and inexpensive way of copying a target sequence of DNA.<br />
|-bgcolor="FFFAFA"<br />
| Particularly useful for the diagnosis of single cell defects.<br />
|-bgcolor="FFFAFA"<br />
| Rapid generation of results (within hours).<br />
|-bgcolor="FFFAFA"<br />
| Highly sensitive, a single molecule of DNA is sufficient for reaction.<br />
|-bgcolor="FFFAFA"<br />
| Generates DNA copies exponentially.<br />
|-bgcolor="FFFAFA"<br />
| This enables DNA amplification required for molecular and genetic diagnostic analysis<ref> Dreesen, J., Drusedaul, M., Smeets, H., Die-Smulders, C., Coonen, E., Dumoulin, J., Gielen, M., Evers, J., Herbergers, J. & Geradets, J. (2008) Validation of preimplantation genetic diagnosis by PCR analysis: genotype comparison of the blastomere and corresponding embryo, implications for clinical practice. Mol. Hum. Reprod. 14 (10):573-579.doi: 10.1093/molehr/gan052. Retrieved from [http://molehr.oxfordjournals.org/content/14/10/573.short] </ref> <ref><pubmed>20966460</pubmed></ref>.<br />
|-bgcolor="DDCEF2"<br />
| rowspan="7"|'''Disadvantages'''<br />
|-bgcolor="FFFAFA"<br />
| Only during the exponential DNA replication phase, the starting quantity sequence contained in the original sample (template DNA strand) can be determined.<br />
|-bgcolor="FFFAFA"<br />
| PCR reaction is limited to by presence of inhibitors in the sample.<br />
|-bgcolor="FFFAFA"<br />
| Self annealing due to the accumulation of the product and the stopping exponential amplification for the target sequence and reaching of a plateau<br />
quantification of the end point of reaction of PCR products make real time quantitative RT-PCR necessary<ref name="NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute">NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref>.<br />
|-bgcolor="FFFAFA"<br />
| Not a diagnostic method on its own, but requires further analysis.<br />
|-bgcolor="FFFAFA"<br />
|Low-quantity DNA template may result in amplification failure<ref name="PMID24907939"/>.<br />
|-bgcolor="FFFAFA"<br />
|Allele drop-out (ADO) in heterozygous loci is possible<ref name="PMID24907939"/>.<br />
|}<br />
===Fluorescent In Situ Hybridisation===<br />
FISH is the one of the most effective and rapid <ref name="PMID26338801"><pubmed>26338801</pubmed></ref> method as part of PGD. This technique locates a specific DNA sequences within a chromosome. FISH facilitates the clinical diagnosis of chromosomal abnormalities indicated by sequential duplications, deletions and rearrangements of chromosome, that are usually missed with microscopic analysis. This technique is especially relevant for female embryos with X-linked diseases<ref name="PMID20809319"><pubmed>20809319</pubmed></ref>.[http://www.ncbi.nlm.nih.gov/pubmed/20809319] As part of PGD, it enabled the screening for aneuploidies and increased live birth rates in women with advanced age<ref name="PMID24907939"/> <ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. FISH is 99% effective when used in conjunction with competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities<ref name="PMID26338801"/>.<br />
{|<br />
|- align="left" bgcolor="DDCEF2"<br />
|'''Procedure'''<br />
|}<br />
Samples collected from the embryo<ref name="PMID21748341"><pubmed>21748341</pubmed></ref> are collected, processed, and its DNA strands are heated and denatured causing their the individual DNA strands to break apart. Then, probes of single complimentary stands of DNA a that have been tagged with small chemical agents that glow brightly in the presence of a specific region on a chromosome are added. These specific probes then hybridize and join to their complementary DNA strand. The fluorescent tags enable the correct identification of the presence or lack thereof and location of specific chromosomes that are tested for<ref name="PMID17876073"><pubmed>17876073</pubmed></ref>. The number and the relative location of the fluorescent dots generated by the FISH images is analysed and gives rise to diagnosis<ref name="PMID17970921"><pubmed>17970921</pubmed></ref>. The probe will not fully hybridise if there has been a duplication or a deletion of the DNA - indicating chromosomal and sex chromosomal anomalies like trisomies and aneuploidies. <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref>. Different probes are used for different purposes: <ref>Unique, Rare Chromosome Disorder Support Group (2013) Fluorescence in situ hybridisation (FISH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/Other/FISH%20FTNW.pdf]</ref><br />
*'''Locus specific tags''' detect very small imbalances, and locate isolated small portions <br />
of genes within a chromosome<br />
*'''Alphoid/Centomeric Repeat probes''' are developed from the repetitive sequence located in the middle region of each chromosome, useful in determining the number of chromosomes , detecting rearrangement and when used in conjunction with locus probes to determine the absence of genetic material on a chromosome. <br />
*'''Paint Probes''' are collections of smaller probes with their own stains that bind to a different section on the chromosome - allowing the full chromosome too be labeled a unique colour, this "full colour map" can be used to know the spectral karyotype- full chromosomal mapping is useful in examining chromosomal abnormalities. <br />
[[File:Fluorescent In Situ Hybridisation (FISH).jpg|thumb|right|'''FISH''' Specific DNA sequences using probes which have been tagged with fluorescent labels are visualised.This technique enables the clinical diagnosis of chromosomal abnormalities, indicated by sequential duplication, deletions and rearrangements of chromosome <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref>]]<br />
<br />
{|class="wikitable" align="center"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="5" |'''Advantages''' <br />
|-bgcolor="FFFAFA" <br />
| FISH is 99% effective when used in conjunction with CGH to diagnose chromosomal abnormalities<ref><pubmed>26338801</pubmed></ref>.<br />
|-bgcolor="FFFAFA" <br />
| Results are rapidly generated. <br />
|-bgcolor="FFFAFA"<br />
| Very small translocations and aneuploidies that occur within chromosomes, that would usually be missed under microscopic analysis, can be identified<ref name="Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd)">Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref>.<br />
|-bgcolor="FFFAFA" <br />
| The most common chromosomal abnormalities, such as down syndrome chromosomes 13,16,18,21 and 22<ref><pubmed>21749752</pubmed></ref>, and inheritable X-linked disease or sex chromosome anomalies such as Duchenne's Muscular Dystrophy, hemophilia, ectodermal dysplasia<ref><pubmed>17876073</pubmed></ref> can be identified.<br />
|-bgcolor="DDCEF2"<br />
| rowspan="5"|'''Disadvantages'''<br />
|-bgcolor="FFFAFA" <br />
| FISH destroys all cells tested <ref> O'Connor, C. (2008) Fluorescence in situ hybridization (FISH). Nature Education 1(1):171. retrieved from [http://www.nature.com/scitable/topicpage/fluorescence-in-situ-hybridization-fish-327] </ref>.<br />
|-bgcolor="FFFAFA" <br />
| It does not fully access all chromosomes (only ~ 12)<ref name="PMID24907939"/>.<br />
|-bgcolor="FFFAFA" <br />
| The analysis of results is dependent upon the dot quality impacted by hybridisation efficiency or the camera sensitivity<ref name="PMID17970921"><pubmed>17970921</pubmed></ref>.<br />
|-bgcolor="FFFAFA" <br />
| Some studies indicate that using FISH on a day-3 embryo biopsy decreases the rate of live births<ref><pubmed>26168107</pubmed></ref>.<br />
|}<br />
<br />
===Array Comparative Genomic Hybridisation (aCGH)===<br />
aCGH also known as Microarray analysis efficiently scans the entire genome for chromosomal imbalances. CGH was initially developed to detect the number of changes in a solid tumor mass. It uses 2 genomes comparing the sample to the control, with each labeled in a different fluorescent dye<ref name="PMID1876176"><pubmed>1876176</pubmed></ref>. Earlier CGH techniques were limited by the resolution of the imaging <ref> Lichter, P., et al. Comparative genomic hybridization: Uses and limitations. Seminars in Hematology 37, 348–357 (2000)</ref> , these initial limitations were overcome by using Microarrays in conjunction with CGh to improve the resolution of the imaging, Array Comparative Genomic Hybridisation (aCGH). This method compares sample and control microarrayed slides containing small segments of DNA (probes). <ref> Lucito, R., et al. Representational oligonucleotide microarray analysis: A high-resolution method to detect genome copy number variation. Genome Research 13, 2291–2305 (2003) </ref> the Probes used will vary according from the small (25-85 base pairs) oligonucleotides manufactured to highlight different target sequences, to the very large genomic clones (80,000- 200,00 base pairs), and as these are significantly smaller than the traditional metaphase chromosomes used for CGH, generating a higher resolution of image. <ref name="PMID22467166"><pubmed>22467166</pubmed></ref>.aCGH is used as a diagnostic tool for prenatal detection f chromosomal abnormalities <ref name="PMID19012303"><pubmed>19012303</pubmed></ref>.<br />
{|<br />
|- align="left" bgcolor="DDCEF2"<br />
|'''Procedure'''<br />
|}<br />
<ref name="Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45"> Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432] </ref><br />
The sample is obtained (skin, blood or fetal cells) and DNA is obtained. <br />
As a part of PGD fetal cell samples are collected from; the fertilized egg polar bodies, the blastomere (day 3 embryo) or the blastocyst/tropoectoderm stage (day 5 embryo).<br />
Sample DNA is labeled with one fluorescent dye, and the control DNA is labeled with a different colored fluorescent dye. the control DNA is used as the base point of reference. <br />
heated and denatured single DNA strands then hybridize to their complementary single strand probes, which are then combined and applied to a microarray and the results are run through a computer program and a digital imaging system is used to quantify the results( fluorescent intensities of the labeled probes). <br />
<br />
[[File:aCGH.jpg|thumb|right|'''aCGH''' checks the entire genome for chromosomal imbalances, by comparing control and a sample slides contatining small segements of DNA sample microarrayed slides small segments of DNA. Illustrated by student z5020317 and adapted from <ref> NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation. retrieved from [http://www.phgfoundation.org/file/5237/]</ref> <ref name="Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45"> Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432] </ref>]]<br />
<br />
The fluorescent ratio and the hybridization signal at different locations on the genome of the control DNA are used to identify any variances present in the sample DNA. aCGH facilitates the clinical diagnosis of submicroscopic chromosomal duplication, deletion and rearrangements indicative of chromosomal disorders such as trisomies 1-22and specific sex linked disorders. <br />
Duplications in the DNA are displayed by the computer program as spikes/ peaks over an established threshold and deletions in DNA are displayed by the computer program as spikes/ toughs beneath this threshold <br />
<br />
{|class="wikitable" align="center"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="12" |'''Advantages''' <br />
|-bgcolor="FFFAFA"<br />
| Multiple applications: prenatal genetic diagnosis, cancer diagnosis, <ref name="PMID20193845"><pubmed>20193845</pubmed></ref> genetic screening for developmental delay (learning disabilities) <ref name="PMID17309648"><pubmed>17309648</pubmed></ref>. or congenital anomalies that are suspected to be genetic in origin <ref>NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation . retrieved from [http://www.phgfoundation.org/file/5237/]</ref><br />
|-bgcolor="FFFAFA"<br />
| trace represents all chromosomes present in the human genome chromosomes 1-22 and the X & Y chromosomes, and therefore is the most accurate method for testing whole embryo aneuploidy<br />
|-bgcolor="FFFAFA"<br />
| aCGH has been extensively tested, and Validated, and is now used world wide.<br />
|-bgcolor="FFFAFA"<br />
| Detects submicroscopic alterations<br />
|-bgcolor="FFFAFA"<br />
| Detects deletions and additions and rearrangements as well as amplification, of the WHOLE genome, simultaneously.<br />
|-bgcolor="FFFAFA"<br />
| Used as a diagnostic tool for prenatal detection of chromosomal abnormalities <ref name="PMID22034057"><pubmed>22034057</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Provides high resolution genomewide screening of segmental genomic copy number variations<br />
|-bgcolor="FFFAFA"<br />
| Very accurate when used in conjunction with FISH<br />
|-bgcolor="FFFAFA"<br />
| Alone is more reliable and in detecting chromosomal abnormalities, with a higher implantation success rate, than FISH <ref name="PMID20494259"><pubmed>20494259</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Allows an in depth research focus upon specific types of rearrangements within selected chromosomal regions, a recent particular area of interest is subtelomeric and pericentromeric rearrangements<br />
|-bgcolor="FFFAFA"<br />
| Reduces the risk of failed implantation and miscarriage, improving the chance of a healthy baby <ref name="Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd)">Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref>><br />
|-bgcolor="DDCEF2"<br />
| rowspan="9" |'''Disadvantages'''<br />
|-bgcolor="FFFAFA"<br />
| Translocations and inversions of DNA are not detected<br />
|-bgcolor="FFFAFA"<br />
| Limited ability diagnosing specific polyploidies such as triploidy <ref> Unique, Rare Chromosome Disorder Support Group (2013) Microarray-based Comparative Genomic Hybridiation (array CGH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/other/array%20cgh%20ftnw.pdf] </ref><br />
|-bgcolor="FFFAFA"<br />
| Will not detect mosaicism detection <20% (cultures where >1 of 5 cells are trisomy 12)<br />
|-bgcolor="FFFAFA"<br />
| Will not detect balanced chromosomal rearrangement<br />
|-bgcolor="FFFAFA"<br />
| Will not detect duplications or deletions <80kb<br />
|-bgcolor="FFFAFA"<br />
| Will not detect point mutations within genes <ref>Washington department of education (CGH- FAQ for physicians. Signature Genomic LAboratories, LLC. Retrieved from [https://depts.washington.edu/dbpeds/Lab%20Tests/SignatureCGH-physician_FAQ.pdf]</ref><br />
|-bgcolor="FFFAFA"<br />
| will not detect chromosomal position of genomic gains<br />
|-bgcolor="FFFAFA"<br />
| Will not detect loos of heterozygosity (LOH) or Absence of heterozygosity (AOH) <ref>WiCell Research Institute Inc. (2012) Comparative Genomic Hybridization Microarray. <br />
retrieved from [http://www.wicell.org/home/cytogenetic-services/cgh-microarray/array-comparative-genomic-hybridization-acgh.cmsx]</ref><br />
|}<br />
<br />
===Next Generation Sequencing===<br />
The development and advances within ART in the past 20 years, as well as the increasing popularity of IV, has lead to an influx of new technologies developed to screen embryos for chromosomal anomalies, which are covered by the umbrella term of Next generation Sequencing (NGS). NGS is a general term used to describe all of the new and emerging screening techniques currently being introduced and used as part of PGD for IVF . NGS screens for single gene disorders as well as conducting extensive and very comprehensive chromosome diagnosis by sequencing, counting, and accurately assembling millions of DNA reads, simultaneously. <ref name="PMID23499002"><pubmed>23499002</pubmed></ref> There is a movement for NGS to replace the other limited testing techniques and be used as the standard. <br />
{|<br />
|- align="left" bgcolor="DDCEF2"<br />
|'''Procedure'''<br />
|}<br />
Samples are collected from either blastomere or the blastocyst/tropoectoderm and processed for analysis by a computer system. <br />
The methodology of each process is unique to the technique being used. <br />
<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="14" |'''Advantages''' <br />
|-bgcolor="FFFAFA" <br />
| Cost effective<br />
|-bgcolor="FFFAFA"<br />
| Opens new diagnostic possibilities<br />
|-bgcolor="FFFAFA"<br />
| Accurately tests all 24 chromosomes<br />
|-bgcolor="FFFAFA"<br />
| Tests for the presence of monogenic diseases of known genetic background<br />
|-bgcolor="FFFAFA"<br />
| Reduces the number of biopsies required for diagnosis<br />
|-bgcolor="FFFAFA"<br />
| Higher detection rate of small translocations<br />
|-bgcolor="FFFAFA"<br />
| Highly accurate is testing for compound point mutations, chromosomal duplication, deletions and insertions <ref name="PMID23312231"><pubmed>23312231</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| It accurately detects chromosomal aneuploidy and unbalanced rearrangement <ref name="PMID25685330"><pubmed>25685330</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Higher detection rate of small translocations<br />
|-bgcolor="FFFAFA"<br />
| NGS single gene disorder screenings can conducted in conjunction with PCR comprehensive chromosomal screening<br />
|-bgcolor="FFFAFA"<br />
| Reduces human error <br />
|-bgcolor="FFFAFA"<br />
| Better detects the presence of mosaicism<br />
|-bgcolor="FFFAFA"<br />
| Work well in conjunction with CGH and aCGH as part of PGD, improving the chances of IVF. <ref> Morris, R. S. (2015 ) Next generation sequencing for PCG|PGS|CCS. IVF1 retrieved from [http://www.ivf1.com/next-generation-sequencing for-pgd] </ref><br />
|-bgcolor="DDCEF2"<br />
| '''Disadvantages''' <br />
|-bgcolor="FFFAFA"<br />
| There are limited information available to clinical applications of NGS <ref><pubmed>26100406</pubmed></ref><br />
|}<br />
<br />
==Diagnosis==<br />
There are a large amount of diseases that PGD can apply to, below are descriptions of the diseases that PGD are more commonly used for. Upon completion of the genetic testing for the genes of concern the cells the embryos are discarded and priority is given to those that are healthy. <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/><br />
===Cystic Fibrosis===<br />
Cystic fibrosis is a single gene disorder. It is autosomal recessive and involves mutations in the cystic fibrosis transmembrane conductance regulator (CTFR) gene. The CTFR gene is normally responsible for the decrease in chloride and the transport of bicarbonate in epithelial cells thus playing a major physiological role. In PGD procedures, identification of the gene is assisted by microsatellite markers that have similar composition to the CTFR gene itself. Biopsy of two cells at the blastocyst stage is recommended if markers are not available. There are many variations of cystic fibrosis the most common being P.Phe508del <ref name="PMID26014425"><pubmed>26014425</pubmed></ref>.<br />
===Duchenne Muscular Dystrophy ===<br />
Duchenne Muscular Dystrophy is an X-linked recessive disease. It involves the Xp21 gene where majority of the mutations are chromosomal deletions with a smaller percentage resulting from duplications <ref name="PMID18359022"><pubmed>18359022</pubmed></ref>.<br />
<br />
===Autosomal Recessive Meckel-Gruber Syndrome===<br />
Autosomal recessive genetic defect caused by the TMEM67 gene. It results in cystic dysplasia of the kidneys with fibrotic change in the liber and occipital encephalocele. Other malformations could also be present in the central nervous system. In PGD whole genome amplification of single blastomeres are taken to identify the gene, this is also coupled with PCR techniques. Maternal plasma can also be extracted for PGS. <ref><pubmed>24039893</pubmed></ref> <br />
===β – Thalassemia=== <br />
β – Thalassemia is known as the most common type of autosomal recessive inherited disorder among haemoglobinopathies. It involves the adult β-globin gene and is associated with the absent or decreased expression of the gene. This is commonly caused by a single nucleotide change in the gene. PGD has been used successfully worldwide to identify the β-globin gene where its application is usually performed on a single blastomere or polar body <ref name="PMID19064120">19064120</pubmed></ref>.<br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
! Applicable diseases for PGD <ref>Genoma Group (2014). Retrieved September 18th, 2015, from http://www.preimplantationgeneticdiagnosis.it/genetic-diseases-diagnosed-by-pgd.htm </ref> <ref>Genesis Genetics (2015). Retrieved September 18th, 2015, from http://genesisgenetics.org/pgd/what-we-test-for/</ref> <ref>Human Fertilisation & Embryology Authority (2015). Retrieved Septembr 18th, 2015, from http://guide.hfea.gov.uk/pgd/</ref><br />
|-<br />
| '''Disease'''<br />
| '''Involved Genes'''<br />
|-<br />
| 5 Alpha Reductase Deficiency (5ARD)<br />
| SRD5A2 <br />
|-<br />
| Achondroplasia<br />
|FGFR3 <br />
|-<br />
| Acute Intermittent Porphyria <br />
| ALAD, ALAS2, CPOX, FECH, HMBS, PPOX, UROD, or UROS<br />
|-<br />
| Adrenoleukodystrophy (Adrenomyeloneuropathy)<br />
| ABCD1 <br />
|-<br />
| Agammaglobulinaemia (x-linked) <br />
|BTK <br />
|-<br />
| Agammaglobulinemia Bruton Tyrosine Kinase (BTK) <br />
|BTK <br />
|-<br />
| Aicardi Goutieres Syndrome 1 (AGS1) <br />
|TREX1, RNASEH2A, RNASEH2B, RNASEH2C, SAMHD1<br />
|-<br />
| Alagille Syndrome<br />
|JAG1 or NOTCH2<br />
|- <br />
| Alpers-Huttenlocher Syndrome <br />
|POLG <br />
|-<br />
| Alpha-1-antitrypsin deficiency <br />
|SERPINA1 <br />
|-<br />
| Alpha-Mannosidosis<br />
| MAN2B1 <br />
|-<br />
| Alpha Thalassemia <br />
|HBA1 or HBA2 <br />
|-<br />
| Alports Syndrome<br />
|COL4A3, COL4A4, COL4A5<br />
|-<br />
| Alzheimer's Disease - early onset (Type 3 and 4) <br />
|APP, PSEN1, or PSEN2<br />
|-<br />
| Amyotrophic Lateral Sclerosis 1 (ALS1) <br />
|C9orf72, SOD1, TARDBP, FUS, ANG, ALS2, SETX, VAPB <br />
|-<br />
| Argininosuccinic Aciduria <br />
| ASL<br />
|-<br />
| Arrhythmogenic Right Ventricular Cardiomyopathy/ Dysplasia (ARVC/D)<br />
| DSG2; DSP; PKP2<br />
|-<br />
| Ataxia Telangiectasia<br />
| ATM<br />
|-<br />
| Autosomal Recessive Meckel-Gruber Syndrome<br />
| TMEM67<br />
|-<br />
| Bardet-Biedl Syndrome (BBS)<br />
| BBS1; BBS10<br />
|-<br />
| Barth Syndrome<br />
| TAZ<br />
|-<br />
| Beta Thalassaemia<br />
| HBB<br />
|-<br />
| Birt-Hogg-Dubé Syndrome<br />
| FLCN<br />
|-<br />
| Breast Ovarian Cancer Familial Susceptibility (BRCA2)<br />
| BRCA1; BRCA2<br />
|-<br />
| Canavan Disease <br />
| ASPA<br />
|-<br />
| Carnitine-Acylcarnitine Translocase Deficiency <br />
| SLC25A20<br />
|-<br />
| Cerebral Arteriopathy with Subcortical Infarcts & Leukoencephalopathy (CADASIL)<br />
| NOTCH3<br />
|-<br />
| Cerebral Cavernous Malformation<br />
| CCM1<br />
|-<br />
| Charcot-Marie-Tooth Disease<br />
| GJB1; MPZ; NEFL; PMP22<br />
|-<br />
| CHARGE Syndrome<br />
| CHD7<br />
|-<br />
| Cherubism<br />
| SH3BP2<br />
|-<br />
| Choroideremia<br />
| CHM<br />
|-<br />
| Chronic Granulomatous Disease<br />
| CYBB; NCF1<br />
|-<br />
| Ciliary Dyskinesia<br />
| DNAH5<br />
|-<br />
| Citrullinemia<br />
| ASS1<br />
|-<br />
| Cleidocranial Dysplasia<br />
| RUNX2<br />
|-<br />
| Cockayne Syndrome<br />
| ERCC6<br />
|-<br />
| Congenital Adrenal Hyperplasia<br />
| CYP21A2<br />
|-<br />
| Congenital Cataracts<br />
| GJA8; VSX2<br />
|-<br />
| Congenital Diarrhea, Syndromic<br />
| SPINT2<br />
|-<br />
| Congenital Disorders of Glycosylation (CDG)<br />
| ALG1; ALG6; CDG1C; DOLK; PMM2<br />
|-<br />
| Cornelia de Lange Syndrome <br />
| NIPBL<br />
|-<br />
| Craniosynostosis<br />
| TWIST1<br />
|-<br />
| Crouzon Syndrome<br />
| FGFR2<br />
|-<br />
| Cysteinyl Leukotriene Receptor 1 Deficiency <br />
| CYSLTR1<br />
|-<br />
| Cystic Fibrosis<br />
| CFTR<br />
|-<br />
| Diamond –Blackfan Anemia <br />
| RPS19<br />
|-<br />
| Duchenne Muscular Dystrophy <br />
| DMD<br />
|-<br />
| Dyskeratosis congenita (Male embryos only)<br />
| DKC1<br />
|-<br />
| Ectodermal dysplasia (Hypohidrotic)<br />
| EDA; EDA1; GJB6; IKBKG<br />
|-<br />
| Familial Adenomatous polyposis coli (FAP)<br />
| APC<br />
|-<br />
| Familial Dysautonomia<br />
| IKBKAP<br />
|-<br />
| Fanconi Anemia <br />
| FANCA; FANCC; FANCD2; FANCF; FANCG; FANCJ<br />
|-<br />
| Fragile X Syndrome (FRAX)<br />
| FMR1<br />
|-<br />
| Galactosemia <br />
| GALT<br />
|-<br />
| Gangliosidosis<br />
| GLB1<br />
|-<br />
| Glanzmann Thrombasthenia <br />
| ITGA2B<br />
|-<br />
| Glutaric Acidemia (aciduria)<br />
| GCDH <br />
|-<br />
| Glycogen Storage Disease <br />
| G6PC; GAA; SLC37A4<br />
|-<br />
| Haemophilia A<br />
| F8<br />
|-<br />
| Haemophilia B<br />
| F9<br />
|-<br />
| Hereditary Nonpolyposis Colorectal Cancer: Lynch Syndrome<br />
| MLH1; MSH2; MSH6<br />
|-<br />
| Holt Oram Syndrome<br />
| TBX5<br />
|-<br />
| Huntington Disease<br />
| HD<br />
|-<br />
| Hydrocephalus<br />
| L1CAM<br />
|-<br />
| Ichthyosis <br />
| ABCA12; STS<br />
|-<br />
| Incontinentia Pigmenti (IP)<br />
| NEMO<br />
|-<br />
| Joubert Syndrome 5<br />
| INPP5E<br />
|-<br />
| Krabbe Disease<br />
| GALC<br />
|-<br />
| Leber Congenital Amaurosis (LCA)<br />
| CEP290; GUCY2D<br />
|-<br />
| Leigh Syndrome (Infantile Subacute Necrotising Encephalopathy)<br />
| LRPPRC<br />
|-<br />
| Lesch Nyan Syndrome<br />
| HPRT1<br />
|-<br />
| Leukocyte Adhesion Deficiency (Type I)<br />
| ITGB2<br />
|-<br />
| Li-Fraumeni Syndrome<br />
| TP53<br />
|-<br />
| Macular Dystrophy Retinal <br />
| VMD2<br />
|-<br />
| Maple Syrup Urine Disorder (MSUD)<br />
| BCKDHB<br />
|-<br />
| Marfan Syndrome <br />
| FBN1<br />
|-<br />
| Menkes Syndrome<br />
| ATP7A<br />
|-<br />
| Mitochondrial DNA Depletion Syndrom <br />
| POLG; RRM2B; SUCLA2; TK2<br />
|-<br />
| Mucolipidosis type II<br />
| GNPTAB<br />
|-<br />
| Multiple Endocrine Neoplasia<br />
| MEN1; MEN2A; MEN2B<br />
|-<br />
| Multiple Exostoses<br />
| EXT1; EXT2 <br />
|-<br />
| Myotubular myopathy<br />
| MTM1 <br />
|-<br />
| Nail-Patella Syndrome<br />
| LMX1B<br />
|-<br />
| Neurofibromatosis Type 1<br />
| NF1<br />
|-<br />
| Neurofibromatosis Type 2 <br />
| NF2<br />
|-<br />
| Noonan Syndrome<br />
| KRAS, PTPN11; SOS1<br />
|-<br />
| Norrie Disease<br />
| NDP<br />
|-<br />
| Ocular Albinism <br />
| GPR143<br />
|-<br />
| Oculocutaneous Albinism <br />
| OCA2; TYR <br />
|-<br />
| Oculodentaldigital Dysplasia<br />
| GJA1<br />
|-<br />
| Optic Atrophy<br />
| OPA1<br />
|-<br />
| Ornithine Transcarbamylase Deficiency <br />
| OTC<br />
|-<br />
| Osteogenesis imperfeca <br />
| COL1A1; COL1A2<br />
|-<br />
| Osteopetrosis <br />
| CLCN7; OSTM1; TCIRG1<br />
|-<br />
| Pachyonychia Congenita <br />
| KRT16; KRT6A<br />
|-<br />
| Pancreatitis, Hereditary<br />
| PRSS1 <br />
|-<br />
| Papillorenal syndrome <br />
| PAX2<br />
|-<br />
| Phenylketonuria <br />
| PAH <br />
|-<br />
| This table does not cover the complete list of diseases that PGD can be applied to.<br />
|}<br />
<br />
==Laws & Legal status==<br />
<br />
{| class="wikitable" <br />
|-bgcolor="DDCEF2"<br />
|'''Country'''<br />
|'''Legislation'''<br />
|-bgcolor="FFFAFA" <br />
| Australia<br />
| PGD is currently used to detect serious genetic conditions to improve the outcome of Assisted Reproductive Technologies (ART). In very rare cases it may be used to select an embryo with compatible tissue for a sibling who has a life-threatening disease where other means of treatment is unavailable. This is with the conditions that the use of PGD will not affect the welfare and interests of the child to be born. The parents must also receive adequate counselling and have full understanding of the procedures of PGD. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"> National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art</ref><br />
The use of PGD for sex-selection is prohibited with the exception of reducing the risk of the transmission of serious sex-linked genetic conditions. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"/><br />
|-bgcolor="FFFAFA"<br />
| Brazil<br />
| The laws regarding PGD in Brazil are not strictly regulated. They are vague and there is limited information surround the activities of assisted reproduction in general in the country <ref name="PMID25493379"><pubmed>25493379</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| Czech Republic<br />
| The laws in the Czech Republic allow those with a “defined indication in order to exclude risk of serous genetically conditioned disease and defects with embryos before they are implanted into the cavity of the uterus”. Couples that undergo any assisted reproductive treatment including PGD have to be married. Sex-selection is illegal except in regards to serious sex-linked genetic diseases <ref name="PMID24777348"><pubmed>24777348</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| Greece<br />
| In Greece, ART is open to those up to the age of 50 with written consent. It can only be used if a medical necessity is present such as the susceptibility of serious hereditary diseases. Sex selection is banned apart from cases of sex-linked diseases and sexually transmitted diseases <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| India<br />
| In India there is a cultural preference for boys thus the Prenatal Diagnostic Techniques (Regulation and Prevention of Misuse) Act was introduced in 1994. This law limits the use of PGD for sex determination except in cases of specific congenital diseases. These laws however are not strictly enforced. <ref>World Health Organisation (2015) Gender and Genetics Retrieved on October 21st 2015 from:http://www.who.int/genomics/gender/en/index4.html</ref><br />
|-bgcolor="FFFAFA"<br />
| Portugal <br />
| ART is only available to those who are married or have a similar type of relationship for at least two years. The couples cannot be of the same sex and must be at least 18 years of age. Sex selection is illegal except in cases of sex-linked diseases. The use of PGD is illegal if the predictive value of genetic tests are very low <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| Spain<br />
| PGD can be applied to “serious hereditary diseases not amenable to postnatal curative treatment” and “detection of other abnormalities which may compromise the viability of the pre-embryo”. If PGD is to be used for any other purpose authorisation must be acquired <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| Sweden <br />
| The use of PGD is strictly regulated and couples must achieve authorisation of the National Board of Health and Welfare. It can only be used it can only be used if the child is at risk to inheriting a serious chromosomal or monogenetic disease. It cannot be used for selection of specific characteristics <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| United Kingdom<br />
| Those involved with carrying out the IVF treatment must have a license from the Human Fertilisation and Embryology Authority (HFEA). Only embryos that are approved by the HFEA can be implanted where the embryonic nuclear or mitochondrial DNA cannot be altered with the exception of preventing mitochondrial diseases <ref name="PMID24777348"/>. <br />
|}<br />
<br />
==Future/Current Research==<br />
In addition to research efforts for improving overall performance of established PGD/S techniques, such as finding the ideal zona pellucida insection site in an fully automatic manner<ref name="PMID26259216"><pubmed>26259216</pubmed></ref>, many research efforts have been spent to find alternative, non-invasive techniques to test for diseases and abnormalities<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
===Non-invasive Preimplantation Genetic Testing without Embryo Biopsy===<br />
Different parameters of gametes, zygotes, embryos (“vacuoles in sperm heads, spindle position in mature oocytes, cleavage intervals of zygote, and embryo developmental dynamics”) may correlate with aneuploidy rates. This knowledge may be applied in potential noninvasive preimplantation diagnostic methods. Several methods have been proposed and are currently further researched<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Sperm Selection====<br />
Intracytoplasmic morphologically selected sperm injection (IMSI) is common procedure in IVF treatment to improve fertilization rates in patients with poor semen quality. In addition, studies have found that IMSI improves embryo development and that spermatozoa with large vacuoles in their heads correlate with increased aneuploidy rates and disturbed chromosomal structures. Thus, selecting spermatozoa based on morphological hallmarks may decrease aneuploidy rates in the fertilized embryos. As with polar body biopsies, however, this approach will solely be applicable if evidence for severe male detrimental contribution is given<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Blastocoel Fluid Extraction====<br />
In addition, a less invasive retrieval of material for diagnosis could include the extraction of the blastocoel fluid. The cavity of the blastocyst, lined by the trophectoderm, is filled with this blastocoel fluid, which contains metabolites of both trophectoderm and inner cell mass origin. The retrieval does not require a biopsy but merely a small opening to extract the fluid and, thus, causes less harm to the embryo. Multiple studies have applied this method<ref name="PMID22020776"><pubmed>22020776</pubmed></ref> <ref name="PMID23148560"><pubmed>23148560</pubmed></ref> <ref name="PMID26006737"><pubmed>26006737</pubmed></ref> and it may in the future become of clinical relevance.[[File:Aspiration_of_the_Blastocoel_Fluid.jpeg|400px|thumb|Aspiration of the Blastocoel Fluid using a ICSI pipette<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.]]Next to metabolites, the blastocoel fluid can contain DNA. Studies have shown that genomic DNA is present in about 90% of the blastocoel fluid samples tested. Typically the fluid is removed with an ICSI pipette from a day five blastocyst through its mural trophectoderm until the blastocyst fully collapses around the embryo. Several concerns regarding this method in a clinical setting have been raised. The collected DNA may be contaminated by the culture media that contains DNA fractions. The DNA may also be least representative of the actual embryos genome as the DNA may originate from abnormal or degenerated cells. Even though labelled noninvasive, the blastocyst still undergoes manipulation to some degree which may affect its viability. Thus, more research is required until this method can evolve from research to clinical use<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
====Proteomics and Medium Based PGD====<br />
The media in which embryos are kept during the early IVF procedures, gives rise to potential non-invasive techniques. For instance, the protein secretome of blastocysts may be representative of its chromosome constitution Recent studies have found biomarkers such as lipocalin-1, interleukin-10, tumor necrosis factor, stem cell factor, and chemokine ligand 13 to be differently secreted by aneuploid blastocyst than by euploid ones. The most significant biomarker appears to be interleukin-10. Paired with novel proteomic technologies and mass spectrometry this knowledge when extended may contribute to a new invasive PGD method<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. In addition, medium based non-invasive PGD has been researched for the diagnose of human α-thalassemia-SEA. Genomic DNA was collected from the media and the study surprisingly resulted in increased diagnosis efficacy compared to biopsy-based methods<ref name="PMID25816038"><pubmed>25816038</pubmed></ref>.<br />
====Embryo Morphology====<br />
Using time lapse imaging the embryo’s morphology can be closely observed and potential aneuploidy characteristics detected. Such characteristics may include the time of division to five cells, the time between the division from three to four cells, and the duration of the division from one to two and subsequently to three. In addition, the morphological quality of ICM an TE has been positively associated with aneuploidy or euploidy prognosis<ref name="PMID26246880"><pubmed>26246880</pubmed></ref>. These may give rise to an embryo quality screening prior to implantation<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
==Glossary==<br />
'''Biopsy:''' sample of tissue taken for examination <br />
<br />
'''Blastocyst:''' Stage of embryo at approximately day 5 consisting of an outer (trophoblast) layer and inner (embryoblast) cell mass. <br />
<br />
'''Blastomere:''' Initial cells formed through mitosis of the zygote<br />
<br />
'''CTFR''' Cystic Fibrosis Transmembrane Conductance Regulator, responsible for transport of chloride across the cell membrane<br />
<br />
'''Fluorescent In situ hybridisation:''' technique use to locate specific gene sequences using fluorescence tags <br />
<br />
'''Intracytoplasmic Morphologically Selected Sperm Injection (IMSI):''' IVF technique involving morphological selection of sperm under the microscope to be injected to oocyte<br />
<br />
'''Intracytoplasmic Sperm Injection (ICSI):''' IVF technique used to treat male infertility and involves direct injection of one sperm into an oocyte<br />
<br />
'''Next Generation Sequencing (NGS):''' Term used to describe the collection of recent findings regarding embryo screening<br />
<br />
'''Polar bodies:''' cell formed during the meiotic stages of the oocyte containing extra genetic material <br />
<br />
'''Polymerase Chain Reaction (PCR):''' Technique used to amplify DNA to study a specific genetic sequence<br />
<br />
'''Preimplantation Genetic Diagnosis (PGD):''' Involves genetic testing conducted to identify abnormalities in an embryo before implantation.<br />
<br />
'''Preimplantation Genetic Screening (PGS):''' Involves genetic screening for genetic abnormalities using techniques such as FISH and PCR to eliminate unhealthy embryos <br />
<br />
'''Robertsonian Translocations:''' Type of structural chromosomal translocation <br />
<br />
<br />
<br />
==References==<br />
<br />
<references/><br />
<br />
<br />
{{StudentPage2015}}</div>Z5017878https://embryology.med.unsw.edu.au/embryology/index.php?title=2015_Group_Project_6&diff=2080412015 Group Project 62015-10-23T02:23:59Z<p>Z5017878: </p>
<hr />
<div>{{ANAT2341Project2015header}}<br />
<br />
<br />
=Preimplantation Genetic Diagnosis and Preimplantation Genetic Screening=<br />
==Introduction==<br />
Preimplantation genetic diagnosis (PGD) and preimplantation genetic screening (PGS) are reproductive options for couples with known family histories of genetic disease or couples undergoing IVF procedures due to infertility issues. PGD can diagnose many genetic disorders caused by known chromosomal abnormalities (number and/or structure) or single gene mutations, and, thus decrease the risk of termination of pregnancy or miscarriages and enable such couples to have an unaffected child<ref name="PMID24907939"><pubmed>24907939</pubmed></ref>. Through major improvements in PGD/S and general laboratory technology, the testing for abnormalities in fetuses has shifted from prenatal diagnosis during the first 2 trimesters <ref> Blackburn, S.L. (2003) '''Maternal, Fetal & Neonatal physiology: a Clinical perspective''' (2nd ed.). Seattle: Saudners </ref>, testing for overall fetal growth, complications of pregnancy, and birth defects<ref> Sadler T.W.(2012) '''Langman's Medical Embryology''' (12th ed.) Philadelphia: Lipincott, Wiliams & Wilkins, a Wolters Kluwer Business </ref>, to an embryonic focus especially in advancements in Artificial Reproductive Technologies (ART)<ref><pubmed>20638568</pubmed></ref>. In 1990 PGD for a recessive X-linked disease resulted in the first live birth<ref><pubmed>2330030</pubmed></ref> and has since been incorporated in clinical routine and applied for a variety of genetic diseases, such as sickle cell anemia, thalassemia, or cystic fibrosis<ref name="PMID24907939"/>.<br />
[[File:Preimplantation Genetic Diagnosis Procedure.jpeg|600px|left|thumb| Simplified steps for PGD<ref name="PMID24907939"/>]]<br />
{|class="wikitable"align="right" <br />
| <html5media height="400" width="533">https://www.youtube.com/watch?v=0e-79qKllqk</html5media><br />
|-<br />
| Preimplantation Genetic Diagnosis<ref>IVF Florida (2011, December 11) IVF Florida - South Florida Fertility Specialists - Pre-Implantation Genetic Diagnosis [Video file]. Retrieved from https://www.youtube.com/watch?v=0e-79qKllqk</ref><br />
|}<br />
<br />
==History==<br />
The advances in reproductive technology during the second half of the 20th century, led to PGD's first clinical application in 1990 <ref>Harper, J. (n.d.). The history of PGD. Lecture. UCL Centre for PG&D and CRGH.University College London</ref>.<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
|Year<br />
|<br />
|- bgcolor="FFFAFA"<br />
| '''1967''' <br />
|First PGD on rabbit blastocysts (Gardner& Edwards) <ref name="PMID6036172"><pubmed>6036172</pubmed></ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1986''' <br />
|First Cleavage Biopsy (Wilton & Trounson)<ref>Wilton, L. J., & Trounson, A. O. (1986). Viability of mouse embryos and blastomeres following biopsy of a single cell. In Proceedings of the 18th Annual Conference of the Australian Society for Reproductive Biology, Brisbane, Australia.</ref><br />
|- bgcolor="FFFAFA"<br />
|'''1987''' <br />
|First Blastocyst Biopsy (Muggleton-Harris, Monk, Rawlings, & Whittingham)<ref name="PMID3372699"><pubmed>3372699</pubmed></ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1988''' <br />
|First Polar Body Biopsy (Yury Verlinksy)<ref> Verlinsky, Y., Pergament, E., Andresen, P., Enriquez, G., & Strom, C. (1989). Genetic analysis of polar body DNA: A new approach to preimplantation genetic diagnosis. Am J Hum Genet, 45(4), A272.</ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1990''' <br />
|First Clinical PGD using PCR testing for X-linked (Handyside, Kontogianni, Hardy, & Winston)<ref name="PMID2330030"><pubmed>2330030</pubmed></ref> <br />
|} <br />
==Preimplantation Genetic Diagnosis==<br />
PGD is used to test the genetic makeup of embryos to detect single gene disorders, chromosomal abnormalities and mitochondrial disorders. It also has applications in gender selection for diseases with unequal gender distributions <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Some diseases commonly involved with PGD include cystic fibrosis, spinal muscular atrophy and beta – thalassaemia <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press.">Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press</ref> <ref name="PMID17823145"><pubmed>17823145</pubmed></ref>. It was first used in the United Kingdom in the 1980s of arenoleucodystrophy and primarily focusing on sex- linked disorders <ref name="PMID17823145"/><ref name="PMID23150080"><pubmed>23150080</pubmed></ref>. PGD is now capable of detecting single cell defects (molecular) and chromosomal disorders resulting from the inversion, translocation or deletion of chromosomes (cytogenic) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>,<ref name="PMID11325751"><pubmed>11325751</pubmed></ref>. PGD can be applied to the embryo at different stages. That is on polar bodies, blastomeres or blastocyst <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>.<br />
Depending on the type of genetic disorder, PGD utilises different methods of genetic testing. These include Fluorescence in situ hybridisation (FISH) which is used for sex – linked disorders and detects chromosomal rearrangements <ref name="PMID11325751"/><ref name="PMID17876073"><pubmed>17876073</pubmed></ref> and Embryo halotyping which allows the identification of chromosomes causing the inherited disorder through knowledge of the pattern of closely linked markers <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. Polymerase chain reaction (PCR) is also widely used to detect molecular abnormalities <ref name="PMID11325751"/>.<br />
PGD is tightly regulated and supported by large organisations namely The American Society for Reproductive Medicine, The European Society for Human Reproduction and Embryology (ESHRE), The European Society of Human Genetics and the Preimplantation Genetic Diagnosis International Society <ref name="PMID25500181><pubmed>25500181</pubmed></ref>.<br />
===Sex-linked disorders===<br />
The determination of a disease as gender specific usually correlates with the presence or absence of specific genes such as SRY on the Y chromosome. It is known that females have two X chromosomes and males have an X and a Y chromosome where abnormalities are more prevalent on the X chromosome. PGD can be used for sex selection where only male embryos are transferred to reduce the chance of inheriting X-linked disorders. However, this does not completely eradicate the problem as male embryos remain susceptible to inheriting an affected X chromosome. Sex determination is only used when the specific mutation is unknown and has yet to be discovered <ref name="PMID24866878"><pubmed>24866878</pubmed></ref>.<br />
===Single gene defects===<br />
Single gene defects can be dominant, recessive, autosomal or X-linked. They are commonly diagnosed using PCR and although the PCR available today is complex and capable of combatting a large range of disease the development of new protocols has been proven to be difficult due to the small DNA sample available <ref name="PMID26168107"><pubmed>26168107</pubmed></ref><br />
===Mitochondrial disorders===<br />
Mitochondrial disorders also known as oxidative phosphorylation disorders arise from mutations in the nuclear DNA or mitochondrial DNA <ref name="PMID26312584"><pubmed>26312584</pubmed></ref>. They pose as a problem because they are unrecognisable until the mutations in the cell reach a detrimental level <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Mitochondrial disorders cause miscarriages and stillbirths as well as death in children and young adults. The effects can either be contained in a single organ or more commonly involve multiple organ failure where organs with high energy demands such as the brain, liver muscle and heart and heavily influenced. They are usually occur spontaneously or result from inheritance from the mother. Since mitochondria are solely inherited from the mother oocyte donations have been used as a solution to combat mitochondrial disorders. Additionally, there has been an increasing use in PGD where embryos that stay under the given threshold of 18% gene-mutations are allowed to be transferred and result in normal development. New technology in the areas of nuclear gene transfer and genome editing are also being experimented with <ref name="PMID26312584"/>. <br />
===Chromosomal disorders===<br />
Chromosomal disorders can be reciprocal, Robertsonian translocations, inversions, deletions and insertions <ref name="PMID26168107"/>. . Data from ESHRE collected between 2010 and 2011 has shown that the most common chromosomal abnormality confronted in PGD are reciprocal chromosomal abnormalities <ref name"PMID26071418"><pubmed>26071418</pubmed></ref>. PGD has also been used successfully for Robertsonian translocations (RT), a type of structural translocation. Children who carry RT are phenotypically normal, however in their later years it is found that they will suffer from infertility and repeated miscarriages due to the high frequency of abnormal embryos <ref name="PMID22081077"><pubmed>22081077</pubmed></ref>. PCR and FISH are the two main techniques used for chromosomal disorders. To be able to conduct the examinations the cells are required to be at the metaphase stage <ref name="PMID26168107"/>. <br />
[[File:Reasons_for_PGD.jpg|600px|thumb|Reasons for PGD<ref name= "PMID24764761"><pubmed><24764761</pubmed></ref>]]<br />
==Preimplantation Genetic Screening==<br />
PGS involves an array of methods or ideas that aim to segregate embryos that have genetic flaws and those that are healthy <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. The occurrence of aneuploidy is high around the stages of early embryonic development and they are the most common cause if miscarriages and congenital birth defects <ref name= "PMID26085841"><pubmed>26085841</pubmed></ref>. They have little effect on the morphology of the embryo making them difficult to identify thus identification heavily relies on genetic testing <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. <br />
Genetic sampling is most commonly conducted using Microarray Comparative Genomic Hybridisation (aCGH) as well as FISH, Quantitative PCR and Single Nucleotide Polymorphism (SNP) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. These methods collectively aim to assess numeral and structural chromosomal errors <ref name= "PMID26085841"/>. Studies have also introduced Next- Generation Sequencing (NGS) <ref name= "PMID26085841"/> and Whole Genome Amplification used to screen imbalances in the complete 24-chromosomes <ref name="PMID25953353"><pubmed>25953353</pubmed></ref><br />
Statistics from ESHRE have shown that the most common indications for PGS is advanced age, followed by repeated implantation failure or recurrent miscarriage and male infertility <ref name="PMID26071418"><pubmed>26071418</pubmed></ref>.<br />
===Indications===<br />
A low percentage of structural abnormalities in chromosomes are responsible for the cause of miscarriages. Despite this, they are the most prevalent type of chromosomal abnormality accounted for in PGD <ref name="PMID20638568"/>. The presence of specific gene cycles, initiation of embryonic protein synthesis and evident physiological development are all indicative of a successful in vitro fertilisation procedure <ref name="PMID11576737"><pubmed>11576737</pubmed></ref>. To eliminate further errors from occurring during the PGD procedure it is recommended to undertake further prenatal testing such as amniocentesis in the later stages <ref name="PMID20638568"/>. <br />
====Advanced maternal age====<br />
Data provided by the ESHRE has shown that the mean age of women undergoing PGS is 39 years <ref name="PMID26071418"/>. Women of advanced age have been shown to have a lower rate of pregnancies reaching childbirth <ref name="PMID18583331"><pubmed>18583331</pubmed></ref>. The highlighted concern revolves around the increased occurrence of aneuploidy following maternal age. The optimal age range for the lowest aneuploidy incidence was found to be between 27 to 37 years of age (6%) then progressively higher in women aged up to 42 (33%) and most common in those 44 and above (53%) <ref name="PMID24355045"><pubmed>24355045</pubmed></ref>. <br />
====Recurrent pregnancy loss / IVF failure====<br />
Recurrent pregnancy loss is defined as three or more IVF failures after cumulative transfer of more than 10 good-quality embryos. These are primarily caused by two main factors, reduced endometrium receptivity or embryonic defects. Endometrium receptivity can be negatively influences by instances including uterine pathologies such as thin endometrium, altered expression of adhesive molecules and immunological factors. Additionally, embryonic defects may be due to genetic abnormalities, embryonic aneuploidy or zona hardening. Endometriosis and hydrosalpinx has been known to effect both the endometrium and embryo <ref name="PMID23260857"><pubmed>23260857</pubmed></ref>.<br />
====Human leukocyte antigen matching====<br />
First used in 2001, HLA matching is an option given to parents to save a child with haematological or immunological disease through conceiving another child who would potentially be able to donate cord blood or haematopoietic stem cells from the bone marrow for transplantation. The process namely PGD-HLA has shown to improve haematopoietic stem cell transplant (HSCT). PGD-HLA can only be performed when HSCT is not needed urgently due to the time needed to conceive and delivery the baby <ref name="PMID25500181"><pubmed>25500181</pubmed></ref>. It is most commonly applied to children suffering from relapsed leukaemia <ref name="PMID22524201"><pubmed>22524201</pubmed></ref>. In a case study PGD-HLA was proven to successfully cure 10 diseases including Fanconi anaemia, Diamond-Blackfan anaemia and beta thalassemia <ref name="PMID25066893><pubmed>25066893</pubmed></ref>.<br />
==Biopsy Methods==<br />
Biopsy, the removal of genetic materials, from oocytes or embryos in the preimplantation stage is the primary step in PGD. For the past two decades these biopsies have been performed at three stages, the polar body, blastomere, and blastocyst, and the methodologies optimized to ensure the embryo’s viability. The most common approach involves biopsies at the cleavage stage. However, polar body and blastocyst biopsies are increasingly more often tested and applied. Approached for opening the zona pellucida involve next to the traditional mechanical and chemical means, novel approaches such as noncontact lasers. Their application may simplify and secure the procedure significantly. The most challenging question about PGD procedures remains at what stage biopsies should be taken. Much controversy has developed around this topic, highlighting the varying disadvantages and advantages of temporal biopsies. <ref name="PMID22723007"><pubmed>22723007</pubmed></ref><br />
<br />
[[File:Polar_Body,_Blastomere,_and_Trophectoderm_Biopsy.jpeg|400px|thumb|Polar body (A), blastomere (B) and trophectoderm (C) biopsies<ref name="PMID25625041"><pubmed>25625041</pubmed></ref>.]]<br />
{| class="wikitable"<br />
|- align="center" bgcolor="DDCEF2"<br />
|<br />
| Time of Biopsy<br />
| Advantages <br />
| Disadvantages<br />
|- bgcolor="FFFAFA"<br />
| Polar Body<br />
| Day 1<br />
| No harm to oocyte<br />
| Only maternal DNA is tested, often needs to be coupled with other biopsies, and there are difficulties distinguishing between the first and second PB.<br />
|- bgcolor="FFFAFA"<br />
| Blastomere<br />
| Day 3<br />
| …<br />
| … <br />
|- bgcolor="FFFAFA"<br />
| Trophectoderm<br />
| Day 5 and 6 <br />
| Little harm to the embryo and large amount of genetic material is extracted. <br />
| Opening of blastocyst necessary, small time window for procedure<br />
|}<br />
===Polar Body Analysis===<br />
Day 1<br />
====Description====<br />
Polar body (PB) biopsy offers a promising alternative to biopsies performed at the blastomere stage for PGD/S indications on legal and practical grounds. Consequent embryo development does not necessitate the presence of the first and second PB and their removal may not be crucial. PB biopsy requires precise timing. Keeping track of the meiotic cell cycle is necessary to perform a successful biopsy and, therefore, PB biopsy usually is applied in combination with intracytoplasmic sperm injection (ICSI). During the maturation from the germinal vesicle stage to the metaphase-II stage the first PB is formed. A cytoplasmic bridge containing spindle remnants, that are still in contact with the cellular genetic material, links this PB to the oolemma for about 90 minutes after extrusion. It is possible to visualize these remnants by polarization microscopy and it is crucial to not perform the biopsy until the first PB is no longer firmly attached to the oolemma as this indicates an immature embryo.The oocyte tolerates mechanical zona dissection best during hours four until six after ICSI as the oolemma has stabilized by that time because of the cortical granule reaction. Over time the first PB degenerates stressing a temporal biopsy and its optimal extraction time window is four to 12 hours after ICSI. The second PB forms around two to four hours after ICSI. Its optimal time window for biopsy is set to be eight to 16 hours after ICSI due to the second PB being attached to the oolemma with spindle remnants until six hours after ICSI. Biopsy at this point may cause enucleation of the oocyte. Studies have shown that the amplification efficiency of second PB’s DNA is worse if the PB is extracted prior to eight hours after ICSI. Thus, it is possible to perform sequential and simultaneous biopsies for the first and second PB. If performed, sequentially the first PB may be removed four to 12 hours and the second PB eight to 16 hours after ICSI. The optimal time window for a biopsy for both the first and second PB simultaneously is eight to 12 hours after ICSI. It is highly preferred to analyze both PBs due to potential aneuploidies in either PB and crossing overs during meiosis<ref name="PMID22723007"/>. <br />
====Procedure====<br />
Chemical opening achieved with for example acidic tyrode’s solution of the zona pellucida is not tolerated by the oocyte and may have detrimental effects on the embryo’s development. Therefore, the access to the perivitelline space of the oocyte is provided by mechanical zona dissection or by laser. Both techniques work well if performed by experienced embryologist. However, laser-assisted biopsy is less time consuming when compared to manual dissection. It is critical to consider the size of the introduced opening as it will remain permanent. If it is too large the blastomere may be lost during embryo development and if it is too small it may interfere with hatching of the embryo during blastocyst stage<ref name="PMID22723007"/>.<br />
[[File:Polar_Body_Biopsy.jpeg|left|thumb|The presence of a faint but clearly identifiable strand connecting PB2 to the oolemma. The biopsy was performed ∼9 h after ICSI<ref name="PMID21908464"><pubmed>21908464</pubmed></ref>.]]<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JTaQzszVr8o</html5media><br />
|-<br />
| Laser-assisted polar body biopsy<ref>RIUK, R. (2013, June 25) Polar Body Biopsy [Video file]. Retrieved from https://www.youtube.com/watch?v=JTaQzszVr8o</ref><br />
|}<br />
====Advantages & Disadvantages====<br />
PB biopsies can only investigate the maternal contributions to the embryo as they are of maternal origin. Thus, this procedure is appropriate for PGD solely for monogenetic diseases from the maternal side. Recessive diseases may be evaluated with PB biopsies on the basis that the embryo’s outcome will be determined by the paternal contribution. It may still be applied for PGS as it is a fairly safe biopsy option and most aneuploidies either arise during meiosis or origin from the maternal genome. However, diagnosis error has been reported due to the lack of considering paternal contributions.Because PB biopsies are performed very early it is not yet known whether the oocyte will develop into a viable embryo. Thus, PBs are commonly frozen or fixed after biopsy and depending on the state of the embryo only chosen PBs will be tested. This is primarily an economic issue as many genetic testing procedures are very cost-intensive<ref name="PMID22723007"/>[[File:Implantation_predictive_value_of_euploid_screening_results.jpeg|thumb|The sustained implantation predictive value (with 95 % confidence interval) of a euploid screening result obtained from the first polar body (PB1), PB1 and the second polar body (PB2), or a direct embryo biopsy for each stage of embryo transfer (cleavage-stage and blastocyst stage)<ref name="PMID25106935"><pubmed>25106935</pubmed></ref>.]] Generally the sustained implantation predictive value of screening of PBs is significantly lower than of for example biopsies of the blastocyst stage<ref name="PMID25106935"/>. Moreover, it is often difficult to distinguish between the first and the second PB. As the first one degenerates quicker, this may influence diagnostic procedures<ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
===Blastomere biopsy===<br />
Day 3 <br />
====Description====<br />
Blastomere biopsy has been the prevalent method for PGD and PGS in the last two decades. At least one, but up to two, blastomeres are biopsied on day three of the cleavage stage embryo. The right number of blastomeres removed is a controversial topic as two cells allow for more genetic material and more accurate results. However, removing two cells might be too invasive and damaging to the embryo. As PGS tries to improve implantation rates, whereas PGD sets out to avoid known genetic disorders, for the former only one cell is removed, while for the latter often two need to be removed, to ensure results as correct as possible<ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
====Procedure====<br />
Initially a hole was drilled into the zona pellucida using acid tyrodes with the consequent aspiration of blastomeres with a pipette. Nowadays the zona pellucida is largely opened using a laser and calcium and magnesium free media have been introduced to decrease junctions between blastomeres, which facilitates the biopsy<ref name="PMID21748341"/>.<br />
[[File:Aspiration_of_a_Blastomere.jpeg|thumb|Aspiration of a Blastomere into the biopsy pipette<ref name=" PMID24783200"><pubmed>24783200</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=TbridWVwipI</html5media><br />
|-<br />
| Laser-assisted blastomere biopsy<ref>Sukprasert, M. (2014, March 5) Day 3 Blastomere Biopsy 1 [Video file]. Retrieved from https://www.youtube.com/watch?v=TbridWVwipI</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
===Trophectoderm biopsy===<br />
Day 5 and 6<br />
====Description====<br />
The improvement of embryo culture media allowed the in vitro development of human embryos until the blastocyst stage and opened up the possibility to take blastocyst biopsies. During day three to day five the haploid maternal and paternal genomes work together for the first time to form the genome of the embryo. The maternal epigenetic control lessens significantly while preparing for implantation with precisely arranged events happening. The first event includes a rapid increase in the number of embryonic cells which are active in mitotic divisions and apoptosis of aberrant cells. This is followed by the formation of blastocoel (cavitation) which results from the flattening of cell located on the outside of the blastomere. Now the blastocyst will expand until the embryo hatches by rupturing the zona pellucida. The cells of the blastocyst will differentiate to form two distinct cell lineages, the outer trophectoderm and the inner cell mass<ref name="PMID22723007"/>.<br />
====Procedure====<br />
Trophectoderm biopsy is usually performed in Hepes buffered biopsy medium and opening approaches include needle cutting which has been replaced by lasers in past years. Different research groups report different timings of the opening to be the most successful. Some open the blastocyst on day three or four by creating a 25 µm which causes the trophectoderm to herniate through this hole and is, thus, accessible for biopsy. Others create this hole about four hours before biopsy which allows sufficient herniation of trophectoderm cells. It is also possible to open the blastocyst immediately before biopsy. This avoids an extra step and the inner cell mass usually is easy to locate. Blastocyst biopsies involve the removal of trophectoderm cells and the ideal time for the procedure is day five. Successful biopsies on day six have been performed, while little is known about the results of biopsies on day seven. However, since the window of implantation in humans is from day eight to ten after ovulation, day seven biopsies appear to be possible<ref name="PMID22723007"/>.<br />
-collapse of trophoblasts<br />
-possible: biopsy of hatched blastocyst, holding pipette careful mild suction force to hold embryo near ICM <br />
-Cryopreservation<br />
<br />
<br />
[[File:Microscopic images of human blastocysts for biopsy.jpeg|thumb|(A) Some trophectoderm cells in a blastocyst started to hatch and (B) the trophectoderm cells were biopsied with assisted laser cutting. Images in C–D show the blastocysts after vitrification and warming. Blastocysts had been cultured for 2–4 hrs after warming, showing good (ICM and trophectoderm cells) hatched (C) and hatching (D) blastocysts. The hatching blastocyst in (E) has good ICM but fair trophectoderm while the blastocyst in (F) has both fair ICM and trophectoderm. Arrows indicate ICMs and arrow heads indicate trophectoderm cells. Bar = 40 µm<ref name="PMID2190846"><pubmed>2190846</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JI_TQ8d8tNM</html5media><br />
|-<br />
| Laser-assisted blastocyst biopsy (at 00:50 min)<ref>Coco, R. (2014, April 30) Trophectoderm biopsy in a Hatching blastocyst protruding ICM [Video file]. Retrieved from https://www.youtube.com/watch?v=JI_TQ8d8tNM</ref><br />
|}<br />
<br />
====Advantages & Disadvantages====<br />
Blastocyst biopsies are believed to be less damaging to the embryo and appear to be unrelated to implantation rates. In addition, this biopsy method allows for a larger extraction of cells for genetic testing. However, since they are performed late in in vitro development, the time window for genetic testing is relatively small. Fast and accurate genetic testing methods are needed to ensure a successful and safe result from this biopsy. Thus, blastocyst biopsies may gain more popularity in the future when such methods have been developed or improved<ref name="PMID22723007"/>. <br />
==Genetic Techniques==<br />
===Polymerase Chain Reaction===<br />
PCR amplifies DNA specific to genetic sequence of interest . PCR was developed by Kay Mullis in the 1980's, for which he was awarded the Nobel prize for chemistry in 1993. <ref> Pubmed Docs (2015) Polymerase Chain Reaction (PCR) Pubmed. Retrieved from [http://www.ncbi.nlm.nih.gov/probe/docs/techpcr/]</ref> This technique enables clinicians to monitor and diagnose diseases using minute samples such as embryonic cells. <ref>Roche (2015) PCR: How We Copy DNA. Roche Molecular Systems Inc. retrieved From [http://molecular.roche.com/pcr/Pages/Process.aspx]</ref>. PCR is used to detect genetic disorders, as a part of PGD, in conjunction with IVF<ref name="PMID24301057"><pubmed>24301057</pubmed></ref>. It is used to detect molecular abnormalities, such as single gene disorders including Tay Sach, Cycstic fibrosis, Duchenne Muscular Dystrophy, Thalassemia, Huntington disease, Spinal muscular atrophy and many more. Molecular and genetic analysis require a significant amount of DNA, which can be delivered by PCR. It revolutionized the study of DNA, replacing all previous recombinant DNA technology and is a significant component of PGD procedures<ref name="PMID24907939"/>.<br />
<br />
[[File:PCR.jpg|thumb|PCR amplifies DNA specific to genetic sequence of interest, enabling the monitoring and diagnose molecular abnormalities such as single gene disorders using minute samples such as embryonic cells, blood & tissue <ref name="NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute">NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref>]]<br />
{|<br />
|- align="left" bgcolor="DDCEF2"<br />
|'''Procedure'''<br />
|}<br />
Samples are obtained from the the blastocyst, a polar body biopsy or the blastomeres stages of the embryo. <br />
*Stage 1 Denaturing: separating the target strands of DNA <br />
The obtained sample is heated to roughly 90 degrees celcius, this heat breaks the relatively weak bonds between nucleotides that form DNA. The double stranded DNA is split into two single strands of DNA that are used as templates.<br />
*Stage 2 Annealing: Binding the Primers to the target DNA sequence <ref name="PMID25250056"><pubmed>25250056</pubmed></ref><br />
PCR will only copy the target sequence of DNA specified by specific PCR primer. These synthesized primers oligonucleotides are small artificial pieces of DNA. TAQ polymerase enzyme synthesize two new strands of DNA duplicate to the single sample DNA stand template indicated by these primers. During this stage the reaction is cooled to a temperature between 40-60 degrees Celsius. <br />
*Stage 3- Extension- making copies <br />
Each of these two copies are then used again as templates generating two further replications This cycle can occur as many 30 -40 times within a couple hours leading to billions of extra copies of the original DNA segment. Generally the optimal temperature for the further replication is roughly 72 degrees Celsius, although, this may vary according to the analysis machines used. <ref name="PMID26092180"><pubmed>26092180</pubmed></ref><br />
This process mediated by a thermocycler machine that is programmed to alter the temperature of the reaction every couple of minutes, perpetuating the cycle of DNA denaturing and synthesis. <br />
This process, generates exponentially exact copies of the original template DNA sequence. <ref> Mullins, K., Francois, F.& Gibbs R.A. (1994 ) The Polymerase Chain Reaction. p3. Springer- Science +Business Media. Birkhauser, Boston<br />
Available at [https://books.google.com.au/books?hl=en&lr=&id=gjrTBwAAQBAJ&oi=fnd&pg=PR5&dq=kary+mullis+PCR&ots=mpzAyRh5ZY&sig=PQ4goNoKJ90tb3-MkPk62zrTGbw#v=onepage&q=kary%20mullis%20PCR&f=false] </ref><br />
<br />
<br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
!PCR cycles<br />
|-<br />
| '''PCR Cycle'''<br />
| '''Target Copies'''<br />
|-<br />
| 1<br />
| 2<br />
|-<br />
| 2<br />
| 4<br />
|-<br />
| 3<br />
| 8<br />
|-<br />
| 4<br />
| 16<br />
|-"<br />
| 5 <br />
| 32<br />
|-<br />
| 6 <br />
| 64<br />
|-<br />
| 7 <br />
| 128<br />
|-<br />
| 8<br />
| 256<br />
|- <br />
| 9<br />
| 512 <br />
|-<br />
| 10<br />
| 1024<br />
|-<br />
| 15<br />
| 32,768<br />
|-<br />
| 20 <br />
| 1,048,578<br />
|-<br />
| 25<br />
| 33,554,432<br />
|-<br />
| 30 <br />
| 1,073,741,842<br />
|-<br />
|}<br />
<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="7" |'''Advantages'''<br />
|-bgcolor="FFFAFA"<br />
| Fast and inexpensive way of copying a target sequence of DNA.<br />
|-bgcolor="FFFAFA"<br />
| Particularly useful for the diagnosis of single cell defects.<br />
|-bgcolor="FFFAFA"<br />
| Rapid generation of results (within hours).<br />
|-bgcolor="FFFAFA"<br />
| Highly sensitive, a single molecule of DNA is sufficient for reaction.<br />
|-bgcolor="FFFAFA"<br />
| Generates DNA copies exponentially.<br />
|-bgcolor="FFFAFA"<br />
| This enables DNA amplification required for molecular and genetic diagnostic analysis<ref> Dreesen, J., Drusedaul, M., Smeets, H., Die-Smulders, C., Coonen, E., Dumoulin, J., Gielen, M., Evers, J., Herbergers, J. & Geradets, J. (2008) Validation of preimplantation genetic diagnosis by PCR analysis: genotype comparison of the blastomere and corresponding embryo, implications for clinical practice. Mol. Hum. Reprod. 14 (10):573-579.doi: 10.1093/molehr/gan052. Retrieved from [http://molehr.oxfordjournals.org/content/14/10/573.short] </ref> <ref><pubmed>20966460</pubmed></ref>.<br />
|-bgcolor="DDCEF2"<br />
| rowspan="7"|'''Disadvantages'''<br />
|-bgcolor="FFFAFA"<br />
| Only during the exponential DNA replication phase, the starting quantity sequence contained in the original sample (template DNA strand) can be determined.<br />
|-bgcolor="FFFAFA"<br />
| PCR reaction is limited to by presence of inhibitors in the sample.<br />
|-bgcolor="FFFAFA"<br />
| Self annealing due to the accumulation of the product and the stopping exponential amplification for the target sequence and reaching of a plateau<br />
quantification of the end point of reaction of PCR products make real time quantitative RT-PCR necessary<ref name="NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute">NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref>.<br />
|-bgcolor="FFFAFA"<br />
| Not a diagnostic method on its own, but requires further analysis.<br />
|-bgcolor="FFFAFA"<br />
|Low-quantity DNA template may result in amplification failure<ref name="PMID24907939"/>.<br />
|-bgcolor="FFFAFA"<br />
|Allele drop-out (ADO) in heterozygous loci is possible<ref name="PMID24907939"/>.<br />
|}<br />
===Fluorescent In Situ Hybridisation===<br />
FISH is the one of the most effective and rapid <ref name="PMID26338801"><pubmed>26338801</pubmed></ref> method as part of PGD. This technique locates a specific DNA sequences within a chromosome. FISH facilitates the clinical diagnosis of chromosomal abnormalities indicated by sequential duplications, deletions and rearrangements of chromosome, that are usually missed with microscopic analysis. This technique is especially relevant for female embryos with X-linked diseases<ref name="PMID20809319"><pubmed>20809319</pubmed></ref>.[http://www.ncbi.nlm.nih.gov/pubmed/20809319] As part of PGD, it enabled the screening for aneuploidies and increased live birth rates in women with advanced age<ref name="PMID24907939"/> <ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. FISH is 99% effective when used in conjunction with competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities<ref name="PMID26338801"/>.<br />
{|<br />
|- align="left" bgcolor="DDCEF2"<br />
|'''Procedure'''<br />
|}<br />
Samples collected from the embryo<ref name="PMID21748341"><pubmed>21748341</pubmed></ref> are collected, processed, and its DNA strands are heated and denatured causing their the individual DNA strands to break apart. Then, probes of single complimentary stands of DNA a that have been tagged with small chemical agents that glow brightly in the presence of a specific region on a chromosome are added. These specific probes then hybridize and join to their complementary DNA strand. The fluorescent tags enable the correct identification of the presence or lack thereof and location of specific chromosomes that are tested for<ref name="PMID17876073"><pubmed>17876073</pubmed></ref>. The number and the relative location of the fluorescent dots generated by the FISH images is analysed and gives rise to diagnosis<ref name="PMID17970921"><pubmed>17970921</pubmed></ref>. The probe will not fully hybridise if there has been a duplication or a deletion of the DNA - indicating chromosomal and sex chromosomal anomalies like trisomies and aneuploidies. <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref>. Different probes are used for different purposes: <ref>Unique, Rare Chromosome Disorder Support Group (2013) Fluorescence in situ hybridisation (FISH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/Other/FISH%20FTNW.pdf]</ref><br />
*'''Locus specific tags''' detect very small imbalances, and locate isolated small portions <br />
of genes within a chromosome<br />
*'''Alphoid/Centomeric Repeat probes''' are developed from the repetitive sequence located in the middle region of each chromosome, useful in determining the number of chromosomes , detecting rearrangement and when used in conjunction with locus probes to determine the absence of genetic material on a chromosome. <br />
*'''Paint Probes''' are collections of smaller probes with their own stains that bind to a different section on the chromosome - allowing the full chromosome too be labeled a unique colour, this "full colour map" can be used to know the spectral karyotype- full chromosomal mapping is useful in examining chromosomal abnormalities. <br />
[[File:Fluorescent In Situ Hybridisation (FISH).jpg|thumb|right|'''FISH''' Specific DNA sequences using probes which have been tagged with fluorescent labels are visualised.This technique enables the clinical diagnosis of chromosomal abnormalities, indicated by sequential duplication, deletions and rearrangements of chromosome <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref>]]<br />
<br />
{|class="wikitable" align="center"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="5" |'''Advantages''' <br />
|-bgcolor="FFFAFA" <br />
| FISH is 99% effective when used in conjunction with Competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities<ref><pubmed>26338801</pubmed></ref>.<br />
|-bgcolor="FFFAFA" <br />
| Results are rapidly generated. <br />
|-bgcolor="FFFAFA"<br />
| Very small translocations and aneuploidies that occur within chromosomes, that would usually be missed under microscopic analysis, can be identified<ref name="Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd)">Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref>.<br />
|-bgcolor="FFFAFA" <br />
| The most common chromosomal abnormalities, such as down syndrome chromosomes 13,16,18,21 and 22<ref><pubmed>21749752</pubmed></ref>, and inheritable X-linked disease or sex chromosome anomalies such as Duchenne's Muscular Dystrophy, hemophilia, ectodermal dysplasia<ref><pubmed>17876073</pubmed></ref> can be identified.<br />
|-bgcolor="DDCEF2"<br />
| rowspan="5"|'''Disadvantages'''<br />
|-bgcolor="FFFAFA" <br />
| FISH destroys all cells tested <ref> O'Connor, C. (2008) Fluorescence in situ hybridization (FISH). Nature Education 1(1):171. retrieved from [http://www.nature.com/scitable/topicpage/fluorescence-in-situ-hybridization-fish-327] </ref>.<br />
|-bgcolor="FFFAFA" <br />
| It does not fully access all chromosomes (only ~ 12)<ref name="PMID24907939"/>.<br />
|-bgcolor="FFFAFA" <br />
| The analysis of results is dependent upon the dot quality impacted by hybridisation efficiency or the camera sensitivity<ref name="PMID17970921"><pubmed>17970921</pubmed></ref>.<br />
|-bgcolor="FFFAFA" <br />
| Some studies indicate that using FISH on a day-3 embryo biopsy decreases the rate of live births<ref><pubmed>26168107</pubmed></ref>.<br />
|}<br />
<br />
===Array Comparative Genomic Hybridisation (aCGH)===<br />
aCGH also known as Microarray analysis efficiently scans the entire genome for chromosomal imbalances. CGH was initially developed to detect the number of changes in a solid tumor mass. It uses 2 genomes comparing the sample to the control, with each labeled in a different fluorescent dye<ref name="PMID1876176"><pubmed>1876176</pubmed></ref>. Earlier CGH techniques were limited by the resolution of the imaging <ref> Lichter, P., et al. Comparative genomic hybridization: Uses and limitations. Seminars in Hematology 37, 348–357 (2000)</ref> , these initial limitations were overcome by using Microarrays in conjunction with CGh to improve the resolution of the imaging, Array Comparative Genomic Hybridisation (aCGH). This method compares sample and control microarrayed slides containing small segments of DNA (probes). <ref> Lucito, R., et al. Representational oligonucleotide microarray analysis: A high-resolution method to detect genome copy number variation. Genome Research 13, 2291–2305 (2003) </ref> the Probes used will vary according from the small (25-85 base pairs) oligonucleotides manufactured to highlight different target sequences, to the very large genomic clones (80,000- 200,00 base pairs), and as these are significantly smaller than the traditional metaphase chromosomes used for CGH, generating a higher resolution of image. <ref name="PMID22467166"><pubmed>22467166</pubmed></ref>.aCGH is used as a diagnostic tool for prenatal detection f chromosomal abnormalities <ref name="PMID19012303"><pubmed>19012303</pubmed></ref>.<br />
{|<br />
|- align="left" bgcolor="DDCEF2"<br />
|'''Procedure'''<br />
|}<br />
<ref name="Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45"> Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432] </ref><br />
The sample is obtained (skin, blood or fetal cells) and DNA is obtained. <br />
As a part of PGD fetal cell samples are collected from; the fertilized egg polar bodies, the blastomere (day 3 embryo) or the blastocyst/tropoectoderm stage (day 5 embryo).<br />
Sample DNA is labeled with one fluorescent dye, and the control DNA is labeled with a different colored fluorescent dye. the control DNA is used as the base point of reference. <br />
heated and denatured single DNA strands then hybridize to their complementary single strand probes, which are then combined and applied to a microarray and the results are run through a computer program and a digital imaging system is used to quantify the results( fluorescent intensities of the labeled probes). <br />
<br />
[[File:aCGH.jpg|thumb|right|'''aCGH''' checks the entire genome for chromosomal imbalances, by comparing control and a sample slides contatining small segements of DNA sample microarrayed slides small segments of DNA. Illustrated by student z5020317 and adapted from <ref> NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation. retrieved from [http://www.phgfoundation.org/file/5237/]</ref> <ref name="Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45"> Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432] </ref>]]<br />
<br />
The fluorescent ratio and the hybridization signal at different locations on the genome of the control DNA are used to identify any variances present in the sample DNA. aCGH facilitates the clinical diagnosis of submicroscopic chromosomal duplication, deletion and rearrangements indicative of chromosomal disorders such as trisomies 1-22and specific sex linked disorders. <br />
Duplications in the DNA are displayed by the computer program as spikes/ peaks over an established threshold and deletions in DNA are displayed by the computer program as spikes/ toughs beneath this threshold <br />
<br />
{|class="wikitable" align="center"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="12" |'''Advantages''' <br />
|-bgcolor="FFFAFA"<br />
| Multiple applications: prenatal genetic diagnosis, cancer diagnosis, <ref name="PMID20193845"><pubmed>20193845</pubmed></ref> genetic screening for developmental delay (learning disabilities) <ref name="PMID17309648"><pubmed>17309648</pubmed></ref>. or congenital anomalies that are suspected to be genetic in origin <ref>NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation . retrieved from [http://www.phgfoundation.org/file/5237/]</ref><br />
|-bgcolor="FFFAFA"<br />
| trace represents all chromosomes present in the human genome chromosomes 1-22 and the X & Y chromosomes, and therefore is the most accurate method for testing whole embryo aneuploidy<br />
|-bgcolor="FFFAFA"<br />
| aCGH has been extensively tested, and Validated, and is now used world wide.<br />
|-bgcolor="FFFAFA"<br />
| Detects submicroscopic alterations<br />
|-bgcolor="FFFAFA"<br />
| Detects deletions and additions and rearrangements as well as amplification, of the WHOLE genome, simultaneously.<br />
|-bgcolor="FFFAFA"<br />
| Used as a diagnostic tool for prenatal detection of chromosomal abnormalities <ref name="PMID22034057"><pubmed>22034057</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Provides high resolution genomewide screening of segmental genomic copy number variations<br />
|-bgcolor="FFFAFA"<br />
| Very accurate when used in conjunction with FISH<br />
|-bgcolor="FFFAFA"<br />
| Alone is more reliable and in detecting chromosomal abnormalities, with a higher implantation success rate, than FISH <ref name="PMID20494259"><pubmed>20494259</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Allows an in depth research focus upon specific types of rearrangements within selected chromosomal regions, a recent particular area of interest is subtelomeric and pericentromeric rearrangements<br />
|-bgcolor="FFFAFA"<br />
| Reduces the risk of failed implantation and miscarriage, improving the chance of a healthy baby <ref name="Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd)">Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref>><br />
|-bgcolor="DDCEF2"<br />
| rowspan="9" |'''Disadvantages'''<br />
|-bgcolor="FFFAFA"<br />
| Translocations and inversions of DNA are not detected<br />
|-bgcolor="FFFAFA"<br />
| Limited ability diagnosing specific polyploidies such as triploidy <ref> Unique, Rare Chromosome Disorder Support Group (2013) Microarray-based Comparative Genomic Hybridiation (array CGH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/other/array%20cgh%20ftnw.pdf] </ref><br />
|-bgcolor="FFFAFA"<br />
| Will not detect mosaicism detection <20% (cultures where >1 of 5 cells are trisomy 12)<br />
|-bgcolor="FFFAFA"<br />
| Will not detect balanced chromosomal rearrangement<br />
|-bgcolor="FFFAFA"<br />
| Will not detect duplications or deletions <80kb<br />
|-bgcolor="FFFAFA"<br />
| Will not detect point mutations within genes <ref>Washington department of education (CGH- FAQ for physicians. Signature Genomic LAboratories, LLC. Retrieved from [https://depts.washington.edu/dbpeds/Lab%20Tests/SignatureCGH-physician_FAQ.pdf]</ref><br />
|-bgcolor="FFFAFA"<br />
| will not detect chromosomal position of genomic gains<br />
|-bgcolor="FFFAFA"<br />
| Will not detect loos of heterozygosity (LOH) or Absence of heterozygosity (AOH) <ref>WiCell Research Institute Inc. (2012) Comparative Genomic Hybridization Microarray. <br />
retrieved from [http://www.wicell.org/home/cytogenetic-services/cgh-microarray/array-comparative-genomic-hybridization-acgh.cmsx]</ref><br />
|}<br />
<br />
===Next Generation Sequencing===<br />
The development and advances within ART in the past 20 years, as well as the increasing popularity of IV, has lead to an influx of new technologies developed to screen embryos for chromosomal anomalies, which are covered by the umbrella term of Next generation Sequencing (NGS). NGS is a general term used to describe all of the new and emerging screening techniques currently being introduced and used as part of PGD for IVF . NGS screens for single gene disorders as well as conducting extensive and very comprehensive chromosome diagnosis by sequencing, counting, and accurately assembling millions of DNA reads, simultaneously. <ref name="PMID23499002"><pubmed>23499002</pubmed></ref> There is a movement for NGS to replace the other limited testing techniques and be used as the standard. <br />
{|<br />
|- align="left" bgcolor="DDCEF2"<br />
|'''Procedure'''<br />
|}<br />
Samples are collected from either blastomere or the blastocyst/tropoectoderm and processed for analysis by a computer system. <br />
The methodology of each process is unique to the technique being used. <br />
<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="14" |'''Advantages''' <br />
|-bgcolor="FFFAFA" <br />
| Cost effective<br />
|-bgcolor="FFFAFA"<br />
| Opens new diagnostic possibilities<br />
|-bgcolor="FFFAFA"<br />
| Accurately tests all 24 chromosomes<br />
|-bgcolor="FFFAFA"<br />
| Tests for the presence of monogenic diseases of known genetic background<br />
|-bgcolor="FFFAFA"<br />
| Reduces the number of biopsies required for diagnosis<br />
|-bgcolor="FFFAFA"<br />
| Higher detection rate of small translocations<br />
|-bgcolor="FFFAFA"<br />
| Highly accurate is testing for compound point mutations, chromosomal duplication, deletions and insertions <ref name="PMID23312231"><pubmed>23312231</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| It accurately detects chromosomal aneuploidy and unbalanced rearrangement <ref name="PMID25685330"><pubmed>25685330</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Higher detection rate of small translocations<br />
|-bgcolor="FFFAFA"<br />
| NGS single gene disorder screenings can conducted in conjunction with PCR comprehensive chromosomal screening<br />
|-bgcolor="FFFAFA"<br />
| Reduces human error <br />
|-bgcolor="FFFAFA"<br />
| Better detects the presence of mosaicism<br />
|-bgcolor="FFFAFA"<br />
| Work well in conjunction with CGH and aCGH as part of PGD, improving the chances of IVF. <ref> Morris, R. S. (2015 ) Next generation sequencing for PCG|PGS|CCS. IVF1 retrieved from [http://www.ivf1.com/next-generation-sequencing for-pgd] </ref><br />
|-bgcolor="DDCEF2"<br />
| '''Disadvantages''' <br />
|-bgcolor="FFFAFA"<br />
| There are limited information available to clinical applications of NGS <ref><pubmed>26100406</pubmed></ref><br />
|}<br />
<br />
==Diagnosis==<br />
There are a large amount of diseases that PGD can apply to, below are descriptions of the diseases that PGD are more commonly used for. Upon completion of the genetic testing for the genes of concern the cells the embryos are discarded and priority is given to those that are healthy. <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/><br />
===Cystic Fibrosis===<br />
Cystic fibrosis is a single gene disorder. It is autosomal recessive and involves mutations in the cystic fibrosis transmembrane conductance regulator (CTFR) gene. The CTFR gene is normally responsible for the decrease in chloride and the transport of bicarbonate in epithelial cells thus playing a major physiological role. In PGD procedures, identification of the gene is assisted by microsatellite markers that have similar composition to the CTFR gene itself. Biopsy of two cells at the blastocyst stage is recommended if markers are not available. There are many variations of cystic fibrosis the most common being P.Phe508del <ref name="PMID26014425"><pubmed>26014425</pubmed></ref>.<br />
===Duchenne Muscular Dystrophy ===<br />
Duchenne Muscular Dystrophy is an X-linked recessive disease. It involves the Xp21 gene where majority of the mutations are chromosomal deletions with a smaller percentage resulting from duplications <ref name="PMID18359022"><pubmed>18359022</pubmed></ref>.<br />
<br />
===Autosomal Recessive Meckel-Gruber Syndrome===<br />
Autosomal recessive genetic defect caused by the TMEM67 gene. It results in cystic dysplasia of the kidneys with fibrotic change in the liber and occipital encephalocele. Other malformations could also be present in the central nervous system. In PGD whole genome amplification of single blastomeres are taken to identify the gene, this is also coupled with PCR techniques. Maternal plasma can also be extracted for PGS. <ref><pubmed>24039893</pubmed></ref> <br />
===β – Thalassemia=== <br />
β – Thalassemia is known as the most common type of autosomal recessive inherited disorder among haemoglobinopathies. It involves the adult β-globin gene and is associated with the absent or decreased expression of the gene. This is commonly caused by a single nucleotide change in the gene. PGD has been used successfully worldwide to identify the β-globin gene where its application is usually performed on a single blastomere or polar body <ref name="PMID19064120">19064120</pubmed></ref>.<br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
! Applicable diseases for PGD <ref>Genoma Group (2014). Retrieved September 18th, 2015, from http://www.preimplantationgeneticdiagnosis.it/genetic-diseases-diagnosed-by-pgd.htm </ref> <ref>Genesis Genetics (2015). Retrieved September 18th, 2015, from http://genesisgenetics.org/pgd/what-we-test-for/</ref> <ref>Human Fertilisation & Embryology Authority (2015). Retrieved Septembr 18th, 2015, from http://guide.hfea.gov.uk/pgd/</ref><br />
|-<br />
| '''Disease'''<br />
| '''Involved Genes'''<br />
|-<br />
| 5 Alpha Reductase Deficiency (5ARD)<br />
| SRD5A2 <br />
|-<br />
| Achondroplasia<br />
|FGFR3 <br />
|-<br />
| Acute Intermittent Porphyria <br />
| ALAD, ALAS2, CPOX, FECH, HMBS, PPOX, UROD, or UROS<br />
|-<br />
| Adrenoleukodystrophy (Adrenomyeloneuropathy)<br />
| ABCD1 <br />
|-<br />
| Agammaglobulinaemia (x-linked) <br />
|BTK <br />
|-<br />
| Agammaglobulinemia Bruton Tyrosine Kinase (BTK) <br />
|BTK <br />
|-<br />
| Aicardi Goutieres Syndrome 1 (AGS1) <br />
|TREX1, RNASEH2A, RNASEH2B, RNASEH2C, SAMHD1<br />
|-<br />
| Alagille Syndrome<br />
|JAG1 or NOTCH2<br />
|- <br />
| Alpers-Huttenlocher Syndrome <br />
|POLG <br />
|-<br />
| Alpha-1-antitrypsin deficiency <br />
|SERPINA1 <br />
|-<br />
| Alpha-Mannosidosis<br />
| MAN2B1 <br />
|-<br />
| Alpha Thalassemia <br />
|HBA1 or HBA2 <br />
|-<br />
| Alports Syndrome<br />
|COL4A3, COL4A4, COL4A5<br />
|-<br />
| Alzheimer's Disease - early onset (Type 3 and 4) <br />
|APP, PSEN1, or PSEN2<br />
|-<br />
| Amyotrophic Lateral Sclerosis 1 (ALS1) <br />
|C9orf72, SOD1, TARDBP, FUS, ANG, ALS2, SETX, VAPB <br />
|-<br />
| Argininosuccinic Aciduria <br />
| ASL<br />
|-<br />
| Arrhythmogenic Right Ventricular Cardiomyopathy/ Dysplasia (ARVC/D)<br />
| DSG2; DSP; PKP2<br />
|-<br />
| Ataxia Telangiectasia<br />
| ATM<br />
|-<br />
| Autosomal Recessive Meckel-Gruber Syndrome<br />
| TMEM67<br />
|-<br />
| Bardet-Biedl Syndrome (BBS)<br />
| BBS1; BBS10<br />
|-<br />
| Barth Syndrome<br />
| TAZ<br />
|-<br />
| Beta Thalassaemia<br />
| HBB<br />
|-<br />
| Birt-Hogg-Dubé Syndrome<br />
| FLCN<br />
|-<br />
| Breast Ovarian Cancer Familial Susceptibility (BRCA2)<br />
| BRCA1; BRCA2<br />
|-<br />
| Canavan Disease <br />
| ASPA<br />
|-<br />
| Carnitine-Acylcarnitine Translocase Deficiency <br />
| SLC25A20<br />
|-<br />
| Cerebral Arteriopathy with Subcortical Infarcts & Leukoencephalopathy (CADASIL)<br />
| NOTCH3<br />
|-<br />
| Cerebral Cavernous Malformation<br />
| CCM1<br />
|-<br />
| Charcot-Marie-Tooth Disease<br />
| GJB1; MPZ; NEFL; PMP22<br />
|-<br />
| CHARGE Syndrome<br />
| CHD7<br />
|-<br />
| Cherubism<br />
| SH3BP2<br />
|-<br />
| Choroideremia<br />
| CHM<br />
|-<br />
| Chronic Granulomatous Disease<br />
| CYBB; NCF1<br />
|-<br />
| Ciliary Dyskinesia<br />
| DNAH5<br />
|-<br />
| Citrullinemia<br />
| ASS1<br />
|-<br />
| Cleidocranial Dysplasia<br />
| RUNX2<br />
|-<br />
| Cockayne Syndrome<br />
| ERCC6<br />
|-<br />
| Congenital Adrenal Hyperplasia<br />
| CYP21A2<br />
|-<br />
| Congenital Cataracts<br />
| GJA8; VSX2<br />
|-<br />
| Congenital Diarrhea, Syndromic<br />
| SPINT2<br />
|-<br />
| Congenital Disorders of Glycosylation (CDG)<br />
| ALG1; ALG6; CDG1C; DOLK; PMM2<br />
|-<br />
| Cornelia de Lange Syndrome <br />
| NIPBL<br />
|-<br />
| Craniosynostosis<br />
| TWIST1<br />
|-<br />
| Crouzon Syndrome<br />
| FGFR2<br />
|-<br />
| Cysteinyl Leukotriene Receptor 1 Deficiency <br />
| CYSLTR1<br />
|-<br />
| Cystic Fibrosis<br />
| CFTR<br />
|-<br />
| Diamond –Blackfan Anemia <br />
| RPS19<br />
|-<br />
| Duchenne Muscular Dystrophy <br />
| DMD<br />
|-<br />
| Dyskeratosis congenita (Male embryos only)<br />
| DKC1<br />
|-<br />
| Ectodermal dysplasia (Hypohidrotic)<br />
| EDA; EDA1; GJB6; IKBKG<br />
|-<br />
| Familial Adenomatous polyposis coli (FAP)<br />
| APC<br />
|-<br />
| Familial Dysautonomia<br />
| IKBKAP<br />
|-<br />
| Fanconi Anemia <br />
| FANCA; FANCC; FANCD2; FANCF; FANCG; FANCJ<br />
|-<br />
| Fragile X Syndrome (FRAX)<br />
| FMR1<br />
|-<br />
| Galactosemia <br />
| GALT<br />
|-<br />
| Gangliosidosis<br />
| GLB1<br />
|-<br />
| Glanzmann Thrombasthenia <br />
| ITGA2B<br />
|-<br />
| Glutaric Acidemia (aciduria)<br />
| GCDH <br />
|-<br />
| Glycogen Storage Disease <br />
| G6PC; GAA; SLC37A4<br />
|-<br />
| Haemophilia A<br />
| F8<br />
|-<br />
| Haemophilia B<br />
| F9<br />
|-<br />
| Hereditary Nonpolyposis Colorectal Cancer: Lynch Syndrome<br />
| MLH1; MSH2; MSH6<br />
|-<br />
| Holt Oram Syndrome<br />
| TBX5<br />
|-<br />
| Huntington Disease<br />
| HD<br />
|-<br />
| Hydrocephalus<br />
| L1CAM<br />
|-<br />
| Ichthyosis <br />
| ABCA12; STS<br />
|-<br />
| Incontinentia Pigmenti (IP)<br />
| NEMO<br />
|-<br />
| Joubert Syndrome 5<br />
| INPP5E<br />
|-<br />
| Krabbe Disease<br />
| GALC<br />
|-<br />
| Leber Congenital Amaurosis (LCA)<br />
| CEP290; GUCY2D<br />
|-<br />
| Leigh Syndrome (Infantile Subacute Necrotising Encephalopathy)<br />
| LRPPRC<br />
|-<br />
| Lesch Nyan Syndrome<br />
| HPRT1<br />
|-<br />
| Leukocyte Adhesion Deficiency (Type I)<br />
| ITGB2<br />
|-<br />
| Li-Fraumeni Syndrome<br />
| TP53<br />
|-<br />
| Macular Dystrophy Retinal <br />
| VMD2<br />
|-<br />
| Maple Syrup Urine Disorder (MSUD)<br />
| BCKDHB<br />
|-<br />
| Marfan Syndrome <br />
| FBN1<br />
|-<br />
| Menkes Syndrome<br />
| ATP7A<br />
|-<br />
| Mitochondrial DNA Depletion Syndrom <br />
| POLG; RRM2B; SUCLA2; TK2<br />
|-<br />
| Mucolipidosis type II<br />
| GNPTAB<br />
|-<br />
| Multiple Endocrine Neoplasia<br />
| MEN1; MEN2A; MEN2B<br />
|-<br />
| Multiple Exostoses<br />
| EXT1; EXT2 <br />
|-<br />
| Myotubular myopathy<br />
| MTM1 <br />
|-<br />
| Nail-Patella Syndrome<br />
| LMX1B<br />
|-<br />
| Neurofibromatosis Type 1<br />
| NF1<br />
|-<br />
| Neurofibromatosis Type 2 <br />
| NF2<br />
|-<br />
| Noonan Syndrome<br />
| KRAS, PTPN11; SOS1<br />
|-<br />
| Norrie Disease<br />
| NDP<br />
|-<br />
| Ocular Albinism <br />
| GPR143<br />
|-<br />
| Oculocutaneous Albinism <br />
| OCA2; TYR <br />
|-<br />
| Oculodentaldigital Dysplasia<br />
| GJA1<br />
|-<br />
| Optic Atrophy<br />
| OPA1<br />
|-<br />
| Ornithine Transcarbamylase Deficiency <br />
| OTC<br />
|-<br />
| Osteogenesis imperfeca <br />
| COL1A1; COL1A2<br />
|-<br />
| Osteopetrosis <br />
| CLCN7; OSTM1; TCIRG1<br />
|-<br />
| Pachyonychia Congenita <br />
| KRT16; KRT6A<br />
|-<br />
| Pancreatitis, Hereditary<br />
| PRSS1 <br />
|-<br />
| Papillorenal syndrome <br />
| PAX2<br />
|-<br />
| Phenylketonuria <br />
| PAH <br />
|-<br />
| This table does not cover the complete list of diseases that PGD can be applied to.<br />
|}<br />
<br />
==Laws & Legal status==<br />
<br />
{| class="wikitable" <br />
|-bgcolor="DDCEF2"<br />
|'''Country'''<br />
|'''Legislation'''<br />
|-bgcolor="FFFAFA" <br />
| Australia<br />
| PGD is currently used to detect serious genetic conditions to improve the outcome of Assisted Reproductive Technologies (ART). In very rare cases it may be used to select an embryo with compatible tissue for a sibling who has a life-threatening disease where other means of treatment is unavailable. This is with the conditions that the use of PGD will not affect the welfare and interests of the child to be born. The parents must also receive adequate counselling and have full understanding of the procedures of PGD. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"> National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art</ref><br />
The use of PGD for sex-selection is prohibited with the exception of reducing the risk of the transmission of serious sex-linked genetic conditions. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"/><br />
|-bgcolor="FFFAFA"<br />
| Brazil<br />
| The laws regarding PGD in Brazil are not strictly regulated. They are vague and there is limited information surround the activities of assisted reproduction in general in the country <ref name="PMID25493379"><pubmed>25493379</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| Czech Republic<br />
| The laws in the Czech Republic allow those with a “defined indication in order to exclude risk of serous genetically conditioned disease and defects with embryos before they are implanted into the cavity of the uterus”. Couples that undergo any assisted reproductive treatment including PGD have to be married. Sex-selection is illegal except in regards to serious sex-linked genetic diseases <ref name="PMID24777348"><pubmed>24777348</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| Greece<br />
| In Greece, ART is open to those up to the age of 50 with written consent. It can only be used if a medical necessity is present such as the susceptibility of serious hereditary diseases. Sex selection is banned apart from cases of sex-linked diseases and sexually transmitted diseases <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| India<br />
| In India there is a cultural preference for boys thus the Prenatal Diagnostic Techniques (Regulation and Prevention of Misuse) Act was introduced in 1994. This law limits the use of PGD for sex determination except in cases of specific congenital diseases. These laws however are not strictly enforced. <ref>World Health Organisation (2015) Gender and Genetics Retrieved on October 21st 2015 from:http://www.who.int/genomics/gender/en/index4.html</ref><br />
|-bgcolor="FFFAFA"<br />
| Portugal <br />
| ART is only available to those who are married or have a similar type of relationship for at least two years. The couples cannot be of the same sex and must be at least 18 years of age. Sex selection is illegal except in cases of sex-linked diseases. The use of PGD is illegal if the predictive value of genetic tests are very low <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| Spain<br />
| PGD can be applied to “serious hereditary diseases not amenable to postnatal curative treatment” and “detection of other abnormalities which may compromise the viability of the pre-embryo”. If PGD is to be used for any other purpose authorisation must be acquired <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| Sweden <br />
| The use of PGD is strictly regulated and couples must achieve authorisation of the National Board of Health and Welfare. It can only be used it can only be used if the child is at risk to inheriting a serious chromosomal or monogenetic disease. It cannot be used for selection of specific characteristics <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| United Kingdom<br />
| Those involved with carrying out the IVF treatment must have a license from the Human Fertilisation and Embryology Authority (HFEA). Only embryos that are approved by the HFEA can be implanted where the embryonic nuclear or mitochondrial DNA cannot be altered with the exception of preventing mitochondrial diseases <ref name="PMID24777348"/>. <br />
|}<br />
<br />
==Future/Current Research==<br />
In addition to research efforts for improving overall performance of established PGD/S techniques, such as finding the ideal zona pellucida insection site in an fully automatic manner<ref name="PMID26259216"><pubmed>26259216</pubmed></ref>, many research efforts have been spent to find alternative, non-invasive techniques to test for diseases and abnormalities<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
===Non-invasive Preimplantation Genetic Testing without Embryo Biopsy===<br />
Different parameters of gametes, zygotes, embryos (“vacuoles in sperm heads, spindle position in mature oocytes, cleavage intervals of zygote, and embryo developmental dynamics”) may correlate with aneuploidy rates. This knowledge may be applied in potential noninvasive preimplantation diagnostic methods. Several methods have been proposed and are currently further researched<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Sperm Selection====<br />
Intracytoplasmic morphologically selected sperm injection (IMSI) is common procedure in IVF treatment to improve fertilization rates in patients with poor semen quality. In addition, studies have found that IMSI improves embryo development and that spermatozoa with large vacuoles in their heads correlate with increased aneuploidy rates and disturbed chromosomal structures. Thus, selecting spermatozoa based on morphological hallmarks may decrease aneuploidy rates in the fertilized embryos. As with polar body biopsies, however, this approach will solely be applicable if evidence for severe male detrimental contribution is given<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Blastocoel Fluid Extraction====<br />
In addition, a less invasive retrieval of material for diagnosis could include the extraction of the blastocoel fluid. The cavity of the blastocyst, lined by the trophectoderm, is filled with this blastocoel fluid, which contains metabolites of both trophectoderm and inner cell mass origin. The retrieval does not require a biopsy but merely a small opening to extract the fluid and, thus, causes less harm to the embryo. Multiple studies have applied this method<ref name="PMID22020776"><pubmed>22020776</pubmed></ref> <ref name="PMID23148560"><pubmed>23148560</pubmed></ref> <ref name="PMID26006737"><pubmed>26006737</pubmed></ref> and it may in the future become of clinical relevance.[[File:Aspiration_of_the_Blastocoel_Fluid.jpeg|400px|thumb|Aspiration of the Blastocoel Fluid using a ICSI pipette<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.]]Next to metabolites, the blastocoel fluid can contain DNA. Studies have shown that genomic DNA is present in about 90% of the blastocoel fluid samples tested. Typically the fluid is removed with an ICSI pipette from a day five blastocyst through its mural trophectoderm until the blastocyst fully collapses around the embryo. Several concerns regarding this method in a clinical setting have been raised. The collected DNA may be contaminated by the culture media that contains DNA fractions. The DNA may also be least representative of the actual embryos genome as the DNA may originate from abnormal or degenerated cells. Even though labelled noninvasive, the blastocyst still undergoes manipulation to some degree which may affect its viability. Thus, more research is required until this method can evolve from research to clinical use<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
====Proteomics and Medium Based PGD====<br />
The media in which embryos are kept during the early IVF procedures, gives rise to potential non-invasive techniques. For instance, the protein secretome of blastocysts may be representative of its chromosome constitution Recent studies have found biomarkers such as lipocalin-1, interleukin-10, tumor necrosis factor, stem cell factor, and chemokine ligand 13 to be differently secreted by aneuploid blastocyst than by euploid ones. The most significant biomarker appears to be interleukin-10. Paired with novel proteomic technologies and mass spectrometry this knowledge when extended may contribute to a new invasive PGD method<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. In addition, medium based non-invasive PGD has been researched for the diagnose of human α-thalassemia-SEA. Genomic DNA was collected from the media and the study surprisingly resulted in increased diagnosis efficacy compared to biopsy-based methods<ref name="PMID25816038"><pubmed>25816038</pubmed></ref>.<br />
====Embryo Morphology====<br />
Using time lapse imaging the embryo’s morphology can be closely observed and potential aneuploidy characteristics detected. Such characteristics may include the time of division to five cells, the time between the division from three to four cells, and the duration of the division from one to two and subsequently to three. In addition, the morphological quality of ICM an TE has been positively associated with aneuploidy or euploidy prognosis<ref name="PMID26246880"><pubmed>26246880</pubmed></ref>. These may give rise to an embryo quality screening prior to implantation<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
==Glossary==<br />
'''Biopsy:''' sample of tissue taken for examination <br />
<br />
'''Blastocyst:''' Stage of embryo at approximately day 5 consisting of an outer (trophoblast) layer and inner (embryoblast) cell mass. <br />
<br />
'''Blastomere:''' Initial cells formed through mitosis of the zygote<br />
<br />
'''CTFR''' Cystic Fibrosis Transmembrane Conductance Regulator, responsible for transport of chloride across the cell membrane<br />
<br />
'''Fluorescent In situ hybridisation:''' technique use to locate specific gene sequences using fluorescence tags <br />
<br />
'''Intracytoplasmic Morphologically Selected Sperm Injection (IMSI):''' IVF technique involving morphological selection of sperm under the microscope to be injected to oocyte<br />
<br />
'''Intracytoplasmic Sperm Injection (ICSI):''' IVF technique used to treat male infertility and involves direct injection of one sperm into an oocyte<br />
<br />
'''Next Generation Sequencing (NGS):''' Term used to describe the collection of recent findings regarding embryo screening<br />
<br />
'''Polar bodies:''' cell formed during the meiotic stages of the oocyte containing extra genetic material <br />
<br />
'''Polymerase Chain Reaction (PCR):''' Technique used to amplify DNA to study a specific genetic sequence<br />
<br />
'''Preimplantation Genetic Diagnosis (PGD):''' Involves genetic testing conducted to identify abnormalities in an embryo before implantation.<br />
<br />
'''Preimplantation Genetic Screening (PGS):''' Involves genetic screening for genetic abnormalities using techniques such as FISH and PCR to eliminate unhealthy embryos <br />
<br />
'''Robertsonian Translocations:''' Type of structural chromosomal translocation <br />
<br />
<br />
<br />
==References==<br />
<br />
<references/><br />
<br />
<br />
{{StudentPage2015}}</div>Z5017878https://embryology.med.unsw.edu.au/embryology/index.php?title=2015_Group_Project_6&diff=2073312015 Group Project 62015-10-22T05:41:42Z<p>Z5017878: </p>
<hr />
<div>{{ANAT2341Project2015header}}<br />
<br />
<br />
=Preimplantation Genetic Diagnosis and Preimplantation Genetic Screening=<br />
==Introduction==<br />
Preimplantation genetic diagnosis (PGD) and preimplantation genetic screening (PGS) are reproductive options for couples with known family histories of genetic disease or couples undergoing IVF procedures due to infertility issues. PGD can diagnose many genetic disorders caused by known chromosomal abnormalities (number and/or structure) or single gene mutations, and, thus decrease the risk of termination of pregnancy or miscarriages and enable such couples to have an unaffected child<ref name="PMID24907939"><pubmed>24907939</pubmed></ref>. Through major improvements in PGD/S and general laboratory technology, the testing for abnormalities in fetuses has shifted from prenatal diagnosis during the first 2 trimesters <ref> Blackburn, S.L. (2003) '''Maternal, Fetal & Neonatal physiology: a Clinical perspective''' (2nd ed.). Seattle: Saudners </ref>, testing for overall fetal growth, complications of pregnancy, and birth defects<ref> Sadler T.W.(2012) '''Langman's Medical Embryology''' (12th ed.) Philadelphia: Lipincott, Wiliams & Wilkins, a Wolters Kluwer Business </ref>, to an embryonic focus especially in advancements in Artificial Reproductive Technologies (ART)<ref><pubmed>20638568</pubmed></ref>. In 1990 PGD for a recessive X-linked disease resulted in the first live birth<ref><pubmed>2330030</pubmed></ref> and has since been incorporated in clinical routine and applied for a variety of genetic diseases, such as sickle cell anemia, thalassemia, or cystic fibrosis<ref name="PMID24907939"/>.<br />
[[File:Preimplantation Genetic Diagnosis Procedure.jpeg|600px|left|thumb| Simplified steps for PGD<ref name="PMID24907939"/>]]<br />
{|class="wikitable"align="right" <br />
| <html5media height="400" width="533">https://www.youtube.com/watch?v=0e-79qKllqk</html5media><br />
|-<br />
| Preimplantation Genetic Diagnosis<ref>IVF Florida (2011, December 11) IVF Florida - South Florida Fertility Specialists - Pre-Implantation Genetic Diagnosis [Video file]. Retrieved from https://www.youtube.com/watch?v=0e-79qKllqk</ref><br />
|}<br />
<br />
==History==<br />
The advances in reproductive technology during the second half of the 20th century, led to PGD's first clinical application in 1990 <ref>Harper, J. (n.d.). The history of PGD. Lecture. UCL Centre for PG&D and CRGH.University College London</ref>.<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
|Year<br />
|<br />
|- bgcolor="FFFAFA"<br />
| '''1967''' <br />
|First PGD on rabbit blastocysts (Gardner& Edwards) <ref name="PMID6036172"><pubmed>6036172</pubmed></ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1986''' <br />
|First Cleavage Biopsy (Wilton & Trounson)<ref>Wilton, L. J., & Trounson, A. O. (1986). Viability of mouse embryos and blastomeres following biopsy of a single cell. In Proceedings of the 18th Annual Conference of the Australian Society for Reproductive Biology, Brisbane, Australia.</ref><br />
|- bgcolor="FFFAFA"<br />
|'''1987''' <br />
|First Blastocyst Biopsy (Muggleton-Harris, Monk, Rawlings, & Whittingham)<ref name="PMID3372699"><pubmed>3372699</pubmed></ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1988''' <br />
|First Polar Body Biopsy (Yury Verlinksy)<ref> Verlinsky, Y., Pergament, E., Andresen, P., Enriquez, G., & Strom, C. (1989). Genetic analysis of polar body DNA: A new approach to preimplantation genetic diagnosis. Am J Hum Genet, 45(4), A272.</ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1990''' <br />
|First Clinical PGD using PCR testing for X-linked (Handyside, Kontogianni, Hardy, & Winston)<ref name="PMID2330030"><pubmed>2330030</pubmed></ref> <br />
|} <br />
==Preimplantation Genetic Diagnosis==<br />
PGD is used to test the genetic makeup of embryos to detect single gene disorders, chromosomal abnormalities and mitochondrial disorders. It also has applications in gender selection for diseases with unequal gender distributions <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Some diseases commonly involved with PGD include cystic fibrosis, spinal muscular atrophy and beta – thalassaemia <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press.">Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press</ref> <ref name="PMID17823145"><pubmed>17823145</pubmed></ref>. It was first used in the United Kingdom in the 1980s of arenoleucodystrophy and primarily focusing on sex- linked disorders <ref name="PMID17823145"/><ref name="PMID23150080"><pubmed>23150080</pubmed></ref>. PGD is now capable of detecting single cell defects (molecular) and chromosomal disorders resulting from the inversion, translocation or deletion of chromosomes (cytogenic) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>,<ref name="PMID11325751"><pubmed>11325751</pubmed></ref>. PGD can be applied to the embryo at different stages. That is on polar bodies, blastomeres or blastocyst <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>.<br />
Depending on the type of genetic disorder, PGD utilises different methods of genetic testing. These include Fluorescence in situ hybridisation (FISH) which is used for sex – linked disorders and detects chromosomal rearrangements <ref name="PMID11325751"/><ref name="PMID17876073"><pubmed>17876073</pubmed></ref> and Embryo halotyping which allows the identification of chromosomes causing the inherited disorder through knowledge of the pattern of closely linked markers <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. Polymerase chain reaction (PCR) is also widely used to detect molecular abnormalities <ref name="PMID11325751"/>.<br />
PGD is tightly regulated and supported by large organisations namely The American Society for Reproductive Medicine, The European Society for Human Reproduction and Embryology (ESHRE), The European Society of Human Genetics and the Preimplantation Genetic Diagnosis International Society <ref name="PMID25500181><pubmed>25500181</pubmed></ref>.<br />
===Sex-linked disorders===<br />
The determination of a disease as gender specific usually correlates with the presence or absence of specific genes such as SRY on the Y chromosome. It is known that females have two X chromosomes and males have an X and a Y chromosome where abnormalities are more prevalent on the X chromosome. PGD can be used for sex selection where only male embryos are transferred to reduce the chance of inheriting X-linked disorders. However, this does not completely eradicate the problem as male embryos remain susceptible to inheriting an affected X chromosome. Sex determination is only used when the specific mutation is unknown and has yet to be discovered <ref name="PMID24866878"><pubmed>24866878</pubmed></ref>.<br />
===Single gene defects===<br />
Single gene defects can be dominant, recessive, autosomal or X-linked. They are commonly diagnosed using PCR and although the PCR available today is complex and capable of combatting a large range of disease the development of new protocols has been proven to be difficult due to the small DNA sample available <ref name="PMID26168107"><pubmed>26168107</pubmed></ref><br />
===Mitochondrial disorders===<br />
Mitochondrial disorders also known as oxidative phosphorylation disorders arise from mutations in the nuclear DNA or mitochondrial DNA <ref name="PMID26312584"><pubmed>26312584</pubmed></ref>. They pose as a problem because they are unrecognisable until the mutations in the cell reach a detrimental level <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Mitochondrial disorders cause miscarriages and stillbirths as well as death in children and young adults. The effects can either be contained in a single organ or more commonly involve multiple organ failure where organs with high energy demands such as the brain, liver muscle and heart and heavily influenced. They are usually occur spontaneously or result from inheritance from the mother. Since mitochondria are solely inherited from the mother oocyte donations have been used as a solution to combat mitochondrial disorders. Additionally, there has been an increasing use in PGD where embryos that stay under the given threshold of 18% gene-mutations are allowed to be transferred and result in normal development. New technology in the areas of nuclear gene transfer and genome editing are also being experimented with <ref name="PMID26312584"/>. <br />
===Chromosomal disorders===<br />
Chromosomal disorders can be reciprocal, Robertsonian translocations, inversions, deletions and insertions <ref name="PMID26168107"/>. . Data from ESHRE collected between 2010 and 2011 has shown that the most common chromosomal abnormality confronted in PGD are reciprocal chromosomal abnormalities <ref name"PMID26071418"><pubmed>26071418</pubmed></ref>. PGD has also been used successfully for Robertsonian translocations (RT), a type of structural translocation. Children who carry RT are phenotypically normal, however in their later years it is found that they will suffer from infertility and repeated miscarriages due to the high frequency of abnormal embryos <ref name="PMID22081077"><pubmed>22081077</pubmed></ref>. PCR and FISH are the two main techniques used for chromosomal disorders. To be able to conduct the examinations the cells are required to be at the metaphase stage <ref name="PMID26168107"/>. <br />
[[File:Reasons_for_PGD.jpg|600px|thumb|Reasons for PGD<ref name= "PMID24764761"><pubmed><24764761</pubmed></ref>]]<br />
==Preimplantation Genetic Screening==<br />
PGS involves an array of methods or ideas that aim to segregate embryos that have genetic flaws and those that are healthy <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. The occurrence of aneuploidy is high around the stages of early embryonic development and they are the most common cause if miscarriages and congenital birth defects <ref name= "PMID26085841"><pubmed>26085841</pubmed></ref>. They have little effect on the morphology of the embryo making them difficult to identify thus identification heavily relies on genetic testing <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. <br />
Genetic sampling is most commonly conducted using Microarray Comparative Genomic Hybridisation (aCGH) as well as FISH, Quantitative PCR and Single Nucleotide Polymorphism (SNP) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. These methods collectively aim to assess numeral and structural chromosomal errors <ref name= "PMID26085841"/>. Studies have also introduced Next- Generation Sequencing (NGS) <ref name= "PMID26085841"/> and Whole Genome Amplification used to screen imbalances in the complete 24-chromosomes <ref name="PMID25953353"><pubmed>25953353</pubmed></ref><br />
Statistics from ESHRE have shown that the most common indications for PGS is advanced age, followed by repeated implantation failure or recurrent miscarriage and male infertility <ref name="PMID26071418"><pubmed>26071418</pubmed></ref>.<br />
===Indications===<br />
A low percentage of structural abnormalities in chromosomes are responsible for the cause of miscarriages. Despite this, they are the most prevalent type of chromosomal abnormality accounted for in PGD <ref name="PMID20638568"/>. The presence of specific gene cycles, initiation of embryonic protein synthesis and evident physiological development are all indicative of a successful in vitro fertilisation procedure <ref name="PMID11576737"><pubmed>11576737</pubmed></ref>. To eliminate further errors from occurring during the PGD procedure it is recommended to undertake further prenatal testing such as amniocentesis in the later stages <ref name="PMID20638568"/>. <br />
====Advanced maternal age====<br />
Data provided by the ESHRE has shown that the mean age of women undergoing PGS is 39 years <ref name="PMID26071418"/>. Women of advanced age have been shown to have a lower rate of pregnancies reaching childbirth <ref name="PMID18583331"><pubmed>18583331</pubmed></ref>. The highlighted concern revolves around the increased occurrence of aneuploidy following maternal age. The optimal age range for the lowest aneuploidy incidence was found to be between 27 to 37 years of age (6%) then progressively higher in women aged up to 42 (33%) and most common in those 44 and above (53%) <ref name="PMID24355045"><pubmed>24355045</pubmed></ref>. <br />
====Recurrent pregnancy loss / IVF failure====<br />
Recurrent pregnancy loss is defined as three or more IVF failures after cumulative transfer of more than 10 good-quality embryos. These are primarily caused by two main factors, reduced endometrium receptivity or embryonic defects. Endometrium receptivity can be negatively influences by instances including uterine pathologies such as thin endometrium, altered expression of adhesive molecules and immunological factors. Additionally, embryonic defects may be due to genetic abnormalities, embryonic aneuploidy or zona hardening. Endometriosis and hydrosalpinx has been known to effect both the endometrium and embryo <ref name="PMID23260857"><pubmed>23260857</pubmed></ref>.<br />
====Human leukocyte antigen matching====<br />
First used in 2001, HLA matching is an option given to parents to save a child with haematological or immunological disease through conceiving another child who would potentially be able to donate cord blood or haematopoietic stem cells from the bone marrow for transplantation. The process namely PGD-HLA has shown to improve haematopoietic stem cell transplant (HSCT). PGD-HLA can only be performed when HSCT is not needed urgently due to the time needed to conceive and delivery the baby <ref name="PMID25500181"><pubmed>25500181</pubmed></ref>. It is most commonly applied to children suffering from relapsed leukaemia <ref name="PMID22524201"><pubmed>22524201</pubmed></ref>. In a case study PGD-HLA was proven to successfully cure 10 diseases including Fanconi anaemia, Diamond-Blackfan anaemia and beta thalassemia <ref name="PMID25066893><pubmed>25066893</pubmed></ref>.<br />
==Biopsy Methods==<br />
Biopsy, the removal of genetic materials, from oocytes or embryos in the preimplantation stage is the primary step in PGD. For the past two decades these biopsies have been performed at three stages, the polar body, blastomere, and blastocyst, and the methodologies optimized to ensure the embryo’s viability. The most common approach involves biopsies at the cleavage stage. However, polar body and blastocyst biopsies are increasingly more often tested and applied. Approached for opening the zona pellucida involve next to the traditional mechanical and chemical means, novel approaches such as noncontact lasers. Their application may simplify and secure the procedure significantly. The most challenging question about PGD procedures remains at what stage biopsies should be taken. Much controversy has developed around this topic, highlighting the varying disadvantages and advantages of temporal biopsies. <ref name="PMID22723007"><pubmed>22723007</pubmed></ref><br />
<br />
[[File:Polar_Body,_Blastomere,_and_Trophectoderm_Biopsy.jpeg|400px|thumb|Polar body (A), blastomere (B) and trophectoderm (C) biopsies<ref name="PMID25625041"><pubmed>25625041</pubmed></ref>.]]<br />
{| class="wikitable"<br />
|- align="center" bgcolor="DDCEF2"<br />
|<br />
| Time of Biopsy<br />
| Advantages <br />
| Disadvantages<br />
|- bgcolor="FFFAFA"<br />
| Polar Body<br />
| Day 1<br />
| No harm to oocyte<br />
| Only maternal DNA is tested, often needs to be coupled with other biopsies, and there are difficulties distinguishing between the first and second PB.<br />
|- bgcolor="FFFAFA"<br />
| Blastomere<br />
| Day 3<br />
| …<br />
| … <br />
|- bgcolor="FFFAFA"<br />
| Trophectoderm<br />
| Day 5 and 6 <br />
| Little harm to the embryo and large amount of genetic material is extracted. <br />
| Opening of blastocyst necessary, small time window for procedure<br />
|}<br />
===Polar Body Analysis===<br />
Day 1<br />
====Description====<br />
Polar body (PB) biopsy offers a promising alternative to biopsies performed at the blastomere stage for PGD/S indications on legal and practical grounds. Consequent embryo development does not necessitate the presence of the first and second PB and their removal may not be crucial. PB biopsy requires precise timing. Keeping track of the meiotic cell cycle is necessary to perform a successful biopsy and, therefore, PB biopsy usually is applied in combination with intracytoplasmic sperm injection (ICSI). During the maturation from the germinal vesicle stage to the metaphase-II stage the first PB is formed. A cytoplasmic bridge containing spindle remnants, that are still in contact with the cellular genetic material, links this PB to the oolemma for about 90 minutes after extrusion. It is possible to visualize these remnants by polarization microscopy and it is crucial to not perform the biopsy until the first PB is no longer firmly attached to the oolemma as this indicates an immature embryo.The oocyte tolerates mechanical zona dissection best during hours four until six after ICSI as the oolemma has stabilized by that time because of the cortical granule reaction. Over time the first PB degenerates stressing a temporal biopsy and its optimal extraction time window is four to 12 hours after ICSI. The second PB forms around two to four hours after ICSI. Its optimal time window for biopsy is set to be eight to 16 hours after ICSI due to the second PB being attached to the oolemma with spindle remnants until six hours after ICSI. Biopsy at this point may cause enucleation of the oocyte. Studies have shown that the amplification efficiency of second PB’s DNA is worse if the PB is extracted prior to eight hours after ICSI. Thus, it is possible to perform sequential and simultaneous biopsies for the first and second PB. If performed, sequentially the first PB may be removed four to 12 hours and the second PB eight to 16 hours after ICSI. The optimal time window for a biopsy for both the first and second PB simultaneously is eight to 12 hours after ICSI. It is highly preferred to analyze both PBs due to potential aneuploidies in either PB and crossing overs during meiosis<ref name="PMID22723007"/>. <br />
====Procedure====<br />
Chemical opening achieved with for example acidic tyrode’s solution of the zona pellucida is not tolerated by the oocyte and may have detrimental effects on the embryo’s development. Therefore, the access to the perivitelline space of the oocyte is provided by mechanical zona dissection or by laser. Both techniques work well if performed by experienced embryologist. However, laser-assisted biopsy is less time consuming when compared to manual dissection. It is critical to consider the size of the introduced opening as it will remain permanent. If it is too large the blastomere may be lost during embryo development and if it is too small it may interfere with hatching of the embryo during blastocyst stage<ref name="PMID22723007"/>.<br />
[[File:Polar_Body_Biopsy.jpeg|left|thumb|The presence of a faint but clearly identifiable strand connecting PB2 to the oolemma. The biopsy was performed ∼9 h after ICSI<ref name="PMID21908464"><pubmed>21908464</pubmed></ref>.]]<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JTaQzszVr8o</html5media><br />
|-<br />
| Laser-assisted polar body biopsy<ref>RIUK, R. (2013, June 25) Polar Body Biopsy [Video file]. Retrieved from https://www.youtube.com/watch?v=JTaQzszVr8o</ref><br />
|}<br />
====Advantages & Disadvantages====<br />
PB biopsies can only investigate the maternal contributions to the embryo as they are of maternal origin. Thus, this procedure is appropriate for PGD solely for monogenetic diseases from the maternal side. Recessive diseases may be evaluated with PB biopsies on the basis that the embryo’s outcome will be determined by the paternal contribution. It may still be applied for PGS as it is a fairly safe biopsy option and most aneuploidies either arise during meiosis or origin from the maternal genome. However, diagnosis error has been reported due to the lack of considering paternal contributions.Because PB biopsies are performed very early it is not yet known whether the oocyte will develop into a viable embryo. Thus, PBs are commonly frozen or fixed after biopsy and depending on the state of the embryo only chosen PBs will be tested. This is primarily an economic issue as many genetic testing procedures are very cost-intensive<ref name="PMID22723007"/>[[File:Implantation_predictive_value_of_euploid_screening_results.jpeg|thumb|The sustained implantation predictive value (with 95 % confidence interval) of a euploid screening result obtained from the first polar body (PB1), PB1 and the second polar body (PB2), or a direct embryo biopsy for each stage of embryo transfer (cleavage-stage and blastocyst stage)<ref name="PMID25106935"><pubmed>25106935</pubmed></ref>.]] Generally the sustained implantation predictive value of screening of PBs is significantly lower than of for example biopsies of the blastocyst stage<ref name="PMID25106935"/>. Moreover, it is often difficult to distinguish between the first and the second PB. As the first one degenerates quicker, this may influence diagnostic procedures<ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
===Blastomere biopsy===<br />
Day 3 <br />
====Description====<br />
Blastomere biopsy has been the prevalent method for PGD and PGS in the last two decades. At least one, but up to two, blastomeres are biopsied on day three of the cleavage stage embryo. The right number of blastomeres removed is a controversial topic as two cells allow for more genetic material and more accurate results. However, removing two cells might be too invasive and damaging to the embryo. As PGS tries to improve implantation rates, whereas PGD sets out to avoid known genetic disorders, for the former only one cell is removed, while for the latter often two need to be removed, to ensure results as correct as possible<ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
====Procedure====<br />
Initially a hole was drilled into the zona pellucida using acid tyrodes with the consequent aspiration of blastomeres with a pipette. Nowadays the zona pellucida is largely opened using a laser and calcium and magnesium free media have been introduced to decrease junctions between blastomeres, which facilitates the biopsy<ref name="PMID21748341"/>.<br />
[[File:Aspiration_of_a_Blastomere.jpeg|thumb|Aspiration of a Blastomere into the biopsy pipette<ref name=" PMID24783200"><pubmed>24783200</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=TbridWVwipI</html5media><br />
|-<br />
| Laser-assisted blastomere biopsy<ref>Sukprasert, M. (2014, March 5) Day 3 Blastomere Biopsy 1 [Video file]. Retrieved from https://www.youtube.com/watch?v=TbridWVwipI</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
===Trophectoderm biopsy===<br />
Day 5 and 6<br />
====Description====<br />
The improvement of embryo culture media allowed the in vitro development of human embryos until the blastocyst stage and opened up the possibility to take blastocyst biopsies. During day three to day five the haploid maternal and paternal genomes work together for the first time to form the genome of the embryo. The maternal epigenetic control lessens significantly while preparing for implantation with precisely arranged events happening. The first event includes a rapid increase in the number of embryonic cells which are active in mitotic divisions and apoptosis of aberrant cells. This is followed by the formation of blastocoel (cavitation) which results from the flattening of cell located on the outside of the blastomere. Now the blastocyst will expand until the embryo hatches by rupturing the zona pellucida. The cells of the blastocyst will differentiate to form two distinct cell lineages, the outer trophectoderm and the inner cell mass<ref name="PMID22723007"/>.<br />
====Procedure====<br />
Trophectoderm biopsy is usually performed in Hepes buffered biopsy medium and opening approaches include needle cutting which has been replaced by lasers in past years. Different research groups report different timings of the opening to be the most successful. Some open the blastocyst on day three or four by creating a 25 µm which causes the trophectoderm to herniate through this hole and is, thus, accessible for biopsy. Others create this hole about four hours before biopsy which allows sufficient herniation of trophectoderm cells. It is also possible to open the blastocyst immediately before biopsy. This avoids an extra step and the inner cell mass usually is easy to locate. Blastocyst biopsies involve the removal of trophectoderm cells and the ideal time for the procedure is day five. Successful biopsies on day six have been performed, while little is known about the results of biopsies on day seven. However, since the window of implantation in humans is from day eight to ten after ovulation, day seven biopsies appear to be possible<ref name="PMID22723007"/>.<br />
-collapse of trophoblasts<br />
-possible: biopsy of hatched blastocyst, holding pipette careful mild suction force to hold embryo near ICM <br />
-Cryopreservation<br />
<br />
<br />
[[File:Microscopic images of human blastocysts for biopsy.jpeg|thumb|(A) Some trophectoderm cells in a blastocyst started to hatch and (B) the trophectoderm cells were biopsied with assisted laser cutting. Images in C–D show the blastocysts after vitrification and warming. Blastocysts had been cultured for 2–4 hrs after warming, showing good (ICM and trophectoderm cells) hatched (C) and hatching (D) blastocysts. The hatching blastocyst in (E) has good ICM but fair trophectoderm while the blastocyst in (F) has both fair ICM and trophectoderm. Arrows indicate ICMs and arrow heads indicate trophectoderm cells. Bar = 40 µm<ref name="PMID2190846"><pubmed>2190846</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JI_TQ8d8tNM</html5media><br />
|-<br />
| Laser-assisted blastocyst biopsy (at 00:50 min)<ref>Coco, R. (2014, April 30) Trophectoderm biopsy in a Hatching blastocyst protruding ICM [Video file]. Retrieved from https://www.youtube.com/watch?v=JI_TQ8d8tNM</ref><br />
|}<br />
<br />
====Advantages & Disadvantages====<br />
Blastocyst biopsies are believed to be less damaging to the embryo and appear to be unrelated to implantation rates. In addition, this biopsy method allows for a larger extraction of cells for genetic testing. However, since they are performed late in in vitro development, the time window for genetic testing is relatively small. Fast and accurate genetic testing methods are needed to ensure a successful and safe result from this biopsy. Thus, blastocyst biopsies may gain more popularity in the future whn such methods have been developed or improved<ref name="PMID22723007"/>. <br />
==Genetic Techniques==<br />
===Polymerase Chain Reaction===<br />
PCR amplifies DNA specific to genetic sequence of interest . PCR was developed by Kay Mullis in the 1980s, for which he was awarded the Nobel prize for chemistry in 1993. <ref> Pubmed Docs (2015) Polymerase Chain Reaction (PCR) Pubmen. Retrieved from [http://www.ncbi.nlm.nih.gov/probe/docs/techpcr/]</ref> This technique enables clinicians to monitor and diagnose diseases using minute samples such as embryonic cells. <ref>Roche (2015) PCR: How We Copy DNA. Roche Molecular Systems Inc. retrieved From [http://molecular.roche.com/pcr/Pages/Process.aspx]</ref> PCR is used to detect genetic disorders, as a part of PGD, in conjunction with IVF. It is used to detect molecular abnormalities, such as single gene disorders including Tay Sach, Cycstic fibrosis, Duchenne Muscular Dystrophy, Thalassemia, Huntington disease, Spinal muscular atrophy and many more. Molecular and genetic analysis require a significant amount of DNA, which can be delivered by PCR. It revolutionized the study of DNA, replacing all previous recombinant DNA technology>.<ref> Mullins, K., Francois, F.& Gibbs R.A. (1994 ) The Polymerase Chain Reaction. p3. Springer- Science +Business Media. Birkhauser, Boston<br />
Available at [https://books.google.com.au/books?hl=en&lr=&id=gjrTBwAAQBAJ&oi=fnd&pg=PR5&dq=kary+mullis+PCR&ots=mpzAyRh5ZY&sig=PQ4goNoKJ90tb3-MkPk62zrTGbw#v=onepage&q=kary%20mullis%20PCR&f=false] </ref> and is a significant compenent of PGD procedures<ref name="PMID24907939"/<br />
[[File:PCR.jpg|thumb|right|Polymerase chain reaction (PCR) amplifies DNA specific to genetic sequence of interest, enabling the monitoring and diagnose molecular abnormalities such as single gene disorders using minute samples such as embryonic cells, blood & tissue <ref>NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref>]]<br />
{|<br />
|- align="left" bgcolor="DDCEF2"<br />
|'''Procedure'''<br />
|}<br />
Samples are obtained from the the blastocyst, a polar body biopsy or the blastomeres stages of the embryo. <br />
*Stage 1 Denaturing: separating the target strands of DNA <br />
The obtained sample is heated to roughly 90 degrees celcius, this heat breaks the relatively weak bonds between nucleotides that form DNA. The double stranded DNA is split into two single strands of DNA that are used as templates.<br />
*Stage 2 Annealing: Binding the Primers to the target DNA sequence <br />
PCR will only copy the target sequence of DNA specified by specific PCR primer. These synthesized primers oligonucleotides are small artificial pieces of DNA. TAQ polymerase enzyme synthesize two new strands of DNA duplicate to the single sample DNA stand template indicated by these primers. During this stage the reaction is cooled to a temperature between 40-60 degrees Celsius. <br />
*Stage 3- Extension- making copies <br />
Each of these two copies are then used again as templates generating two further replications This cycle can occur as many 30 -40 times within a couple hours leading to billions of extra copies of the original DNA segment. The optimal temperature for the further replication is roughly 72 degrees Celsius. <br />
This process mediated by a thermocycler machine that is programmed to alter the temperature of the reaction every couple of minutes, perpetuating the cycle of DNA denaturing and synthesis. <br />
This process, generates exponentially exact copies of the original template DNA sequence. <br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
!PCR cycles<br />
|-<br />
| '''PCR Cycle'''<br />
| '''Target Copies'''<br />
|-<br />
| 1<br />
| 2<br />
|-<br />
| 2<br />
| 4<br />
|-<br />
| 3<br />
| 8<br />
|-<br />
| 4<br />
| 16<br />
|-"<br />
| 5 <br />
| 32<br />
|-<br />
| 6 <br />
| 64<br />
|-<br />
| 7 <br />
| 128<br />
|-<br />
| 8<br />
| 256<br />
|- <br />
| 9<br />
| 512 <br />
|-<br />
| 10<br />
| 1024<br />
|-<br />
| 15<br />
| 32,768<br />
|-<br />
| 20 <br />
| 1,048,578<br />
|-<br />
| 25<br />
| 33,554,432<br />
|-<br />
| 30 <br />
| 1,073,741,842<br />
|-<br />
|}<br />
<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="7" |'''Advantages'''<br />
|-bgcolor="FFFAFA"<br />
| Fast and inexpensive way of copying a target sequence of DNA.<br />
|-bgcolor="FFFAFA"<br />
| Particularly useful for the diagnosis of single cell defects.<br />
|-bgcolor="FFFAFA"<br />
| Rapid generation of results (within hours).<br />
|-bgcolor="FFFAFA"<br />
| Highly sensitive, a single molecule of DNA is sufficient for reaction.<br />
|-bgcolor="FFFAFA"<br />
| Generates DNA copies exponentially.<br />
|-bgcolor="FFFAFA"<br />
| This enables DNA amplification required for molecular and genetic diagnostic analysis<ref> Dreesen, J., Drusedaul, M., Smeets, H., Die-Smulders, C., Coonen, E., Dumoulin, J., Gielen, M., Evers, J., Herbergers, J. & Geradets, J. (2008) Validation of preimplantation genetic diagnosis by PCR analysis: genotype comparison of the blastomere and corresponding embryo, implications for clinical practice. Mol. Hum. Reprod. 14 (10):573-579.doi: 10.1093/molehr/gan052. Retrieved from [http://molehr.oxfordjournals.org/content/14/10/573.short] </ref> <ref><pubmed>20966460</pubmed></ref>.<br />
|-bgcolor="DDCEF2"<br />
| rowspan="7"|'''Disadvantages'''<br />
|-bgcolor="FFFAFA"<br />
| Only during the exponential DNA replication phase, the starting quantity sequence contained in the original sample (template DNA strand) can be determined.<br />
|-bgcolor="FFFAFA"<br />
| PCR reaction is limited to by presence of inhibitors in the sample.<br />
|-bgcolor="FFFAFA"<br />
| Self annealing due to the accumulation of the product and the stopping exponential amplification for the target sequence and reaching of a plateau<br />
quantification of the end point of reaction of PCR products make real time quantitative RT-PCR necessary<ref> NIS (2015) Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref>.<br />
|-bgcolor="FFFAFA"<br />
| Not a diagnostic method on its own, but requires further analysis.<br />
|-bgcolor="FFFAFA"<br />
|Low-quantity DNA template may result in amplification failure<ref name="PMID24907939"/>.<br />
|-bgcolor="FFFAFA"<br />
|Allele drop-out (ADO) in heterozygous loci is possible<ref name="PMID24907939"/>.<br />
|}<br />
===Fluorescent In Situ Hybridisation===<br />
FISH is the one of the most effective and rapid <ref name="PMID26338801"><pubmed>26338801</pubmed></ref> method of conducting PGD. This techniques used to locate a specific DNA sequences within a chromosome. FISH facilitates the clinical diagnosis of chromosomal abnormalities indicated by sequential duplications, deletions and rearrangements of chromosome, that are usually missed with microscopic analysis. This technique is especially relevant for female embryos with X-linked diseases,<ref name="PMID20809319"><pubmed>20809319</pubmed></ref> that have no other mutation specific tests [http://www.ncbi.nlm.nih.gov/pubmed/20809319] As part of PGD, samples are collected from various stages of the embyro,and they are able to conducted tests on the blastocyst, a polar body biopsy and the blastomeres <ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. FISH is 99% effective when used in conjunction with competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities<ref name="PMID26338801"/>.<br />
{|<br />
|- align="left" bgcolor="DDCEF2"<br />
|'''Procedure'''<br />
|}<br />
Samples are collected from either the blastocyst, a polar body biopsy or the blastomeres stages of the embryo <ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
DNA strands are heated and denatured causing their the individual DNA strands to break apart<br />
Probes are single complimentary stands of DNA a that have been tagged with small chemical agents that glow brightly in the presence of a specific region on a chromosome. These specific probes then hybridize and join to their complementary DNA strand. <br />
The fluorescent tags enable the researchers to correctly identify the presence or lack thereof and location of the specific chromosomes that they are testing for. <ref name="PMID17876073"><pubmed>17876073</pubmed></ref><br />
Researcher analyse the results by identifying the number and the relative location of the fluorescent dots generated by the FISH images.<ref name="PMID17970921"><pubmed>17970921</pubmed></ref><br />
The probe will not fully hybridise if there has been a duplication or a deletion of the DNA - indicating chromosomal and sex chromosomal anomalies like trisomies and aneuploidies. <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref><br />
Different probes are used for different purposes: <ref>Unique, Rare Chromosome Disorder Support Group (2013) Fluorescence in situ hybridisation (FISH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/Other/FISH%20FTNW.pdf]</ref><br />
*'''Locus specific tags''' detect very small imbalances, and locate isolated small portions <br />
of genes within a chromosome<br />
*'''Alphoid/Centomeric Repeat probes''' are developed from the repetitive sequence located in the middle region of each chromosome, useful in determining the number of chromosomes , detecting rearrangement and when used in conjunction with locus probes to determine the absence of genetic material on a chromosome. <br />
*'''Paint Probes''' are collections of smaller probes with their own stains that bind to a different section on the chromosome - allowing the full chromosome too be labeled a unique colour, this "full colour map" can be used to know the spectral karyotype- full chromosomal mapping is useful in examining chromosomal abnormalities. <br />
[[File:Fluorescent In Situ Hybridisation (FISH).jpg|thumb|right|'''FISH''' We are able to tag Specific DNA sequences using Probes which have been tagged with fluorescent Labels.This technique enables the clinical diagnosis of chromosomal abnormalities, indicated by sequential duplication, deletions and rearrangements of chromosome <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref>]]<br />
<br />
{|class="wikitable" align="center"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="8" |'''Advantages''' <br />
|-bgcolor="FFFAFA" <br />
| FISH is 99% effective when used in conjunction with Competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities.<ref><pubmed>26338801</pubmed></ref><br />
|-bgcolor="FFFAFA" <br />
| Rapid generation of results<br />
|-bgcolor="FFFAFA"<br />
| Identifies very small translocations and aneuploidies that occur within chromosomes, that would usually be missed under microscopic analysis<br />
|-bgcolor="FFFAFA" <br />
| Indicates whether the accessed chromosomes are normal <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|-bgcolor="FFFAFA" <br />
| Tests for the most common chromosomal abnormalities - down syndrome chromosomes 13,16,18,21 and 22 <ref><pubmed>21749752</pubmed></ref><br />
|-bgcolor="FFFAFA" <br />
| It may be used to compare the chromosomal gene arrangements in related species<br />
|-bgcolor="FFFAFA" <br />
| Can be used to identify and remove inheritable X-linked disease or sex chromosome anomalies such as Duchenne's Muscular Dystrophy, hemophilia, ectodermal dysplasia <ref><pubmed>17876073</pubmed></ref><br />
|-bgcolor="DDCEF2"<br />
| rowspan="5"|'''Disadvantages'''<br />
|-bgcolor="FFFAFA" <br />
| FISH destroys all cells tested <ref> O'Connor, C. (2008) Fluorescence in situ hybridization (FISH). Nature Education 1(1):171. retrieved from [http://www.nature.com/scitable/topicpage/fluorescence-in-situ-hybridization-fish-327] </ref><br />
|-bgcolor="FFFAFA" <br />
| It does not fully access all chromosomes (only ~ 12)<br />
|-bgcolor="FFFAFA" <br />
| Analysis of results is dependent upon the dot quality impacted by hybridisation efficiency or the camera sensitivity <ref><pubmed>17970921</pubmed></ref><br />
|-bgcolor="FFFAFA" <br />
| Some studies indicate that using FISH on a day-3 embryo biopsy decreases the rate of live births <ref><pubmed>26168107</pubmed></ref><br />
|}<br />
<br />
===Array Comparative Genomic Hybridisation (aCGH)===<br />
aCGH also known as Microarray analysis efficiently scans the entire genome for chromosomal imbalances. CGH was initially developed to detect the number of changes in a solid tumor mass. It uses 2 genomes comparing the sample to the control, with each labeled in a different fluorescent dye<ref name="PMID1876176"><pubmed>1876176</pubmed></ref>. Earlier CGH techniques were limited by the resolution of the imaging <ref> Lichter, P., et al. Comparative genomic hybridization: Uses and limitations. Seminars in Hematology 37, 348–357 (2000)</ref> , these initial limitations were overcome by using Microarrays in conjunction with CGh to improve the resolution of the imaging, Array Comparative Genomic Hybridisation (aCGH). This method compares sample and control microarrayed slides containing small segments of DNA (probes). <ref> Lucito, R., et al. Representational oligonucleotide microarray analysis: A high-resolution method to detect genome copy number variation. Genome Research 13, 2291–2305 (2003) </ref> the Probes used will vary according from the small (25-85 base pairs) oligonucleotides manufactured to highlight different target sequences, to the very large genomic clones (80,000- 200,00 base pairs), and as these are significantly smaller than the traditional metaphase chromosomes used for CGH, generating a higher resolution of image. <ref name="PMID22467166"><pubmed>22467166</pubmed></ref>.aCGH is used as a diagnostic tool for prenatal detection f chromosomal abnormalities <ref name="PMID19012303"><pubmed>19012303</pubmed></ref>.<br />
{|<br />
|- align="left" bgcolor="DDCEF2"<br />
|'''Procedure'''<br />
|}<br />
<ref> Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432] </ref><br />
The sample is obtained (skin, blood or fetal cells) and DNA is obtained. <br />
As a part of PGD fetal cell samples are collected from; the fertilized egg polar bodies, the blastomere (day 3 embryo) or the blastocyst/tropoectoderm stage (day 5 embryo).<br />
Sample DNA is labeled with one fluorescent dye, and the control DNA is labeled with a different colored fluorescent dye. the control DNA is used as the base point of reference. <br />
heated and denatured single DNA strands then hybridize to their complementary single strand probes, which are then combined and applied to a microarray and the results are run through a computer program and a digital imaging system is used to quantify the results( fluorescent intensities of the labeled probes). <br />
<br />
[[File:aCGH.jpg|thumb|right|'''aCGH''' checks the entire genome for chromosomal imbalances, by comparing control and a sample slides contatining small segements of DNA sample microarrayed slides small segments of DNA. Illustrated by student z5020317 and adapted from <ref> NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation. retrieved from [http://www.phgfoundation.org/file/5237/]</ref> <ref>Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432]</ref>]]<br />
<br />
The fluorescent ratio and the hybridization signal at different locations on the genome of the control DNA are used to identify any variances present in the sample DNA. aCGH facilitates the clinical diagnosis of submicroscopic chromosomal duplication, deletion and rearrangements indicative of chromosomal disorders such as trisomies 1-22and specific sex linked disorders. <br />
Duplications in the DNA are displayed by the computer program as spikes/ peaks over an established threshold and deletions in DNA are displayed by the computer program as spikes/ toughs beneath this threshold <br />
<br />
{|class="wikitable" align="center"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="12" |'''Advantages''' <br />
|-bgcolor="FFFAFA"<br />
| Multiple applications: prenatal genetic diagnosis, cancer diagnosis, <ref name="PMID20193845"><pubmed>20193845</pubmed></ref> genetic screening for developmental delay (learning disabilities) <ref name="PMID17309648"><pubmed>17309648</pubmed></ref>. or congenital anomalies that are suspected to be genetic in origin <ref>NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation . retrieved from [http://www.phgfoundation.org/file/5237/]</ref><br />
|-bgcolor="FFFAFA"<br />
| trace represents all chromosomes present in the human genome chromosomes 1-22 and the X & Y chromosomes, and therefore is the most accurate method for testing whole embryo aneuploidy<br />
|-bgcolor="FFFAFA"<br />
| aCGH has been extensively tested, and Validated, and is now used world wide.<br />
|-bgcolor="FFFAFA"<br />
| Detects submicroscopic alterations<br />
|-bgcolor="FFFAFA"<br />
| Detects deletions and additions and rearrangements as well as amplification, of the WHOLE genome, simultaneously.<br />
|-bgcolor="FFFAFA"<br />
| Used as a diagnostic tool for prenatal detection of chromosomal abnormalities <ref name="PMID22034057"><pubmed>22034057</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Provides high resolution genomewide screening of segmental genomic copy number variations<br />
|-bgcolor="FFFAFA"<br />
| Very accurate when used in conjunction with FISH<br />
|-bgcolor="FFFAFA"<br />
| Alone is more reliable and in detecting chromosomal abnormalities, with a higher implantation success rate, than FISH <ref name="PMID20494259"><pubmed>20494259</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Allows an in depth research focus upon specific types of rearrangements within selected chromosomal regions, a recent particular area of interest is subtelomeric and pericentromeric rearrangements<br />
|-bgcolor="FFFAFA"<br />
| Reduces the risk of failed implantation and miscarriage, improving the chance of a healthy baby <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|-bgcolor="DDCEF2"<br />
| rowspan="9" |'''Disadvantages'''<br />
|-bgcolor="FFFAFA"<br />
| Translocations and inversions of DNA are not detected<br />
|-bgcolor="FFFAFA"<br />
| Limited ability diagnosing specific polyploidies such as triploidy <ref> Unique, Rare Chromosome Disorder Support Group (2013) Microarray-based Comparative Genomic Hybridiation (array CGH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/other/array%20cgh%20ftnw.pdf] </ref><br />
|-bgcolor="FFFAFA"<br />
| Will not detect mosaicism detection <20% (cultures where >1 of 5 cells are trisomy 12)<br />
|-bgcolor="FFFAFA"<br />
| Will not detect balanced chromosomal rearrangement<br />
|-bgcolor="FFFAFA"<br />
| Will not detect duplications or deletions <80kb<br />
|-bgcolor="FFFAFA"<br />
| Will not detect point mutations within genes <ref>Washington department of education (CGH- FAQ for physicians. Signature Genomic LAboratories, LLC. Retrieved from [https://depts.washington.edu/dbpeds/Lab%20Tests/SignatureCGH-physician_FAQ.pdf]</ref><br />
|-bgcolor="FFFAFA"<br />
| will not detect chromosomal position of genomic gains<br />
|-bgcolor="FFFAFA"<br />
| Will not detect loos of heterozygosity (LOH) or Absence of heterozygosity (AOH) <ref>WiCell Research Institute Inc. (2012) Comparative Genomic Hybridization Microarray. <br />
retrieved from [http://www.wicell.org/home/cytogenetic-services/cgh-microarray/array-comparative-genomic-hybridization-acgh.cmsx]</ref><br />
|}<br />
<br />
===Next Generation Sequencing===<br />
The development and advances within ART in the past 20 years, as well as the increasing popularity of IV, has lead to an influx of new technologies developed to screen embryos for chromosomal anomalies, which are covered by the umbrella term of Next generation Sequencing (NGS). NGS is a general term used to describe all of the new and emerging screening techniques currently being introduced and used as part of PGD for IVF . NGS screens for single gene disorders as well as conducting extensive and very comprehensive chromosome diagnosis by sequencing, counting, and accurately assembling millions of DNA reads, simultaneously. <ref name="PMID23499002"><pubmed>23499002</pubmed></ref> There is a movement for NGS to replace the other limited testing techniques and be used as the standard. <br />
{|<br />
|- align="left" bgcolor="DDCEF2"<br />
|'''Procedure'''<br />
|}<br />
Samples are collected from either blastomere or the blastocyst/tropoectoderm and processed for analysis by a computer system. <br />
The methodology of each process is unique to the technique being used. <br />
<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="14" |'''Advantages''' <br />
|-bgcolor="FFFAFA" <br />
| Cheaper<br />
|-bgcolor="FFFAFA"<br />
| Opens new diagnostic possibilities<br />
|-bgcolor="FFFAFA"<br />
| Accurately tests all 24 chromosomes<br />
|-bgcolor="FFFAFA"<br />
| Tests for the presence of monogenic diseases of known genetic background<br />
|-bgcolor="FFFAFA"<br />
| Reduces the number of biopsies required for diagnosis<br />
|-bgcolor="FFFAFA"<br />
| Higher detection rate of small translocations<br />
|-bgcolor="FFFAFA"<br />
| Highly accurate is testing for compound point mutations, chromosomal duplication, deletions and insertions <ref name="PMID23312231"><pubmed>23312231</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| It accurately detects chromosomal aneuploidy and unbalanced rearrangement <ref name="PMID25685330"><pubmed>25685330</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Higher detection rate of small translocations<br />
|-bgcolor="FFFAFA"<br />
| NGS single gene disorder screenings can conducted in conjunction with PCR comprehensive chromosomal screening<br />
|-bgcolor="FFFAFA"<br />
| Reduces human error <br />
|-bgcolor="FFFAFA"<br />
| Better detects the presence of mosaicism<br />
|-bgcolor="FFFAFA"<br />
| Work well in conjunction with CGH and aCGH as part of PGD, improving the chances of IVF. <ref> Morris, R. S. (2015 ) Next generation sequencing for PCG|PGS|CCS. IVF1 retrieved from [http://www.ivf1.com/next-generation-sequencing for-pgd] </ref><br />
|-bgcolor="DDCEF2"<br />
| '''Disadvantages''' <br />
|-bgcolor="FFFAFA"<br />
| There are limited information available to clinical applications of NGS <ref><pubmed>26100406</pubmed></ref><br />
|}<br />
<br />
==Diagnosis==<br />
There are a large amount of diseases that PGD can apply to, below are descriptions of the diseases that PGD are more commonly used for. Upon completion of the genetic testing for the genes of concern the cells the embryos are discarded and priority is given to those that are healthy. <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/><br />
===Cystic Fibrosis===<br />
Cystic fibrosis is a single gene disorder. It is autosomal recessive and involves mutations in the cystic fibrosis transmembrane conductance regulator (CTFR) gene. The CTFR gene is normally responsible for the decrease in chloride and the transport of bicarbonate in epithelial cells thus playing a major physiological role. In PGD procedures, identification of the gene is assisted by microsatellite markers that have similar composition to the CTFR gene itself. Biopsy of two cells at the blastocyst stage is recommended if markers are not available. There are many variations of cystic fibrosis the most common being P.Phe508del <ref name="PMID26014425"><pubmed>26014425</pubmed></ref>.<br />
===Duchenne Muscular Dystrophy ===<br />
Duchenne Muscular Dystrophy is an X-linked recessive disease. It involves the Xp21 gene where majority of the mutations are chromosomal deletions with a smaller percentage resulting from duplications <ref name="PMID18359022"><pubmed>18359022</pubmed></ref>.<br />
<br />
===Autosomal Recessive Meckel-Gruber Syndrome===<br />
Autosomal recessive genetic defect caused by the TMEM67 gene. It results in cystic dysplasia of the kidneys with fibrotic change in the liber and occipital encephalocele. Other malformations could also be present in the central nervous system. In PGD whole genome amplification of single blastomeres are taken to identify the gene, this is also coupled with PCR techniques. Maternal plasma can also be extracted for PGS. <ref><pubmed>24039893</pubmed></ref> <br />
===β – Thalassemia=== <br />
β – Thalassemia is known as the most common type of autosomal recessive inherited disorder among haemoglobinopathies. It involves the adult β-globin gene and is associated with the absent or decreased expression of the gene. This is commonly caused by a single nucleotide change in the gene. PGD has been used successfully worldwide to identify the β-globin gene where its application is usually performed on a single blastomere or polar body <ref name="PMID19064120">19064120</pubmed></ref>.<br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
! Applicable diseases for PGD <ref>Genoma Group (2014). Retrieved September 18th, 2015, from http://www.preimplantationgeneticdiagnosis.it/genetic-diseases-diagnosed-by-pgd.htm </ref>, <ref>Genesis Genetics (2015). Retrieved September 18th, 2015, from http://genesisgenetics.org/pgd/what-we-test-for/</ref>, <ref>Human Fertilisation & Embryology Authority (2015). Retrieved Septembr 18th, 2015, from http://guide.hfea.gov.uk/pgd/</ref><br />
|-<br />
| '''Disease'''<br />
| '''Involved Genes'''<br />
|-<br />
| 5 Alpha Reductase Deficiency (5ARD)<br />
| SRD5A2 <br />
|-<br />
| Achondroplasia<br />
|FGFR3 <br />
|-<br />
| Acute Intermittent Porphyria <br />
| ALAD, ALAS2, CPOX, FECH, HMBS, PPOX, UROD, or UROS<br />
|-<br />
| Adrenoleukodystrophy (Adrenomyeloneuropathy)<br />
| ABCD1 <br />
|-<br />
| Agammaglobulinaemia (x-linked) <br />
|BTK <br />
|-<br />
| Agammaglobulinemia Bruton Tyrosine Kinase (BTK) <br />
|BTK <br />
|-<br />
| Aicardi Goutieres Syndrome 1 (AGS1) <br />
|TREX1, RNASEH2A, RNASEH2B, RNASEH2C, SAMHD1<br />
|-<br />
| Alagille Syndrome<br />
|JAG1 or NOTCH2<br />
|- <br />
| Alpers-Huttenlocher Syndrome <br />
|POLG <br />
|-<br />
| Alpha-1-antitrypsin deficiency <br />
|SERPINA1 <br />
|-<br />
| Alpha-Mannosidosis<br />
| MAN2B1 <br />
|-<br />
| Alpha Thalassemia <br />
|HBA1 or HBA2 <br />
|-<br />
| Alports Syndrome<br />
|COL4A3, COL4A4, COL4A5<br />
|-<br />
| Alzheimer's Disease - early onset (Type 3 and 4) <br />
|APP, PSEN1, or PSEN2<br />
|-<br />
| Amyotrophic Lateral Sclerosis 1 (ALS1) <br />
|C9orf72, SOD1, TARDBP, FUS, ANG, ALS2, SETX, VAPB <br />
|-<br />
| Argininosuccinic Aciduria <br />
| ASL<br />
|-<br />
| Arrhythmogenic Right Ventricular Cardiomyopathy/ Dysplasia (ARVC/D)<br />
| DSG2; DSP; PKP2<br />
|-<br />
| Ataxia Telangiectasia<br />
| ATM<br />
|-<br />
| Autosomal Recessive Meckel-Gruber Syndrome<br />
| TMEM67<br />
|-<br />
| Bardet-Biedl Syndrome (BBS)<br />
| BBS1; BBS10<br />
|-<br />
| Barth Syndrome<br />
| TAZ<br />
|-<br />
| Beta Thalassaemia<br />
| HBB<br />
|-<br />
| Birt-Hogg-Dubé Syndrome<br />
| FLCN<br />
|-<br />
| Breast Ovarian Cancer Familial Susceptibility (BRCA2)<br />
| BRCA1; BRCA2<br />
|-<br />
| Canavan Disease <br />
| ASPA<br />
|-<br />
| Carnitine-Acylcarnitine Translocase Deficiency <br />
| SLC25A20<br />
|-<br />
| Cerebral Arteriopathy with Subcortical Infarcts & Leukoencephalopathy (CADASIL)<br />
| NOTCH3<br />
|-<br />
| Cerebral Cavernous Malformation<br />
| CCM1<br />
|-<br />
| Charcot-Marie-Tooth Disease<br />
| GJB1; MPZ; NEFL; PMP22<br />
|-<br />
| CHARGE Syndrome<br />
| CHD7<br />
|-<br />
| Cherubism<br />
| SH3BP2<br />
|-<br />
| Choroideremia<br />
| CHM<br />
|-<br />
| Chronic Granulomatous Disease<br />
| CYBB; NCF1<br />
|-<br />
| Ciliary Dyskinesia<br />
| DNAH5<br />
|-<br />
| Citrullinemia<br />
| ASS1<br />
|-<br />
| Cleidocranial Dysplasia<br />
| RUNX2<br />
|-<br />
| Cockayne Syndrome<br />
| ERCC6<br />
|-<br />
| Congenital Adrenal Hyperplasia<br />
| CYP21A2<br />
|-<br />
| Congenital Cataracts<br />
| GJA8; VSX2<br />
|-<br />
| Congenital Diarrhea, Syndromic<br />
| SPINT2<br />
|-<br />
| Congenital Disorders of Glycosylation (CDG)<br />
| ALG1; ALG6; CDG1C; DOLK; PMM2<br />
|-<br />
| Cornelia de Lange Syndrome <br />
| NIPBL<br />
|-<br />
| Craniosynostosis<br />
| TWIST1<br />
|-<br />
| Crouzon Syndrome<br />
| FGFR2<br />
|-<br />
| Cysteinyl Leukotriene Receptor 1 Deficiency <br />
| CYSLTR1<br />
|-<br />
| Cystic Fibrosis<br />
| CFTR<br />
|-<br />
| Diamond –Blackfan Anemia <br />
| RPS19<br />
|-<br />
| Duchenne Muscular Dystrophy <br />
| DMD<br />
|-<br />
| Dyskeratosis congenita (Male embryos only)<br />
| DKC1<br />
|-<br />
| Ectodermal dysplasia (Hypohidrotic)<br />
| EDA; EDA1; GJB6; IKBKG<br />
|-<br />
| Familial Adenomatous polyposis coli (FAP)<br />
| APC<br />
|-<br />
| Familial Dysautonomia<br />
| IKBKAP<br />
|-<br />
| Fanconi Anemia <br />
| FANCA; FANCC; FANCD2; FANCF; FANCG; FANCJ<br />
|-<br />
| Fragile X Syndrome (FRAX)<br />
| FMR1<br />
|-<br />
| Galactosemia <br />
| GALT<br />
|-<br />
| Gangliosidosis<br />
| GLB1<br />
|-<br />
| Glanzmann Thrombasthenia <br />
| ITGA2B<br />
|-<br />
| Glutaric Acidemia (aciduria)<br />
| GCDH <br />
|-<br />
| Glycogen Storage Disease <br />
| G6PC; GAA; SLC37A4<br />
|-<br />
| Haemophilia A<br />
| F8<br />
|-<br />
| Haemophilia B<br />
| F9<br />
|-<br />
| Hereditary Nonpolyposis Colorectal Cancer: Lynch Syndrome<br />
| MLH1; MSH2; MSH6<br />
|-<br />
| Holt Oram Syndrome<br />
| TBX5<br />
|-<br />
| Huntington Disease<br />
| HD<br />
|-<br />
| Hydrocephalus<br />
| L1CAM<br />
|-<br />
| Ichthyosis <br />
| ABCA12; STS<br />
|-<br />
| Incontinentia Pigmenti (IP)<br />
| NEMO<br />
|-<br />
| Joubert Syndrome 5<br />
| INPP5E<br />
|-<br />
| Krabbe Disease<br />
| GALC<br />
|-<br />
| Leber Congenital Amaurosis (LCA)<br />
| CEP290; GUCY2D<br />
|-<br />
| Leigh Syndrome (Infantile Subacute Necrotising Encephalopathy)<br />
| LRPPRC<br />
|-<br />
| Lesch Nyan Syndrome<br />
| HPRT1<br />
|-<br />
| Leukocyte Adhesion Deficiency (Type I)<br />
| ITGB2<br />
|-<br />
| Li-Fraumeni Syndrome<br />
| TP53<br />
|-<br />
| Macular Dystrophy Retinal <br />
| VMD2<br />
|-<br />
| Maple Syrup Urine Disorder (MSUD)<br />
| BCKDHB<br />
|-<br />
| Marfan Syndrome <br />
| FBN1<br />
|-<br />
| Menkes Syndrome<br />
| ATP7A<br />
|-<br />
| Mitochondrial DNA Depletion Syndrom <br />
| POLG; RRM2B; SUCLA2; TK2<br />
|-<br />
| Mucolipidosis type II<br />
| GNPTAB<br />
|-<br />
| Multiple Endocrine Neoplasia<br />
| MEN1; MEN2A; MEN2B<br />
|-<br />
| Multiple Exostoses<br />
| EXT1; EXT2 <br />
|-<br />
| Myotubular myopathy<br />
| MTM1 <br />
|-<br />
| Nail-Patella Syndrome<br />
| LMX1B<br />
|-<br />
| Neurofibromatosis Type 1<br />
| NF1<br />
|-<br />
| Neurofibromatosis Type 2 <br />
| NF2<br />
|-<br />
| Noonan Syndrome<br />
| KRAS, PTPN11; SOS1<br />
|-<br />
| Norrie Disease<br />
| NDP<br />
|-<br />
| Ocular Albinism <br />
| GPR143<br />
|-<br />
| Oculocutaneous Albinism <br />
| OCA2; TYR <br />
|-<br />
| Oculodentaldigital Dysplasia<br />
| GJA1<br />
|-<br />
| Optic Atrophy<br />
| OPA1<br />
|-<br />
| Ornithine Transcarbamylase Deficiency <br />
| OTC<br />
|-<br />
| Osteogenesis imperfeca <br />
| COL1A1; COL1A2<br />
|-<br />
| Osteopetrosis <br />
| CLCN7; OSTM1; TCIRG1<br />
|-<br />
| Pachyonychia Congenita <br />
| KRT16; KRT6A<br />
|-<br />
| Pancreatitis, Hereditary<br />
| PRSS1 <br />
|-<br />
| Papillorenal syndrome <br />
| PAX2<br />
|-<br />
| Phenylketonuria <br />
| PAH <br />
|-<br />
| This table does not cover the complete list of diseases that PGD can be applied to.<br />
|}<br />
<br />
==Laws & Legal status==<br />
<br />
{| class="wikitable" <br />
|-bgcolor="DDCEF2"<br />
|'''Country'''<br />
|'''Legislation'''<br />
|-bgcolor="FFFAFA" <br />
| Australia<br />
| PGD is currently used to detect serious genetic conditions to improve the outcome of Assisted Reproductive Technologies (ART). In very rare cases it may be used to select an embryo with compatible tissue for a sibling who has a life-threatening disease where other means of treatment is unavailable. This is with the conditions that the use of PGD will not affect the welfare and interests of the child to be born. The parents must also receive adequate counselling and have full understanding of the procedures of PGD. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"> National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art</ref><br />
The use of PGD for sex-selection is prohibited with the exception of reducing the risk of the transmission of serious sex-linked genetic conditions. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"/><br />
|-bgcolor="FFFAFA"<br />
| Brazil<br />
| The laws regarding PGD in Brazil are not strictly regulated. They are vague and there is limited information surround the activities of assisted reproduction in general in the country <ref name="PMID25493379"><pubmed>25493379</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| Czech Republic<br />
| The laws in the Czech Republic allow those with a “defined indication in order to exclude risk of serous genetically conditioned disease and defects with embryos before they are implanted into the cavity of the uterus”. Couples that undergo any assisted reproductive treatment including PGD have to be married. Sex-selection is illegal except in regards to serious sex-linked genetic diseases <ref name="PMID24777348"><pubmed>24777348</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| Greece<br />
| In Greece, ART is open to those up to the age of 50 with written consent. It can only be used if a medical necessity is present such as the susceptibility of serious hereditary diseases. Sex selection is banned apart from cases of sex-linked diseases and sexually transmitted diseases <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| India<br />
| In India there is a cultural preference for boys thus the Prenatal Diagnostic Techniques (Regulation and Prevention of Misuse) Act was introduced in 1994. This law limits the use of PGD for sex determination except in cases of specific congenital diseases. These laws however are not strictly enforced. <ref>World Health Organisation (2015) Gender and Genetics Retrieved on October 21st 2015 from:http://www.who.int/genomics/gender/en/index4.html</ref><br />
|-bgcolor="FFFAFA"<br />
| Portugal <br />
| ART is only available to those who are married or have a similar type of relationship for at least two years. The couples cannot be of the same sex and must be at least 18 years of age. Sex selection is illegal except in cases of sex-linked diseases. The use of PGD is illegal if the predictive value of genetic tests are very low <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| Spain<br />
| PGD can be applied to “serious hereditary diseases not amenable to postnatal curative treatment” and “detection of other abnormalities which may compromise the viability of the pre-embryo”. If PGD is to be used for any other purpose authorisation must be acquired <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| Sweden <br />
| The use of PGD is strictly regulated and couples must achieve authorisation of the National Board of Health and Welfare. It can only be used it can only be used if the child is at risk to inheriting a serious chromosomal or monogenetic disease. It cannot be used for selection of specific characteristics <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| United Kingdom<br />
| Those involved with carrying out the IVF treatment must have a license from the Human Fertilisation and Embryology Authority (HFEA). Only embryos that are approved by the HFEA can be implanted where the embryonic nuclear or mitochondrial DNA cannot be altered with the exception of preventing mitochondrial diseases <ref name="PMID24777348"/>. <br />
|}<br />
<br />
==Future/Current Research==<br />
In addition to research efforts for improving overall performance of established PGD/S techniques, such as finding the ideal zona pellucida insection site in an fully automatic manner<ref name="PMID26259216"><pubmed>26259216</pubmed></ref>, many research efforts have been spent to find alternative, non-invasive techniques to test for diseases and abnormalities<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
===Non-invasive Preimplantation Genetic Testing without Embryo Biopsy===<br />
Different parameters of gametes, zygotes, embryos (“vacuoles in sperm heads, spindle position in mature oocytes, cleavage intervals of zygote, and embryo developmental dynamics”) may correlate with aneuploidy rates. This knowledge may be applied in potential noninvasive preimplantation diagnostic methods. Several methods have been proposed and are currently further researched<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Sperm Selection====<br />
Intracytoplasmic morphologically selected sperm injection (IMSI) is common procedure in IVF treatment to improve fertilization rates in patients with poor semen quality. In addition, studies have found that IMSI improves embryo development and that spermatozoa with large vacuoles in their heads correlate with increased aneuploidy rates and disturbed chromosomal structures. Thus, selecting spermatozoa based on morphological hallmarks may decrease aneuploidy rates in the fertilized embryos. As with polar body biopsies, however, this approach will solely be applicable if evidence for severe male detrimental contribution is given<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Blastocoel Fluid Extraction====<br />
In addition, a less invasive retrieval of material for diagnosis could include the extraction of the blastocoel fluid. The cavity of the blastocyst, lined by the trophectoderm, is filled with this blastocoel fluid, which contains metabolites of both trophectoderm and inner cell mass origin. The retrieval does not require a biopsy but merely a small opening to extract the fluid and, thus, causes less harm to the embryo. Multiple studies have applied this method<ref name="PMID22020776"><pubmed>22020776</pubmed></ref> <ref name="PMID23148560"><pubmed>23148560</pubmed></ref> <ref name="PMID26006737"><pubmed>26006737</pubmed></ref> and it may in the future become of clinical relevance.[[File:Aspiration_of_the_Blastocoel_Fluid.jpeg|400px|thumb|Aspiration of the Blastocoel Fluid using a ICSI pipette<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.]]Next to metabolites, the blastocoel fluid can contain DNA. Studies have shown that genomic DNA is present in about 90% of the blastocoel fluid samples tested. Typically the fluid is removed with an ICSI pipette from a day five blastocyst through its mural trophectoderm until the blastocyst fully collapses around the embryo. Several concerns regarding this method in a clinical setting have been raised. The collected DNA may be contaminated by the culture media that contains DNA fractions. The DNA may also be least representative of the actual embryos genome as the DNA may originate from abnormal or degenerated cells. Even though labelled noninvasive, the blastocyst still undergoes manipulation to some degree which may affect its viability. Thus, more research is required until this method can evolve from research to clinical use<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
====Proteomics and Medium Based PGD====<br />
The media in which embryos are kept during the early IVF procedures, gives rise to potential non-invasive techniques. For instance, the protein secretome of blastocysts may be representative of its chromosome constitution Recent studies have found biomarkers such as lipocalin-1, interleukin-10, tumor necrosis factor, stem cell factor, and chemokine ligand 13 to be differently secreted by aneuploid blastocyst than by euploid ones. The most significant biomarker appears to be interleukin-10. Paired with novel proteomic technologies and mass spectrometry this knowledge when extended may contribute to a new invasive PGD method<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. In addition, medium based non-invasive PGD has been researched for the diagnose of human α-thalassemia-SEA. Genomic DNA was collected from the media and the study surprisingly resulted in increased diagnosis efficacy compared to biopsy-based methods<ref name="PMID25816038"><pubmed>25816038</pubmed></ref>.<br />
====Embryo Morphology====<br />
Using time lapse imaging the embryo’s morphology can be closely observed and potential aneuploidy characteristics detected. Such characteristics may include the time of division to five cells, the time between the division from three to four cells, and the duration of the division from one to two and subsequently to three. In addition, the morphological quality of ICM an TE has been positively associated with aneuploidy or euploidy prognosis<ref name="PMID26246880"><pubmed>26246880</pubmed></ref>. These may give rise to an embryo quality screening prior to implantation<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
==Glossary==<br />
'''Biopsy:''' sample of tissue taken for examination <br />
<br />
'''Blastocyst:''' Stage of embryo at approximately day 5 consisting of an outer (trophoblast) layer and inner (embryoblast) cell mass. <br />
<br />
'''Blastomere:''' Initial cells formed through mitosis of the zygote<br />
<br />
'''CTFR''' Cystic Fibrosis Transmembrane Conductance Regulator, responsible for transport of chloride across the cell membrane<br />
<br />
'''Fluorescent In situ hybridisation:''' technique use to locate specific gene sequences using fluorescence tags <br />
<br />
'''Intracytoplasmic Morphologically Selected Sperm Injection (IMSI):''' IVF technique involving morphological selection of sperm under the microscope to be injected to oocyte<br />
<br />
'''Intracytoplasmic Sperm Injection (ICSI):''' IVF technique used to treat male infertility and involves direct injection of one sperm into an oocyte<br />
<br />
'''Next Generation Sequencing (NGS):''' Term used to describe the collection of recent findings regarding embryo screening<br />
<br />
'''Polar bodies:''' cell formed during the meiotic stages of the oocyte containing extra genetic material <br />
<br />
'''Polymerase Chain Reaction (PCR):''' Technique used to amplify DNA to study a specific genetic sequence<br />
<br />
'''Preimplantation Genetic Diagnosis (PGD):''' Involves genetic testing conducted to identify abnormalities in an embryo before implantation.<br />
<br />
'''Preimplantation Genetic Screening (PGS):''' Involves genetic screening for genetic abnormalities using techniques such as FISH and PCR to eliminate unhealthy embryos <br />
<br />
'''Robertsonian Translocations:''' Type of structural chromosomal translocation <br />
<br />
<br />
'''ESHRE'''The European Society for Human Reproduction and Embryology<br />
<br />
<br />
'''ICSI''' Intracytoplasmic Sperm Injection<br />
<br />
'''IMSI''' Intracytoplasmic Morphologically Selected Sperm Injection<br />
<br />
'''NGS''' Next Generation Sequencing <br />
<br />
<br />
''SNP''' Single Nucleotide Polymorphism <br />
==References==<br />
<br />
<references/><br />
<br />
<br />
{{StudentPage2015}}</div>Z5017878https://embryology.med.unsw.edu.au/embryology/index.php?title=2015_Group_Project_6&diff=2073192015 Group Project 62015-10-22T05:27:03Z<p>Z5017878: </p>
<hr />
<div>{{ANAT2341Project2015header}}<br />
<br />
<br />
=Preimplantation Genetic Diagnosis and Preimplantation Genetic Screening=<br />
==Introduction==<br />
Preimplantation genetic diagnosis (PGD) and preimplantation genetic screening (PGS) are reproductive options for couples with known family histories of genetic disease or couples undergoing IVF procedures due to infertility issues. PGD can diagnose many genetic disorders caused by known chromosomal abnormalities (number and/or structure) or single gene mutations, and, thus decrease the risk of termination of pregnancy or miscarriages and enable such couples to have an unaffected child<ref name="PMID24907939"><pubmed>24907939</pubmed></ref>. Through major improvements in PGD/S and general laboratory technology, the testing for abnormalities in fetuses has shifted from prenatal diagnosis during the first 2 trimesters <ref> Blackburn, S.L. (2003) '''Maternal, Fetal & Neonatal physiology: a Clinical perspective''' (2nd ed.). Seattle: Saudners </ref>, testing for overall fetal growth, complications of pregnancy, and birth defects<ref> Sadler T.W.(2012) '''Langman's Medical Embryology''' (12th ed.) Philadelphia: Lipincott, Wiliams & Wilkins, a Wolters Kluwer Business </ref>, to an embryonic focus especially in advancements in Artificial Reproductive Technologies (ART)<ref><pubmed>20638568</pubmed></ref>. In 1990 PGD for a recessive X-linked disease resulted in the first live birth<ref><pubmed>2330030</pubmed></ref> and has since been incorporated in clinical routine and applied for a variety of genetic diseases, such as sickle cell anemia, thalassemia, or cystic fibrosis<ref name="PMID24907939"/>.<br />
[[File:Preimplantation Genetic Diagnosis Procedure.jpeg|600px|left|thumb| Simplified steps for PGD<ref name="PMID24907939"/>]]<br />
{|class="wikitable"align="right" <br />
| <html5media height="400" width="533">https://www.youtube.com/watch?v=0e-79qKllqk</html5media><br />
|-<br />
| Preimplantation Genetic Diagnosis<ref>IVF Florida (2011, December 11) IVF Florida - South Florida Fertility Specialists - Pre-Implantation Genetic Diagnosis [Video file]. Retrieved from https://www.youtube.com/watch?v=0e-79qKllqk</ref><br />
|}<br />
<br />
==History==<br />
The advances in reproductive technology during the second half of the 20th century, led to PGD's first clinical application in 1990 <ref>Harper, J. (n.d.). The history of PGD. Lecture. UCL Centre for PG&D and CRGH.University College London</ref>.<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
|Year<br />
|<br />
|- bgcolor="FFFAFA"<br />
| '''1967''' <br />
|First PGD on rabbit blastocysts (Gardner& Edwards) <ref name="PMID6036172"><pubmed>6036172</pubmed></ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1986''' <br />
|First Cleavage Biopsy (Wilton & Trounson)<ref>Wilton, L. J., & Trounson, A. O. (1986). Viability of mouse embryos and blastomeres following biopsy of a single cell. In Proceedings of the 18th Annual Conference of the Australian Society for Reproductive Biology, Brisbane, Australia.</ref><br />
|- bgcolor="FFFAFA"<br />
|'''1987''' <br />
|First Blastocyst Biopsy (Muggleton-Harris, Monk, Rawlings, & Whittingham)<ref name="PMID3372699"><pubmed>3372699</pubmed></ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1988''' <br />
|First Polar Body Biopsy (Yury Verlinksy)<ref> Verlinsky, Y., Pergament, E., Andresen, P., Enriquez, G., & Strom, C. (1989). Genetic analysis of polar body DNA: A new approach to preimplantation genetic diagnosis. Am J Hum Genet, 45(4), A272.</ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1990''' <br />
|First Clinical PGD using PCR testing for X-linked (Handyside, Kontogianni, Hardy, & Winston)<ref name="PMID2330030"><pubmed>2330030</pubmed></ref> <br />
|} <br />
==Preimplantation Genetic Diagnosis==<br />
PGD is used to test the genetic makeup of embryos to detect single gene disorders, chromosomal abnormalities and mitochondrial disorders. It also has applications in gender selection for diseases with unequal gender distributions <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Some diseases commonly involved with PGD include cystic fibrosis, spinal muscular atrophy and beta – thalassaemia <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press.">Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press</ref> <ref name="PMID17823145"><pubmed>17823145</pubmed></ref>. It was first used in the United Kingdom in the 1980s of arenoleucodystrophy and primarily focusing on sex- linked disorders <ref name="PMID17823145"/><ref name="PMID23150080"><pubmed>23150080</pubmed></ref>. PGD is now capable of detecting single cell defects (molecular) and chromosomal disorders resulting from the inversion, translocation or deletion of chromosomes (cytogenic) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>,<ref name="PMID11325751"><pubmed>11325751</pubmed></ref>. PGD can be applied to the embryo at different stages. That is on polar bodies, blastomeres or blastocyst <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>.<br />
Depending on the type of genetic disorder, PGD utilises different methods of genetic testing. These include Fluorescence in situ hybridisation (FISH) which is used for sex – linked disorders and detects chromosomal rearrangements <ref name="PMID11325751"/><ref name="PMID17876073"><pubmed>17876073</pubmed></ref> and Embryo halotyping which allows the identification of chromosomes causing the inherited disorder through knowledge of the pattern of closely linked markers <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. Polymerase chain reaction (PCR) is also widely used to detect molecular abnormalities <ref name="PMID11325751"/>.<br />
PGD is tightly regulated and supported by large organisations namely The American Society for Reproductive Medicine, The European Society for Human Reproduction and Embryology (ESHRE), The European Society of Human Genetics and the Preimplantation Genetic Diagnosis International Society <ref name="PMID25500181><pubmed>25500181</pubmed></ref>.<br />
===Sex-linked disorders===<br />
The determination of a disease as gender specific usually correlates with the presence or absence of specific genes such as SRY on the Y chromosome. It is known that females have two X chromosomes and males have an X and a Y chromosome where abnormalities are more prevalent on the X chromosome. PGD can be used for sex selection where only male embryos are transferred to reduce the chance of inheriting X-linked disorders. However, this does not completely eradicate the problem as male embryos remain susceptible to inheriting an affected X chromosome. Sex determination is only used when the specific mutation is unknown and has yet to be discovered <ref name="PMID24866878"><pubmed>24866878</pubmed></ref>.<br />
===Single gene defects===<br />
Single gene defects can be dominant, recessive, autosomal or X-linked. They are commonly diagnosed using PCR and although the PCR available today is complex and capable of combatting a large range of disease the development of new protocols has been proven to be difficult due to the small DNA sample available <ref name="PMID26168107"><pubmed>26168107</pubmed></ref><br />
===Mitochondrial disorders===<br />
Mitochondrial disorders also known as oxidative phosphorylation disorders arise from mutations in the nuclear DNA or mitochondrial DNA <ref name="PMID26312584"><pubmed>26312584</pubmed></ref>. They pose as a problem because they are unrecognisable until the mutations in the cell reach a detrimental level <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Mitochondrial disorders cause miscarriages and stillbirths as well as death in children and young adults. The effects can either be contained in a single organ or more commonly involve multiple organ failure where organs with high energy demands such as the brain, liver muscle and heart and heavily influenced. They are usually occur spontaneously or result from inheritance from the mother. Since mitochondria are solely inherited from the mother oocyte donations have been used as a solution to combat mitochondrial disorders. Additionally, there has been an increasing use in PGD where embryos that stay under the given threshold of 18% gene-mutations are allowed to be transferred and result in normal development. New technology in the areas of nuclear gene transfer and genome editing are also being experimented with <ref name="PMID26312584"/>. <br />
===Chromosomal disorders===<br />
Chromosomal disorders can be reciprocal, Robertsonian translocations, inversions, deletions and insertions <ref name="PMID26168107"/>. . Data from ESHRE collected between 2010 and 2011 has shown that the most common chromosomal abnormality confronted in PGD are reciprocal chromosomal abnormalities <ref name"PMID26071418"><pubmed>26071418</pubmed></ref>. PGD has also been used successfully for Robertsonian translocations (RT), a type of structural translocation. Children who carry RT are phenotypically normal, however in their later years it is found that they will suffer from infertility and repeated miscarriages due to the high frequency of abnormal embryos <ref name="PMID22081077"><pubmed>22081077</pubmed></ref>. PCR and FISH are the two main techniques used for chromosomal disorders. To be able to conduct the examinations the cells are required to be at the metaphase stage <ref name="PMID26168107"/>. <br />
[[File:Reasons_for_PGD.jpg|600px|thumb|Reasons for PGD<ref name= "PMID24764761"><pubmed><24764761</pubmed></ref>]]<br />
==Preimplantation Genetic Screening==<br />
PGS involves an array of methods or ideas that aim to segregate embryos that have genetic flaws and those that are healthy <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. The occurrence of aneuploidy is high around the stages of early embryonic development and they are the most common cause if miscarriages and congenital birth defects <ref name= "PMID26085841"><pubmed>26085841</pubmed></ref>. They have little effect on the morphology of the embryo making them difficult to identify thus identification heavily relies on genetic testing <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. <br />
Genetic sampling is most commonly conducted using Microarray Comparative Genomic Hybridisation (aCGH) as well as FISH, Quantitative PCR and Single Nucleotide Polymorphism (SNP) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. These methods collectively aim to assess numeral and structural chromosomal errors <ref name= "PMID26085841"/>. Studies have also introduced Next- Generation Sequencing (NGS) <ref name= "PMID26085841"/> and Whole Genome Amplification used to screen imbalances in the complete 24-chromosomes <ref name="PMID25953353"><pubmed>25953353</pubmed></ref><br />
Statistics from ESHRE have shown that the most common indications for PGS is advanced age, followed by repeated implantation failure or recurrent miscarriage and male infertility <ref name="PMID26071418"><pubmed>26071418</pubmed></ref>.<br />
===Indications===<br />
A low percentage of structural abnormalities in chromosomes are responsible for the cause of miscarriages. Despite this, they are the most prevalent type of chromosomal abnormality accounted for in PGD <ref name="PMID20638568"/>. The presence of specific gene cycles, initiation of embryonic protein synthesis and evident physiological development are all indicative of a successful in vitro fertilisation procedure <ref name="PMID11576737"><pubmed>11576737</pubmed></ref>. To eliminate further errors from occurring during the PGD procedure it is recommended to undertake further prenatal testing such as amniocentesis in the later stages <ref name="PMID20638568"/>. <br />
====Advanced maternal age====<br />
Data provided by the ESHRE has shown that the mean age of women undergoing PGS is 39 years <ref name="PMID26071418"/>. Women of advanced age have been shown to have a lower rate of pregnancies reaching childbirth <ref name="PMID18583331"><pubmed>18583331</pubmed></ref>. The highlighted concern revolves around the increased occurrence of aneuploidy following maternal age. The optimal age range for the lowest aneuploidy incidence was found to be between 27 to 37 years of age (6%) then progressively higher in women aged up to 42 (33%) and most common in those 44 and above (53%) <ref name="PMID24355045"><pubmed>24355045</pubmed></ref>. <br />
====Recurrent pregnancy loss / IVF failure====<br />
Recurrent pregnancy loss is defined as three or more IVF failures after cumulative transfer of more than 10 good-quality embryos. These are primarily caused by two main factors, reduced endometrium receptivity or embryonic defects. Endometrium receptivity can be negatively influences by instances including uterine pathologies such as thin endometrium, altered expression of adhesive molecules and immunological factors. Additionally, embryonic defects may be due to genetic abnormalities, embryonic aneuploidy or zona hardening. Endometriosis and hydrosalpinx has been known to effect both the endometrium and embryo <ref name="PMID23260857"><pubmed>23260857</pubmed></ref>.<br />
====Human leukocyte antigen matching====<br />
First used in 2001, HLA matching is an option given to parents to save a child with haematological or immunological disease through conceiving another child who would potentially be able to donate cord blood or haematopoietic stem cells from the bone marrow for transplantation. The process namely PGD-HLA has shown to improve haematopoietic stem cell transplant (HSCT). PGD-HLA can only be performed when HSCT is not needed urgently due to the time needed to conceive and delivery the baby <ref name="PMID25500181"><pubmed>25500181</pubmed></ref>. It is most commonly applied to children suffering from relapsed leukaemia <ref name="PMID22524201"><pubmed>22524201</pubmed></ref>. In a case study PGD-HLA was proven to successfully cure 10 diseases including Fanconi anaemia, Diamond-Blackfan anaemia and beta thalassemia <ref name="PMID25066893><pubmed>25066893</pubmed></ref>.<br />
==Biopsy Methods==<br />
Biopsy, the removal of genetic materials, from oocytes or embryos in the preimplantation stage is the primary step in PGD. For the past two decades these biopsies have been performed at three stages, the polar body, blastomere, and blastocyst, and the methodologies optimized to ensure the embryo’s viability. The most common approach involves biopsies at the cleavage stage. However, polar body and blastocyst biopsies are increasingly more often tested and applied. Approached for opening the zona pellucida involve next to the traditional mechanical and chemical means, novel approaches such as noncontact lasers. Their application may simplify and secure the procedure significantly. The most challenging question about PGD procedures remains at what stage biopsies should be taken. Much controversy has developed around this topic, highlighting the varying disadvantages and advantages of temporal biopsies. <ref name="PMID22723007"><pubmed>22723007</pubmed></ref><br />
<br />
[[File:Polar_Body,_Blastomere,_and_Trophectoderm_Biopsy.jpeg|400px|thumb|Polar body (A), blastomere (B) and trophectoderm (C) biopsies<ref name="PMID25625041"><pubmed>25625041</pubmed></ref>.]]<br />
{| class="wikitable"<br />
|- align="center" bgcolor="DDCEF2"<br />
|<br />
| Time of Biopsy<br />
| Advantages <br />
| Disadvantages<br />
|- bgcolor="FFFAFA"<br />
| Polar Body<br />
| Day 1<br />
| No harm to oocyte<br />
| Only maternal DNA is tested, often needs to be coupled with other biopsies, and there are difficulties distinguishing between the first and second PB.<br />
|- bgcolor="FFFAFA"<br />
| Blastomere<br />
| Day 3<br />
| …<br />
| … <br />
|- bgcolor="FFFAFA"<br />
| Trophectoderm<br />
| Day 5 and 6 <br />
| Little harm to the embryo and large amount of genetic material is extracted. <br />
| Opening of blastocyst necessary, small time window for procedure<br />
|}<br />
===Polar Body Analysis===<br />
Day 1<br />
====Description====<br />
Polar body (PB) biopsy offers a promising alternative to biopsies performed at the blastomere stage for PGD/S indications on legal and practical grounds. Consequent embryo development does not necessitate the presence of the first and second PB and their removal may not be crucial. PB biopsy requires precise timing. Keeping track of the meiotic cell cycle is necessary to perform a successful biopsy and, therefore, PB biopsy usually is applied in combination with intracytoplasmic sperm injection (ICSI). During the maturation from the germinal vesicle stage to the metaphase-II stage the first PB is formed. A cytoplasmic bridge containing spindle remnants, that are still in contact with the cellular genetic material, links this PB to the oolemma for about 90 minutes after extrusion. It is possible to visualize these remnants by polarization microscopy and it is crucial to not perform the biopsy until the first PB is no longer firmly attached to the oolemma as this indicates an immature embryo.The oocyte tolerates mechanical zona dissection best during hours four until six after ICSI as the oolemma has stabilized by that time because of the cortical granule reaction. Over time the first PB degenerates stressing a temporal biopsy and its optimal extraction time window is four to 12 hours after ICSI. The second PB forms around two to four hours after ICSI. Its optimal time window for biopsy is set to be eight to 16 hours after ICSI due to the second PB being attached to the oolemma with spindle remnants until six hours after ICSI. Biopsy at this point may cause enucleation of the oocyte. Studies have shown that the amplification efficiency of second PB’s DNA is worse if the PB is extracted prior to eight hours after ICSI. Thus, it is possible to perform sequential and simultaneous biopsies for the first and second PB. If performed, sequentially the first PB may be removed four to 12 hours and the second PB eight to 16 hours after ICSI. The optimal time window for a biopsy for both the first and second PB simultaneously is eight to 12 hours after ICSI. It is highly preferred to analyze both PBs due to potential aneuploidies in either PB and crossing overs during meiosis<ref name="PMID22723007"/>. <br />
====Procedure====<br />
Chemical opening achieved with for example acidic tyrode’s solution of the zona pellucida is not tolerated by the oocyte and may have detrimental effects on the embryo’s development. Therefore, the access to the perivitelline space of the oocyte is provided by mechanical zona dissection or by laser. Both techniques work well if performed by experienced embryologist. However, laser-assisted biopsy is less time consuming when compared to manual dissection. It is critical to consider the size of the introduced opening as it will remain permanent. If it is too large the blastomere may be lost during embryo development and if it is too small it may interfere with hatching of the embryo during blastocyst stage<ref name="PMID22723007"/>.<br />
[[File:Polar_Body_Biopsy.jpeg|left|thumb|The presence of a faint but clearly identifiable strand connecting PB2 to the oolemma. The biopsy was performed ∼9 h after ICSI<ref name="PMID21908464"><pubmed>21908464</pubmed></ref>.]]<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JTaQzszVr8o</html5media><br />
|-<br />
| Laser-assisted polar body biopsy<ref>RIUK, R. (2013, June 25) Polar Body Biopsy [Video file]. Retrieved from https://www.youtube.com/watch?v=JTaQzszVr8o</ref><br />
|}<br />
====Advantages & Disadvantages====<br />
PB biopsies can only investigate the maternal contributions to the embryo as they are of maternal origin. Thus, this procedure is appropriate for PGD solely for monogenetic diseases from the maternal side. Recessive diseases may be evaluated with PB biopsies on the basis that the embryo’s outcome will be determined by the paternal contribution. It may still be applied for PGS as it is a fairly safe biopsy option and most aneuploidies either arise during meiosis or origin from the maternal genome. However, diagnosis error has been reported due to the lack of considering paternal contributions.Because PB biopsies are performed very early it is not yet known whether the oocyte will develop into a viable embryo. Thus, PBs are commonly frozen or fixed after biopsy and depending on the state of the embryo only chosen PBs will be tested. This is primarily an economic issue as many genetic testing procedures are very cost-intensive<ref name="PMID22723007"/>[[File:Implantation_predictive_value_of_euploid_screening_results.jpeg|thumb|The sustained implantation predictive value (with 95 % confidence interval) of a euploid screening result obtained from the first polar body (PB1), PB1 and the second polar body (PB2), or a direct embryo biopsy for each stage of embryo transfer (cleavage-stage and blastocyst stage)<ref name="PMID25106935"><pubmed>25106935</pubmed></ref>.]] Generally the sustained implantation predictive value of screening of PBs is significantly lower than of for example biopsies of the blastocyst stage<ref name="PMID25106935"/>. Moreover, it is often difficult to distinguish between the first and the second PB. As the first one degenerates quicker, this may influence diagnostic procedures<ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
===Blastomere biopsy===<br />
Day 3 <br />
====Description====<br />
Blastomere biopsy has been the prevalent method for PGD and PGS in the last two decades. At least one, but up to two, blastomeres are biopsied on day three of the cleavage stage embryo. The right number of blastomeres removed is a controversial topic as two cells allow for more genetic material and more accurate results. However, removing two cells might be too invasive and damaging to the embryo. As PGS tries to improve implantation rates, whereas PGD sets out to avoid known genetic disorders, for the former only one cell is removed, while for the latter often two need to be removed, to ensure results as correct as possible<ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
====Procedure====<br />
Initially a hole was drilled into the zona pellucida using acid tyrodes with the consequent aspiration of blastomeres with a pipette. Nowadays the zona pellucida is largely opened using a laser and calcium and magnesium free media have been introduced to decrease junctions between blastomeres, which facilitates the biopsy<ref name="PMID21748341"/>.<br />
[[File:Aspiration_of_a_Blastomere.jpeg|thumb|Aspiration of a Blastomere into the biopsy pipette<ref name=" PMID24783200"><pubmed>24783200</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=TbridWVwipI</html5media><br />
|-<br />
| Laser-assisted blastomere biopsy<ref>Sukprasert, M. (2014, March 5) Day 3 Blastomere Biopsy 1 [Video file]. Retrieved from https://www.youtube.com/watch?v=TbridWVwipI</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
===Trophectoderm biopsy===<br />
Day 5 and 6<br />
====Description====<br />
The improvement of embryo culture media allowed the in vitro development of human embryos until the blastocyst stage and opened up the possibility to take blastocyst biopsies. During day three to day five the haploid maternal and paternal genomes work together for the first time to form the genome of the embryo. The maternal epigenetic control lessens significantly while preparing for implantation with precisely arranged events happening. The first event includes a rapid increase in the number of embryonic cells which are active in mitotic divisions and apoptosis of aberrant cells. This is followed by the formation of blastocoel (cavitation) which results from the flattening of cell located on the outside of the blastomere. Now the blastocyst will expand until the embryo hatches by rupturing the zona pellucida. The cells of the blastocyst will differentiate to form two distinct cell lineages, the outer trophectoderm and the inner cell mass<ref name="PMID22723007"/>.<br />
====Procedure====<br />
Trophectoderm biopsy is usually performed in Hepes buffered biopsy medium and opening approaches include needle cutting which has been replaced by lasers in past years. Different research groups report different timings of the opening to be the most successful. Some open the blastocyst on day three or four by creating a 25 µm which causes the trophectoderm to herniate through this hole and is, thus, accessible for biopsy. Others create this hole about four hours before biopsy which allows sufficient herniation of trophectoderm cells. It is also possible to open the blastocyst immediately before biopsy. This avoids an extra step and the inner cell mass usually is easy to locate. Blastocyst biopsies involve the removal of trophectoderm cells and the ideal time for the procedure is day five. Successful biopsies on day six have been performed, while little is known about the results of biopsies on day seven. However, since the window of implantation in humans is from day eight to ten after ovulation, day seven biopsies appear to be possible<ref name="PMID22723007"/>.<br />
-collapse of trophoblasts<br />
-possible: biopsy of hatched blastocyst, holding pipette careful mild suction force to hold embryo near ICM <br />
-Cryopreservation<br />
<br />
<br />
[[File:Microscopic images of human blastocysts for biopsy.jpeg|thumb|(A) Some trophectoderm cells in a blastocyst started to hatch and (B) the trophectoderm cells were biopsied with assisted laser cutting. Images in C–D show the blastocysts after vitrification and warming. Blastocysts had been cultured for 2–4 hrs after warming, showing good (ICM and trophectoderm cells) hatched (C) and hatching (D) blastocysts. The hatching blastocyst in (E) has good ICM but fair trophectoderm while the blastocyst in (F) has both fair ICM and trophectoderm. Arrows indicate ICMs and arrow heads indicate trophectoderm cells. Bar = 40 µm<ref name="PMID2190846"><pubmed>2190846</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JI_TQ8d8tNM</html5media><br />
|-<br />
| Laser-assisted blastocyst biopsy (at 00:50 min)<ref>Coco, R. (2014, April 30) Trophectoderm biopsy in a Hatching blastocyst protruding ICM [Video file]. Retrieved from https://www.youtube.com/watch?v=JI_TQ8d8tNM</ref><br />
|}<br />
<br />
====Advantages & Disadvantages====<br />
Blastocyst biopsies are believed to be less damaging to the embryo and appear to be unrelated to implantation rates. In addition, this biopsy method allows for a larger extraction of cells for genetic testing. However, since they are performed late in in vitro development, the time window for genetic testing is relatively small. Fast and accurate genetic testing methods are needed to ensure a successful and safe result from this biopsy. Thus, blastocyst biopsies may gain more popularity in the future whn such methods have been developed or improved<ref name="PMID22723007"/>. <br />
==Genetic Techniques==<br />
===Polymerase Chain Reaction===<br />
PCR amplifies DNA specific to genetic sequence of interest . PCR was developed by Kay Mullis in the 1980s, for which he was awarded the Nobel prize for chemistry in 1993. <ref> Pubmed Docs (2015) Polymerase Chain Reaction (PCR) Pubmen. Retrieved from [http://www.ncbi.nlm.nih.gov/probe/docs/techpcr/]</ref> This technique enables clinicians to monitor and diagnose diseases using minute samples such as embryonic cells, blood & tissue. <ref>Roche (2015) PCR: How We Copy DNA. Roche Molecular Systems Inc. retrieved From [http://molecular.roche.com/pcr/Pages/Process.aspx]</ref> PCR has many important applications like DNA fingerprinting, genetic mapping, detection of viruses and bacteria as well as being used to detect genetic disorders, as a part of PGD, in conjunction with IVF. It is used to detect molecular abnormalities such as single gene disorders like Tay Sach, Cycstic fibrosis, Duchenne Muscular Dystrophy, Thalassemia, Huntington disease, Spinal muscular atrophy and many more. Molecular and Genetic analysis require a significant amount of DNA, which we would not have without PCR. It revolutionized the study of DNA, replacing all previous recombinant DNA technology. <ref> Mullins, K., Francois, F.& Gibbs R.A. (1994 ) The Polymerase Chain Reaction. p3. Springer- Science +Business Media. Birkhauser, Boston<br />
Available at [https://books.google.com.au/books?hl=en&lr=&id=gjrTBwAAQBAJ&oi=fnd&pg=PR5&dq=kary+mullis+PCR&ots=mpzAyRh5ZY&sig=PQ4goNoKJ90tb3-MkPk62zrTGbw#v=onepage&q=kary%20mullis%20PCR&f=false] </ref> <br />
<br />
[[File:PCR.jpg|thumb|right|Polymerase chain reaction (PCR) amplifies DNA specific to genetic sequence of interest, enabling the monitoring and diagnose molecular abnormalities such as single gene disorders using minute samples such as embryonic cells, blood & tissue <ref>NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref>]]<br />
{|<br />
|- align="left" bgcolor="DDCEF2"<br />
|'''Procedure'''<br />
|}<br />
Samples are obtained from the the blastocyst, a polar body biopsy or the blastomeres stages of the embryo. <br />
*Stage 1 Denaturing: separating the target strands of DNA <br />
The obtained sample is heated to roughly 90 degrees celcius, this heat breaks the relatively weak bonds between nucleotides that form DNA. The double stranded DNA is split into two single strands of DNA that are used as templates.<br />
*Stage 2 Annealing: Binding the Primers to the target DNA sequence <br />
PCR will only copy the target sequence of DNA specified by specific PCR primer. These synthesized primers oligonucleotides are small artificial pieces of DNA. TAQ polymerase enzyme synthesize two new strands of DNA duplicate to the single sample DNA stand template indicated by these primers. During this stage the reaction is cooled to a temperature between 40-60 degrees Celsius. <br />
*Stage 3- Extension- making copies <br />
Each of these two copies are then used again as templates generating two further replications This cycle can occur as many 30 -40 times within a couple hours leading to billions of extra copies of the original DNA segment. The optimal temperature for the further replication is roughly 72 degrees Celsius. <br />
This process mediated by a thermocycler machine that is programmed to alter the temperature of the reaction every couple of minutes, perpetuating the cycle of DNA denaturing and synthesis. <br />
This process, generates exponentially exact copies of the original template DNA sequence. <br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
!PCR cycles<br />
|-<br />
| '''PCR Cycle'''<br />
| '''Target Copies'''<br />
|-<br />
| 1<br />
| 2<br />
|-<br />
| 2<br />
| 4<br />
|-<br />
| 3<br />
| 8<br />
|-<br />
| 4<br />
| 16<br />
|-"<br />
| 5 <br />
| 32<br />
|-<br />
| 6 <br />
| 64<br />
|-<br />
| 7 <br />
| 128<br />
|-<br />
| 8<br />
| 256<br />
|- <br />
| 9<br />
| 512 <br />
|-<br />
| 10<br />
| 1024<br />
|-<br />
| 15<br />
| 32,768<br />
|-<br />
| 20 <br />
| 1,048,578<br />
|-<br />
| 25<br />
| 33,554,432<br />
|-<br />
| 30 <br />
| 1,073,741,842<br />
|-<br />
|}<br />
<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="7" |'''Advantages'''<br />
|-bgcolor="FFFAFA"<br />
| Fast and inexpensive way of copying a target sequence of DNA<br />
|-bgcolor="FFFAFA"<br />
| Particularly useful for the diagnosis of single cell defects<br />
|-bgcolor="FFFAFA"<br />
| Rapid generation of results (within hours)<br />
|-bgcolor="FFFAFA"<br />
| Highly sensitive, a single molecule of DNA is sufficient for reaction<br />
|-bgcolor="FFFAFA"<br />
| Generates DNA copies exponentially<br />
|-bgcolor="FFFAFA"<br />
| This enables DNA amplification required for molecular and genetic diagnostic analysis<ref> Dreesen, J., Drusedaul, M., Smeets, H., Die-Smulders, C., Coonen, E., Dumoulin, J., Gielen, M., Evers, J., Herbergers, J. & Geradets, J. (2008) Validation of preimplantation genetic diagnosis by PCR analysis: genotype comparison of the blastomere and corresponding embryo, implications for clinical practice. Mol. Hum. Reprod. 14 (10):573-579.doi: 10.1093/molehr/gan052. Retrieved from [http://molehr.oxfordjournals.org/content/14/10/573.short] </ref> <ref><pubmed>20966460</pubmed></ref><br />
|-bgcolor="DDCEF2"<br />
| rowspan="5"|'''Disadvantages'''<br />
|-bgcolor="FFFAFA"<br />
| Only during the exponential DNA replication phase, the starting quantity sequence contained in the original sample (template DNA strand) can be determined<br />
|-bgcolor="FFFAFA"<br />
| PCR reaction is limited to by presence of inhibitors in the sample<br />
|-bgcolor="FFFAFA"<br />
| Self annealing due to the accumulation of the product -stopping exponential amplification for the target sequence and reach a plateau<br />
quantification of the end point of reaction of PCR products unreliable - therefore real time quantitative RT-PCR is necessary<br />
<ref> NIS (2015) Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref><br />
|-bgcolor="FFFAFA"<br />
| Not a diagnostic method on its own, requires further analysis<br />
|}<br />
===Fluorescent In Situ Hybridisation===<br />
FISH is the one of the most effective and rapid <ref name="PMID26338801"><pubmed>26338801</pubmed></ref> method of conducting PGD. This techniques used to locate a specific DNA sequences within a chromosome. FISH facilitates the clinical diagnosis of chromosomal abnormalities indicated by sequential duplications, deletions and rearrangements of chromosome, that are usually missed with microscopic analysis. This technique is especially relevant for female embryos with X-linked diseases,<ref name="PMID20809319"><pubmed>20809319</pubmed></ref> that have no other mutation specific tests [http://www.ncbi.nlm.nih.gov/pubmed/20809319] As part of PGD, samples are collected from various stages of the embyro,and they are able to conducted tests on the blastocyst, a polar body biopsy and the blastomeres <ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. FISH is 99% effective when used in conjunction with competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities<ref name="PMID26338801"/>.<br />
{|<br />
|- align="left" bgcolor="DDCEF2"<br />
|'''Procedure'''<br />
|}<br />
Samples are collected from either the blastocyst, a polar body biopsy or the blastomeres stages of the embryo <ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
DNA strands are heated and denatured causing their the individual DNA strands to break apart<br />
Probes are single complimentary stands of DNA a that have been tagged with small chemical agents that glow brightly in the presence of a specific region on a chromosome. These specific probes then hybridize and join to their complementary DNA strand. <br />
The fluorescent tags enable the researchers to correctly identify the presence or lack thereof and location of the specific chromosomes that they are testing for. <ref name="PMID17876073"><pubmed>17876073</pubmed></ref><br />
Researcher analyse the results by identifying the number and the relative location of the fluorescent dots generated by the FISH images.<ref name="PMID17970921"><pubmed>17970921</pubmed></ref><br />
The probe will not fully hybridise if there has been a duplication or a deletion of the DNA - indicating chromosomal and sex chromosomal anomalies like trisomies and aneuploidies. <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref><br />
Different probes are used for different purposes: <ref>Unique, Rare Chromosome Disorder Support Group (2013) Fluorescence in situ hybridisation (FISH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/Other/FISH%20FTNW.pdf]</ref><br />
*'''Locus specific tags''' detect very small imbalances, and locate isolated small portions <br />
of genes within a chromosome<br />
*'''Alphoid/Centomeric Repeat probes''' are developed from the repetitive sequence located in the middle region of each chromosome, useful in determining the number of chromosomes , detecting rearrangement and when used in conjunction with locus probes to determine the absence of genetic material on a chromosome. <br />
*'''Paint Probes''' are collections of smaller probes with their own stains that bind to a different section on the chromosome - allowing the full chromosome too be labeled a unique colour, this "full colour map" can be used to know the spectral karyotype- full chromosomal mapping is useful in examining chromosomal abnormalities. <br />
[[File:Fluorescent In Situ Hybridisation (FISH).jpg|thumb|right|'''FISH''' We are able to tag Specific DNA sequences using Probes which have been tagged with fluorescent Labels.This technique enables the clinical diagnosis of chromosomal abnormalities, indicated by sequential duplication, deletions and rearrangements of chromosome <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref>]]<br />
<br />
{|class="wikitable" align="center"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="8" |'''Advantages''' <br />
|-bgcolor="FFFAFA" <br />
| FISH is 99% effective when used in conjunction with Competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities.<ref><pubmed>26338801</pubmed></ref><br />
|-bgcolor="FFFAFA" <br />
| Rapid generation of results<br />
|-bgcolor="FFFAFA"<br />
| Identifies very small translocations and aneuploidies that occur within chromosomes, that would usually be missed under microscopic analysis<br />
|-bgcolor="FFFAFA" <br />
| Indicates whether the accessed chromosomes are normal <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|-bgcolor="FFFAFA" <br />
| Tests for the most common chromosomal abnormalities - down syndrome chromosomes 13,16,18,21 and 22 <ref><pubmed>21749752</pubmed></ref><br />
|-bgcolor="FFFAFA" <br />
| It may be used to compare the chromosomal gene arrangements in related species<br />
|-bgcolor="FFFAFA" <br />
| Can be used to identify and remove inheritable X-linked disease or sex chromosome anomalies such as Duchenne's Muscular Dystrophy, hemophilia, ectodermal dysplasia <ref><pubmed>17876073</pubmed></ref><br />
|-bgcolor="DDCEF2"<br />
| rowspan="5"|'''Disadvantages'''<br />
|-bgcolor="FFFAFA" <br />
| FISH destroys all cells tested <ref> O'Connor, C. (2008) Fluorescence in situ hybridization (FISH). Nature Education 1(1):171. retrieved from [http://www.nature.com/scitable/topicpage/fluorescence-in-situ-hybridization-fish-327] </ref><br />
|-bgcolor="FFFAFA" <br />
| It does not fully access all chromosomes (only ~ 12)<br />
|-bgcolor="FFFAFA" <br />
| Analysis of results is dependent upon the dot quality impacted by hybridisation efficiency or the camera sensitivity <ref><pubmed>17970921</pubmed></ref><br />
|-bgcolor="FFFAFA" <br />
| Some studies indicate that using FISH on a day-3 embryo biopsy decreases the rate of live births <ref><pubmed>26168107</pubmed></ref><br />
|}<br />
<br />
===Array Comparative Genomic Hybridisation (aCGH)===<br />
aCGH also known as Microarray analysis efficiently scans the entire genome for chromosomal imbalances. CGH was initially developed to detect the number of changes in a solid tumor mass. It uses 2 genomes comparing the sample to the control, with each labeled in a different fluorescent dye<ref name="PMID1876176"><pubmed>1876176</pubmed></ref>. Earlier CGH techniques were limited by the resolution of the imaging <ref> Lichter, P., et al. Comparative genomic hybridization: Uses and limitations. Seminars in Hematology 37, 348–357 (2000)</ref> , these initial limitations were overcome by using Microarrays in conjunction with CGh to improve the resolution of the imaging, Array Comparative Genomic Hybridisation (aCGH). This method compares sample and control microarrayed slides containing small segments of DNA (probes). <ref> Lucito, R., et al. Representational oligonucleotide microarray analysis: A high-resolution method to detect genome copy number variation. Genome Research 13, 2291–2305 (2003) </ref> the Probes used will vary according from the small (25-85 base pairs) oligonucleotides manufactured to highlight different target sequences, to the very large genomic clones (80,000- 200,00 base pairs), and as these are significantly smaller than the traditional metaphase chromosomes used for CGH, generating a higher resolution of image. <ref name="PMID22467166"><pubmed>22467166</pubmed></ref>.aCGH is used as a diagnostic tool for prenatal detection f chromosomal abnormalities <ref name="PMID19012303"><pubmed>19012303</pubmed></ref>.<br />
{|<br />
|- align="left" bgcolor="DDCEF2"<br />
|'''Procedure'''<br />
|}<br />
<ref> Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432] </ref><br />
The sample is obtained (skin, blood or fetal cells) and DNA is obtained. <br />
As a part of PGD fetal cell samples are collected from; the fertilized egg polar bodies, the blastomere (day 3 embryo) or the blastocyst/tropoectoderm stage (day 5 embryo).<br />
Sample DNA is labeled with one fluorescent dye, and the control DNA is labeled with a different colored fluorescent dye. the control DNA is used as the base point of reference. <br />
heated and denatured single DNA strands then hybridize to their complementary single strand probes, which are then combined and applied to a microarray and the results are run through a computer program and a digital imaging system is used to quantify the results( fluorescent intensities of the labeled probes). <br />
<br />
[[File:aCGH.jpg|thumb|right|'''aCGH''' checks the entire genome for chromosomal imbalances, by comparing control and a sample slides contatining small segements of DNA sample microarrayed slides small segments of DNA. Illustrated by student z5020317 and adapted from <ref> NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation. retrieved from [http://www.phgfoundation.org/file/5237/]</ref> <ref>Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432]</ref>]]<br />
<br />
The fluorescent ratio and the hybridization signal at different locations on the genome of the control DNA are used to identify any variances present in the sample DNA. aCGH facilitates the clinical diagnosis of submicroscopic chromosomal duplication, deletion and rearrangements indicative of chromosomal disorders such as trisomies 1-22and specific sex linked disorders. <br />
Duplications in the DNA are displayed by the computer program as spikes/ peaks over an established threshold and deletions in DNA are displayed by the computer program as spikes/ toughs beneath this threshold <br />
<br />
{|class="wikitable" align="center"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="12" |'''Advantages''' <br />
|-bgcolor="FFFAFA"<br />
| Multiple applications: prenatal genetic diagnosis, cancer diagnosis, <ref name="PMID20193845"><pubmed>20193845</pubmed></ref> genetic screening for developmental delay (learning disabilities) <ref name="PMID17309648"><pubmed>17309648</pubmed></ref>. or congenital anomalies that are suspected to be genetic in origin <ref>NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation . retrieved from [http://www.phgfoundation.org/file/5237/]</ref><br />
|-bgcolor="FFFAFA"<br />
| trace represents all chromosomes present in the human genome chromosomes 1-22 and the X & Y chromosomes, and therefore is the most accurate method for testing whole embryo aneuploidy<br />
|-bgcolor="FFFAFA"<br />
| aCGH has been extensively tested, and Validated, and is now used world wide.<br />
|-bgcolor="FFFAFA"<br />
| Detects submicroscopic alterations<br />
|-bgcolor="FFFAFA"<br />
| Detects deletions and additions and rearrangements as well as amplification, of the WHOLE genome, simultaneously.<br />
|-bgcolor="FFFAFA"<br />
| Used as a diagnostic tool for prenatal detection of chromosomal abnormalities <ref name="PMID22034057"><pubmed>22034057</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Provides high resolution genomewide screening of segmental genomic copy number variations<br />
|-bgcolor="FFFAFA"<br />
| Very accurate when used in conjunction with FISH<br />
|-bgcolor="FFFAFA"<br />
| Alone is more reliable and in detecting chromosomal abnormalities, with a higher implantation success rate, than FISH <ref name="PMID20494259"><pubmed>20494259</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Allows an in depth research focus upon specific types of rearrangements within selected chromosomal regions, a recent particular area of interest is subtelomeric and pericentromeric rearrangements<br />
|-bgcolor="FFFAFA"<br />
| Reduces the risk of failed implantation and miscarriage, improving the chance of a healthy baby <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|-bgcolor="DDCEF2"<br />
| rowspan="9" |'''Disadvantages'''<br />
|-bgcolor="FFFAFA"<br />
| Translocations and inversions of DNA are not detected<br />
|-bgcolor="FFFAFA"<br />
| Limited ability diagnosing specific polyploidies such as triploidy <ref> Unique, Rare Chromosome Disorder Support Group (2013) Microarray-based Comparative Genomic Hybridiation (array CGH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/other/array%20cgh%20ftnw.pdf] </ref><br />
|-bgcolor="FFFAFA"<br />
| Will not detect mosaicism detection <20% (cultures where >1 of 5 cells are trisomy 12)<br />
|-bgcolor="FFFAFA"<br />
| Will not detect balanced chromosomal rearrangement<br />
|-bgcolor="FFFAFA"<br />
| Will not detect duplications or deletions <80kb<br />
|-bgcolor="FFFAFA"<br />
| Will not detect point mutations within genes <ref>Washington department of education (CGH- FAQ for physicians. Signature Genomic LAboratories, LLC. Retrieved from [https://depts.washington.edu/dbpeds/Lab%20Tests/SignatureCGH-physician_FAQ.pdf]</ref><br />
|-bgcolor="FFFAFA"<br />
| will not detect chromosomal position of genomic gains<br />
|-bgcolor="FFFAFA"<br />
| Will not detect loos of heterozygosity (LOH) or Absence of heterozygosity (AOH) <ref>WiCell Research Institute Inc. (2012) Comparative Genomic Hybridization Microarray. <br />
retrieved from [http://www.wicell.org/home/cytogenetic-services/cgh-microarray/array-comparative-genomic-hybridization-acgh.cmsx]</ref><br />
|}<br />
<br />
===Next Generation Sequencing===<br />
The development and advances within ART in the past 20 years, as well as the increasing popularity of IV, has lead to an influx of new technologies developed to screen embryos for chromosomal anomalies, which are covered by the umbrella term of Next generation Sequencing (NGS). NGS is a general term used to describe all of the new and emerging screening techniques currently being introduced and used as part of PGD for IVF . NGS screens for single gene disorders as well as conducting extensive and very comprehensive chromosome diagnosis by sequencing, counting, and accurately assembling millions of DNA reads, simultaneously. <ref name="PMID23499002"><pubmed>23499002</pubmed></ref> There is a movement for NGS to replace the other limited testing techniques and be used as the standard. <br />
{|<br />
|- align="left" bgcolor="DDCEF2"<br />
|'''Procedure'''<br />
|}<br />
Samples are collected from either blastomere or the blastocyst/tropoectoderm and processed for analysis by a computer system. <br />
The methodology of each process is unique to the technique being used. <br />
<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="14" |'''Advantages''' <br />
|-bgcolor="FFFAFA" <br />
| Cheaper<br />
|-bgcolor="FFFAFA"<br />
| Opens new diagnostic possibilities<br />
|-bgcolor="FFFAFA"<br />
| Accurately tests all 24 chromosomes<br />
|-bgcolor="FFFAFA"<br />
| Tests for the presence of monogenic diseases of known genetic background<br />
|-bgcolor="FFFAFA"<br />
| Reduces the number of biopsies required for diagnosis<br />
|-bgcolor="FFFAFA"<br />
| Higher detection rate of small translocations<br />
|-bgcolor="FFFAFA"<br />
| Highly accurate is testing for compound point mutations, chromosomal duplication, deletions and insertions <ref name="PMID23312231"><pubmed>23312231</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| It accurately detects chromosomal aneuploidy and unbalanced rearrangement <ref name="PMID25685330"><pubmed>25685330</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Higher detection rate of small translocations<br />
|-bgcolor="FFFAFA"<br />
| NGS single gene disorder screenings can conducted in conjunction with PCR comprehensive chromosomal screening<br />
|-bgcolor="FFFAFA"<br />
| Reduces human error <br />
|-bgcolor="FFFAFA"<br />
| Better detects the presence of mosaicism<br />
|-bgcolor="FFFAFA"<br />
| Work well in conjunction with CGH and aCGH as part of PGD, improving the chances of IVF. <ref> Morris, R. S. (2015 ) Next generation sequencing for PCG|PGS|CCS. IVF1 retrieved from [http://www.ivf1.com/next-generation-sequencing for-pgd] </ref><br />
|-bgcolor="DDCEF2"<br />
| '''Disadvantages''' <br />
|-bgcolor="FFFAFA"<br />
| There are limited information available to clinical applications of NGS <ref><pubmed>26100406</pubmed></ref><br />
|}<br />
<br />
==Diagnosis==<br />
There are a large amount of diseases that PGD can apply to, below are descriptions of the diseases that PGD are more commonly used for. Upon completion of the genetic testing for the genes of concern the cells the embryos are discarded and priority is given to those that are healthy. <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/><br />
===Cystic Fibrosis===<br />
Cystic fibrosis is a single gene disorder. It is autosomal recessive and involves mutations in the cystic fibrosis transmembrane conductance regulator (CTFR) gene. The CTFR gene is normally responsible for the decrease in chloride and the transport of bicarbonate in epithelial cells thus playing a major physiological role. In PGD procedures, identification of the gene is assisted by microsatellite markers that have similar composition to the CTFR gene itself. Biopsy of two cells at the blastocyst stage is recommended if markers are not available. There are many variations of cystic fibrosis the most common being P.Phe508del <ref name="PMID26014425"><pubmed>26014425</pubmed></ref>.<br />
===Duchenne Muscular Dystrophy ===<br />
Duchenne Muscular Dystrophy is an X-linked recessive disease. It involves the Xp21 gene where majority of the mutations are chromosomal deletions with a smaller percentage resulting from duplications <ref name="PMID18359022"><pubmed>18359022</pubmed></ref>.<br />
<br />
===Autosomal Recessive Meckel-Gruber Syndrome===<br />
Autosomal recessive genetic defect caused by the TMEM67 gene. It results in cystic dysplasia of the kidneys with fibrotic change in the liber and occipital encephalocele. Other malformations could also be present in the central nervous system. In PGD whole genome amplification of single blastomeres are taken to identify the gene, this is also coupled with PCR techniques. Maternal plasma can also be extracted for PGS. <ref><pubmed>24039893</pubmed></ref> <br />
===β – Thalassemia=== <br />
β – Thalassemia is known as the most common type of autosomal recessive inherited disorder among haemoglobinopathies. It involves the adult β-globin gene and is associated with the absent or decreased expression of the gene. This is commonly caused by a single nucleotide change in the gene. PGD has been used successfully worldwide to identify the β-globin gene where its application is usually performed on a single blastomere or polar body <ref name="PMID19064120">19064120</pubmed></ref>.<br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
! Applicable diseases for PGD <ref>Genoma Group (2014). Retrieved September 18th, 2015, from http://www.preimplantationgeneticdiagnosis.it/genetic-diseases-diagnosed-by-pgd.htm </ref>, <ref>Genesis Genetics (2015). Retrieved September 18th, 2015, from http://genesisgenetics.org/pgd/what-we-test-for/</ref>, <ref>Human Fertilisation & Embryology Authority (2015). Retrieved Septembr 18th, 2015, from http://guide.hfea.gov.uk/pgd/</ref><br />
|-<br />
| '''Disease'''<br />
| '''Involved Genes'''<br />
|-<br />
| 5 Alpha Reductase Deficiency (5ARD)<br />
| SRD5A2 <br />
|-<br />
| Achondroplasia<br />
|FGFR3 <br />
|-<br />
| Acute Intermittent Porphyria <br />
| ALAD, ALAS2, CPOX, FECH, HMBS, PPOX, UROD, or UROS<br />
|-<br />
| Adrenoleukodystrophy (Adrenomyeloneuropathy)<br />
| ABCD1 <br />
|-<br />
| Agammaglobulinaemia (x-linked) <br />
|BTK <br />
|-<br />
| Agammaglobulinemia Bruton Tyrosine Kinase (BTK) <br />
|BTK <br />
|-<br />
| Aicardi Goutieres Syndrome 1 (AGS1) <br />
|TREX1, RNASEH2A, RNASEH2B, RNASEH2C, SAMHD1<br />
|-<br />
| Alagille Syndrome<br />
|JAG1 or NOTCH2<br />
|- <br />
| Alpers-Huttenlocher Syndrome <br />
|POLG <br />
|-<br />
| Alpha-1-antitrypsin deficiency <br />
|SERPINA1 <br />
|-<br />
| Alpha-Mannosidosis<br />
| MAN2B1 <br />
|-<br />
| Alpha Thalassemia <br />
|HBA1 or HBA2 <br />
|-<br />
| Alports Syndrome<br />
|COL4A3, COL4A4, COL4A5<br />
|-<br />
| Alzheimer's Disease - early onset (Type 3 and 4) <br />
|APP, PSEN1, or PSEN2<br />
|-<br />
| Amyotrophic Lateral Sclerosis 1 (ALS1) <br />
|C9orf72, SOD1, TARDBP, FUS, ANG, ALS2, SETX, VAPB <br />
|-<br />
| Argininosuccinic Aciduria <br />
| ASL<br />
|-<br />
| Arrhythmogenic Right Ventricular Cardiomyopathy/ Dysplasia (ARVC/D)<br />
| DSG2; DSP; PKP2<br />
|-<br />
| Ataxia Telangiectasia<br />
| ATM<br />
|-<br />
| Autosomal Recessive Meckel-Gruber Syndrome<br />
| TMEM67<br />
|-<br />
| Bardet-Biedl Syndrome (BBS)<br />
| BBS1; BBS10<br />
|-<br />
| Barth Syndrome<br />
| TAZ<br />
|-<br />
| Beta Thalassaemia<br />
| HBB<br />
|-<br />
| Birt-Hogg-Dubé Syndrome<br />
| FLCN<br />
|-<br />
| Breast Ovarian Cancer Familial Susceptibility (BRCA2)<br />
| BRCA1; BRCA2<br />
|-<br />
| Canavan Disease <br />
| ASPA<br />
|-<br />
| Carnitine-Acylcarnitine Translocase Deficiency <br />
| SLC25A20<br />
|-<br />
| Cerebral Arteriopathy with Subcortical Infarcts & Leukoencephalopathy (CADASIL)<br />
| NOTCH3<br />
|-<br />
| Cerebral Cavernous Malformation<br />
| CCM1<br />
|-<br />
| Charcot-Marie-Tooth Disease<br />
| GJB1; MPZ; NEFL; PMP22<br />
|-<br />
| CHARGE Syndrome<br />
| CHD7<br />
|-<br />
| Cherubism<br />
| SH3BP2<br />
|-<br />
| Choroideremia<br />
| CHM<br />
|-<br />
| Chronic Granulomatous Disease<br />
| CYBB; NCF1<br />
|-<br />
| Ciliary Dyskinesia<br />
| DNAH5<br />
|-<br />
| Citrullinemia<br />
| ASS1<br />
|-<br />
| Cleidocranial Dysplasia<br />
| RUNX2<br />
|-<br />
| Cockayne Syndrome<br />
| ERCC6<br />
|-<br />
| Congenital Adrenal Hyperplasia<br />
| CYP21A2<br />
|-<br />
| Congenital Cataracts<br />
| GJA8; VSX2<br />
|-<br />
| Congenital Diarrhea, Syndromic<br />
| SPINT2<br />
|-<br />
| Congenital Disorders of Glycosylation (CDG)<br />
| ALG1; ALG6; CDG1C; DOLK; PMM2<br />
|-<br />
| Cornelia de Lange Syndrome <br />
| NIPBL<br />
|-<br />
| Craniosynostosis<br />
| TWIST1<br />
|-<br />
| Crouzon Syndrome<br />
| FGFR2<br />
|-<br />
| Cysteinyl Leukotriene Receptor 1 Deficiency <br />
| CYSLTR1<br />
|-<br />
| Cystic Fibrosis<br />
| CFTR<br />
|-<br />
| Diamond –Blackfan Anemia <br />
| RPS19<br />
|-<br />
| Duchenne Muscular Dystrophy <br />
| DMD<br />
|-<br />
| Dyskeratosis congenita (Male embryos only)<br />
| DKC1<br />
|-<br />
| Ectodermal dysplasia (Hypohidrotic)<br />
| EDA; EDA1; GJB6; IKBKG<br />
|-<br />
| Familial Adenomatous polyposis coli (FAP)<br />
| APC<br />
|-<br />
| Familial Dysautonomia<br />
| IKBKAP<br />
|-<br />
| Fanconi Anemia <br />
| FANCA; FANCC; FANCD2; FANCF; FANCG; FANCJ<br />
|-<br />
| Fragile X Syndrome (FRAX)<br />
| FMR1<br />
|-<br />
| Galactosemia <br />
| GALT<br />
|-<br />
| Gangliosidosis<br />
| GLB1<br />
|-<br />
| Glanzmann Thrombasthenia <br />
| ITGA2B<br />
|-<br />
| Glutaric Acidemia (aciduria)<br />
| GCDH <br />
|-<br />
| Glycogen Storage Disease <br />
| G6PC; GAA; SLC37A4<br />
|-<br />
| Haemophilia A<br />
| F8<br />
|-<br />
| Haemophilia B<br />
| F9<br />
|-<br />
| Hereditary Nonpolyposis Colorectal Cancer: Lynch Syndrome<br />
| MLH1; MSH2; MSH6<br />
|-<br />
| Holt Oram Syndrome<br />
| TBX5<br />
|-<br />
| Huntington Disease<br />
| HD<br />
|-<br />
| Hydrocephalus<br />
| L1CAM<br />
|-<br />
| Ichthyosis <br />
| ABCA12; STS<br />
|-<br />
| Incontinentia Pigmenti (IP)<br />
| NEMO<br />
|-<br />
| Joubert Syndrome 5<br />
| INPP5E<br />
|-<br />
| Krabbe Disease<br />
| GALC<br />
|-<br />
| Leber Congenital Amaurosis (LCA)<br />
| CEP290; GUCY2D<br />
|-<br />
| Leigh Syndrome (Infantile Subacute Necrotising Encephalopathy)<br />
| LRPPRC<br />
|-<br />
| Lesch Nyan Syndrome<br />
| HPRT1<br />
|-<br />
| Leukocyte Adhesion Deficiency (Type I)<br />
| ITGB2<br />
|-<br />
| Li-Fraumeni Syndrome<br />
| TP53<br />
|-<br />
| Macular Dystrophy Retinal <br />
| VMD2<br />
|-<br />
| Maple Syrup Urine Disorder (MSUD)<br />
| BCKDHB<br />
|-<br />
| Marfan Syndrome <br />
| FBN1<br />
|-<br />
| Menkes Syndrome<br />
| ATP7A<br />
|-<br />
| Mitochondrial DNA Depletion Syndrom <br />
| POLG; RRM2B; SUCLA2; TK2<br />
|-<br />
| Mucolipidosis type II<br />
| GNPTAB<br />
|-<br />
| Multiple Endocrine Neoplasia<br />
| MEN1; MEN2A; MEN2B<br />
|-<br />
| Multiple Exostoses<br />
| EXT1; EXT2 <br />
|-<br />
| Myotubular myopathy<br />
| MTM1 <br />
|-<br />
| Nail-Patella Syndrome<br />
| LMX1B<br />
|-<br />
| Neurofibromatosis Type 1<br />
| NF1<br />
|-<br />
| Neurofibromatosis Type 2 <br />
| NF2<br />
|-<br />
| Noonan Syndrome<br />
| KRAS, PTPN11; SOS1<br />
|-<br />
| Norrie Disease<br />
| NDP<br />
|-<br />
| Ocular Albinism <br />
| GPR143<br />
|-<br />
| Oculocutaneous Albinism <br />
| OCA2; TYR <br />
|-<br />
| Oculodentaldigital Dysplasia<br />
| GJA1<br />
|-<br />
| Optic Atrophy<br />
| OPA1<br />
|-<br />
| Ornithine Transcarbamylase Deficiency <br />
| OTC<br />
|-<br />
| Osteogenesis imperfeca <br />
| COL1A1; COL1A2<br />
|-<br />
| Osteopetrosis <br />
| CLCN7; OSTM1; TCIRG1<br />
|-<br />
| Pachyonychia Congenita <br />
| KRT16; KRT6A<br />
|-<br />
| Pancreatitis, Hereditary<br />
| PRSS1 <br />
|-<br />
| Papillorenal syndrome <br />
| PAX2<br />
|-<br />
| Phenylketonuria <br />
| PAH <br />
|-<br />
| This table does not cover the complete list of diseases that PGD can be applied to.<br />
|}<br />
<br />
==Laws & Legal status==<br />
<br />
{| class="wikitable" <br />
|-bgcolor="DDCEF2"<br />
|'''Country'''<br />
|'''Legislation'''<br />
|-bgcolor="FFFAFA" <br />
| Australia<br />
| PGD is currently used to detect serious genetic conditions to improve the outcome of Assisted Reproductive Technologies (ART). In very rare cases it may be used to select an embryo with compatible tissue for a sibling who has a life-threatening disease where other means of treatment is unavailable. This is with the conditions that the use of PGD will not affect the welfare and interests of the child to be born. The parents must also receive adequate counselling and have full understanding of the procedures of PGD. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"> National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art</ref><br />
The use of PGD for sex-selection is prohibited with the exception of reducing the risk of the transmission of serious sex-linked genetic conditions. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"/><br />
|-bgcolor="FFFAFA"<br />
| Brazil<br />
| The laws regarding PGD in Brazil are not strictly regulated. They are vague and there is limited information surround the activities of assisted reproduction in general in the country <ref name="PMID25493379"><pubmed>25493379</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| Czech Republic<br />
| The laws in the Czech Republic allow those with a “defined indication in order to exclude risk of serous genetically conditioned disease and defects with embryos before they are implanted into the cavity of the uterus”. Couples that undergo any assisted reproductive treatment including PGD have to be married. Sex-selection is illegal except in regards to serious sex-linked genetic diseases <ref name="PMID24777348"><pubmed>24777348</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| Greece<br />
| In Greece, ART is open to those up to the age of 50 with written consent. It can only be used if a medical necessity is present such as the susceptibility of serious hereditary diseases. Sex selection is banned apart from cases of sex-linked diseases and sexually transmitted diseases <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| India<br />
| In India there is a cultural preference for boys thus the Prenatal Diagnostic Techniques (Regulation and Prevention of Misuse) Act was introduced in 1994. This law limits the use of PGD for sex determination except in cases of specific congenital diseases. These laws however are not strictly enforced. <ref>World Health Organisation (2015) Gender and Genetics Retrieved on October 21st 2015 from:http://www.who.int/genomics/gender/en/index4.html</ref><br />
|-bgcolor="FFFAFA"<br />
| Portugal <br />
| ART is only available to those who are married or have a similar type of relationship for at least two years. The couples cannot be of the same sex and must be at least 18 years of age. Sex selection is illegal except in cases of sex-linked diseases. The use of PGD is illegal if the predictive value of genetic tests are very low <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| Spain<br />
| PGD can be applied to “serious hereditary diseases not amenable to postnatal curative treatment” and “detection of other abnormalities which may compromise the viability of the pre-embryo”. If PGD is to be used for any other purpose authorisation must be acquired <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| Sweden <br />
| The use of PGD is strictly regulated and couples must achieve authorisation of the National Board of Health and Welfare. It can only be used it can only be used if the child is at risk to inheriting a serious chromosomal or monogenetic disease. It cannot be used for selection of specific characteristics <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| United Kingdom<br />
| Those involved with carrying out the IVF treatment must have a license from the Human Fertilisation and Embryology Authority (HFEA). Only embryos that are approved by the HFEA can be implanted where the embryonic nuclear or mitochondrial DNA cannot be altered with the exception of preventing mitochondrial diseases <ref name="PMID24777348"/>. <br />
|}<br />
<br />
==Future/Current Research==<br />
In addition to research efforts for improving overall performance of established PGD/S techniques, such as finding the ideal zona pellucida insection site in an fully automatic manner<ref name="PMID26259216"><pubmed>26259216</pubmed></ref>, many research efforts have been spent to find alternative, non-invasive techniques to test for diseases and abnormalities<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
===Non-invasive Preimplantation Genetic Testing without Embryo Biopsy===<br />
Different parameters of gametes, zygotes, embryos (“vacuoles in sperm heads, spindle position in mature oocytes, cleavage intervals of zygote, and embryo developmental dynamics”) may correlate with aneuploidy rates. This knowledge may be applied in potential noninvasive preimplantation diagnostic methods. Several methods have been proposed and are currently further researched<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Sperm Selection====<br />
Intracytoplasmic morphologically selected sperm injection (IMSI) is common procedure in IVF treatment to improve fertilization rates in patients with poor semen quality. In addition, studies have found that IMSI improves embryo development and that spermatozoa with large vacuoles in their heads correlate with increased aneuploidy rates and disturbed chromosomal structures. Thus, selecting spermatozoa based on morphological hallmarks may decrease aneuploidy rates in the fertilized embryos. As with polar body biopsies, however, this approach will solely be applicable if evidence for severe male detrimental contribution is given<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Blastocoel Fluid Extraction====<br />
In addition, a less invasive retrieval of material for diagnosis could include the extraction of the blastocoel fluid. The cavity of the blastocyst, lined by the trophectoderm, is filled with this blastocoel fluid, which contains metabolites of both trophectoderm and inner cell mass origin. The retrieval does not require a biopsy but merely a small opening to extract the fluid and, thus, causes less harm to the embryo. Multiple studies have applied this method<ref name="PMID22020776"><pubmed>22020776</pubmed></ref> <ref name="PMID23148560"><pubmed>23148560</pubmed></ref> <ref name="PMID26006737"><pubmed>26006737</pubmed></ref> and it may in the future become of clinical relevance.[[File:Aspiration_of_the_Blastocoel_Fluid.jpeg|400px|thumb|Aspiration of the Blastocoel Fluid using a ICSI pipette<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.]]Next to metabolites, the blastocoel fluid can contain DNA. Studies have shown that genomic DNA is present in about 90% of the blastocoel fluid samples tested. Typically the fluid is removed with an ICSI pipette from a day five blastocyst through its mural trophectoderm until the blastocyst fully collapses around the embryo. Several concerns regarding this method in a clinical setting have been raised. The collected DNA may be contaminated by the culture media that contains DNA fractions. The DNA may also be least representative of the actual embryos genome as the DNA may originate from abnormal or degenerated cells. Even though labelled noninvasive, the blastocyst still undergoes manipulation to some degree which may affect its viability. Thus, more research is required until this method can evolve from research to clinical use<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
====Proteomics and Medium Based PGD====<br />
The media in which embryos are kept during the early IVF procedures, gives rise to potential non-invasive techniques. For instance, the protein secretome of blastocysts may be representative of its chromosome constitution Recent studies have found biomarkers such as lipocalin-1, interleukin-10, tumor necrosis factor, stem cell factor, and chemokine ligand 13 to be differently secreted by aneuploid blastocyst than by euploid ones. The most significant biomarker appears to be interleukin-10. Paired with novel proteomic technologies and mass spectrometry this knowledge when extended may contribute to a new invasive PGD method<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. In addition, medium based non-invasive PGD has been researched for the diagnose of human α-thalassemia-SEA. Genomic DNA was collected from the media and the study surprisingly resulted in increased diagnosis efficacy compared to biopsy-based methods<ref name="PMID25816038"><pubmed>25816038</pubmed></ref>.<br />
====Embryo Morphology====<br />
Using time lapse imaging the embryo’s morphology can be closely observed and potential aneuploidy characteristics detected. Such characteristics may include the time of division to five cells, the time between the division from three to four cells, and the duration of the division from one to two and subsequently to three. In addition, the morphological quality of ICM an TE has been positively associated with aneuploidy or euploidy prognosis<ref name="PMID26246880"><pubmed>26246880</pubmed></ref>. These may give rise to an embryo quality screening prior to implantation<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
==Glossary==<br />
'''Biopsy:''' sample of tissue taken for examination <br />
<br />
'''Blastocyst:''' Stage of embryo at approximately day 5 consisting of an outer (trophoblast) layer and inner (embryoblast) cell mass. <br />
<br />
'''Blastomere:''' Initial cells formed through mitosis of the zygote<br />
<br />
'''CTFR''' Cystic Fibrosis Transmembrane Conductance Regulator, responsible for transport of chloride across the cell membrane<br />
<br />
'''Fluorescent In situ hybridisation:''' technique use to locate specific gene sequences using fluorescence tags <br />
<br />
'''Polar bodies:''' cell formed during the meiotic stages of the oocyte containing extra genetic material <br />
<br />
'''Polymerase Chain Reaction (PCR):''' Technique used to amplify DNA to study a specific genetic sequence<br />
<br />
'''Preimplantation Genetic Diagnosis (PGD):''' Involves genetic testing conducted to identify abnormalities in an embryo before implantation.<br />
<br />
'''Preimplantation Genetic Screening (PGS):''' Involves genetic screening for genetic abnormalities using techniques such as FISH and PCR to eliminate unhealthy embryos <br />
<br />
'''Robertsonian Translocations:''' Type of structural chromosomal translocation <br />
<br />
<br />
'''ESHRE'''The European Society for Human Reproduction and Embryology<br />
<br />
<br />
'''ICSI''' Intracytoplasmic Sperm Injection<br />
<br />
'''IMSI''' Intracytoplasmic Morphologically Selected Sperm Injection<br />
<br />
'''NGS''' Next Generation Sequencing <br />
<br />
<br />
''SNP''' Single Nucleotide Polymorphism <br />
==References==<br />
<br />
<references/><br />
<br />
<br />
{{StudentPage2015}}</div>Z5017878https://embryology.med.unsw.edu.au/embryology/index.php?title=2015_Group_Project_6&diff=2073132015 Group Project 62015-10-22T05:24:44Z<p>Z5017878: </p>
<hr />
<div>{{ANAT2341Project2015header}}<br />
<br />
<br />
=Preimplantation Genetic Diagnosis and Preimplantation Genetic Screening=<br />
==Introduction==<br />
Preimplantation genetic diagnosis (PGD) and preimplantation genetic screening (PGS) are reproductive options for couples with known family histories of genetic disease or couples undergoing IVF procedures due to infertility issues. PGD can diagnose many genetic disorders caused by known chromosomal abnormalities (number and/or structure) or single gene mutations, and, thus decrease the risk of termination of pregnancy or miscarriages and enable such couples to have an unaffected child<ref name="PMID24907939"><pubmed>24907939</pubmed></ref>. Through major improvements in PGD/S and general laboratory technology, the testing for abnormalities in fetuses has shifted from prenatal diagnosis during the first 2 trimesters <ref> Blackburn, S.L. (2003) '''Maternal, Fetal & Neonatal physiology: a Clinical perspective''' (2nd ed.). Seattle: Saudners </ref>, testing for overall fetal growth, complications of pregnancy, and birth defects<ref> Sadler T.W.(2012) '''Langman's Medical Embryology''' (12th ed.) Philadelphia: Lipincott, Wiliams & Wilkins, a Wolters Kluwer Business </ref>, to an embryonic focus especially in advancements in Artificial Reproductive Technologies (ART)<ref><pubmed>20638568</pubmed></ref>. In 1990 PGD for a recessive X-linked disease resulted in the first live birth<ref><pubmed>2330030</pubmed></ref> and has since been incorporated in clinical routine and applied for a variety of genetic diseases, such as sickle cell anemia, thalassemia, or cystic fibrosis<ref name="PMID24907939"/>.<br />
[[File:Preimplantation Genetic Diagnosis Procedure.jpeg|600px|left|thumb| Simplified steps for PGD<ref name="PMID24907939"/>]]<br />
{|class="wikitable"align="right" <br />
| <html5media height="400" width="533">https://www.youtube.com/watch?v=0e-79qKllqk</html5media><br />
|-<br />
| Preimplantation Genetic Diagnosis<ref>IVF Florida (2011, December 11) IVF Florida - South Florida Fertility Specialists - Pre-Implantation Genetic Diagnosis [Video file]. Retrieved from https://www.youtube.com/watch?v=0e-79qKllqk</ref><br />
|}<br />
<br />
==History==<br />
The advances in reproductive technology during the second half of the 20th century, led to PGD's first clinical application in 1990 <ref>Harper, J. (n.d.). The history of PGD. Lecture. UCL Centre for PG&D and CRGH.University College London</ref>.<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
|Year<br />
|<br />
|- bgcolor="FFFAFA"<br />
| '''1967''' <br />
|First PGD on rabbit blastocysts (Gardner& Edwards) <ref name="PMID6036172"><pubmed>6036172</pubmed></ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1986''' <br />
|First Cleavage Biopsy (Wilton & Trounson)<ref>Wilton, L. J., & Trounson, A. O. (1986). Viability of mouse embryos and blastomeres following biopsy of a single cell. In Proceedings of the 18th Annual Conference of the Australian Society for Reproductive Biology, Brisbane, Australia.</ref><br />
|- bgcolor="FFFAFA"<br />
|'''1987''' <br />
|First Blastocyst Biopsy (Muggleton-Harris, Monk, Rawlings, & Whittingham)<ref name="PMID3372699"><pubmed>3372699</pubmed></ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1988''' <br />
|First Polar Body Biopsy (Yury Verlinksy)<ref> Verlinsky, Y., Pergament, E., Andresen, P., Enriquez, G., & Strom, C. (1989). Genetic analysis of polar body DNA: A new approach to preimplantation genetic diagnosis. Am J Hum Genet, 45(4), A272.</ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1990''' <br />
|First Clinical PGD using PCR testing for X-linked (Handyside, Kontogianni, Hardy, & Winston)<ref name="PMID2330030"><pubmed>2330030</pubmed></ref> <br />
|} <br />
==Preimplantation Genetic Diagnosis==<br />
PGD is used to test the genetic makeup of embryos to detect single gene disorders, chromosomal abnormalities and mitochondrial disorders. It also has applications in gender selection for diseases with unequal gender distributions <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Some diseases commonly involved with PGD include cystic fibrosis, spinal muscular atrophy and beta – thalassaemia <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press.">Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press</ref> <ref name="PMID17823145"><pubmed>17823145</pubmed></ref>. It was first used in the United Kingdom in the 1980s of arenoleucodystrophy and primarily focusing on sex- linked disorders <ref name="PMID17823145"/><ref name="PMID23150080"><pubmed>23150080</pubmed></ref>. PGD is now capable of detecting single cell defects (molecular) and chromosomal disorders resulting from the inversion, translocation or deletion of chromosomes (cytogenic) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>,<ref name="PMID11325751"><pubmed>11325751</pubmed></ref>. PGD can be applied to the embryo at different stages. That is on polar bodies, blastomeres or blastocyst <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>.<br />
Depending on the type of genetic disorder, PGD utilises different methods of genetic testing. These include Fluorescence in situ hybridisation (FISH) which is used for sex – linked disorders and detects chromosomal rearrangements <ref name="PMID11325751"/><ref name="PMID17876073"><pubmed>17876073</pubmed></ref> and Embryo halotyping which allows the identification of chromosomes causing the inherited disorder through knowledge of the pattern of closely linked markers <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. Polymerase chain reaction (PCR) is also widely used to detect molecular abnormalities <ref name="PMID11325751"/>.<br />
PGD is tightly regulated and supported by large organisations namely The American Society for Reproductive Medicine, The European Society for Human Reproduction and Embryology (ESHRE), The European Society of Human Genetics and the Preimplantation Genetic Diagnosis International Society <ref name="PMID25500181><pubmed>25500181</pubmed></ref>.<br />
===Sex-linked disorders===<br />
The determination of a disease as gender specific usually correlates with the presence or absence of specific genes such as SRY on the Y chromosome. It is known that females have two X chromosomes and males have an X and a Y chromosome where abnormalities are more prevalent on the X chromosome. PGD can be used for sex selection where only male embryos are transferred to reduce the chance of inheriting X-linked disorders. However, this does not completely eradicate the problem as male embryos remain susceptible to inheriting an affected X chromosome. Sex determination is only used when the specific mutation is unknown and has yet to be discovered <ref name="PMID24866878"><pubmed>24866878</pubmed></ref>.<br />
===Single gene defects===<br />
Single gene defects can be dominant, recessive, autosomal or X-linked. They are commonly diagnosed using PCR and although the PCR available today is complex and capable of combatting a large range of disease the development of new protocols has been proven to be difficult due to the small DNA sample available <ref name="PMID26168107"><pubmed>26168107</pubmed></ref><br />
===Mitochondrial disorders===<br />
Mitochondrial disorders also known as oxidative phosphorylation disorders arise from mutations in the nuclear DNA or mitochondrial DNA <ref name="PMID26312584"><pubmed>26312584</pubmed></ref>. They pose as a problem because they are unrecognisable until the mutations in the cell reach a detrimental level <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Mitochondrial disorders cause miscarriages and stillbirths as well as death in children and young adults. The effects can either be contained in a single organ or more commonly involve multiple organ failure where organs with high energy demands such as the brain, liver muscle and heart and heavily influenced. They are usually occur spontaneously or result from inheritance from the mother. Since mitochondria are solely inherited from the mother oocyte donations have been used as a solution to combat mitochondrial disorders. Additionally, there has been an increasing use in PGD where embryos that stay under the given threshold of 18% gene-mutations are allowed to be transferred and result in normal development. New technology in the areas of nuclear gene transfer and genome editing are also being experimented with <ref name="PMID26312584"/>. <br />
===Chromosomal disorders===<br />
Chromosomal disorders can be reciprocal, Robertsonian translocations, inversions, deletions and insertions <ref name="PMID26168107"/>. . Data from ESHRE collected between 2010 and 2011 has shown that the most common chromosomal abnormality confronted in PGD are reciprocal chromosomal abnormalities <ref name"PMID26071418"><pubmed>26071418</pubmed></ref>. PGD has also been used successfully for Robertsonian translocations (RT), a type of structural translocation. Children who carry RT are phenotypically normal, however in their later years it is found that they will suffer from infertility and repeated miscarriages due to the high frequency of abnormal embryos <ref name="PMID22081077"><pubmed>22081077</pubmed></ref>. PCR and FISH are the two main techniques used for chromosomal disorders. To be able to conduct the examinations the cells are required to be at the metaphase stage <ref name="PMID26168107"/>. <br />
[[File:Reasons_for_PGD.jpg|600px|thumb|Reasons for PGD<ref name= "PMID24764761"><pubmed><24764761</pubmed></ref>]]<br />
==Preimplantation Genetic Screening==<br />
PGS involves an array of methods or ideas that aim to segregate embryos that have genetic flaws and those that are healthy <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. The occurrence of aneuploidy is high around the stages of early embryonic development and they are the most common cause if miscarriages and congenital birth defects <ref name= "PMID26085841"><pubmed>26085841</pubmed></ref>. They have little effect on the morphology of the embryo making them difficult to identify thus identification heavily relies on genetic testing <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. <br />
Genetic sampling is most commonly conducted using Microarray Comparative Genomic Hybridisation (aCGH) as well as FISH, Quantitative PCR and Single Nucleotide Polymorphism (SNP) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. These methods collectively aim to assess numeral and structural chromosomal errors <ref name= "PMID26085841"/>. Studies have also introduced Next- Generation Sequencing (NGS) <ref name= "PMID26085841"/> and Whole Genome Amplification used to screen imbalances in the complete 24-chromosomes <ref name="PMID25953353"><pubmed>25953353</pubmed></ref><br />
Statistics from ESHRE have shown that the most common indications for PGS is advanced age, followed by repeated implantation failure or recurrent miscarriage and male infertility <ref name="PMID26071418"><pubmed>26071418</pubmed></ref>.<br />
===Indications===<br />
A low percentage of structural abnormalities in chromosomes are responsible for the cause of miscarriages. Despite this, they are the most prevalent type of chromosomal abnormality accounted for in PGD <ref name="PMID20638568"/>. The presence of specific gene cycles, initiation of embryonic protein synthesis and evident physiological development are all indicative of a successful in vitro fertilisation procedure <ref name="PMID11576737"><pubmed>11576737</pubmed></ref>. To eliminate further errors from occurring during the PGD procedure it is recommended to undertake further prenatal testing such as amniocentesis in the later stages <ref name="PMID20638568"/>. <br />
====Advanced maternal age====<br />
Data provided by the ESHRE has shown that the mean age of women undergoing PGS is 39 years <ref name="PMID26071418"/>. Women of advanced age have been shown to have a lower rate of pregnancies reaching childbirth <ref name="PMID18583331"><pubmed>18583331</pubmed></ref>. The highlighted concern revolves around the increased occurrence of aneuploidy following maternal age. The optimal age range for the lowest aneuploidy incidence was found to be between 27 to 37 years of age (6%) then progressively higher in women aged up to 42 (33%) and most common in those 44 and above (53%) <ref name="PMID24355045"><pubmed>24355045</pubmed></ref>. <br />
====Recurrent pregnancy loss / IVF failure====<br />
Recurrent pregnancy loss is defined as three or more IVF failures after cumulative transfer of more than 10 good-quality embryos. These are primarily caused by two main factors, reduced endometrium receptivity or embryonic defects. Endometrium receptivity can be negatively influences by instances including uterine pathologies such as thin endometrium, altered expression of adhesive molecules and immunological factors. Additionally, embryonic defects may be due to genetic abnormalities, embryonic aneuploidy or zona hardening. Endometriosis and hydrosalpinx has been known to effect both the endometrium and embryo <ref name="PMID23260857"><pubmed>23260857</pubmed></ref>.<br />
====Human leukocyte antigen matching====<br />
First used in 2001, HLA matching is an option given to parents to save a child with haematological or immunological disease through conceiving another child who would potentially be able to donate cord blood or haematopoietic stem cells from the bone marrow for transplantation. The process namely PGD-HLA has shown to improve haematopoietic stem cell transplant (HSCT). PGD-HLA can only be performed when HSCT is not needed urgently due to the time needed to conceive and delivery the baby <ref name="PMID25500181"><pubmed>25500181</pubmed></ref>. It is most commonly applied to children suffering from relapsed leukaemia <ref name="PMID22524201"><pubmed>22524201</pubmed></ref>. In a case study PGD-HLA was proven to successfully cure 10 diseases including Fanconi anaemia, Diamond-Blackfan anaemia and beta thalassemia <ref name="PMID25066893><pubmed>25066893</pubmed></ref>.<br />
==Biopsy Methods==<br />
Biopsy, the removal of genetic materials, from oocytes or embryos in the preimplantation stage is the primary step in PGD. For the past two decades these biopsies have been performed at three stages, the polar body, blastomere, and blastocyst, and the methodologies optimized to ensure the embryo’s viability. The most common approach involves biopsies at the cleavage stage. However, polar body and blastocyst biopsies are increasingly more often tested and applied. Approached for opening the zona pellucida involve next to the traditional mechanical and chemical means, novel approaches such as noncontact lasers. Their application may simplify and secure the procedure significantly. The most challenging question about PGD procedures remains at what stage biopsies should be taken. Much controversy has developed around this topic, highlighting the varying disadvantages and advantages of temporal biopsies. <ref name="PMID22723007"><pubmed>22723007</pubmed></ref><br />
<br />
[[File:Polar_Body,_Blastomere,_and_Trophectoderm_Biopsy.jpeg|400px|thumb|Polar body (A), blastomere (B) and trophectoderm (C) biopsies<ref name="PMID25625041"><pubmed>25625041</pubmed></ref>.]]<br />
{| class="wikitable"<br />
|- align="center" bgcolor="DDCEF2"<br />
|<br />
| Time of Biopsy<br />
| Advantages <br />
| Disadvantages<br />
|- bgcolor="FFFAFA"<br />
| Polar Body<br />
| Day 1<br />
| No harm to oocyte<br />
| Only maternal DNA is tested, often needs to be coupled with other biopsies, and there are difficulties distinguishing between the first and second PB.<br />
|- bgcolor="FFFAFA"<br />
| Blastomere<br />
| Day 3<br />
| …<br />
| … <br />
|- bgcolor="FFFAFA"<br />
| Trophectoderm<br />
| Day 5 and 6 <br />
| Little harm to the embryo and large amount of genetic material is extracted. <br />
| Opening of blastocyst necessary, small time window for procedure<br />
|}<br />
===Polar Body Analysis===<br />
Day 1<br />
====Description====<br />
Polar body (PB) biopsy offers a promising alternative to biopsies performed at the blastomere stage for PGD/S indications on legal and practical grounds. Consequent embryo development does not necessitate the presence of the first and second PB and their removal may not be crucial. PB biopsy requires precise timing. Keeping track of the meiotic cell cycle is necessary to perform a successful biopsy and, therefore, PB biopsy usually is applied in combination with intracytoplasmic sperm injection (ICSI). During the maturation from the germinal vesicle stage to the metaphase-II stage the first PB is formed. A cytoplasmic bridge containing spindle remnants, that are still in contact with the cellular genetic material, links this PB to the oolemma for about 90 minutes after extrusion. It is possible to visualize these remnants by polarization microscopy and it is crucial to not perform the biopsy until the first PB is no longer firmly attached to the oolemma as this indicates an immature embryo.The oocyte tolerates mechanical zona dissection best during hours four until six after ICSI as the oolemma has stabilized by that time because of the cortical granule reaction. Over time the first PB degenerates stressing a temporal biopsy and its optimal extraction time window is four to 12 hours after ICSI. The second PB forms around two to four hours after ICSI. Its optimal time window for biopsy is set to be eight to 16 hours after ICSI due to the second PB being attached to the oolemma with spindle remnants until six hours after ICSI. Biopsy at this point may cause enucleation of the oocyte. Studies have shown that the amplification efficiency of second PB’s DNA is worse if the PB is extracted prior to eight hours after ICSI. Thus, it is possible to perform sequential and simultaneous biopsies for the first and second PB. If performed, sequentially the first PB may be removed four to 12 hours and the second PB eight to 16 hours after ICSI. The optimal time window for a biopsy for both the first and second PB simultaneously is eight to 12 hours after ICSI. It is highly preferred to analyze both PBs due to potential aneuploidies in either PB and crossing overs during meiosis<ref name="PMID22723007"/>. <br />
====Procedure====<br />
Chemical opening achieved with for example acidic tyrode’s solution of the zona pellucida is not tolerated by the oocyte and may have detrimental effects on the embryo’s development. Therefore, the access to the perivitelline space of the oocyte is provided by mechanical zona dissection or by laser. Both techniques work well if performed by experienced embryologist. However, laser-assisted biopsy is less time consuming when compared to manual dissection. It is critical to consider the size of the introduced opening as it will remain permanent. If it is too large the blastomere may be lost during embryo development and if it is too small it may interfere with hatching of the embryo during blastocyst stage<ref name="PMID22723007"/>.<br />
[[File:Polar_Body_Biopsy.jpeg|left|thumb|The presence of a faint but clearly identifiable strand connecting PB2 to the oolemma. The biopsy was performed ∼9 h after ICSI<ref name="PMID21908464"><pubmed>21908464</pubmed></ref>.]]<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JTaQzszVr8o</html5media><br />
|-<br />
| Laser-assisted polar body biopsy<ref>RIUK, R. (2013, June 25) Polar Body Biopsy [Video file]. Retrieved from https://www.youtube.com/watch?v=JTaQzszVr8o</ref><br />
|}<br />
====Advantages & Disadvantages====<br />
PB biopsies can only investigate the maternal contributions to the embryo as they are of maternal origin. Thus, this procedure is appropriate for PGD solely for monogenetic diseases from the maternal side. Recessive diseases may be evaluated with PB biopsies on the basis that the embryo’s outcome will be determined by the paternal contribution. It may still be applied for PGS as it is a fairly safe biopsy option and most aneuploidies either arise during meiosis or origin from the maternal genome. However, diagnosis error has been reported due to the lack of considering paternal contributions.Because PB biopsies are performed very early it is not yet known whether the oocyte will develop into a viable embryo. Thus, PBs are commonly frozen or fixed after biopsy and depending on the state of the embryo only chosen PBs will be tested. This is primarily an economic issue as many genetic testing procedures are very cost-intensive<ref name="PMID22723007"/>[[File:Implantation_predictive_value_of_euploid_screening_results.jpeg|thumb|The sustained implantation predictive value (with 95 % confidence interval) of a euploid screening result obtained from the first polar body (PB1), PB1 and the second polar body (PB2), or a direct embryo biopsy for each stage of embryo transfer (cleavage-stage and blastocyst stage)<ref name="PMID25106935"><pubmed>25106935</pubmed></ref>.]] Generally the sustained implantation predictive value of screening of PBs is significantly lower than of for example biopsies of the blastocyst stage<ref name="PMID25106935"/>. Moreover, it is often difficult to distinguish between the first and the second PB. As the first one degenerates quicker, this may influence diagnostic procedures<ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
===Blastomere biopsy===<br />
Day 3 <br />
====Description====<br />
Blastomere biopsy has been the prevalent method for PGD and PGS in the last two decades. At least one, but up to two, blastomeres are biopsied on day three of the cleavage stage embryo. The right number of blastomeres removed is a controversial topic as two cells allow for more genetic material and more accurate results. However, removing two cells might be too invasive and damaging to the embryo. As PGS tries to improve implantation rates, whereas PGD sets out to avoid known genetic disorders, for the former only one cell is removed, while for the latter often two need to be removed, to ensure results as correct as possible<ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
====Procedure====<br />
Initially a hole was drilled into the zona pellucida using acid tyrodes with the consequent aspiration of blastomeres with a pipette. Nowadays the zona pellucida is largely opened using a laser and calcium and magnesium free media have been introduced to decrease junctions between blastomeres, which facilitates the biopsy<ref name="PMID21748341"/>.<br />
[[File:Aspiration_of_a_Blastomere.jpeg|thumb|Aspiration of a Blastomere into the biopsy pipette<ref name=" PMID24783200"><pubmed>24783200</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=TbridWVwipI</html5media><br />
|-<br />
| Laser-assisted blastomere biopsy<ref>Sukprasert, M. (2014, March 5) Day 3 Blastomere Biopsy 1 [Video file]. Retrieved from https://www.youtube.com/watch?v=TbridWVwipI</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
===Trophectoderm biopsy===<br />
Day 5 and 6<br />
====Description====<br />
The improvement of embryo culture media allowed the in vitro development of human embryos until the blastocyst stage and opened up the possibility to take blastocyst biopsies. During day three to day five the haploid maternal and paternal genomes work together for the first time to form the genome of the embryo. The maternal epigenetic control lessens significantly while preparing for implantation with precisely arranged events happening. The first event includes a rapid increase in the number of embryonic cells which are active in mitotic divisions and apoptosis of aberrant cells. This is followed by the formation of blastocoel (cavitation) which results from the flattening of cell located on the outside of the blastomere. Now the blastocyst will expand until the embryo hatches by rupturing the zona pellucida. The cells of the blastocyst will differentiate to form two distinct cell lineages, the outer trophectoderm and the inner cell mass<ref name="PMID22723007"/>.<br />
====Procedure====<br />
Trophectoderm biopsy is usually performed in Hepes buffered biopsy medium and opening approaches include needle cutting which has been replaced by lasers in past years. Different research groups report different timings of the opening to be the most successful. Some open the blastocyst on day three or four by creating a 25 µm which causes the trophectoderm to herniate through this hole and is, thus, accessible for biopsy. Others create this hole about four hours before biopsy which allows sufficient herniation of trophectoderm cells. It is also possible to open the blastocyst immediately before biopsy. This avoids an extra step and the inner cell mass usually is easy to locate. Blastocyst biopsies involve the removal of trophectoderm cells and the ideal time for the procedure is day five. Successful biopsies on day six have been performed, while little is known about the results of biopsies on day seven. However, since the window of implantation in humans is from day eight to ten after ovulation, day seven biopsies appear to be possible<ref name="PMID22723007"/>.<br />
-collapse of trophoblasts<br />
-possible: biopsy of hatched blastocyst, holding pipette careful mild suction force to hold embryo near ICM <br />
-Cryopreservation<br />
<br />
<br />
[[File:Microscopic images of human blastocysts for biopsy.jpeg|thumb|(A) Some trophectoderm cells in a blastocyst started to hatch and (B) the trophectoderm cells were biopsied with assisted laser cutting. Images in C–D show the blastocysts after vitrification and warming. Blastocysts had been cultured for 2–4 hrs after warming, showing good (ICM and trophectoderm cells) hatched (C) and hatching (D) blastocysts. The hatching blastocyst in (E) has good ICM but fair trophectoderm while the blastocyst in (F) has both fair ICM and trophectoderm. Arrows indicate ICMs and arrow heads indicate trophectoderm cells. Bar = 40 µm<ref name="PMID2190846"><pubmed>2190846</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JI_TQ8d8tNM</html5media><br />
|-<br />
| Laser-assisted blastocyst biopsy (at 00:50 min)<ref>Coco, R. (2014, April 30) Trophectoderm biopsy in a Hatching blastocyst protruding ICM [Video file]. Retrieved from https://www.youtube.com/watch?v=JI_TQ8d8tNM</ref><br />
|}<br />
<br />
====Advantages & Disadvantages====<br />
Blastocyst biopsies are believed to be less damaging to the embryo and appear to be unrelated to implantation rates. In addition, this biopsy method allows for a larger extraction of cells for genetic testing. However, since they are performed late in in vitro development, the time window for genetic testing is relatively small. Fast and accurate genetic testing methods are needed to ensure a successful and safe result from this biopsy. Thus, blastocyst biopsies may gain more popularity in the future whn such methods have been developed or improved<ref name="PMID22723007"/>. <br />
==Genetic Techniques==<br />
===Polymerase Chain Reaction===<br />
PCR amplifies DNA specific to genetic sequence of interest . PCR was developed by Kay Mullis in the 1980s, for which he was awarded the Nobel prize for chemistry in 1993. <ref> Pubmed Docs (2015) Polymerase Chain Reaction (PCR) Pubmen. Retrieved from [http://www.ncbi.nlm.nih.gov/probe/docs/techpcr/]</ref> This technique enables clinicians to monitor and diagnose diseases using minute samples such as embryonic cells, blood & tissue. <ref>Roche (2015) PCR: How We Copy DNA. Roche Molecular Systems Inc. retrieved From [http://molecular.roche.com/pcr/Pages/Process.aspx]</ref> PCR has many important applications like DNA fingerprinting, genetic mapping, detection of viruses and bacteria as well as being used to detect genetic disorders, as a part of PGD, in conjunction with IVF. It is used to detect molecular abnormalities such as single gene disorders like Tay Sach, Cycstic fibrosis, Duchenne Muscular Dystrophy, Thalassemia, Huntington disease, Spinal muscular atrophy and many more. Molecular and Genetic analysis require a significant amount of DNA, which we would not have without PCR. It revolutionized the study of DNA, replacing all previous recombinant DNA technology. <ref> Mullins, K., Francois, F.& Gibbs R.A. (1994 ) The Polymerase Chain Reaction. p3. Springer- Science +Business Media. Birkhauser, Boston<br />
Available at [https://books.google.com.au/books?hl=en&lr=&id=gjrTBwAAQBAJ&oi=fnd&pg=PR5&dq=kary+mullis+PCR&ots=mpzAyRh5ZY&sig=PQ4goNoKJ90tb3-MkPk62zrTGbw#v=onepage&q=kary%20mullis%20PCR&f=false] </ref> <br />
<br />
[[File:PCR.jpg|thumb|right|Polymerase chain reaction (PCR) amplifies DNA specific to genetic sequence of interest, enabling the monitoring and diagnose molecular abnormalities such as single gene disorders using minute samples such as embryonic cells, blood & tissue <ref>NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref>]]<br />
{|<br />
|- align="left" bgcolor="DDCEF2"<br />
|'''Procedure'''<br />
|}<br />
Samples are obtained from the the blastocyst, a polar body biopsy or the blastomeres stages of the embryo. <br />
*Stage 1 Denaturing: separating the target strands of DNA <br />
The obtained sample is heated to roughly 90 degrees celcius, this heat breaks the relatively weak bonds between nucleotides that form DNA. The double stranded DNA is split into two single strands of DNA that are used as templates.<br />
*Stage 2 Annealing: Binding the Primers to the target DNA sequence <br />
PCR will only copy the target sequence of DNA specified by specific PCR primer. These synthesized primers oligonucleotides are small artificial pieces of DNA. TAQ polymerase enzyme synthesize two new strands of DNA duplicate to the single sample DNA stand template indicated by these primers. During this stage the reaction is cooled to a temperature between 40-60 degrees Celsius. <br />
*Stage 3- Extension- making copies <br />
Each of these two copies are then used again as templates generating two further replications This cycle can occur as many 30 -40 times within a couple hours leading to billions of extra copies of the original DNA segment. The optimal temperature for the further replication is roughly 72 degrees Celsius. <br />
This process mediated by a thermocycler machine that is programmed to alter the temperature of the reaction every couple of minutes, perpetuating the cycle of DNA denaturing and synthesis. <br />
This process, generates exponentially exact copies of the original template DNA sequence. <br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
!PCR cycles<br />
|-<br />
| '''PCR Cycle'''<br />
| '''Target Copies'''<br />
|-<br />
| 1<br />
| 2<br />
|-<br />
| 2<br />
| 4<br />
|-<br />
| 3<br />
| 8<br />
|-<br />
| 4<br />
| 16<br />
|-"<br />
| 5 <br />
| 32<br />
|-<br />
| 6 <br />
| 64<br />
|-<br />
| 7 <br />
| 128<br />
|-<br />
| 8<br />
| 256<br />
|- <br />
| 9<br />
| 512 <br />
|-<br />
| 10<br />
| 1024<br />
|-<br />
| 15<br />
| 32,768<br />
|-<br />
| 20 <br />
| 1,048,578<br />
|-<br />
| 25<br />
| 33,554,432<br />
|-<br />
| 30 <br />
| 1,073,741,842<br />
|-<br />
|}<br />
<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="7" |'''Advantages'''<br />
|-bgcolor="FFFAFA"<br />
| Fast and inexpensive way of copying a target sequence of DNA<br />
|-bgcolor="FFFAFA"<br />
| Particularly useful for the diagnosis of single cell defects<br />
|-bgcolor="FFFAFA"<br />
| Rapid generation of results (within hours)<br />
|-bgcolor="FFFAFA"<br />
| Highly sensitive, a single molecule of DNA is sufficient for reaction<br />
|-bgcolor="FFFAFA"<br />
| Generates DNA copies exponentially<br />
|-bgcolor="FFFAFA"<br />
| This enables DNA amplification required for molecular and genetic diagnostic analysis<ref> Dreesen, J., Drusedaul, M., Smeets, H., Die-Smulders, C., Coonen, E., Dumoulin, J., Gielen, M., Evers, J., Herbergers, J. & Geradets, J. (2008) Validation of preimplantation genetic diagnosis by PCR analysis: genotype comparison of the blastomere and corresponding embryo, implications for clinical practice. Mol. Hum. Reprod. 14 (10):573-579.doi: 10.1093/molehr/gan052. Retrieved from [http://molehr.oxfordjournals.org/content/14/10/573.short] </ref> <ref><pubmed>20966460</pubmed></ref><br />
|-bgcolor="DDCEF2"<br />
| rowspan="5"|'''Disadvantages'''<br />
|-bgcolor="FFFAFA"<br />
| Only during the exponential DNA replication phase, the starting quantity sequence contained in the original sample (template DNA strand) can be determined<br />
|-bgcolor="FFFAFA"<br />
| PCR reaction is limited to by presence of inhibitors in the sample<br />
|-bgcolor="FFFAFA"<br />
| Self annealing due to the accumulation of the product -stopping exponential amplification for the target sequence and reach a plateau<br />
quantification of the end point of reaction of PCR products unreliable - therefore real time quantitative RT-PCR is necessary<br />
<ref> NIS (2015) Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref><br />
|-bgcolor="FFFAFA"<br />
| Not a diagnostic method on its own, requires further analysis<br />
|}<br />
===Fluorescent In Situ Hybridisation===<br />
FISH is the one of the most effective and rapid <ref name="PMID26338801"><pubmed>26338801</pubmed></ref> method of conducting PGD. This techniques used to locate a specific DNA sequences within a chromosome. FISH facilitates the clinical diagnosis of chromosomal abnormalities indicated by sequential duplications, deletions and rearrangements of chromosome, that are usually missed with microscopic analysis. This technique is especially relevant for female embryos with X-linked diseases,<ref name="PMID20809319"><pubmed>20809319</pubmed></ref> that have no other mutation specific tests [http://www.ncbi.nlm.nih.gov/pubmed/20809319] As part of PGD, samples are collected from various stages of the embyro,and they are able to conducted tests on the blastocyst, a polar body biopsy and the blastomeres <ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. FISH is 99% effective when used in conjunction with competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities<ref name="PMID26338801"/>.<br />
{|<br />
|- align="left" bgcolor="DDCEF2"<br />
|'''Procedure'''<br />
|}<br />
Samples are collected from either the blastocyst, a polar body biopsy or the blastomeres stages of the embryo <ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
DNA strands are heated and denatured causing their the individual DNA strands to break apart<br />
Probes are single complimentary stands of DNA a that have been tagged with small chemical agents that glow brightly in the presence of a specific region on a chromosome. These specific probes then hybridize and join to their complementary DNA strand. <br />
The fluorescent tags enable the researchers to correctly identify the presence or lack thereof and location of the specific chromosomes that they are testing for. <ref name="PMID17876073"><pubmed>17876073</pubmed></ref><br />
Researcher analyse the results by identifying the number and the relative location of the fluorescent dots generated by the FISH images.<ref name="PMID17970921"><pubmed>17970921</pubmed></ref><br />
The probe will not fully hybridise if there has been a duplication or a deletion of the DNA - indicating chromosomal and sex chromosomal anomalies like trisomies and aneuploidies. <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref><br />
Different probes are used for different purposes: <ref>Unique, Rare Chromosome Disorder Support Group (2013) Fluorescence in situ hybridisation (FISH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/Other/FISH%20FTNW.pdf]</ref><br />
*'''Locus specific tags''' detect very small imbalances, and locate isolated small portions <br />
of genes within a chromosome<br />
*'''Alphoid/Centomeric Repeat probes''' are developed from the repetitive sequence located in the middle region of each chromosome, useful in determining the number of chromosomes , detecting rearrangement and when used in conjunction with locus probes to determine the absence of genetic material on a chromosome. <br />
*'''Paint Probes''' are collections of smaller probes with their own stains that bind to a different section on the chromosome - allowing the full chromosome too be labeled a unique colour, this "full colour map" can be used to know the spectral karyotype- full chromosomal mapping is useful in examining chromosomal abnormalities. <br />
[[File:Fluorescent In Situ Hybridisation (FISH).jpg|thumb|right|'''FISH''' We are able to tag Specific DNA sequences using Probes which have been tagged with fluorescent Labels.This technique enables the clinical diagnosis of chromosomal abnormalities, indicated by sequential duplication, deletions and rearrangements of chromosome <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref>]]<br />
<br />
{|class="wikitable" align="center"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="8" |'''Advantages''' <br />
|-bgcolor="FFFAFA" <br />
| FISH is 99% effective when used in conjunction with Competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities.<ref><pubmed>26338801</pubmed></ref><br />
|-bgcolor="FFFAFA" <br />
| Rapid generation of results<br />
|-bgcolor="FFFAFA"<br />
| Identifies very small translocations and aneuploidies that occur within chromosomes, that would usually be missed under microscopic analysis<br />
|-bgcolor="FFFAFA" <br />
| Indicates whether the accessed chromosomes are normal <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|-bgcolor="FFFAFA" <br />
| Tests for the most common chromosomal abnormalities - down syndrome chromosomes 13,16,18,21 and 22 <ref><pubmed>21749752</pubmed></ref><br />
|-bgcolor="FFFAFA" <br />
| It may be used to compare the chromosomal gene arrangements in related species<br />
|-bgcolor="FFFAFA" <br />
| Can be used to identify and remove inheritable X-linked disease or sex chromosome anomalies such as Duchenne's Muscular Dystrophy, hemophilia, ectodermal dysplasia <ref><pubmed>17876073</pubmed></ref><br />
|-bgcolor="DDCEF2"<br />
| rowspan="5"|'''Disadvantages'''<br />
|-bgcolor="FFFAFA" <br />
| FISH destroys all cells tested <ref> O'Connor, C. (2008) Fluorescence in situ hybridization (FISH). Nature Education 1(1):171. retrieved from [http://www.nature.com/scitable/topicpage/fluorescence-in-situ-hybridization-fish-327] </ref><br />
|-bgcolor="FFFAFA" <br />
| It does not fully access all chromosomes (only ~ 12)<br />
|-bgcolor="FFFAFA" <br />
| Analysis of results is dependent upon the dot quality impacted by hybridisation efficiency or the camera sensitivity <ref><pubmed>17970921</pubmed></ref><br />
|-bgcolor="FFFAFA" <br />
| Some studies indicate that using FISH on a day-3 embryo biopsy decreases the rate of live births <ref><pubmed>26168107</pubmed></ref><br />
|}<br />
<br />
===Array Comparative Genomic Hybridisation (aCGH)===<br />
aCGH also known as Microarray analysis efficiently scans the entire genome for chromosomal imbalances. CGH was initially developed to detect the number of changes in a solid tumor mass. It uses 2 genomes comparing the sample to the control, with each labeled in a different fluorescent dye<ref name="PMID1876176"><pubmed>1876176</pubmed></ref>. Earlier CGH techniques were limited by the resolution of the imaging <ref> Lichter, P., et al. Comparative genomic hybridization: Uses and limitations. Seminars in Hematology 37, 348–357 (2000)</ref> , these initial limitations were overcome by using Microarrays in conjunction with CGh to improve the resolution of the imaging, Array Comparative Genomic Hybridisation (aCGH). This method compares sample and control microarrayed slides containing small segments of DNA (probes). <ref> Lucito, R., et al. Representational oligonucleotide microarray analysis: A high-resolution method to detect genome copy number variation. Genome Research 13, 2291–2305 (2003) </ref> the Probes used will vary according from the small (25-85 base pairs) oligonucleotides manufactured to highlight different target sequences, to the very large genomic clones (80,000- 200,00 base pairs), and as these are significantly smaller than the traditional metaphase chromosomes used for CGH, generating a higher resolution of image. <ref name="PMID22467166"><pubmed>22467166</pubmed></ref>.aCGH is used as a diagnostic tool for prenatal detection f chromosomal abnormalities <ref name="PMID19012303"><pubmed>19012303</pubmed></ref>.<br />
{|<br />
|- align="left" bgcolor="DDCEF2"<br />
|'''Procedure'''<br />
|}<br />
<ref> Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432] </ref><br />
The sample is obtained (skin, blood or fetal cells) and DNA is obtained. <br />
As a part of PGD fetal cell samples are collected from; the fertilized egg polar bodies, the blastomere (day 3 embryo) or the blastocyst/tropoectoderm stage (day 5 embryo).<br />
Sample DNA is labeled with one fluorescent dye, and the control DNA is labeled with a different colored fluorescent dye. the control DNA is used as the base point of reference. <br />
heated and denatured single DNA strands then hybridize to their complementary single strand probes, which are then combined and applied to a microarray and the results are run through a computer program and a digital imaging system is used to quantify the results( fluorescent intensities of the labeled probes). <br />
<br />
[[File:aCGH.jpg|thumb|right|'''aCGH''' checks the entire genome for chromosomal imbalances, by comparing control and a sample slides contatining small segements of DNA sample microarrayed slides small segments of DNA. Illustrated by student z5020317 and adapted from <ref> NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation. retrieved from [http://www.phgfoundation.org/file/5237/]</ref> <ref>Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432]</ref>]]<br />
<br />
The fluorescent ratio and the hybridization signal at different locations on the genome of the control DNA are used to identify any variances present in the sample DNA. aCGH facilitates the clinical diagnosis of submicroscopic chromosomal duplication, deletion and rearrangements indicative of chromosomal disorders such as trisomies 1-22and specific sex linked disorders. <br />
Duplications in the DNA are displayed by the computer program as spikes/ peaks over an established threshold and deletions in DNA are displayed by the computer program as spikes/ toughs beneath this threshold <br />
<br />
{|class="wikitable" align="center"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="12" |'''Advantages''' <br />
|-bgcolor="FFFAFA"<br />
| Multiple applications: prenatal genetic diagnosis, cancer diagnosis, <ref name="PMID20193845"><pubmed>20193845</pubmed></ref> genetic screening for developmental delay (learning disabilities) <ref name="PMID17309648"><pubmed>17309648</pubmed></ref>. or congenital anomalies that are suspected to be genetic in origin <ref>NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation . retrieved from [http://www.phgfoundation.org/file/5237/]</ref><br />
|-bgcolor="FFFAFA"<br />
| trace represents all chromosomes present in the human genome chromosomes 1-22 and the X & Y chromosomes, and therefore is the most accurate method for testing whole embryo aneuploidy<br />
|-bgcolor="FFFAFA"<br />
| aCGH has been extensively tested, and Validated, and is now used world wide.<br />
|-bgcolor="FFFAFA"<br />
| Detects submicroscopic alterations<br />
|-bgcolor="FFFAFA"<br />
| Detects deletions and additions and rearrangements as well as amplification, of the WHOLE genome, simultaneously.<br />
|-bgcolor="FFFAFA"<br />
| Used as a diagnostic tool for prenatal detection of chromosomal abnormalities <ref name="PMID22034057"><pubmed>22034057</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Provides high resolution genomewide screening of segmental genomic copy number variations<br />
|-bgcolor="FFFAFA"<br />
| Very accurate when used in conjunction with FISH<br />
|-bgcolor="FFFAFA"<br />
| Alone is more reliable and in detecting chromosomal abnormalities, with a higher implantation success rate, than FISH <ref name="PMID20494259"><pubmed>20494259</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Allows an in depth research focus upon specific types of rearrangements within selected chromosomal regions, a recent particular area of interest is subtelomeric and pericentromeric rearrangements<br />
|-bgcolor="FFFAFA"<br />
| Reduces the risk of failed implantation and miscarriage, improving the chance of a healthy baby <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|-bgcolor="DDCEF2"<br />
| rowspan="9" |'''Disadvantages'''<br />
|-bgcolor="FFFAFA"<br />
| Translocations and inversions of DNA are not detected<br />
|-bgcolor="FFFAFA"<br />
| Limited ability diagnosing specific polyploidies such as triploidy <ref> Unique, Rare Chromosome Disorder Support Group (2013) Microarray-based Comparative Genomic Hybridiation (array CGH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/other/array%20cgh%20ftnw.pdf] </ref><br />
|-bgcolor="FFFAFA"<br />
| Will not detect mosaicism detection <20% (cultures where >1 of 5 cells are trisomy 12)<br />
|-bgcolor="FFFAFA"<br />
| Will not detect balanced chromosomal rearrangement<br />
|-bgcolor="FFFAFA"<br />
| Will not detect duplications or deletions <80kb<br />
|-bgcolor="FFFAFA"<br />
| Will not detect point mutations within genes <ref>Washington department of education (CGH- FAQ for physicians. Signature Genomic LAboratories, LLC. Retrieved from [https://depts.washington.edu/dbpeds/Lab%20Tests/SignatureCGH-physician_FAQ.pdf]</ref><br />
|-bgcolor="FFFAFA"<br />
| will not detect chromosomal position of genomic gains<br />
|-bgcolor="FFFAFA"<br />
| Will not detect loos of heterozygosity (LOH) or Absence of heterozygosity (AOH) <ref>WiCell Research Institute Inc. (2012) Comparative Genomic Hybridization Microarray. <br />
retrieved from [http://www.wicell.org/home/cytogenetic-services/cgh-microarray/array-comparative-genomic-hybridization-acgh.cmsx]</ref><br />
|}<br />
<br />
===Next Generation Sequencing===<br />
The development and advances within ART in the past 20 years, as well as the increasing popularity of IV, has lead to an influx of new technologies developed to screen embryos for chromosomal anomalies, which are covered by the umbrella term of Next generation Sequencing (NGS). NGS is a general term used to describe all of the new and emerging screening techniques currently being introduced and used as part of PGD for IVF . NGS screens for single gene disorders as well as conducting extensive and very comprehensive chromosome diagnosis by sequencing, counting, and accurately assembling millions of DNA reads, simultaneously. <ref name="PMID23499002"><pubmed>23499002</pubmed></ref> There is a movement for NGS to replace the other limited testing techniques and be used as the standard. <br />
{|<br />
|- align="left" bgcolor="DDCEF2"<br />
|'''Procedure'''<br />
|}<br />
Samples are collected from either blastomere or the blastocyst/tropoectoderm and processed for analysis by a computer system. <br />
The methodology of each process is unique to the technique being used. <br />
<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="14" |'''Advantages''' <br />
|-bgcolor="FFFAFA" <br />
| Cheaper<br />
|-bgcolor="FFFAFA"<br />
| Opens new diagnostic possibilities<br />
|-bgcolor="FFFAFA"<br />
| Accurately tests all 24 chromosomes<br />
|-bgcolor="FFFAFA"<br />
| Tests for the presence of monogenic diseases of known genetic background<br />
|-bgcolor="FFFAFA"<br />
| Reduces the number of biopsies required for diagnosis<br />
|-bgcolor="FFFAFA"<br />
| Higher detection rate of small translocations<br />
|-bgcolor="FFFAFA"<br />
| Highly accurate is testing for compound point mutations, chromosomal duplication, deletions and insertions <ref name="PMID23312231"><pubmed>23312231</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| It accurately detects chromosomal aneuploidy and unbalanced rearrangement <ref name="PMID25685330"><pubmed>25685330</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Higher detection rate of small translocations<br />
|-bgcolor="FFFAFA"<br />
| NGS single gene disorder screenings can conducted in conjunction with PCR comprehensive chromosomal screening<br />
|-bgcolor="FFFAFA"<br />
| Reduces human error <br />
|-bgcolor="FFFAFA"<br />
| Better detects the presence of mosaicism<br />
|-bgcolor="FFFAFA"<br />
| Work well in conjunction with CGH and aCGH as part of PGD, improving the chances of IVF. <ref> Morris, R. S. (2015 ) Next generation sequencing for PCG|PGS|CCS. IVF1 retrieved from [http://www.ivf1.com/next-generation-sequencing for-pgd] </ref><br />
|-bgcolor="DDCEF2"<br />
| '''Disadvantages''' <br />
|-bgcolor="FFFAFA"<br />
| There are limited information available to clinical applications of NGS <ref><pubmed>26100406</pubmed></ref><br />
|}<br />
<br />
==Diagnosis==<br />
There are a large amount of diseases that PGD can apply to, below are descriptions of the diseases that PGD are more commonly used for. Upon completion of the genetic testing for the genes of concern the cells the embryos are discarded and priority is given to those that are healthy. <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/><br />
===Cystic Fibrosis===<br />
Cystic fibrosis is a single gene disorder. It is autosomal recessive and involves mutations in the cystic fibrosis transmembrane conductance regulator (CTFR) gene. The CTFR gene is normally responsible for the decrease in chloride and the transport of bicarbonate in epithelial cells thus playing a major physiological role. In PGD procedures, identification of the gene is assisted by microsatellite markers that have similar composition to the CTFR gene itself. Biopsy of two cells at the blastocyst stage is recommended if markers are not available. There are many variations of cystic fibrosis the most common being P.Phe508del <ref name="PMID26014425"><pubmed>26014425</pubmed></ref>.<br />
===Duchenne Muscular Dystrophy ===<br />
Duchenne Muscular Dystrophy is an X-linked recessive disease. It involves the Xp21 gene where majority of the mutations are chromosomal deletions with a smaller percentage resulting from duplications <ref name="PMID18359022"><pubmed>18359022</pubmed></ref>.<br />
<br />
===Autosomal Recessive Meckel-Gruber Syndrome===<br />
Autosomal recessive genetic defect caused by the TMEM67 gene. It results in cystic dysplasia of the kidneys with fibrotic change in the liber and occipital encephalocele. Other malformations could also be present in the central nervous system. In PGD whole genome amplification of single blastomeres are taken to identify the gene, this is also coupled with PCR techniques. Maternal plasma can also be extracted for PGS. <ref><pubmed>24039893</pubmed></ref> <br />
===β – Thalassemia=== <br />
β – Thalassemia is known as the most common type of autosomal recessive inherited disorder among haemoglobinopathies. It involves the adult β-globin gene and is associated with the absent or decreased expression of the gene. This is commonly caused by a single nucleotide change in the gene. PGD has been used successfully worldwide to identify the β-globin gene where its application is usually performed on a single blastomere or polar body <ref name="PMID19064120">19064120</pubmed></ref>.<br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
! Applicable diseases for PGD <ref>Genoma Group (2014). Retrieved September 18th, 2015, from http://www.preimplantationgeneticdiagnosis.it/genetic-diseases-diagnosed-by-pgd.htm </ref>, <ref>Genesis Genetics (2015). Retrieved September 18th, 2015, from http://genesisgenetics.org/pgd/what-we-test-for/</ref>, <ref>Human Fertilisation & Embryology Authority (2015). Retrieved Septembr 18th, 2015, from http://guide.hfea.gov.uk/pgd/</ref><br />
|-<br />
| '''Disease'''<br />
| '''Involved Genes'''<br />
|-<br />
| 5 Alpha Reductase Deficiency (5ARD)<br />
| SRD5A2 <br />
|-<br />
| Achondroplasia<br />
|FGFR3 <br />
|-<br />
| Acute Intermittent Porphyria <br />
| ALAD, ALAS2, CPOX, FECH, HMBS, PPOX, UROD, or UROS<br />
|-<br />
| Adrenoleukodystrophy (Adrenomyeloneuropathy)<br />
| ABCD1 <br />
|-<br />
| Agammaglobulinaemia (x-linked) <br />
|BTK <br />
|-<br />
| Agammaglobulinemia Bruton Tyrosine Kinase (BTK) <br />
|BTK <br />
|-<br />
| Aicardi Goutieres Syndrome 1 (AGS1) <br />
|TREX1, RNASEH2A, RNASEH2B, RNASEH2C, SAMHD1<br />
|-<br />
| Alagille Syndrome<br />
|JAG1 or NOTCH2<br />
|- <br />
| Alpers-Huttenlocher Syndrome <br />
|POLG <br />
|-<br />
| Alpha-1-antitrypsin deficiency <br />
|SERPINA1 <br />
|-<br />
| Alpha-Mannosidosis<br />
| MAN2B1 <br />
|-<br />
| Alpha Thalassemia <br />
|HBA1 or HBA2 <br />
|-<br />
| Alports Syndrome<br />
|COL4A3, COL4A4, COL4A5<br />
|-<br />
| Alzheimer's Disease - early onset (Type 3 and 4) <br />
|APP, PSEN1, or PSEN2<br />
|-<br />
| Amyotrophic Lateral Sclerosis 1 (ALS1) <br />
|C9orf72, SOD1, TARDBP, FUS, ANG, ALS2, SETX, VAPB <br />
|-<br />
| Argininosuccinic Aciduria <br />
| ASL<br />
|-<br />
| Arrhythmogenic Right Ventricular Cardiomyopathy/ Dysplasia (ARVC/D)<br />
| DSG2; DSP; PKP2<br />
|-<br />
| Ataxia Telangiectasia<br />
| ATM<br />
|-<br />
| Autosomal Recessive Meckel-Gruber Syndrome<br />
| TMEM67<br />
|-<br />
| Bardet-Biedl Syndrome (BBS)<br />
| BBS1; BBS10<br />
|-<br />
| Barth Syndrome<br />
| TAZ<br />
|-<br />
| Beta Thalassaemia<br />
| HBB<br />
|-<br />
| Birt-Hogg-Dubé Syndrome<br />
| FLCN<br />
|-<br />
| Breast Ovarian Cancer Familial Susceptibility (BRCA2)<br />
| BRCA1; BRCA2<br />
|-<br />
| Canavan Disease <br />
| ASPA<br />
|-<br />
| Carnitine-Acylcarnitine Translocase Deficiency <br />
| SLC25A20<br />
|-<br />
| Cerebral Arteriopathy with Subcortical Infarcts & Leukoencephalopathy (CADASIL)<br />
| NOTCH3<br />
|-<br />
| Cerebral Cavernous Malformation<br />
| CCM1<br />
|-<br />
| Charcot-Marie-Tooth Disease<br />
| GJB1; MPZ; NEFL; PMP22<br />
|-<br />
| CHARGE Syndrome<br />
| CHD7<br />
|-<br />
| Cherubism<br />
| SH3BP2<br />
|-<br />
| Choroideremia<br />
| CHM<br />
|-<br />
| Chronic Granulomatous Disease<br />
| CYBB; NCF1<br />
|-<br />
| Ciliary Dyskinesia<br />
| DNAH5<br />
|-<br />
| Citrullinemia<br />
| ASS1<br />
|-<br />
| Cleidocranial Dysplasia<br />
| RUNX2<br />
|-<br />
| Cockayne Syndrome<br />
| ERCC6<br />
|-<br />
| Congenital Adrenal Hyperplasia<br />
| CYP21A2<br />
|-<br />
| Congenital Cataracts<br />
| GJA8; VSX2<br />
|-<br />
| Congenital Diarrhea, Syndromic<br />
| SPINT2<br />
|-<br />
| Congenital Disorders of Glycosylation (CDG)<br />
| ALG1; ALG6; CDG1C; DOLK; PMM2<br />
|-<br />
| Cornelia de Lange Syndrome <br />
| NIPBL<br />
|-<br />
| Craniosynostosis<br />
| TWIST1<br />
|-<br />
| Crouzon Syndrome<br />
| FGFR2<br />
|-<br />
| Cysteinyl Leukotriene Receptor 1 Deficiency <br />
| CYSLTR1<br />
|-<br />
| Cystic Fibrosis<br />
| CFTR<br />
|-<br />
| Diamond –Blackfan Anemia <br />
| RPS19<br />
|-<br />
| Duchenne Muscular Dystrophy <br />
| DMD<br />
|-<br />
| Dyskeratosis congenita (Male embryos only)<br />
| DKC1<br />
|-<br />
| Ectodermal dysplasia (Hypohidrotic)<br />
| EDA; EDA1; GJB6; IKBKG<br />
|-<br />
| Familial Adenomatous polyposis coli (FAP)<br />
| APC<br />
|-<br />
| Familial Dysautonomia<br />
| IKBKAP<br />
|-<br />
| Fanconi Anemia <br />
| FANCA; FANCC; FANCD2; FANCF; FANCG; FANCJ<br />
|-<br />
| Fragile X Syndrome (FRAX)<br />
| FMR1<br />
|-<br />
| Galactosemia <br />
| GALT<br />
|-<br />
| Gangliosidosis<br />
| GLB1<br />
|-<br />
| Glanzmann Thrombasthenia <br />
| ITGA2B<br />
|-<br />
| Glutaric Acidemia (aciduria)<br />
| GCDH <br />
|-<br />
| Glycogen Storage Disease <br />
| G6PC; GAA; SLC37A4<br />
|-<br />
| Haemophilia A<br />
| F8<br />
|-<br />
| Haemophilia B<br />
| F9<br />
|-<br />
| Hereditary Nonpolyposis Colorectal Cancer: Lynch Syndrome<br />
| MLH1; MSH2; MSH6<br />
|-<br />
| Holt Oram Syndrome<br />
| TBX5<br />
|-<br />
| Huntington Disease<br />
| HD<br />
|-<br />
| Hydrocephalus<br />
| L1CAM<br />
|-<br />
| Ichthyosis <br />
| ABCA12; STS<br />
|-<br />
| Incontinentia Pigmenti (IP)<br />
| NEMO<br />
|-<br />
| Joubert Syndrome 5<br />
| INPP5E<br />
|-<br />
| Krabbe Disease<br />
| GALC<br />
|-<br />
| Leber Congenital Amaurosis (LCA)<br />
| CEP290; GUCY2D<br />
|-<br />
| Leigh Syndrome (Infantile Subacute Necrotising Encephalopathy)<br />
| LRPPRC<br />
|-<br />
| Lesch Nyan Syndrome<br />
| HPRT1<br />
|-<br />
| Leukocyte Adhesion Deficiency (Type I)<br />
| ITGB2<br />
|-<br />
| Li-Fraumeni Syndrome<br />
| TP53<br />
|-<br />
| Macular Dystrophy Retinal <br />
| VMD2<br />
|-<br />
| Maple Syrup Urine Disorder (MSUD)<br />
| BCKDHB<br />
|-<br />
| Marfan Syndrome <br />
| FBN1<br />
|-<br />
| Menkes Syndrome<br />
| ATP7A<br />
|-<br />
| Mitochondrial DNA Depletion Syndrom <br />
| POLG; RRM2B; SUCLA2; TK2<br />
|-<br />
| Mucolipidosis type II<br />
| GNPTAB<br />
|-<br />
| Multiple Endocrine Neoplasia<br />
| MEN1; MEN2A; MEN2B<br />
|-<br />
| Multiple Exostoses<br />
| EXT1; EXT2 <br />
|-<br />
| Myotubular myopathy<br />
| MTM1 <br />
|-<br />
| Nail-Patella Syndrome<br />
| LMX1B<br />
|-<br />
| Neurofibromatosis Type 1<br />
| NF1<br />
|-<br />
| Neurofibromatosis Type 2 <br />
| NF2<br />
|-<br />
| Noonan Syndrome<br />
| KRAS, PTPN11; SOS1<br />
|-<br />
| Norrie Disease<br />
| NDP<br />
|-<br />
| Ocular Albinism <br />
| GPR143<br />
|-<br />
| Oculocutaneous Albinism <br />
| OCA2; TYR <br />
|-<br />
| Oculodentaldigital Dysplasia<br />
| GJA1<br />
|-<br />
| Optic Atrophy<br />
| OPA1<br />
|-<br />
| Ornithine Transcarbamylase Deficiency <br />
| OTC<br />
|-<br />
| Osteogenesis imperfeca <br />
| COL1A1; COL1A2<br />
|-<br />
| Osteopetrosis <br />
| CLCN7; OSTM1; TCIRG1<br />
|-<br />
| Pachyonychia Congenita <br />
| KRT16; KRT6A<br />
|-<br />
| Pancreatitis, Hereditary<br />
| PRSS1 <br />
|-<br />
| Papillorenal syndrome <br />
| PAX2<br />
|-<br />
| Phenylketonuria <br />
| PAH <br />
|-<br />
| This table does not cover the complete list of diseases that PGD can be applied to.<br />
|}<br />
<br />
==Laws & Legal status==<br />
<br />
{| class="wikitable" <br />
|-bgcolor="DDCEF2"<br />
|'''Country'''<br />
|'''Legislation'''<br />
|-bgcolor="FFFAFA" <br />
| Australia<br />
| PGD is currently used to detect serious genetic conditions to improve the outcome of Assisted Reproductive Technologies (ART). In very rare cases it may be used to select an embryo with compatible tissue for a sibling who has a life-threatening disease where other means of treatment is unavailable. This is with the conditions that the use of PGD will not affect the welfare and interests of the child to be born. The parents must also receive adequate counselling and have full understanding of the procedures of PGD. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"> National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art</ref><br />
The use of PGD for sex-selection is prohibited with the exception of reducing the risk of the transmission of serious sex-linked genetic conditions. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"/><br />
|-bgcolor="FFFAFA"<br />
| Brazil<br />
| The laws regarding PGD in Brazil are not strictly regulated. They are vague and there is limited information surround the activities of assisted reproduction in general in the country <ref name="PMID25493379"><pubmed>25493379</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| Czech Republic<br />
| The laws in the Czech Republic allow those with a “defined indication in order to exclude risk of serous genetically conditioned disease and defects with embryos before they are implanted into the cavity of the uterus”. Couples that undergo any assisted reproductive treatment including PGD have to be married. Sex-selection is illegal except in regards to serious sex-linked genetic diseases <ref name="PMID24777348"><pubmed>24777348</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| Greece<br />
| In Greece, ART is open to those up to the age of 50 with written consent. It can only be used if a medical necessity is present such as the susceptibility of serious hereditary diseases. Sex selection is banned apart from cases of sex-linked diseases and sexually transmitted diseases <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| India<br />
| In India there is a cultural preference for boys thus the Prenatal Diagnostic Techniques (Regulation and Prevention of Misuse) Act was introduced in 1994. This law limits the use of PGD for sex determination except in cases of specific congenital diseases. These laws however are not strictly enforced. <ref>World Health Organisation (2015) Gender and Genetics Retrieved on October 21st 2015 from:http://www.who.int/genomics/gender/en/index4.html</ref><br />
|-bgcolor="FFFAFA"<br />
| Portugal <br />
| ART is only available to those who are married or have a similar type of relationship for at least two years. The couples cannot be of the same sex and must be at least 18 years of age. Sex selection is illegal except in cases of sex-linked diseases. The use of PGD is illegal if the predictive value of genetic tests are very low <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| Spain<br />
| PGD can be applied to “serious hereditary diseases not amenable to postnatal curative treatment” and “detection of other abnormalities which may compromise the viability of the pre-embryo”. If PGD is to be used for any other purpose authorisation must be acquired <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| Sweden <br />
| The use of PGD is strictly regulated and couples must achieve authorisation of the National Board of Health and Welfare. It can only be used it can only be used if the child is at risk to inheriting a serious chromosomal or monogenetic disease. It cannot be used for selection of specific characteristics <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| United Kingdom<br />
| Those involved with carrying out the IVF treatment must have a license from the Human Fertilisation and Embryology Authority (HFEA). Only embryos that are approved by the HFEA can be implanted where the embryonic nuclear or mitochondrial DNA cannot be altered with the exception of preventing mitochondrial diseases <ref name="PMID24777348"/>. <br />
|}<br />
<br />
==Future/Current Research==<br />
In addition to research efforts for improving overall performance of established PGD/S techniques, such as finding the ideal zona pellucida insection site in an fully automatic manner<ref name="PMID26259216"><pubmed>26259216</pubmed></ref>, many research efforts have been spent to find alternative, non-invasive techniques to test for diseases and abnormalities<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
===Non-invasive Preimplantation Genetic Testing without Embryo Biopsy===<br />
Different parameters of gametes, zygotes, embryos (“vacuoles in sperm heads, spindle position in mature oocytes, cleavage intervals of zygote, and embryo developmental dynamics”) may correlate with aneuploidy rates. This knowledge may be applied in potential noninvasive preimplantation diagnostic methods. Several methods have been proposed and are currently further researched<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Sperm Selection====<br />
Intracytoplasmic morphologically selected sperm injection (IMSI) is common procedure in IVF treatment to improve fertilization rates in patients with poor semen quality. In addition, studies have found that IMSI improves embryo development and that spermatozoa with large vacuoles in their heads correlate with increased aneuploidy rates and disturbed chromosomal structures. Thus, selecting spermatozoa based on morphological hallmarks may decrease aneuploidy rates in the fertilized embryos. As with polar body biopsies, however, this approach will solely be applicable if evidence for severe male detrimental contribution is given<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Blastocoel Fluid Extraction====<br />
In addition, a less invasive retrieval of material for diagnosis could include the extraction of the blastocoel fluid. The cavity of the blastocyst, lined by the trophectoderm, is filled with this blastocoel fluid, which contains metabolites of both trophectoderm and inner cell mass origin. The retrieval does not require a biopsy but merely a small opening to extract the fluid and, thus, causes less harm to the embryo. Multiple studies have applied this method<ref name="PMID22020776"><pubmed>22020776</pubmed></ref> <ref name="PMID23148560"><pubmed>23148560</pubmed></ref> <ref name="PMID26006737"><pubmed>26006737</pubmed></ref> and it may in the future become of clinical relevance.[[File:Aspiration_of_the_Blastocoel_Fluid.jpeg|400px|thumb|Aspiration of the Blastocoel Fluid using a ICSI pipette<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.]]Next to metabolites, the blastocoel fluid can contain DNA. Studies have shown that genomic DNA is present in about 90% of the blastocoel fluid samples tested. Typically the fluid is removed with an ICSI pipette from a day five blastocyst through its mural trophectoderm until the blastocyst fully collapses around the embryo. Several concerns regarding this method in a clinical setting have been raised. The collected DNA may be contaminated by the culture media that contains DNA fractions. The DNA may also be least representative of the actual embryos genome as the DNA may originate from abnormal or degenerated cells. Even though labelled noninvasive, the blastocyst still undergoes manipulation to some degree which may affect its viability. Thus, more research is required until this method can evolve from research to clinical use<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
====Proteomics and Medium Based PGD====<br />
The media in which embryos are kept during the early IVF procedures, gives rise to potential non-invasive techniques. For instance, the protein secretome of blastocysts may be representative of its chromosome constitution Recent studies have found biomarkers such as lipocalin-1, interleukin-10, tumor necrosis factor, stem cell factor, and chemokine ligand 13 to be differently secreted by aneuploid blastocyst than by euploid ones. The most significant biomarker appears to be interleukin-10. Paired with novel proteomic technologies and mass spectrometry this knowledge when extended may contribute to a new invasive PGD method<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. In addition, medium based non-invasive PGD has been researched for the diagnose of human α-thalassemia-SEA. Genomic DNA was collected from the media and the study surprisingly resulted in increased diagnosis efficacy compared to biopsy-based methods<ref name="PMID25816038"><pubmed>25816038</pubmed></ref>.<br />
====Embryo Morphology====<br />
Using time lapse imaging the embryo’s morphology can be closely observed and potential aneuploidy characteristics detected. Such characteristics may include the time of division to five cells, the time between the division from three to four cells, and the duration of the division from one to two and subsequently to three. In addition, the morphological quality of ICM an TE has been positively associated with aneuploidy or euploidy prognosis<ref name="PMID26246880"><pubmed>26246880</pubmed></ref>. These may give rise to an embryo quality screening prior to implantation<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
==Glossary==<br />
'''Biopsy:''' sample of tissue taken for examination <br />
'''Blastocyst:''' Stage of embryo at approximately day 5 consisting of an outer (trophoblast) layer and inner (embryoblast) cell mass. <br />
'''Blastomere:''' Initial cells formed through mitosis of the zygote<br />
'''CTFR''' Cystic Fibrosis Transmembrane Conductance Regulator, responsible for transport of chloride across the cell membrane<br />
'''Fluorescent In situ hybridisation:''' technique use to locate specific gene sequences using fluorescence tags <br />
'''Polar bodies:''' cell formed during the meiotic stages of the oocyte containing extra genetic material <br />
'''Polymerase Chain Reaction (PCR):''' Technique used to amplify DNA to study a specific genetic sequence<br />
'''Preimplantation Genetic Diagnosis (PGD):''' Involves genetic testing conducted to identify abnormalities in an embryo before implantation.<br />
'''Preimplantation Genetic Screening (PGS):''' Involves genetic screening for genetic abnormalities using techniques such as FISH and PCR to eliminate unhealthy embryos <br />
'''Robertsonian Translocations:''' Type of structural chromosomal translocation <br />
<br />
<br />
'''ESHRE'''The European Society for Human Reproduction and Embryology<br />
<br />
<br />
'''ICSI''' Intracytoplasmic Sperm Injection<br />
<br />
'''IMSI''' Intracytoplasmic Morphologically Selected Sperm Injection<br />
<br />
'''NGS''' Next Generation Sequencing <br />
<br />
<br />
''SNP''' Single Nucleotide Polymorphism <br />
==References==<br />
<br />
<references/><br />
<br />
<br />
{{StudentPage2015}}</div>Z5017878https://embryology.med.unsw.edu.au/embryology/index.php?title=ANAT2341_Lab_10_-_Online_Assessment_2015&diff=207283ANAT2341 Lab 10 - Online Assessment 20152015-10-22T04:54:13Z<p>Z5017878: /* Student ROIs */</p>
<hr />
<div>{{Header}}<br />
<br />
==Individual Assessment==<br />
* Place your work on this page under a sub-sub-heading of your ROI.<br />
* Add your own sub-sub-heading '''below''' any existing student ROI.<br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
! About this Assessment<br />
|-<br />
| A demonstration of this assessment will be given in the practical class. Below in the collapsible table are examples of links from a virtual slide. There is also a [[Help:Virtual Slides Permalink|permalink help page]].<br />
<br />
<br />
{{Virtual Slide Features - Stage 22 Liver}}<br />
<br />
<br />
Using the Human Embryo Carnegie Stage 22 [[Embryo Virtual Slides|virtual slides]] shown below:<br />
<br />
# Using the "mobile view" Identify a sensory region of interest ('''ROI''') in one of the virtual slides below.<br />
# View at a high magnification (detailed view) the region of interest.<br />
# Generate a [[Help:Virtual Slides Permalink|permalink]] to the ROI.<br />
# Paste the link on your own page and write a brief description of what the linked region is showing.<br />
# Add a link to the embryology page and sub-heading that relates to your identified feature.<br />
# Paste all the content (text and links) you have just generated on [[ANAT2341 Lab 10 - Online Assessment 2015|'''this page''']] under a sub-heading named after your ROI.<br />
<br />
{|<br />
| valign=bottom|{{SlideStage22-08}}<br />
| valign=bottom|{{SlideStage22-08-eye}}<br />
|-<br />
| valign=bottom|{{SlideStage22-11}}<br />
| valign=bottom|{{SlideStage22-15}}<br />
|}<br />
|}<br />
<br />
==Student ROIs==<br />
<br />
===This is a sub-sub-heading===<br />
<br />
<br />
===Cochlear Duct===<br />
<br />
link to permalink image:[https://embryology.med.unsw.edu.au/embryology/Slides/Embryo_Stages/Stage22/11/Stage22-11.html?zoom=6&lat=-3948&lon=6149&layers=B | Cochlear Duct ]<br />
<br />
<br />
The '''cochlear duct''' is an fluid filled cavity inside the cochlea. It located between the tympanic duct and the vestibular duct, and between the basilr membrane and reissner's memebrane. It derived from otic placode, otic vesicle, and originated from surface ectoderm.<br />
<br />
'''embryology link''' [[Sensory - Hearing and Balance Development]] --Inner Ear<br />
<br />
===Semicircular Canal===<br />
<br />
link to permalink image:[https://embryology.med.unsw.edu.au/embryology/Slides/Embryo_Stages/Stage22/11/Stage22-11.html?zoom=6&lat=-5565.50267&lon=7382.99733&layers=B | Semicircular Canal ]<br />
<br />
The '''semicircular canals''' are part of the inner ear.They are lined with cilia and filled with endolymph which is a liquid substance. Every time the head moves, the endolymph moves the cilia and this movements of the cilia are communicated to the brain. As a result, the brain knows how to keep the body balanced, regardless of the posture.<br />
<br />
'''embryology link''' [[Hearing - Inner Ear Development]] -- Inner Ear <br />
<br />
<br />
===Lens of the Eye===<br />
<br />
Link to permalink image: [https://embryology.med.unsw.edu.au/embryology/Slides/Embryo_Stages/Stage22/08-eye/Stage22-08-eye.html?zoom=6&lat=-2022&lon=2991&layers=B Anterior portion of the Lens of the embryonic eye] <br />
<br />
The lens of the eye is derived from surface ectoderm. Said ectoderm forms a lens/optic placode in the head region which then invaginates to form a lens pit and then later a lens vessel. Lens fibres then develop and are surrounded by a lens capsule. The main function of the lens is to focus light onto the retina. <br />
<br />
'''Embryology link''' [[Vision - Lens Development]] --Development Overview <br />
<br />
===Retina of the Eye===<br />
Link to permalink image: [https://embryology.med.unsw.edu.au/embryology/Slides/Embryo_Stages/Stage22/08-eye/Stage22-08-eye.html?zoom=6&lat=-4961.72287&lon=4821.89847&layers=B Retina of the Eye]<br />
<br />
The retina is the light sensitive portion of the eye. It contains 10 separate layers, including the photoreceptor layer which is comprised of rods and cones. These rods and cones convert light into signals, which are then communicated to the brain via the optic nerve. Optic cup morphogenesis is responsible for the development of the vertebrate eye, and it is believed that this process significantly contributes to the development of the retina.<br />
The image above displays a Carnegie Stage 22 retina. The nerve fibre layer is particularly prominent in this image and is the pale layer closest to the vitreous chamber. The processes of rods, cones and ganglion cells can be observed migrating towards the optic nerve.<br />
<br />
'''Embryology Link''' [[Vision - Retina Development]]<br />
<br />
===Retinal Pigment Epithelium===<br />
<br />
Link to permalink image: [https://embryology.med.unsw.edu.au/embryology/Slides/Embryo_Stages/Stage22/08-eye/Stage22-08-eye.html?zoom=6&lat=-5391.23146&lon=3580.5&layers=B Retinal Pigment Epithelium]<br />
<br />
The '''Retinal Pigment Epithelium (RPE)''' is a complex differentiation of the retina, is generated from the optic neuroepithelium, and is structurally made up of cuboidal cells and multiple villi on its apical side. Its lateral sides are joined together by gap junctions and adherens and the RPE's basal side is in contact with Bruch's membrane. It lies between the neuronal retina and the choroid. The section shows that in the embryo the pigmented retina is still separated by a space from the neuronal retina. This space will be decreased in the adult and closely appose the two to each other. <br />
<br />
'''Embryology Link''' [[Vision - Retina Development#Retinal Pigment Epithelium]]<br />
<br />
===Cornea===<br />
<br />
Permalink: [https://embryology.med.unsw.edu.au/embryology/Slides/Embryo_Stages/Stage22/08-eye/Stage22-08-eye.html?zoom=5&lat=-1186.66894&lon=2284.66894&layers=B Cornea]<br />
<br />
The cornea is the front layer of the eye covering the iris, pupil and anterior chamber. The cornea is a transparent layer that accounts for 2/3 of the eyes total optic power by refracting light along with the anterior chamber and lens. The cornea in humans consist of 5 layers as shown in the permalink, the Corneal epithelium, followed by Bowman’s layer, Corneal stroma, Descemet’s membrane and corneal endothelium. The corneal stroma and endothelium are derived from cranial neural crest cells and the corneal epithelium differentiates from ectoderm interacting with the developing lens. <br />
<br />
Embryology link: [https://embryology.med.unsw.edu.au/embryology/index.php/Vision_-_Cornea_Development Vision – Cornea Development]<br />
<br />
===Middle Ear Ossicles===<br />
<br />
Link to permalink image: [https://embryology.med.unsw.edu.au/embryology/Slides/Embryo_Stages/Stage22/11/Stage22-11.html?zoom=6&lat=-4243.78168&lon=7877.35627&layers=B Middle Ear Ossicles]<br />
<br />
The middle ear ossicles named the malleus, incus, and stapes, are involved in transmitting vibrations from the tympanic membrane to the oval window, and ultimately to the inner ear. The are attached to muscles, tensor tympani and stapedius, to assist in reducing sound vibration and oscillations at the oval window. Embryologically, the malleus and incus are derived from the cartilage of the 1st pharyngeal arch, and the stapes is derived from the cartilage of the 2nd pharyngeal arch. In ossicle development, the malleus and incus initially form as a single structure from Meckel's cartilage, that are later separated by joint that forms between them. This process occurs within solid mesenchyme of the pharyngeal arches, therefore the ossicles are not functioning. It is only after birth that elongation of the auditory tube occurs to form the middle ear cavity that the middle ear ossicles are situated in. <br />
<br />
'''Embryology Link''' [[Hearing - Middle Ear Development]]<br />
<br />
===Embryonic Tongue===<br />
Link to permalink image: Tongue<br />
<br />
The tongue is a muscle and is important for sensing taste. All the pharyngeal arches present in the human embryo contribute to the development of the tongue however, the tongue muscle cells are derived from somites and the muscles of mastication are derived from somitomeres. Each pharyngeal contributes a different portion where arch 1 forms the oral part of the tongue, arch 2 forms the initial transient surface, arch 3 forms the pharyngeal part of the tongue and arch 4 forms the epiglottis and adjacent regions. The superior surface of the tongue comprises of taste buds, various papillae and stratified squamous epithelium. The tongue is innervated by the hypoglossal nerve (CNXII) allowing movement.<br />
Tongue Development<br />
<br />
Embryonic Link: [https://embryology.med.unsw.edu.au/embryology/index.php/Tongue_Development Tongue Development]<br />
<br><br><br><br><br><br><br />
{{ANAT2341Lab10}}<br />
<br />
<br />
<br />
{{2015ANAT2341}}</div>Z5017878https://embryology.med.unsw.edu.au/embryology/index.php?title=User:Z5017878&diff=207277User:Z50178782015-10-22T04:51:52Z<p>Z5017878: </p>
<hr />
<div>--[[User:Z8600021|Mark Hill]] ([[User talk:Z8600021|talk]]) 10:47, 6 August 2015 (AEST) Thanks for setting up your page. We will be talking more about this in the [[ANAT2341_Lab_1_-_Online_Assessment|Practical on Friday]].<br />
<br />
==Lab Attendance==<br />
--[[User:Z5017878|Z5017878]] ([[User talk:Z5017878|talk]]) 13:46, 7 August 2015 (AEST)<br />
<br />
--[[User:Z5017878|Z5017878]] ([[User talk:Z5017878|talk]]) 14:57, 14 August 2015 (AEST)<br />
<br />
--[[User:Z5017878|Z5017878]] ([[User talk:Z5017878|talk]]) 12:51, 21 August 2015 (AEST)<br />
<br />
--[[User:Z5017878|Z5017878]] ([[User talk:Z5017878|talk]]) 12:11, 28 August 2015 (AEST)<br />
<br />
--[[User:Z5017878|Z5017878]] ([[User talk:Z5017878|talk]]) 12:37, 4 September 2015 (AEST)<br />
<br />
--[[User:Z5017878|Z5017878]] ([[User talk:Z5017878|talk]]) 13:24, 11 September 2015 (AEST)<br />
<br />
--[[User:Z5017878|Z5017878]] ([[User talk:Z5017878|talk]]) 14:05, 18 September 2015 (AEST)<br />
<br />
--[[User:Z5017878|Z5017878]] ([[User talk:Z5017878|talk]]) 12:43, 25 September 2015 (AEST)<br />
<br />
--[[User:Z5017878|Z5017878]] ([[User talk:Z5017878|talk]]) 13:55, 9 October 2015 (AEDT)<br />
<br />
--[[User:Z5017878|Z5017878]] ([[User talk:Z5017878|talk]]) 12:03, 16 October 2015 (AEDT)<br />
<br />
==Online Assessments==<br />
<br />
===Lab 1 Assessment===<br />
<br />
'''Relationship of polar bodies morphology to embryo quality'''<br />
<br />
This study was conducted in hopes to find a method to forecast the quality of embryo derived from reproductive technology. 355 patients that were undergoing In-Vitro Fertilisation or Intracytoplasmic Sperm Injection (ICSI) were a part of this study. From these patients 3048 zygotes were extracted and placed into two groups; intact or fragmented. <br />
<br />
The oocyte was extracted 37 to 28 hours after recombinant human chorionic gonadotropin administration followed immediately by the collection of semen sample. The semen sample was then treated and prepared for fertilisation of the oocyte. The zygotes were recruited after 16 to 18 hours and their polar bodies examined and placed into their respective groups based on morphology. The development of the zygotes were then closely studied and graded against systems such as the Istanbul consensus and Gardner's grading system. <br />
<br />
At the conclusion of the study it was deduced that the zygotes with intact polar bodies performed remarkably better than those with fragmented polar bodies. During the third day the intact polar body group had better embryo rates, blastocyst rates and available embryo rates. The pregnancy rate and implantation rate of the two groups however were found to have no differences. <br />
<br />
<ref><pubmed>26198980</pubmed></ref><br />
<br />
'''Microdroplet In Vitro Fertilization Can Reduce the Number of Spermatozoa Necessary for Fertilizing Oocytes'''<br />
<br />
During In vitro fertilisation (IVF) usually a large sample of spermatozoa is needed. In the female body only a few spermatozoa reach the oocyte. This study introduces the idea of micro droplet IVF in hopes of mimicking the in vivo conditions and lowering the amount of spermatozoa needed. Mice were used as the subjects for all the experiments performed and the procedures were conducted using HTF fertilisation medium. <br />
<br />
This study involved several counterparts where each experiment tackled different factors that may affect the microdroplet IVF procedure. The microdroplets conprised of only one microlitre containing either 5, 10, 20 or 50 spermatozoa in comparison to the usual 80 - 500 microlitres. Each of the experiments were replicated four times using spermatozoa from different males and either cyropreserved or fresh samples. The first experiment tested the effects that the cumulus cells, GSH and sperm number, the second on varying numbers of oocytes and spermatozoa, third on the effect of using cyropreserved sperm, the fourth on the effects of using volumes of suspension larger than the optimal for the preparation of the cyropreserved sperm and the fifth was to ensure normal development of embryo. <br />
<br />
The study was deemed successful where as little as 5 spermatozoa could fertilise an oocyte. The rate of success was also found to be heightened depending on factors, for example the presence of cumulus cells was found to be beneficial to the spermatozoa fertilisation rate. Microdroplet IVF could be the alternative pathway for those who have depleted numbers of spermatozoa due to factors such as age, genetic conditions or damages to sperm over time.<br />
<br />
<ref><pubmed>24583808</pubmed></ref><br />
<br />
--[[User:Z8600021|Mark Hill]] ([[User talk:Z8600021|talk]]) 17:02, 3 September 2015 (AEST) These are reasonable summaries of these 2 papers. If you intend to use acronyms, they should be spelt out in full the first time they appear with the acronym then in brackets. (5/5)<br />
<br />
===Lab 2 Assessment ===<br />
<br />
{{Uploading Images in 5 Easy Steps table}}<br />
<br />
[[File:Zona Pellucida and ZPC-ubiquitin.jpg]]<br />
<br />
Zona Pellucida and ZPC-ubiquitin<ref><pubmed>21383844</pubmed>| [http://www.ncbi.nlm.nih.gov/pmc/articles/PMC3044170/]</ref><br />
<br />
PMID 21383844<br />
<br />
--[[User:Z8600021|Mark Hill]] ([[User talk:Z8600021|talk]]) 17:07, 3 September 2015 (AEST) The image has now been uploaded correctly and contains reference, copyright and student template. (5/5)<br />
<br />
===Lab 3 Assessment===<br />
<br />
Here are the articles related to 'Prenatal Genetic Diagnosis':<br />
<br />
<pubmed>24810687</pubmed><br />
<br />
<pubmed>23773313</pubmed><br />
<br />
<pubmed>26201722</pubmed><br />
<br />
--[[User:Z8600021|Mark Hill]] ([[User talk:Z8600021|talk]]) 17:10, 3 September 2015 (AEST) These papers are relevant to Prenatal Genetic Diagnosis. Would have been nice to include a sentence abut each paper though. (5/5)<br />
<br />
===Lab 4 Assessment===<br />
<br />
<quiz display=simple><br />
<br />
{Which ONE of the following is true with regard to the male reproductive system?<br />
|type="()"}<br />
+ The midpiece of spermatozoa is responsible for motility <br />
- The male sex hormone, testosterone is produced by spermatozoa<br />
- Only one spermatozoa has to reach the oocyte for fertilisation to occur<br />
- Spermatozoa primarily use their chemotaxic response to oestrogen to locate the oocyte<br />
||The midpiece of spermatozoa contains a large amount of mitochondria which is responsible for producing ATP to drive motility. <br />
<br />
{Which statement is INCORRECT with regard to the female menstrual cycle:<br />
|type="()"}<br />
+ Gonadotropin releasing hormone is only responsible for signalling the release of luteinising hormone (LH)<br />
- The peak of oestrogen occurs during ovulation <br />
- The female body experiences a rise in temperature during the luteal phase and is an indication of menstruation<br />
- Rising levels of progesterone occur in the luteal phase<br />
||GRH is released by the hypothalamus and is responsible for the release of both LH and FSH in the anterior pituitary.<br />
<br />
{Select the CORRECT statement:<br />
|type="()"}<br />
- Fertilisation usually occurs two thirds down the fallopian tube<br />
- Upon entering the vagina, spermatozoa have up to four days to fertilise the oocyte<br />
+ Spermatozoa contributes to only 10% of seminal fluid upon ejaculation.<br />
- Capacitation is the inactivation of spermatozoa motility<br />
||While 10% of the seminal fluid comprises of spermatozoa, the remaining are contributed from accessory glands (60% seminal vesicle, 10% bulbourethral and 30% prostate). The secretions from these glands provide optimal conditions for the spermatozoa to thrive in. <br />
<br />
</quiz><br />
<br />
[[ANAT2341 Student 2015 Quiz Questions]]<br />
<br />
--[[User:Z8600021|Mark Hill]] ([[User talk:Z8600021|talk]]) 17:15, 3 September 2015 (AEST) You left off the closing quiz code, I have added it above. Q1 is not technically correct as the mid piece provides the energy for motility, not actual motility. You need to also explain in your revealed answer why the other options are incorrect. Q3 first option is not a clear statement 2/3 from which end? (8/10)<br />
<br />
===Lab 5 Assessment===<br />
<br />
'''What is the difference between gastroschisis and omphalocele?'''<br />
<br />
Gastroschisis and omphalocele (also known as exomphalos) are gastrointestinal abnormalities. They are the two most common defects of the anterior abdominal wall where gastroschisis occurs in 2.6 per 10,000 babies and omphalocele occurs in 2.1 per 10,000 babies <ref name="PMID19302857"><pubmed>19302857</pubmed></ref> <ref>Abeywardana, S. Sullivan, EA. (2008) '''Congenital anomalies in Australia 2002-2003''' Birth anomalies series no. 3. Cat. No. PER 41. Canberra: AIHW. Retrieved from: {http://npesu.unsw.edu.au/sites/default/files/npesu/surveillances/Congenital%20anomalies%20in%20Australia%202002-2003.pdf}</ref>. Gastroschisis is usually diagnosed around week 6 of gestation and the mothers are most likely to be under 20, undernourished and are smokers where as omphalocele is usually diagnosed 17 weeks into gestation and occurs predominately in women over the age of 30 <br />
<ref name="PMID23915861"><pubmed>23915861</pubmed></ref> <ref name="PMID22004141"><pubmed>22004141</pubmed></ref>.<br />
<br />
Gastroschisis is a congenital anomaly which affects the abdominal wall, most commonly in the area to the right of the umbilicus <ref name="PMID22004141"/>. It is due to the lack of membranous covering over the wall causing herniation of viscera through the abdominal wall <ref name="PMID17560199"><pubmed>17560199</pubmed></ref>. Gastroschisis is caused by the regression of the omphalomesenteric arteries which connect the yolk sac to the dorsal aorta <ref name="PMID19302857"/>. However factors that also link to its occurrence include failure in mesenchymal differentiation, first trimester vascular accident and use of tobacco and illicit drugs <ref name="PMID17560199"/>.<br />
<br />
Omphalocele on the other hand is the herniation of the abdominal viscera into the base of the umbilicus <ref name="PMID23915861"/>. It is mainly caused by failure to complete lateral body fold migration leading to an open body wall and failure of the intestines to return to the abdominal cavity <ref name="PMID19302857"/> <ref name="PMID23915861"/>. Another cause includes the persistence of the primitive stalk <ref name="PMID23915861"/><br />
<br />
===Lab 7 Assessment===<br />
<br />
'''Identify and write a brief description of the findings of a recent research paper on development of one of the endocrine organs covered in today's practical.'''<br />
<br />
Mechanisms involved in glucocorticoid induction of pituitary GH expression during embryonic development.<br />
<br />
Through the use of chicken embryos the study investigates the pathways in which glucocorticoids undergo to initiate growth hormone in the pituitary during embryo development. The research discovered the pathway namely the ERK1/2 pathway. The ERK1/2 pathway was stimulated by corticosterone treatment, however repetitive stimulation of the pathway was also found to suppress corticosterone thus suppressing the release of growth hormone. Corticosterone is the primary type of glucocorticoid in rodents and birds thus this knowledge was applied to glucocorticoids as a whole and provided the conclusion that the ERK1/2 is a strictly regulated cyclical pathway. <br />
<br />
Somatotrophs are responsible for producing growth hormone in the anterior pituitary. Increased circulation of corticosterone lead to maturation of somatotrophs thus an increase production of growth hormone. The study also used exogenous glucocorticoids and found that it had the same effects. <br />
<br />
PMID 25560830<br />
<br />
'''Identify the embryonic layers and tissues that contribute to the developing teeth.'''<br />
<br />
The embryonic origin of developing teeth are from the ectoderm and mesoderm layers of the trilaminar embryo coupled with neural crest contribution as well. Teeth are primarily derived from two types of cells, the odontoblast and ameloblasts. Odontoblasts are neural crest derived mesenchyme cells. They differentiate under the influence of enamel epithelium to form predentin which later calcifies to form dentin. On the other hand, ameloblasts produce enamel. Growth of teeth occurs in ossifying jaws and the periodontal ligament is responsible for holding the tooth in the bone sockets. <br />
<br />
===Lab 9 Assessment (Peer Reviews)===<br />
<br />
'''Group 1'''<br />
<br />
The entire project is presented simplistically and all the content is relevant and easy to understand. Majority of the flaws I found were based around poor grammar and syntax which could be fixed up with some editing. Below is a more detailed breakdown of some of the things you could fix.<br />
<br />
Firstly, I liked that the introduction was brief and concise and gives the reader a basic understanding of the topic of three person embryo. The video was also informative and provided some background information around the topic. I was informed that mitochondrial DNA was the major factor concerning this topic however there was a lack of information about its importance to the body so a short summary could be included along with some examples of diseases it could cause. <br />
<br />
Also, the use of a timeline to present the history is a great idea and I think it could be improved and would look more aesthetically pleasing if it were to be placed into a table. I also think the 1990s, 2000s and 2010s label could be removed to make it look less clustered since they aren’t particularly necessary. <br />
<br />
Some information under the heading ‘Technical Progression’ has yet to be filled in but from what is there I’d like to suggest exchanging the bullet points for numbering instead for the information under ‘Pronuclear transfer’ and ‘Polar body transfer’ since they sounded like sequence steps as opposed to separate points. <br />
<br />
Finally, I found the layout of the table under the heading ‘Legal status’ to be very well put together. There are however some countries placed under the incorrect continents and I found that the order was easily changed and mixed up. I also noticed that several of the countries were linked to the same sources which made the information very unspecific. Instead of just links I think a few sentences explaining the legislation would be more informative. <br />
<br />
'''Group 2''' <br />
<br />
This wikipage is very well put together. Your choice of headings, subheadings and tables and images is remarkable, it definitely makes the whole page flow very well. I particularly like the hand-drawn image which does a great job at simplifying the process of the pathogenesis of OHSS. <br />
<br />
The introduction very concisely explains the contents of the page and I liked how it was finished off with a statement about the aim of the page. I thought it really brought the introduction together nicely. I can’t say much about the content except that it is very engaging and very well written so well done guys! Keep up the good work!<br />
<br />
Some suggestions I have that could improve your page include adding more images. It would be nice to have some graphs to complement the statistical date from the epidemiology. Also, in some of the paragraphs e.g. in the last paragraph of ‘Epidemiology’ there isn’t a citation that accounts for the information at the end of the paragraph so that should be fixed. <br />
<br />
'''Group 3'''<br />
<br />
First and foremost the PCOS Ovary Vs Non-PCOS Ovary hand drawn image is amazing and its placement at the beginning really drew in my attention to the topic. I also particularly liked the purple theme set up throughout the wikipage, I thought it really helped bring the page together.The headings, subheadings and images are all set out neatly making it very presentable and easy to follow. The language used was also very engaging which is always a plus. Content wise there seems to be sufficient information under most of the headings which really showed your efforts and elaborate research on the topic. The only portion that wasn’t particularly well present was the environmental factors. I felt like it needs the inclusion of some examples. <br />
<br />
To improve your page I would like to suggest the addition of a glossary that you could use to briefly define some terms such as ‘Hirsutism’ to allow a better understanding of the text. Additionally, I also noticed that under the ‘Hyperandrogenemia’ heading there was the use of the acronyms ‘GnRH’ and ‘LH’. Be sure to express the full term placing the acronym in brackets upon their first appearance before extensive use. I saw that this was done in the following paragraph where LH was initially correctly expressed as Luteinising Hormone but again this should be done at its very first appearance. The page also lacked some history surrounding the origin of the disease and how some of the treatments were established so that could also be included. <br />
<br />
Overall, the presentation of the page gave me the impression of a good understanding of the topic so well done guys! Keep up the good work. <br />
<br />
'''Group 4''' <br />
<br />
The wikipage is very well organised and the headings, subheadings and tables made everything easy to follow. I particularly liked the blue theme you kept with all the tables, it is very aesthetically pleasing. In terms of content the background information provided a clear overview of the subject especially the information about the physiology of fertility in males which laid down the foundation some basic knowledge surrounding male fertility under normal circumstances which I found useful in grasping other concepts throughout the page. The page is filled with an extensive amount of content and along with the long list of references I was given the impression of good understanding of the topic and commendable effort placed into the research.<br />
<br />
One thing I found that wasn’t quite compatible with your page was the inclusion of the video in the ‘Causes of infertility section’. Although I do agree that it is a very good video, it had little information surrounding male infertility and was more about infertility in general. Perhaps a video exclusively about male infertility would be more suitable for your page. <br />
<br />
As for some additional improvements, it would be beneficial to include a glossary to explain some difficult terms that would help the audience gain a better understanding of the content. Also, the addition of a hand-drawn image would also be nice. A suggestion would be to exchange your existing ‘components and structure of spermatozoa’ image with a more simplified and schematic diagram of the structure of sperm. <br />
<br />
Overall, I enjoyed reading about male infertility and the page is coming together very nicely.<br />
<br />
'''Group 5''' <br />
<br />
The wikipage looks like it’s progressing very well, especially with the amount of content and references I can safely say you guys have worked hard on it and have done a substantial amount of research so well done guys. I liked the flow chart that you guys inserted, it really simplified the understanding of the IVF procedure as opposed to reading lengthy text. I also particularly liked the collapsible timeline which was presented very nicely and summarised the progress of oncofertility over time very well. <br />
<br />
As for improvements, the references definitely need to be fixed up. There were multiple appearances of the same reference and some of the links also did not work such as reference 24 and 25. On top of that the referencing for the websites were not in a consistent format and some were also done incorrectly so be sure to fix that up. I would also look out for the type of sources used such as webmd and medianews today. I’m not entirely sure if they are reliable or acceptable but I suggest you consult Mark about that. <br />
<br />
Additionally, the use of tables is a very good way of presenting information however, for the tables under the topic of fertility preservation for both men and women I initially though that each of the columns was a comparison against each other. Only later did I realise that each of the columns contained an individual list of treatments. To minimise the confusion I suggest rearranging the table and labelling row 1 as ‘Before treatment’, then row 2 as ‘During treatment’ and finally row 3 as ‘After treatment’ then collectively placing the treatments in their rightful spaces in the following column. <br />
<br />
A glossary is also missing from this page, having the definitions of the more difficult terms would assist with understanding the topic. Also on another note in the ‘Types of Chemotherapy drugs’ section, I think it would look more aesthetically pleasing if bullet points were used rather than the dashes. <br />
<br />
Overall, there is a substantial amount of content, and great use of images, videos and tables. Keep up the good work! <br />
<br />
===Lab 10 Assessment===<br />
<br />
'''Embryonic Tongue'''<br />
<br />
Permalink: [https://embryology.med.unsw.edu.au/embryology/Slides/Embryo_Stages/Stage22/11/Stage22-11.html?zoom=5&lat=-2174.37828&lon=4626.63483&layers=B Tongue]<br />
<br />
The tongue is a muscle and is important for sensing taste. All the pharyngeal arches present in the human embryo contribute to the development of the tongue however, the tongue muscle cells are derived from somites and the muscles of mastication are derived from somitomeres. Each pharyngeal contributes a different portion where arch 1 forms the oral part of the tongue, arch 2 forms the initial transient surface, arch 3 forms the pharyngeal part of the tongue and arch 4 forms the epiglottis and adjacent regions. The superior surface of the tongue comprises of taste buds, various papillae and stratified squamous epithelium. The tongue is innervated by the hypoglossal nerve (CNXII) allowing movement. <br />
<br />
[https://embryology.med.unsw.edu.au/embryology/index.php/Tongue_Development Tongue Development]<br />
===References===<br />
<br />
<references/><br />
<br />
==Test Student 2015==<br />
<br />
===References===<br />
<br />
PMID 26244658<br />
<br />
look at this<ref><pubmed>26244658</pubmed></ref><br />
<br />
Here's the list<br />
<references/><br />
<br />
{{StudentPage2015}}</div>Z5017878https://embryology.med.unsw.edu.au/embryology/index.php?title=2015_Group_Project_6&diff=2072052015 Group Project 62015-10-22T04:08:02Z<p>Z5017878: </p>
<hr />
<div>{{ANAT2341Project2015header}}<br />
<br />
<br />
=Preimplantation Genetic Diagnosis and Preimplantation Genetic Screening=<br />
==Introduction==<br />
Preimplantation genetic diagnosis (PGD) and preimplantation genetic screening (PGS) are reproductive options for couples with known family histories of genetic disease or couples undergoing IVF procedures due to infertility issues. PGD can diagnose many genetic disorders caused by known chromosomal abnormalities (number and/or structure) or single gene mutations, and, thus decrease the risk of termination of pregnancy or miscarriages and enable such couples to have an unaffected child<ref name="PMID24907939"><pubmed>24907939</pubmed></ref>. Through major improvements in PGD/S and general laboratory technology, the testing for abnormalities in fetuses has shifted from prenatal diagnosis during the first 2 trimesters <ref> Blackburn, S.L. (2003) '''Maternal, Fetal & Neonatal physiology: a Clinical perspective''' (2nd ed.). Seattle: Saudners </ref>, testing for overall fetal growth, complications of pregnancy, and birth defects<ref> Sadler T.W.(2012) '''Langman's Medical Embryology''' (12th ed.) Philadelphia: Lipincott, Wiliams & Wilkins, a Wolters Kluwer Business </ref>, to an embryonic focus especially in advancements in Artificial Reproductive Technologies (ART)<ref><pubmed>20638568</pubmed></ref>. In 1990 PGD for a recessive X-linked disease resulted in the first live birth<ref><pubmed>2330030</pubmed></ref> and has since been incorporated in clinical routine and applied for a variety of genetic diseases, such as sickle cell anemia, thalassemia, or cystic fibrosis<ref name="PMID24907939"/>.<br />
[[File:Preimplantation Genetic Diagnosis Procedure.jpeg|600px|left|thumb| Simplified steps for PGD<ref name="PMID24907939"/>]]<br />
{|class="wikitable"align="right" <br />
| <html5media height="400" width="533">https://www.youtube.com/watch?v=0e-79qKllqk</html5media><br />
|-<br />
| Preimplantation Genetic Diagnosis<ref>IVF Florida (2011, December 11) IVF Florida - South Florida Fertility Specialists - Pre-Implantation Genetic Diagnosis [Video file]. Retrieved from https://www.youtube.com/watch?v=0e-79qKllqk</ref><br />
|}<br />
<br />
==History==<br />
The advances in reproductive technology during the second half of the 20th century, led to PGD's first clinical application in 1990 <ref>Harper, J. (n.d.). The history of PGD. Lecture. UCL Centre for PG&D and CRGH.University College London</ref>.<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
|Year<br />
|<br />
|- bgcolor="FFFAFA"<br />
| '''1967''' <br />
|First PGD on rabbit blastocysts (Gardner& Edwards) <ref name="PMID6036172"><pubmed>6036172</pubmed></ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1986''' <br />
|First Cleavage Biopsy (Wilton & Trounson)<ref>Wilton, L. J., & Trounson, A. O. (1986). Viability of mouse embryos and blastomeres following biopsy of a single cell. In Proceedings of the 18th Annual Conference of the Australian Society for Reproductive Biology, Brisbane, Australia.</ref><br />
|- bgcolor="FFFAFA"<br />
|'''1987''' <br />
|First Blastocyst Biopsy (Muggleton-Harris, Monk, Rawlings, & Whittingham)<ref name="PMID3372699"><pubmed>3372699</pubmed></ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1988''' <br />
|First Polar Body Biopsy (Yury Verlinksy)<ref> Verlinsky, Y., Pergament, E., Andresen, P., Enriquez, G., & Strom, C. (1989). Genetic analysis of polar body DNA: A new approach to preimplantation genetic diagnosis. Am J Hum Genet, 45(4), A272.</ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1990''' <br />
|First Clinical PGD using PCR testing for X-linked (Handyside, Kontogianni, Hardy, & Winston)<ref name="PMID2330030"><pubmed>2330030</pubmed></ref> <br />
|} <br />
==Preimplantation Genetic Diagnosis==<br />
PGD is used to test the genetic makeup of embryos to detect single gene disorders, chromosomal abnormalities and mitochondrial disorders. It also has applications in gender selection for diseases with unequal gender distributions <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Some diseases commonly involved with PGD include cystic fibrosis, spinal muscular atrophy and beta – thalassaemia <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press.">Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press</ref> <ref name="PMID17823145"><pubmed>17823145</pubmed></ref>. It was first used in the United Kingdom in the 1980s of arenoleucodystrophy and primarily focusing on sex- linked disorders <ref name="PMID17823145"/><ref name="PMID23150080"><pubmed>23150080</pubmed></ref>. PGD is now capable of detecting single cell defects (molecular) and chromosomal disorders resulting from the inversion, translocation or deletion of chromosomes (cytogenic) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>,<ref name="PMID11325751"><pubmed>11325751</pubmed></ref>. PGD can be applied to the embryo at different stages. That is on polar bodies, blastomeres or blastocyst <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>.<br />
Depending on the type of genetic disorder, PGD utilises different methods of genetic testing. These include Fluorescence in situ hybridisation (FISH) which is used for sex – linked disorders and detects chromosomal rearrangements <ref name="PMID11325751"/><ref name="PMID17876073"><pubmed>17876073</pubmed></ref> and Embryo halotyping which allows the identification of chromosomes causing the inherited disorder through knowledge of the pattern of closely linked markers <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. Polymerase chain reaction (PCR) is also widely used to detect molecular abnormalities <ref name="PMID11325751"/>.<br />
PGD is tightly regulated and supported by large organisations namely The American Society for Reproductive Medicine, The European Society for Human Reproduction and Embryology (ESHRE), The European Society of Human Genetics and the Preimplantation Genetic Diagnosis International Society <ref name="PMID25500181><pubmed>25500181</pubmed></ref>.<br />
===Sex-linked disorders===<br />
The determination of a disease as gender specific usually correlates with the presence or absence of specific genes such as SRY on the Y chromosome. It is known that females have two X chromosomes and males have an X and a Y chromosome where abnormalities are more prevalent on the X chromosome. PGD can be used for sex selection where only male embryos are transferred to reduce the chance of inheriting X-linked disorders. However, this does not completely eradicate the problem as male embryos remain susceptible to inheriting an affected X chromosome. Sex determination is only used when the specific mutation is unknown and has yet to be discovered <ref name="PMID24866878"><pubmed>24866878</pubmed></ref>.<br />
===Single gene defects===<br />
Single gene defects can be dominant, recessive, autosomal or X-linked. They are commonly diagnosed using PCR and although the PCR available today is complex and capable of combatting a large range of disease the development of new protocols has been proven to be difficult due to the small DNA sample available <ref name="PMID26168107"><pubmed>26168107</pubmed></ref><br />
===Mitochondrial disorders===<br />
Mitochondrial disorders also known as oxidative phosphorylation disorders arise from mutations in the nuclear DNA or mitochondrial DNA <ref name="PMID26312584"><pubmed>26312584</pubmed></ref>. They pose as a problem because they are unrecognisable until the mutations in the cell reach a detrimental level <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Mitochondrial disorders cause miscarriages and stillbirths as well as death in children and young adults. The effects can either be contained in a single organ or more commonly involve multiple organ failure where organs with high energy demands such as the brain, liver muscle and heart and heavily influenced. They are usually occur spontaneously or result from inheritance from the mother. Since mitochondria are solely inherited from the mother oocyte donations have been used as a solution to combat mitochondrial disorders. Additionally, there has been an increasing use in PGD where embryos that stay under the given threshold of 18% gene-mutations are allowed to be transferred and result in normal development. New technology in the areas of nuclear gene transfer and genome editing are also being experimented with <ref name="PMID26312584"/>. <br />
===Chromosomal disorders===<br />
Chromosomal disorders can be reciprocal, Robertsonian translocations, inversions, deletions and insertions <ref name="PMID26168107"/>. . Data from ESHRE collected between 2010 and 2011 has shown that the most common chromosomal abnormality confronted in PGD are reciprocal chromosomal abnormalities <ref name"PMID26071418"><pubmed>26071418</pubmed></ref>. PGD has also been used successfully for Robertsonian translocations (RT), a type of structural translocation. Children who carry RT are phenotypically normal, however in their later years it is found that they will suffer from infertility and repeated miscarriages due to the high frequency of abnormal embryos <ref name="PMID22081077"><pubmed>22081077</pubmed></ref>. PCR and FISH are the two main techniques used for chromosomal disorders. To be able to conduct the examinations the cells are required to be at the metaphase stage <ref name="PMID26168107"/>. <br />
[[File:Reasons_for_PGD.jpg|600px|thumb|Reasons for PGD<ref name= "PMID24764761"><pubmed><24764761</pubmed></ref>]]<br />
==Preimplantation Genetic Screening==<br />
PGS involves an array of methods or ideas that aim to segregate embryos that have genetic flaws and those that are healthy <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. The occurrence of aneuploidy is high around the stages of early embryonic development and they are the most common cause if miscarriages and congenital birth defects <ref name= "PMID26085841"><pubmed>26085841</pubmed></ref>. They have little effect on the morphology of the embryo making them difficult to identify thus identification heavily relies on genetic testing <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. <br />
Genetic sampling is most commonly conducted using Microarray Comparative Genomic Hybridisation (aCGH) as well as FISH, Quantitative PCR and Single Nucleotide Polymorphism (SNP) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. These methods collectively aim to assess numeral and structural chromosomal errors <ref name= "PMID26085841"/>. Studies have also introduced Next- Generation Sequencing (NGS) <ref name= "PMID26085841"/> and Whole Genome Amplification used to screen imbalances in the complete 24-chromosomes <ref name="PMID25953353"><pubmed>25953353</pubmed></ref><br />
Statistics from ESHRE have shown that the most common indications for PGS is advanced age, followed by repeated implantation failure or recurrent miscarriage and male infertility <ref name="PMID26071418"><pubmed>26071418</pubmed></ref>.<br />
===Indications===<br />
A low percentage of structural abnormalities in chromosomes are responsible for the cause of miscarriages. Despite this, they are the most prevalent type of chromosomal abnormality accounted for in PGD <ref name="PMID20638568"/>. The presence of specific gene cycles, initiation of embryonic protein synthesis and evident physiological development are all indicative of a successful in vitro fertilisation procedure <ref name="PMID11576737"><pubmed>11576737</pubmed></ref>. To eliminate further errors from occurring during the PGD procedure it is recommended to undertake further prenatal testing such as amniocentesis in the later stages <ref name="PMID20638568"/>. <br />
====Advanced maternal age====<br />
Data provided by the ESHRE has shown that the mean age of women undergoing PGS is 39 years <ref name="PMID26071418"/>. Women of advanced age have been shown to have a lower rate of pregnancies reaching childbirth <ref name="PMID18583331"><pubmed>18583331</pubmed></ref>. The highlighted concern revolves around the increased occurrence of aneuploidy following maternal age. The optimal age range for the lowest aneuploidy incidence was found to be between 27 to 37 years of age (6%) then progressively higher in women aged up to 42 (33%) and most common in those 44 and above (53%) <ref name="PMID24355045"><pubmed>24355045</pubmed></ref>. <br />
====Recurrent pregnancy loss / IVF failure====<br />
Recurrent pregnancy loss is defined as three or more IVF failures after cumulative transfer of more than 10 good-quality embryos. These are primarily caused by two main factors, reduced endometrium receptivity or embryonic defects. Endometrium receptivity can be negatively influences by instances including uterine pathologies such as thin endometrium, altered expression of adhesive molecules and immunological factors. Additionally, embryonic defects may be due to genetic abnormalities, embryonic aneuploidy or zona hardening. Endometriosis and hydrosalpinx has been known to effect both the endometrium and embryo <ref name="PMID23260857"><pubmed>23260857</pubmed></ref>.<br />
====Human leukocyte antigen matching====<br />
First used in 2001, HLA matching is an option given to parents to save a child with haematological or immunological disease through conceiving another child who would potentially be able to donate cord blood or haematopoietic stem cells from the bone marrow for transplantation. The process namely PGD-HLA has shown to improve haematopoietic stem cell transplant (HSCT). PGD-HLA can only be performed when HSCT is not needed urgently due to the time needed to conceive and delivery the baby <ref name="PMID25500181"><pubmed>25500181</pubmed></ref>. It is most commonly applied to children suffering from relapsed leukaemia <ref name="PMID22524201"><pubmed>22524201</pubmed></ref>. In a case study PGD-HLA was proven to successfully cure 10 diseases including Fanconi anaemia, Diamond-Blackfan anaemia and beta thalassemia <ref name="PMID25066893><pubmed>25066893</pubmed></ref>.<br />
==Biopsy Methods==<br />
Biopsy, the removal of genetic materials, from oocytes or embryos in the preimplantation stage is the primary step in PGD. For the past two decades these biopsies have been performed at three stages, the polar body, blastomere, and blastocyst, and the methodologies optimized to ensure the embryo’s viability. The most common approach involves biopsies at the cleavage stage. However, polar body and blastocyst biopsies are increasingly more often tested and applied. Approached for opening the zona pellucida involve next to the traditional mechanical and chemical means, novel approaches such as noncontact lasers. Their application may simplify and secure the procedure significantly. The most challenging question about PGD procedures remains at what stage biopsies should be taken. Much controversy has developed around this topic, highlighting the varying disadvantages and advantages of temporal biopsies. <ref name="PMID22723007"><pubmed>22723007</pubmed></ref><br />
<br />
[[File:Polar_Body,_Blastomere,_and_Trophectoderm_Biopsy.jpeg|400px|thumb|Polar body (A), blastomere (B) and trophectoderm (C) biopsies<ref name="PMID25625041"><pubmed>25625041</pubmed></ref>.]]<br />
{| class="wikitable"<br />
|- align="center" bgcolor="DDCEF2"<br />
|<br />
| Time of Biopsy<br />
| Advantages <br />
| Disadvantages<br />
|- bgcolor="FFFAFA"<br />
| Polar Body<br />
| Day 1<br />
| No harm to oocyte<br />
| Only maternal DNA is tested, often needs to be coupled with other biopsies, and there are difficulties distinguishing between the first and second PB.<br />
|- bgcolor="FFFAFA"<br />
| Blastomere<br />
| Day 3<br />
| …<br />
| … <br />
|- bgcolor="FFFAFA"<br />
| Trophectoderm<br />
| Day 5 and 6 <br />
| Little harm to the embryo and large amount of genetic material is extracted. <br />
| Opening of blastocyst necessary, small time window for procedure<br />
|}<br />
===Polar Body Analysis===<br />
Day 1<br />
====Description====<br />
Polar body (PB) biopsy offers a promising alternative to biopsies performed at the blastomere stage for PGD/S indications on legal and practical grounds. Consequent embryo development does not necessitate the presence of the first and second PB and their removal may not be crucial. PB biopsy requires precise timing. Keeping track of the meiotic cell cycle is necessary to perform a successful biopsy and, therefore, PB biopsy usually is applied in combination with intracytoplasmic sperm injection (ICSI). During the maturation from the germinal vesicle stage to the metaphase-II stage the first PB is formed. A cytoplasmic bridge containing spindle remnants, that are still in contact with the cellular genetic material, links this PB to the oolemma for about 90 minutes after extrusion. It is possible to visualize these remnants by polarization microscopy and it is crucial to not perform the biopsy until the first PB is no longer firmly attached to the oolemma as this indicates an immature embryo.The oocyte tolerates mechanical zona dissection best during hours four until six after ICSI as the oolemma has stabilized by that time because of the cortical granule reaction. Over time the first PB degenerates stressing a temporal biopsy and its optimal extraction time window is four to 12 hours after ICSI. The second PB forms around two to four hours after ICSI. Its optimal time window for biopsy is set to be eight to 16 hours after ICSI due to the second PB being attached to the oolemma with spindle remnants until six hours after ICSI. Biopsy at this point may cause enucleation of the oocyte. Studies have shown that the amplification efficiency of second PB’s DNA is worse if the PB is extracted prior to eight hours after ICSI. Thus, it is possible to perform sequential and simultaneous biopsies for the first and second PB. If performed, sequentially the first PB may be removed four to 12 hours and the second PB eight to 16 hours after ICSI. The optimal time window for a biopsy for both the first and second PB simultaneously is eight to 12 hours after ICSI. It is highly preferred to analyze both PBs due to potential aneuploidies in either PB and crossing overs during meiosis<ref name="PMID22723007"/>. <br />
====Procedure====<br />
Chemical opening achieved with for example acidic tyrode’s solution of the zona pellucida is not tolerated by the oocyte and may have detrimental effects on the embryo’s development. Therefore, the access to the perivitelline space of the oocyte is provided by mechanical zona dissection or by laser. Both techniques work well if performed by experienced embryologist. However, laser-assisted biopsy is less time consuming when compared to manual dissection. It is critical to consider the size of the introduced opening as it will remain permanent. If it is too large the blastomere may be lost during embryo development and if it is too small it may interfere with hatching of the embryo during blastocyst stage<ref name="PMID22723007"/>.<br />
[[File:Polar_Body_Biopsy.jpeg|left|thumb|The presence of a faint but clearly identifiable strand connecting PB2 to the oolemma. The biopsy was performed ∼9 h after ICSI<ref name="PMID21908464"><pubmed>21908464</pubmed></ref>.]]<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JTaQzszVr8o</html5media><br />
|-<br />
| Laser-assisted polar body biopsy<ref>RIUK, R. (2013, June 25) Polar Body Biopsy [Video file]. Retrieved from https://www.youtube.com/watch?v=JTaQzszVr8o</ref><br />
|}<br />
====Advantages & Disadvantages====<br />
PB biopsies can only investigate the maternal contributions to the embryo as they are of maternal origin. Thus, this procedure is appropriate for PGD solely for monogenetic diseases from the maternal side. Recessive diseases may be evaluated with PB biopsies on the basis that the embryo’s outcome will be determined by the paternal contribution. It may still be applied for PGS as it is a fairly safe biopsy option and most aneuploidies either arise during meiosis or origin from the maternal genome. However, diagnosis error has been reported due to the lack of considering paternal contributions.Because PB biopsies are performed very early it is not yet known whether the oocyte will develop into a viable embryo. Thus, PBs are commonly frozen or fixed after biopsy and depending on the state of the embryo only chosen PBs will be tested. This is primarily an economic issue as many genetic testing procedures are very cost-intensive<ref name="PMID22723007"/>[[File:Implantation_predictive_value_of_euploid_screening_results.jpeg|thumb|The sustained implantation predictive value (with 95 % confidence interval) of a euploid screening result obtained from the first polar body (PB1), PB1 and the second polar body (PB2), or a direct embryo biopsy for each stage of embryo transfer (cleavage-stage and blastocyst stage)<ref name="PMID25106935"><pubmed>25106935</pubmed></ref>.]] Generally the sustained implantation predictive value of screening of PBs is significantly lower than of for example biopsies of the blastocyst stage<ref name="PMID25106935"/>. Moreover, it is often difficult to distinguish between the first and the second PB. As the first one degenerates quicker, this may influence diagnostic procedures<ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
===Blastomere biopsy===<br />
Day 3 <br />
====Description====<br />
Blastomere biopsy has been the prevalent method for PGD and PGS in the last two decades. At least one, but up to two, blastomeres are biopsied on day three of the cleavage stage embryo. The right number of blastomeres removed is a controversial topic as two cells allow for more genetic material and more accurate results. However, removing two cells might be too invasive and damaging to the embryo. As PGS tries to improve implantation rates, whereas PGD sets out to avoid known genetic disorders, for the former only one cell is removed, while for the latter often two need to be removed, to ensure results as correct as possible<ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
====Procedure====<br />
Initially a hole was drilled into the zona pellucida using acid tyrodes with the consequent aspiration of blastomeres with a pipette. Nowadays the zona pellucida is largely opened using a laser and calcium and magnesium free media have been introduced to decrease junctions between blastomeres, which facilitates the biopsy<ref name="PMID21748341"/>.<br />
[[File:Aspiration_of_a_Blastomere.jpeg|thumb|Aspiration of a Blastomere into the biopsy pipette<ref name=" PMID24783200"><pubmed>24783200</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=TbridWVwipI</html5media><br />
|-<br />
| Laser-assisted blastomere biopsy<ref>Sukprasert, M. (2014, March 5) Day 3 Blastomere Biopsy 1 [Video file]. Retrieved from https://www.youtube.com/watch?v=TbridWVwipI</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
===Trophectoderm biopsy===<br />
Day 5 and 6<br />
====Description====<br />
The improvement of embryo culture media allowed the in vitro development of human embryos until the blastocyst stage and opened up the possibility to take blastocyst biopsies. During day three to day five the haploid maternal and paternal genomes work together for the first time to form the genome of the embryo. The maternal epigenetic control lessens significantly while preparing for implantation with precisely arranged events happening. The first event includes a rapid increase in the number of embryonic cells which are active in mitotic divisions and apoptosis of aberrant cells. This is followed by the formation of blastocoel (cavitation) which results from the flattening of cell located on the outside of the blastomere. Now the blastocyst will expand until the embryo hatches by rupturing the zona pellucida. The cells of the blastocyst will differentiate to form two distinct cell lineages, the outer trophectoderm and the inner cell mass<ref name="PMID22723007"/>.<br />
====Procedure====<br />
Trophectoderm biopsy is usually performed in Hepes buffered biopsy medium and opening approaches include needle cutting which has been replaced by lasers in past years. Different research groups report different timings of the opening to be the most successful. Some open the blastocyst on day three or four by creating a 25 µm which causes the trophectoderm to herniate through this hole and is, thus, accessible for biopsy. Others create this hole about four hours before biopsy which allows sufficient herniation of trophectoderm cells. It is also possible to open the blastocyst immediately before biopsy. This avoids an extra step and the inner cell mass usually is easy to locate. Blastocyst biopsies involve the removal of trophectoderm cells and the ideal time for the procedure is day five. Successful biopsies on day six have been performed, while little is known about the results of biopsies on day seven. However, since the window of implantation in humans is from day eight to ten after ovulation, day seven biopsies appear to be possible<ref name="PMID22723007"/>.<br />
-collapse of trophoblasts<br />
-possible: biopsy of hatched blastocyst, holding pipette careful mild suction force to hold embryo near ICM <br />
-Cryopreservation<br />
<br />
<br />
[[File:Microscopic images of human blastocysts for biopsy.jpeg|thumb|(A) Some trophectoderm cells in a blastocyst started to hatch and (B) the trophectoderm cells were biopsied with assisted laser cutting. Images in C–D show the blastocysts after vitrification and warming. Blastocysts had been cultured for 2–4 hrs after warming, showing good (ICM and trophectoderm cells) hatched (C) and hatching (D) blastocysts. The hatching blastocyst in (E) has good ICM but fair trophectoderm while the blastocyst in (F) has both fair ICM and trophectoderm. Arrows indicate ICMs and arrow heads indicate trophectoderm cells. Bar = 40 µm<ref name="PMID2190846"><pubmed>2190846</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JI_TQ8d8tNM</html5media><br />
|-<br />
| Laser-assisted blastocyst biopsy (at 00:50 min)<ref>Coco, R. (2014, April 30) Trophectoderm biopsy in a Hatching blastocyst protruding ICM [Video file]. Retrieved from https://www.youtube.com/watch?v=JI_TQ8d8tNM</ref><br />
|}<br />
<br />
====Advantages & Disadvantages====<br />
Blastocyst biopsies are believed to be less damaging to the embryo and appear to be unrelated to implantation rates. In addition, this biopsy method allows for a larger extraction of cells for genetic testing. However, since they are performed late in in vitro development, the time window for genetic testing is relatively small. Fast and accurate genetic testing methods are needed to ensure a successful and safe result from this biopsy. Thus, blastocyst biopsies may gain more popularity in the future whn such methods have been developed or improved<ref name="PMID22723007"/>. <br />
==Genetic Techniques==<br />
===Polymerase Chain Reaction===<br />
PCR amplifies DNA specific to genetic sequence of interest . PCR was developed by Kay Mullis in the 1980s, for which he was awarded the Nobel prize for chemistry in 1993. <ref> Pubmed Docs (2015) Polymerase Chain Reaction (PCR) Pubmen. Retrieved from [http://www.ncbi.nlm.nih.gov/probe/docs/techpcr/]</ref> This technique enables clinicians to monitor and diagnose diseases using minute samples such as embryonic cells, blood & tissue. <ref>Roche (2015) PCR: How We Copy DNA. Roche Molecular Systems Inc. retrieved From [http://molecular.roche.com/pcr/Pages/Process.aspx]</ref> PCR has many important applications like DNA fingerprinting, genetic mapping, detection of viruses and bacteria as well as being used to detect genetic disorders, as a part of PGD, in conjunction with IVF. It is used to detect molecular abnormalities such as single gene disorders like Tay Sach, Cycstic fibrosis, Duchenne Muscular Dystrophy, Thalassemia, Huntington disease, Spinal muscular atrophy and many more. Molecular and Genetic analysis require a significant amount of DNA, which we would not have without PCR. It revolutionized the study of DNA, replacing all previous recombinant DNA technology. <ref> Mullins, K., Francois, F.& Gibbs R.A. (1994 ) The Polymerase Chain Reaction. p3. Springer- Science +Business Media. Birkhauser, Boston<br />
Available at [https://books.google.com.au/books?hl=en&lr=&id=gjrTBwAAQBAJ&oi=fnd&pg=PR5&dq=kary+mullis+PCR&ots=mpzAyRh5ZY&sig=PQ4goNoKJ90tb3-MkPk62zrTGbw#v=onepage&q=kary%20mullis%20PCR&f=false] </ref> <br />
<br />
[[File:PCR.jpg|thumb|right|Polymerase chain reaction (PCR) amplifies DNA specific to genetic sequence of interest, enabling the monitoring and diagnose molecular abnormalities such as single gene disorders using minute samples such as embryonic cells, blood & tissue <ref>NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref>]]<br />
{|<br />
|- align="left" bgcolor="DDCEF2"<br />
|'''Procedure'''<br />
|}<br />
Samples are obtained from the the blastocyst, a polar body biopsy or the blastomeres stages of the embryo. <br />
*Stage 1 Denaturing: separating the target strands of DNA <br />
The obtained sample is heated to roughly 90 degrees celcius, this heat breaks the relatively weak bonds between nucleotides that form DNA. The double stranded DNA is split into two single strands of DNA that are used as templates.<br />
*Stage 2 Annealing: Binding the Primers to the target DNA sequence <br />
PCR will only copy the target sequence of DNA specified by specific PCR primer. These synthesized primers oligonucleotides are small artificial pieces of DNA. TAQ polymerase enzyme synthesize two new strands of DNA duplicate to the single sample DNA stand template indicated by these primers. During this stage the reaction is cooled to a temperature between 40-60 degrees Celsius. <br />
*Stage 3- Extension- making copies <br />
Each of these two copies are then used again as templates generating two further replications This cycle can occur as many 30 -40 times within a couple hours leading to billions of extra copies of the original DNA segment. The optimal temperature for the further replication is roughly 72 degrees Celsius. <br />
This process mediated by a thermocycler machine that is programmed to alter the temperature of the reaction every couple of minutes, perpetuating the cycle of DNA denaturing and synthesis. <br />
This process, generates exponentially exact copies of the original template DNA sequence. <br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
!PCR cycles<br />
|-<br />
| '''PCR Cycle'''<br />
| '''Target Copies'''<br />
|-<br />
| 1<br />
| 2<br />
|-<br />
| 2<br />
| 4<br />
|-<br />
| 3<br />
| 8<br />
|-<br />
| 4<br />
| 16<br />
|-"<br />
| 5 <br />
| 32<br />
|-<br />
| 6 <br />
| 64<br />
|-<br />
| 7 <br />
| 128<br />
|-<br />
| 8<br />
| 256<br />
|- <br />
| 9<br />
| 512 <br />
|-<br />
| 10<br />
| 1024<br />
|-<br />
| 15<br />
| 32,768<br />
|-<br />
| 20 <br />
| 1,048,578<br />
|-<br />
| 25<br />
| 33,554,432<br />
|-<br />
| 30 <br />
| 1,073,741,842<br />
|-<br />
|}<br />
<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="7" |'''Advantages'''<br />
|-bgcolor="FFFAFA"<br />
| Fast and inexpensive way of copying a target sequence of DNA<br />
|-bgcolor="FFFAFA"<br />
| Particularly useful for the diagnosis of single cell defects<br />
|-bgcolor="FFFAFA"<br />
| Rapid generation of results (within hours)<br />
|-bgcolor="FFFAFA"<br />
| Highly sensitive, a single molecule of DNA is sufficient for reaction<br />
|-bgcolor="FFFAFA"<br />
| Generates DNA copies exponentially<br />
|-bgcolor="FFFAFA"<br />
| This enables DNA amplification required for molecular and genetic diagnostic analysis<ref> Dreesen, J., Drusedaul, M., Smeets, H., Die-Smulders, C., Coonen, E., Dumoulin, J., Gielen, M., Evers, J., Herbergers, J. & Geradets, J. (2008) Validation of preimplantation genetic diagnosis by PCR analysis: genotype comparison of the blastomere and corresponding embryo, implications for clinical practice. Mol. Hum. Reprod. 14 (10):573-579.doi: 10.1093/molehr/gan052. Retrieved from [http://molehr.oxfordjournals.org/content/14/10/573.short] </ref> <ref><pubmed>20966460</pubmed></ref><br />
|-bgcolor="DDCEF2"<br />
| rowspan="5"|'''Disadvantages'''<br />
|-bgcolor="FFFAFA"<br />
| Only during the exponential DNA replication phase, the starting quantity sequence contained in the original sample (template DNA strand) can be determined<br />
|-bgcolor="FFFAFA"<br />
| PCR reaction is limited to by presence of inhibitors in the sample<br />
|-bgcolor="FFFAFA"<br />
| Self annealing due to the accumulation of the product -stopping exponential amplification for the target sequence and reach a plateau<br />
quantification of the end point of reaction of PCR products unreliable - therefore real time quantitative RT-PCR is necessary<br />
<ref> NIS (2015) Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref><br />
|-bgcolor="FFFAFA"<br />
| Not a diagnostic method on its own, requires further analysis<br />
|}<br />
===Fluorescent In Situ Hybridisation===<br />
FISH is the one of the most effective and rapid <ref name="PMID26338801"><pubmed>26338801</pubmed></ref> method of conducting PGD. This techniques used to locate a specific DNA sequences within a chromosome. FISH facilitates the clinical diagnosis of chromosomal abnormalities indicated by sequential duplications, deletions and rearrangements of chromosome, that are usually missed with microscopic analysis. This technique is especially relevant for female embryos with X-linked diseases,<ref name="PMID20809319"><pubmed>20809319</pubmed></ref> that have no other mutation specific tests [http://www.ncbi.nlm.nih.gov/pubmed/20809319] As part of PGD, samples are collected from various stages of the embyro,and they are able to conducted tests on the blastocyst, a polar body biopsy and the blastomeres <ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. FISH is 99% effective when used in conjunction with competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities<ref name="PMID26338801"/>.<br />
{|<br />
|- align="left" bgcolor="DDCEF2"<br />
|'''Procedure'''<br />
|}<br />
Samples are collected from either the blastocyst, a polar body biopsy or the blastomeres stages of the embryo <ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
DNA strands are heated and denatured causing their the individual DNA strands to break apart<br />
Probes are single complimentary stands of DNA a that have been tagged with small chemical agents that glow brightly in the presence of a specific region on a chromosome. These specific probes then hybridize and join to their complementary DNA strand. <br />
The fluorescent tags enable the researchers to correctly identify the presence or lack thereof and location of the specific chromosomes that they are testing for. <ref name="PMID17876073"><pubmed>17876073</pubmed></ref><br />
Researcher analyse the results by identifying the number and the relative location of the fluorescent dots generated by the FISH images.<ref name="PMID17970921"><pubmed>17970921</pubmed></ref><br />
The probe will not fully hybridise if there has been a duplication or a deletion of the DNA - indicating chromosomal and sex chromosomal anomalies like trisomies and aneuploidies. <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref><br />
Different probes are used for different purposes: <ref>Unique, Rare Chromosome Disorder Support Group (2013) Fluorescence in situ hybridisation (FISH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/Other/FISH%20FTNW.pdf]</ref><br />
*'''Locus specific tags''' detect very small imbalances, and locate isolated small portions <br />
of genes within a chromosome<br />
*'''Alphoid/Centomeric Repeat probes''' are developed from the repetitive sequence located in the middle region of each chromosome, useful in determining the number of chromosomes , detecting rearrangement and when used in conjunction with locus probes to determine the absence of genetic material on a chromosome. <br />
*'''Paint Probes''' are collections of smaller probes with their own stains that bind to a different section on the chromosome - allowing the full chromosome too be labeled a unique colour, this "full colour map" can be used to know the spectral karyotype- full chromosomal mapping is useful in examining chromosomal abnormalities. <br />
[[File:Fluorescent In Situ Hybridisation (FISH).jpg|thumb|right|'''FISH''' We are able to tag Specific DNA sequences using Probes which have been tagged with fluorescent Labels.This technique enables the clinical diagnosis of chromosomal abnormalities, indicated by sequential duplication, deletions and rearrangements of chromosome <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref>]]<br />
<br />
{|class="wikitable" align="center"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="7" |'''Advantages''' <br />
|-bgcolor="FFFAFA" <br />
| FISH is 99% effective when used in conjunction with Competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities.<ref><pubmed>26338801</pubmed></ref><br />
|-bgcolor="FFFAFA" <br />
| Rapid generation of results<br />
|-bgcolor="FFFAFA"<br />
| Identifies very small translocations and aneuploidies that occur within chromosomes, that would usually be missed under microscopic analysis<br />
|-bgcolor="FFFAFA" <br />
| Indicates whether the accessed chromosomes are normal <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|-bgcolor="FFFAFA" <br />
| Tests for the most common chromosomal abnormalities - down syndrome chromosomes 13,16,18,21 and 22 <ref><pubmed>21749752</pubmed></ref><br />
|-bgcolor="FFFAFA" <br />
| It may be used to compare the chromosomal gene arrangements in related species<br />
|-bgcolor="FFFAFA" <br />
| Can be used to identify and remove inheritable X-linked disease or sex chromosome anomalies such as Duchenne's Muscular Dystrophy, hemophilia, ectodermal dysplasia <ref><pubmed>17876073</pubmed></ref><br />
|-bgcolor="DDCEF2"<br />
| rowspan="4"|'''Disadvantages'''<br />
|-bgcolor="FFFAFA" <br />
| FISH destroys all cells tested <ref> O'Connor, C. (2008) Fluorescence in situ hybridization (FISH). Nature Education 1(1):171. retrieved from [http://www.nature.com/scitable/topicpage/fluorescence-in-situ-hybridization-fish-327] </ref><br />
|-bgcolor="FFFAFA" <br />
| It does not fully access all chromosomes (only ~ 12)<br />
|-bgcolor="FFFAFA" <br />
| Analysis of results is dependent upon the dot quality impacted by hybridisation efficiency or the camera sensitivity <ref><pubmed>17970921</pubmed></ref><br />
|-bgcolor="FFFAFA" <br />
| Some studies indicate that using FISH on a day-3 embryo biopsy decreases the rate of live births <ref><pubmed>26168107</pubmed></ref><br />
|}<br />
<br />
===Array Comparative Genomic Hybridisation (aCGH)===<br />
aCGH also known as Microarray analysis efficiently scans the entire genome for chromosomal imbalances. CGH was initially developed to detect the number of changes in a solid tumor mass. It uses 2 genomes comparing the sample to the control, with each labeled in a different fluorescent dye<ref name="PMID1876176"><pubmed>1876176</pubmed></ref>. Earlier CGH techniques were limited by the resolution of the imaging <ref> Lichter, P., et al. Comparative genomic hybridization: Uses and limitations. Seminars in Hematology 37, 348–357 (2000)</ref> , these initial limitations were overcome by using Microarrays in conjunction with CGh to improve the resolution of the imaging, Array Comparative Genomic Hybridisation (aCGH). This method compares sample and control microarrayed slides containing small segments of DNA (probes). <ref> Lucito, R., et al. Representational oligonucleotide microarray analysis: A high-resolution method to detect genome copy number variation. Genome Research 13, 2291–2305 (2003) </ref> the Probes used will vary according from the small (25-85 base pairs) oligonucleotides manufactured to highlight different target sequences, to the very large genomic clones (80,000- 200,00 base pairs), and as these are significantly smaller than the traditional metaphase chromosomes used for CGH, generating a higher resolution of image. <ref name="PMID22467166"><pubmed>22467166</pubmed></ref>.aCGH is used as a diagnostic tool for prenatal detection f chromosomal abnormalities <ref name="PMID19012303"><pubmed>19012303</pubmed></ref>.<br />
{|<br />
|- align="left" bgcolor="DDCEF2"<br />
|'''Procedure'''<br />
|}<br />
<ref> Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432] </ref><br />
The sample is obtained (skin, blood or fetal cells) and DNA is obtained. <br />
As a part of PGD fetal cell samples are collected from; the fertilized egg polar bodies, the blastomere (day 3 embryo) or the blastocyst/tropoectoderm stage (day 5 embryo).<br />
Sample DNA is labeled with one fluorescent dye, and the control DNA is labeled with a different colored fluorescent dye. the control DNA is used as the base point of reference. <br />
heated and denatured single DNA strands then hybridize to their complementary single strand probes, which are then combined and applied to a microarray and the results are run through a computer program and a digital imaging system is used to quantify the results( fluorescent intensities of the labeled probes). <br />
<br />
[[File:aCGH.jpg|thumb|right|'''aCGH''' checks the entire genome for chromosomal imbalances, by comparing control and a sample slides contatining small segements of DNA sample microarrayed slides small segments of DNA. Illustrated by student z5020317 and adapted from <ref> NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation. retrieved from [http://www.phgfoundation.org/file/5237/]</ref> <ref>Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432]</ref>]]<br />
<br />
The fluorescent ratio and the hybridization signal at different locations on the genome of the control DNA are used to identify any variances present in the sample DNA. aCGH facilitates the clinical diagnosis of submicroscopic chromosomal duplication, deletion and rearrangements indicative of chromosomal disorders such as trisomies 1-22and specific sex linked disorders. <br />
Duplications in the DNA are displayed by the computer program as spikes/ peaks over an established threshold and deletions in DNA are displayed by the computer program as spikes/ toughs beneath this threshold <br />
<br />
{|class="wikitable" align="center"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="12" |'''Advantages''' <br />
|-bgcolor="FFFAFA"<br />
| Multiple applications: prenatal genetic diagnosis, cancer diagnosis, <ref name="PMID20193845"><pubmed>20193845</pubmed></ref> genetic screening for developmental delay (learning disabilities) <ref name="PMID17309648"><pubmed>17309648</pubmed></ref>. or congenital anomalies that are suspected to be genetic in origin <ref>NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation . retrieved from [http://www.phgfoundation.org/file/5237/]</ref><br />
|-bgcolor="FFFAFA"<br />
| trace represents all chromosomes present in the human genome chromosomes 1-22 and the X & Y chromosomes, and therefore is the most accurate method for testing whole embryo aneuploidy<br />
|-bgcolor="FFFAFA"<br />
| aCGH has been extensively tested, and Validated, and is now used world wide.<br />
|-bgcolor="FFFAFA"<br />
| Detects submicroscopic alterations<br />
|-bgcolor="FFFAFA"<br />
| Detects deletions and additions and rearrangements as well as amplification, of the WHOLE genome, simultaneously.<br />
|-bgcolor="FFFAFA"<br />
| Used as a diagnostic tool for prenatal detection of chromosomal abnormalities <ref name="PMID22034057"><pubmed>22034057</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Provides high resolution genomewide screening of segmental genomic copy number variations<br />
|-bgcolor="FFFAFA"<br />
| Very accurate when used in conjunction with FISH<br />
|-bgcolor="FFFAFA"<br />
| Alone is more reliable and in detecting chromosomal abnormalities, with a higher implantation success rate, than FISH <ref name="PMID20494259"><pubmed>20494259</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Allows an in depth research focus upon specific types of rearrangements within selected chromosomal regions, a recent particular area of interest is subtelomeric and pericentromeric rearrangements<br />
|-bgcolor="FFFAFA"<br />
| Reduces the risk of failed implantation and miscarriage, improving the chance of a healthy baby <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|-bgcolor="DDCEF2"<br />
| rowspan="9" |'''Disadvantages'''<br />
|-bgcolor="FFFAFA"<br />
| Translocations and inversions of DNA are not detected<br />
|-bgcolor="FFFAFA"<br />
| Limited ability diagnosing specific polyploidies such as triploidy <ref> Unique, Rare Chromosome Disorder Support Group (2013) Microarray-based Comparative Genomic Hybridiation (array CGH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/other/array%20cgh%20ftnw.pdf] </ref><br />
|-bgcolor="FFFAFA"<br />
| Will not detect mosaicism detection <20% (cultures where >1 of 5 cells are trisomy 12)<br />
|-bgcolor="FFFAFA"<br />
| Will not detect balanced chromosomal rearrangement<br />
|-bgcolor="FFFAFA"<br />
| Will not detect duplications or deletions <80kb<br />
|-bgcolor="FFFAFA"<br />
| Will not detect point mutations within genes <ref>Washington department of education (CGH- FAQ for physicians. Signature Genomic LAboratories, LLC. Retrieved from [https://depts.washington.edu/dbpeds/Lab%20Tests/SignatureCGH-physician_FAQ.pdf]</ref><br />
|-bgcolor="FFFAFA"<br />
| will not detect chromosomal position of genomic gains<br />
|-bgcolor="FFFAFA"<br />
| Will not detect loos of heterozygosity (LOH) or Absence of heterozygosity (AOH) <ref>WiCell Research Institute Inc. (2012) Comparative Genomic Hybridization Microarray. <br />
retrieved from [http://www.wicell.org/home/cytogenetic-services/cgh-microarray/array-comparative-genomic-hybridization-acgh.cmsx]</ref><br />
|}<br />
<br />
===Next Generation Sequencing===<br />
The development and advances within ART in the past 20 years, as well as the increasing popularity of IV, has lead to an influx of new technologies developed to screen embryos for chromosomal anomalies, which are covered by the umbrella term of Next generation Sequencing (NGS). NGS is a general term used to describe all of the new and emerging screening techniques currently being introduced and used as part of PGD for IVF . NGS screens for single gene disorders as well as conducting extensive and very comprehensive chromosome diagnosis by sequencing, counting, and accurately assembling millions of DNA reads, simultaneously. <ref name="PMID23499002"><pubmed>23499002</pubmed></ref> There is a movement for NGS to replace the other limited testing techniques and be used as the standard. <br />
{|<br />
|- align="left" bgcolor="DDCEF2"<br />
|'''Procedure'''<br />
|}<br />
Samples are collected from either blastomere or the blastocyst/tropoectoderm and processed for analysis by a computer system. <br />
The methodology of each process is unique to the technique being used. <br />
<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="14" |'''Advantages''' <br />
|-bgcolor="FFFAFA" <br />
| Cheaper<br />
|-bgcolor="FFFAFA"<br />
| Opens new diagnostic possibilities<br />
|-bgcolor="FFFAFA"<br />
| Accurately tests all 24 chromosomes<br />
|-bgcolor="FFFAFA"<br />
| Tests for the presence of monogenic diseases of known genetic background<br />
|-bgcolor="FFFAFA"<br />
| Reduces the number of biopsies required for diagnosis<br />
|-bgcolor="FFFAFA"<br />
| Higher detection rate of small translocations<br />
|-bgcolor="FFFAFA"<br />
| Highly accurate is testing for compound point mutations, chromosomal duplication, deletions and insertions <ref name="PMID23312231"><pubmed>23312231</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| It accurately detects chromosomal aneuploidy and unbalanced rearrangement <ref name="PMID25685330"><pubmed>25685330</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Higher detection rate of small translocations<br />
|-bgcolor="FFFAFA"<br />
| NGS single gene disorder screenings can conducted in conjunction with PCR comprehensive chromosomal screening<br />
|-bgcolor="FFFAFA"<br />
| Reduces human error <br />
|-bgcolor="FFFAFA"<br />
| Better detects the presence of mosaicism<br />
|-bgcolor="FFFAFA"<br />
| Work well in conjunction with CGH and aCGH as part of PGD, improving the chances of IVF. <ref> Morris, R. S. (2015 ) Next generation sequencing for PCG|PGS|CCS. IVF1 retrieved from [http://www.ivf1.com/next-generation-sequencing for-pgd] </ref><br />
|-bgcolor="DDCEF2"<br />
| '''Disadvantages''' <br />
|-bgcolor="FFFAFA"<br />
| There are limited information available to clinical applications of NGS <ref><pubmed>26100406</pubmed></ref><br />
|}<br />
<br />
==Diagnosis==<br />
There are a large amount of diseases that PGD can apply to, below are descriptions of the diseases that PGD are more commonly used for. Upon completion of the genetic testing for the genes of concern the cells the embryos are discarded and priority is given to those that are healthy. <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/><br />
===Cystic Fibrosis===<br />
Cystic fibrosis is a single gene disorder. It is autosomal recessive and involves mutations in the cystic fibrosis transmembrane conductance regulator (CTFR) gene. The CTFR gene is normally responsible for the decrease in chloride and the transport of bicarbonate in epithelial cells thus playing a major physiological role. In PGD procedures, identification of the gene is assisted by microsatellite markers that have similar composition to the CTFR gene itself. Biopsy of two cells at the blastocyst stage is recommended if markers are not available. There are many variations of cystic fibrosis the most common being P.Phe508del <ref name="PMID26014425"><pubmed>26014425</pubmed></ref>.<br />
===Duchenne Muscular Dystrophy ===<br />
Duchenne Muscular Dystrophy is an X-linked recessive disease. It involves the Xp21 gene where majority of the mutations are chromosomal deletions with a smaller percentage resulting from duplications <ref name="PMID18359022"><pubmed>18359022</pubmed></ref>.<br />
<br />
===Autosomal Recessive Meckel-Gruber Syndrome===<br />
Autosomal recessive genetic defect caused by the TMEM67 gene. It results in cystic dysplasia of the kidneys with fibrotic change in the liber and occipital encephalocele. Other malformations could also be present in the central nervous system. In PGD whole genome amplification of single blastomeres are taken to identify the gene, this is also coupled with PCR techniques. Maternal plasma can also be extracted for PGS. <ref><pubmed>24039893</pubmed></ref> <br />
===β – Thalassemia=== <br />
β – Thalassemia is known as the most common type of autosomal recessive inherited disorder among haemoglobinopathies. It involves the adult β-globin gene and is associated with the absent or decreased expression of the gene. This is commonly caused by a single nucleotide change in the gene. PGD has been used successfully worldwide to identify the β-globin gene where its application is usually performed on a single blastomere or polar body <ref name="PMID19064120">19064120</pubmed></ref>.<br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
! Applicable diseases for PGD <ref>Genoma Group (2014). Retrieved September 18th, 2015, from http://www.preimplantationgeneticdiagnosis.it/genetic-diseases-diagnosed-by-pgd.htm </ref>, <ref>Genesis Genetics (2015). Retrieved September 18th, 2015, from http://genesisgenetics.org/pgd/what-we-test-for/</ref>, <ref>Human Fertilisation & Embryology Authority (2015). Retrieved Septembr 18th, 2015, from http://guide.hfea.gov.uk/pgd/</ref><br />
|-<br />
| '''Disease'''<br />
| '''Involved Genes'''<br />
|-<br />
| 5 Alpha Reductase Deficiency (5ARD)<br />
| SRD5A2 <br />
|-<br />
| Achondroplasia<br />
|FGFR3 <br />
|-<br />
| Acute Intermittent Porphyria <br />
| ALAD, ALAS2, CPOX, FECH, HMBS, PPOX, UROD, or UROS<br />
|-<br />
| Adrenoleukodystrophy (Adrenomyeloneuropathy)<br />
| ABCD1 <br />
|-<br />
| Agammaglobulinaemia (x-linked) <br />
|BTK <br />
|-<br />
| Agammaglobulinemia Bruton Tyrosine Kinase (BTK) <br />
|BTK <br />
|-<br />
| Aicardi Goutieres Syndrome 1 (AGS1) <br />
|TREX1, RNASEH2A, RNASEH2B, RNASEH2C, SAMHD1<br />
|-<br />
| Alagille Syndrome<br />
|JAG1 or NOTCH2<br />
|- <br />
| Alpers-Huttenlocher Syndrome <br />
|POLG <br />
|-<br />
| Alpha-1-antitrypsin deficiency <br />
|SERPINA1 <br />
|-<br />
| Alpha-Mannosidosis<br />
| MAN2B1 <br />
|-<br />
| Alpha Thalassemia <br />
|HBA1 or HBA2 <br />
|-<br />
| Alports Syndrome<br />
|COL4A3, COL4A4, COL4A5<br />
|-<br />
| Alzheimer's Disease - early onset (Type 3 and 4) <br />
|APP, PSEN1, or PSEN2<br />
|-<br />
| Amyotrophic Lateral Sclerosis 1 (ALS1) <br />
|C9orf72, SOD1, TARDBP, FUS, ANG, ALS2, SETX, VAPB <br />
|-<br />
| Argininosuccinic Aciduria <br />
| ASL<br />
|-<br />
| Arrhythmogenic Right Ventricular Cardiomyopathy/ Dysplasia (ARVC/D)<br />
| DSG2; DSP; PKP2<br />
|-<br />
| Ataxia Telangiectasia<br />
| ATM<br />
|-<br />
| Autosomal Recessive Meckel-Gruber Syndrome<br />
| TMEM67<br />
|-<br />
| Bardet-Biedl Syndrome (BBS)<br />
| BBS1; BBS10<br />
|-<br />
| Barth Syndrome<br />
| TAZ<br />
|-<br />
| Beta Thalassaemia<br />
| HBB<br />
|-<br />
| Birt-Hogg-Dubé Syndrome<br />
| FLCN<br />
|-<br />
| Breast Ovarian Cancer Familial Susceptibility (BRCA2)<br />
| BRCA1; BRCA2<br />
|-<br />
| Canavan Disease <br />
| ASPA<br />
|-<br />
| Carnitine-Acylcarnitine Translocase Deficiency <br />
| SLC25A20<br />
|-<br />
| Cerebral Arteriopathy with Subcortical Infarcts & Leukoencephalopathy (CADASIL)<br />
| NOTCH3<br />
|-<br />
| Cerebral Cavernous Malformation<br />
| CCM1<br />
|-<br />
| Charcot-Marie-Tooth Disease<br />
| GJB1; MPZ; NEFL; PMP22<br />
|-<br />
| CHARGE Syndrome<br />
| CHD7<br />
|-<br />
| Cherubism<br />
| SH3BP2<br />
|-<br />
| Choroideremia<br />
| CHM<br />
|-<br />
| Chronic Granulomatous Disease<br />
| CYBB; NCF1<br />
|-<br />
| Ciliary Dyskinesia<br />
| DNAH5<br />
|-<br />
| Citrullinemia<br />
| ASS1<br />
|-<br />
| Cleidocranial Dysplasia<br />
| RUNX2<br />
|-<br />
| Cockayne Syndrome<br />
| ERCC6<br />
|-<br />
| Congenital Adrenal Hyperplasia<br />
| CYP21A2<br />
|-<br />
| Congenital Cataracts<br />
| GJA8; VSX2<br />
|-<br />
| Congenital Diarrhea, Syndromic<br />
| SPINT2<br />
|-<br />
| Congenital Disorders of Glycosylation (CDG)<br />
| ALG1; ALG6; CDG1C; DOLK; PMM2<br />
|-<br />
| Cornelia de Lange Syndrome <br />
| NIPBL<br />
|-<br />
| Craniosynostosis<br />
| TWIST1<br />
|-<br />
| Crouzon Syndrome<br />
| FGFR2<br />
|-<br />
| Cysteinyl Leukotriene Receptor 1 Deficiency <br />
| CYSLTR1<br />
|-<br />
| Cystic Fibrosis<br />
| CFTR<br />
|-<br />
| Diamond –Blackfan Anemia <br />
| RPS19<br />
|-<br />
| Duchenne Muscular Dystrophy <br />
| DMD<br />
|-<br />
| Dyskeratosis congenita (Male embryos only)<br />
| DKC1<br />
|-<br />
| Ectodermal dysplasia (Hypohidrotic)<br />
| EDA; EDA1; GJB6; IKBKG<br />
|-<br />
| Familial Adenomatous polyposis coli (FAP)<br />
| APC<br />
|-<br />
| Familial Dysautonomia<br />
| IKBKAP<br />
|-<br />
| Fanconi Anemia <br />
| FANCA; FANCC; FANCD2; FANCF; FANCG; FANCJ<br />
|-<br />
| Fragile X Syndrome (FRAX)<br />
| FMR1<br />
|-<br />
| Galactosemia <br />
| GALT<br />
|-<br />
| Gangliosidosis<br />
| GLB1<br />
|-<br />
| Glanzmann Thrombasthenia <br />
| ITGA2B<br />
|-<br />
| Glutaric Acidemia (aciduria)<br />
| GCDH <br />
|-<br />
| Glycogen Storage Disease <br />
| G6PC; GAA; SLC37A4<br />
|-<br />
| Haemophilia A<br />
| F8<br />
|-<br />
| Haemophilia B<br />
| F9<br />
|-<br />
| Hereditary Nonpolyposis Colorectal Cancer: Lynch Syndrome<br />
| MLH1; MSH2; MSH6<br />
|-<br />
| Holt Oram Syndrome<br />
| TBX5<br />
|-<br />
| Huntington Disease<br />
| HD<br />
|-<br />
| Hydrocephalus<br />
| L1CAM<br />
|-<br />
| Ichthyosis <br />
| ABCA12; STS<br />
|-<br />
| Incontinentia Pigmenti (IP)<br />
| NEMO<br />
|-<br />
| Joubert Syndrome 5<br />
| INPP5E<br />
|-<br />
| Krabbe Disease<br />
| GALC<br />
|-<br />
| Leber Congenital Amaurosis (LCA)<br />
| CEP290; GUCY2D<br />
|-<br />
| Leigh Syndrome (Infantile Subacute Necrotising Encephalopathy)<br />
| LRPPRC<br />
|-<br />
| Lesch Nyan Syndrome<br />
| HPRT1<br />
|-<br />
| Leukocyte Adhesion Deficiency (Type I)<br />
| ITGB2<br />
|-<br />
| Li-Fraumeni Syndrome<br />
| TP53<br />
|-<br />
| Macular Dystrophy Retinal <br />
| VMD2<br />
|-<br />
| Maple Syrup Urine Disorder (MSUD)<br />
| BCKDHB<br />
|-<br />
| Marfan Syndrome <br />
| FBN1<br />
|-<br />
| Menkes Syndrome<br />
| ATP7A<br />
|-<br />
| Mitochondrial DNA Depletion Syndrom <br />
| POLG; RRM2B; SUCLA2; TK2<br />
|-<br />
| Mucolipidosis type II<br />
| GNPTAB<br />
|-<br />
| Multiple Endocrine Neoplasia<br />
| MEN1; MEN2A; MEN2B<br />
|-<br />
| Multiple Exostoses<br />
| EXT1; EXT2 <br />
|-<br />
| Myotubular myopathy<br />
| MTM1 <br />
|-<br />
| Nail-Patella Syndrome<br />
| LMX1B<br />
|-<br />
| Neurofibromatosis Type 1<br />
| NF1<br />
|-<br />
| Neurofibromatosis Type 2 <br />
| NF2<br />
|-<br />
| Noonan Syndrome<br />
| KRAS, PTPN11; SOS1<br />
|-<br />
| Norrie Disease<br />
| NDP<br />
|-<br />
| Ocular Albinism <br />
| GPR143<br />
|-<br />
| Oculocutaneous Albinism <br />
| OCA2; TYR <br />
|-<br />
| Oculodentaldigital Dysplasia<br />
| GJA1<br />
|-<br />
| Optic Atrophy<br />
| OPA1<br />
|-<br />
| Ornithine Transcarbamylase Deficiency <br />
| OTC<br />
|-<br />
| Osteogenesis imperfeca <br />
| COL1A1; COL1A2<br />
|-<br />
| Osteopetrosis <br />
| CLCN7; OSTM1; TCIRG1<br />
|-<br />
| Pachyonychia Congenita <br />
| KRT16; KRT6A<br />
|-<br />
| Pancreatitis, Hereditary<br />
| PRSS1 <br />
|-<br />
| Papillorenal syndrome <br />
| PAX2<br />
|-<br />
| Phenylketonuria <br />
| PAH <br />
|-<br />
| This table does not cover the complete list of diseases that PGD can be applied to.<br />
|}<br />
<br />
==Laws & Legal status==<br />
<br />
{| class="wikitable" <br />
|-bgcolor="DDCEF2"<br />
|'''Country'''<br />
|'''Legislation'''<br />
|-bgcolor="FFFAFA" <br />
| Australia<br />
| PGD is currently used to detect serious genetic conditions to improve the outcome of Assisted Reproductive Technologies (ART). In very rare cases it may be used to select an embryo with compatible tissue for a sibling who has a life-threatening disease where other means of treatment is unavailable. This is with the conditions that the use of PGD will not affect the welfare and interests of the child to be born. The parents must also receive adequate counselling and have full understanding of the procedures of PGD. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"> National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art</ref><br />
The use of PGD for sex-selection is prohibited with the exception of reducing the risk of the transmission of serious sex-linked genetic conditions. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"/><br />
|-bgcolor="FFFAFA"<br />
| Brazil<br />
| The laws regarding PGD in Brazil are not strictly regulated. They are vague and there is limited information surround the activities of assisted reproduction in general in the country <ref name="PMID25493379"><pubmed>25493379</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| Czech Republic<br />
| The laws in the Czech Republic allow those with a “defined indication in order to exclude risk of serous genetically conditioned disease and defects with embryos before they are implanted into the cavity of the uterus”. Couples that undergo any assisted reproductive treatment including PGD have to be married. Sex-selection is illegal except in regards to serious sex-linked genetic diseases <ref name="PMID24777348"><pubmed>24777348</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| Greece<br />
| In Greece, ART is open to those up to the age of 50 with written consent. It can only be used if a medical necessity is present such as the susceptibility of serious hereditary diseases. Sex selection is banned apart from cases of sex-linked diseases and sexually transmitted diseases <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| India<br />
| In India there is a cultural preference for boys thus the Prenatal Diagnostic Techniques (Regulation and Prevention of Misuse) Act was introduced in 1994. This law limits the use of PGD for sex determination except in cases of specific congenital diseases. These laws however are not strictly enforced. <ref>World Health Organisation (2015) Gender and Genetics Retrieved on October 21st 2015 from:http://www.who.int/genomics/gender/en/index4.html</ref><br />
|-bgcolor="FFFAFA"<br />
| Portugal <br />
| ART is only available to those who are married or have a similar type of relationship for at least two years. The couples cannot be of the same sex and must be at least 18 years of age. Sex selection is illegal except in cases of sex-linked diseases. The use of PGD is illegal if the predictive value of genetic tests are very low <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| Spain<br />
| PGD can be applied to “serious hereditary diseases not amenable to postnatal curative treatment” and “detection of other abnormalities which may compromise the viability of the pre-embryo”. If PGD is to be used for any other purpose authorisation must be acquired <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| Sweden <br />
| The use of PGD is strictly regulated and couples must achieve authorisation of the National Board of Health and Welfare. It can only be used it can only be used if the child is at risk to inheriting a serious chromosomal or monogenetic disease. It cannot be used for selection of specific characteristics <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| United Kingdom<br />
| Those involved with carrying out the IVF treatment must have a license from the Human Fertilisation and Embryology Authority (HFEA). Only embryos that are approved by the HFEA can be implanted where the embryonic nuclear or mitochondrial DNA cannot be altered with the exception of preventing mitochondrial diseases <ref name="PMID24777348"/>. <br />
|}<br />
<br />
==Future/Current Research==<br />
In addition to research efforts for improving overall performance of established PGD/S techniques, such as finding the ideal zona pellucida insection site<ref name="PMID26259216"><pubmed>26259216</pubmed></ref>, many research efforts have been spent to find alternative, non-invasive techniques to test for diseases and abnormalities<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
===Non-invasive Preimplantation Genetic Testing without Embryo Biopsy===<br />
Different parameters of gametes, zygotes, embryos (“vacuoles in sperm heads, spindle position in mature oocytes, cleavage intervals of zygote, and embryo developmental dynamics”) may correlate with aneuploidy rates. This knowledge may be applied in potential noninvasive preimplantation diagnostic methods. Several methods have been proposed and are currently further researched<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Sperm Selection====<br />
Intracytoplasmic morphologically selected sperm injection (IMSI) is common procedure in IVF treatment to improve fertilization rates in patients with poor semen quality. In addition, studies have found that IMSI improves embryo development and that spermatozoa with large vacuoles in their heads correlate with increased aneuploidy rates and disturbed chromosomal structures. Thus, selecting spermatozoa based on morphological hallmarks may decrease aneuploidy rates in the fertilized embryos. As with polar body biopsies, however, this approach will solely be applicable if evidence for severe male detrimental contribution is given<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Blastocoel Fluid Extraction====<br />
In addition, a less invasive retrieval of material for diagnosis could include the extraction of the blastocoel fluid. The cavity of the blastocyst, lined by the trophectoderm, is filled with this blastocoel fluid, which contains metabolites of both trophectoderm and inner cell mass origin. The retrieval does not require a biopsy but merely a small opening to extract the fluid and, thus, causes less harm to the embryo. Multiple studies have applied this method<ref name="PMID22020776"><pubmed>22020776</pubmed></ref> <ref name="PMID23148560"><pubmed>23148560</pubmed></ref> and it may in the future become of clinical relevance.[[File:Aspiration_of_the_Blastocoel_Fluid.jpeg|thumb|Aspiration of the Blastocoel Fluid using a ICSI pipette<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.]]Next to metabolites, the blastocoel fluid can contain DNA. Studies have shown that genomic DNA is present in about 90% of the blastocoel fluid samples tested. Typically the fluid is removed with an ICSI pipette from a day five blastocyst through its mural trophectoderm until the blastocyst fully collapses around the embryo. Several concerns regarding this method in a clinical setting have been raised. The collected DNA may be contaminated by the culture media that contains DNA fractions. The DNA may also be least representative of the actual embryos genome as the DNA may originate from abnormal or degenerated cells. Even though labelled noninvasive, the blastocyst still undergoes manipulation to some degree which may affect its viability. Thus, more research is required until this method can evolve from research to clinical use<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
====Proteomics====<br />
The protein secretome of blastocysts may be representative of its chromosome constitution Recent studies have found biomarkers such as lipocalin-1, interleukin-10, tumor necrosis factor, stem cell factor, and chemokine ligand 13 to be differently secreted by aneuploid blastocyst than by euploid ones. The most significant biomarker appears to be interleukin-10. Paired with novel proteomic technologies and mass spectrometry this knowledge when extended may contribute to a new invasive PGD method<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Embryo Morphology====<br />
Using time lapse imaging the embryo’s morphology can be closely observed and potential aneuploidy characteristics detected. Such characteristics may include the time of division to five cells, the time between the division from three to four cells, and the duration of the division from one to two and subsequently to three. In addition, the morphological quality of ICM an TE has been positively associated with aneuploidy or euploidy prognosis<ref name="PMID26246880"><pubmed>26246880</pubmed></ref>. These may give rise to an embryo quality screening prior to implantation<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
==Glossary==<br />
'''CTFR''' Cystic Fibrosis Transmembrane Conductance Regulator <br />
<br />
'''ESHRE'''The European Society for Human Reproduction and Embryology<br />
<br />
'''FISH''' Fluorescence in situ hybridisation<br />
<br />
'''ICSI''' Intracytoplasmic Sperm Injection<br />
<br />
'''IMSI''' Intracytoplasmic Morphologically Selected Sperm Injection<br />
<br />
'''NGS''' Next Generation Sequencing <br />
<br />
'''PB''' Polar Body<br />
<br />
'''PGD''' Preimplantation Genetic Diagnosis <br />
<br />
'''PGS''' Preimplantation Genetic Screening<br />
<br />
'''PCR''' Polymerase Chain Reaction<br />
<br />
'''RT''' Robertsonian translocations<br />
<br />
''SNP''' Single Nucleotide Polymorphism <br />
==References==<br />
<br />
<references/><br />
<br />
<br />
{{StudentPage2015}}</div>Z5017878https://embryology.med.unsw.edu.au/embryology/index.php?title=2015_Group_Project_6&diff=2072012015 Group Project 62015-10-22T04:02:55Z<p>Z5017878: </p>
<hr />
<div>{{ANAT2341Project2015header}}<br />
<br />
<br />
=Preimplantation Genetic Diagnosis and Preimplantation Genetic Screening=<br />
==Introduction==<br />
Preimplantation genetic diagnosis (PGD) and preimplantation genetic screening (PGS) are reproductive options for couples with known family histories of genetic disease or couples undergoing IVF procedures due to infertility issues. PGD can diagnose many genetic disorders caused by known chromosomal abnormalities (number and/or structure) or single gene mutations, and, thus decrease the risk of termination of pregnancy or miscarriages and enable such couples to have an unaffected child<ref name="PMID24907939"><pubmed>24907939</pubmed></ref>. Through major improvements in PGD/S and general laboratory technology, the testing for abnormalities in fetuses has shifted from prenatal diagnosis during the first 2 trimesters <ref> Blackburn, S.L. (2003) '''Maternal, Fetal & Neonatal physiology: a Clinical perspective''' (2nd ed.). Seattle: Saudners </ref>, testing for overall fetal growth, complications of pregnancy, and birth defects<ref> Sadler T.W.(2012) '''Langman's Medical Embryology''' (12th ed.) Philadelphia: Lipincott, Wiliams & Wilkins, a Wolters Kluwer Business </ref>, to an embryonic focus especially in advancements in Artificial Reproductive Technologies (ART)<ref><pubmed>20638568</pubmed></ref>. In 1990 PGD for a recessive X-linked disease resulted in the first live birth<ref><pubmed>2330030</pubmed></ref> and has since been incorporated in clinical routine and applied for a variety of genetic diseases, such as sickle cell anemia, thalassemia, or cystic fibrosis<ref name="PMID24907939"/>.<br />
[[File:Preimplantation Genetic Diagnosis Procedure.jpeg|600px|left|thumb| Simplified steps for PGD<ref name="PMID24907939"/>]]<br />
{|class="wikitable"align="right" <br />
| <html5media height="400" width="533">https://www.youtube.com/watch?v=0e-79qKllqk</html5media><br />
|-<br />
| Preimplantation Genetic Diagnosis<ref>IVF Florida (2011, December 11) IVF Florida - South Florida Fertility Specialists - Pre-Implantation Genetic Diagnosis [Video file]. Retrieved from https://www.youtube.com/watch?v=0e-79qKllqk</ref><br />
|}<br />
<br />
==History==<br />
The advances in reproductive technology during the second half of the 20th century, led to PGD's first clinical application in 1990 <ref>Harper, J. (n.d.). The history of PGD. Lecture. UCL Centre for PG&D and CRGH.University College London</ref>.<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
|Year<br />
|<br />
|- bgcolor="FFFAFA"<br />
| '''1967''' <br />
|First PGD on rabbit blastocysts (Gardner& Edwards) <ref name="PMID6036172"><pubmed>6036172</pubmed></ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1986''' <br />
|First Cleavage Biopsy (Wilton & Trounson)<ref>Wilton, L. J., & Trounson, A. O. (1986). Viability of mouse embryos and blastomeres following biopsy of a single cell. In Proceedings of the 18th Annual Conference of the Australian Society for Reproductive Biology, Brisbane, Australia.</ref><br />
|- bgcolor="FFFAFA"<br />
|'''1987''' <br />
|First Blastocyst Biopsy (Muggleton-Harris, Monk, Rawlings, & Whittingham)<ref name="PMID3372699"><pubmed>3372699</pubmed></ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1988''' <br />
|First Polar Body Biopsy (Yury Verlinksy)<ref> Verlinsky, Y., Pergament, E., Andresen, P., Enriquez, G., & Strom, C. (1989). Genetic analysis of polar body DNA: A new approach to preimplantation genetic diagnosis. Am J Hum Genet, 45(4), A272.</ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1990''' <br />
|First Clinical PGD using PCR testing for X-linked (Handyside, Kontogianni, Hardy, & Winston)<ref name="PMID2330030"><pubmed>2330030</pubmed></ref> <br />
|} <br />
==Preimplantation Genetic Diagnosis==<br />
PGD is used to test the genetic makeup of embryos to detect single gene disorders, chromosomal abnormalities and mitochondrial disorders. It also has applications in gender selection for diseases with unequal gender distributions <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Some diseases commonly involved with PGD include cystic fibrosis, spinal muscular atrophy and beta – thalassaemia <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press.">Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press</ref> <ref name="PMID17823145"><pubmed>17823145</pubmed></ref>. It was first used in the United Kingdom in the 1980s of arenoleucodystrophy and primarily focusing on sex- linked disorders <ref name="PMID17823145"/><ref name="PMID23150080"><pubmed>23150080</pubmed></ref>. PGD is now capable of detecting single cell defects (molecular) and chromosomal disorders resulting from the inversion, translocation or deletion of chromosomes (cytogenic) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>,<ref name="PMID11325751"><pubmed>11325751</pubmed></ref>. PGD can be applied to the embryo at different stages. That is on polar bodies, blastomeres or blastocyst <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>.<br />
Depending on the type of genetic disorder, PGD utilises different methods of genetic testing. These include Fluorescence in situ hybridisation (FISH) which is used for sex – linked disorders and detects chromosomal rearrangements <ref name="PMID11325751"/><ref name="PMID17876073"><pubmed>17876073</pubmed></ref> and Embryo halotyping which allows the identification of chromosomes causing the inherited disorder through knowledge of the pattern of closely linked markers <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. Polymerase chain reaction (PCR) is also widely used to detect molecular abnormalities <ref name="PMID11325751"/>.<br />
PGD is tightly regulated and supported by large organisations namely The American Society for Reproductive Medicine, The European Society for Human Reproduction and Embryology (ESHRE), The European Society of Human Genetics and the Preimplantation Genetic Diagnosis International Society <ref name="PMID25500181><pubmed>25500181</pubmed></ref>.<br />
===Sex-linked disorders===<br />
The determination of a disease as gender specific usually correlates with the presence or absence of specific genes such as SRY on the Y chromosome. It is known that females have two X chromosomes and males have an X and a Y chromosome where abnormalities are more prevalent on the X chromosome. PGD can be used for sex selection where only male embryos are transferred to reduce the chance of inheriting X-linked disorders. However, this does not completely eradicate the problem as male embryos remain susceptible to inheriting an affected X chromosome. Sex determination is only used when the specific mutation is unknown and has yet to be discovered <ref name="PMID24866878"><pubmed>24866878</pubmed></ref>.<br />
===Single gene defects===<br />
Single gene defects can be dominant, recessive, autosomal or X-linked. They are commonly diagnosed using PCR and although the PCR available today is complex and capable of combatting a large range of disease the development of new protocols has been proven to be difficult due to the small DNA sample available <ref name="PMID26168107"><pubmed>26168107</pubmed></ref><br />
===Mitochondrial disorders===<br />
Mitochondrial disorders also known as oxidative phosphorylation disorders arise from mutations in the nuclear DNA or mitochondrial DNA <ref name="PMID26312584"><pubmed>26312584</pubmed></ref>. They pose as a problem because they are unrecognisable until the mutations in the cell reach a detrimental level <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Mitochondrial disorders cause miscarriages and stillbirths as well as death in children and young adults. The effects can either be contained in a single organ or more commonly involve multiple organ failure where organs with high energy demands such as the brain, liver muscle and heart and heavily influenced. They are usually occur spontaneously or result from inheritance from the mother. Since mitochondria are solely inherited from the mother oocyte donations have been used as a solution to combat mitochondrial disorders. Additionally, there has been an increasing use in PGD where embryos that stay under the given threshold of 18% gene-mutations are allowed to be transferred and result in normal development. New technology in the areas of nuclear gene transfer and genome editing are also being experimented with <ref name="PMID26312584"/>. <br />
===Chromosomal disorders===<br />
Chromosomal disorders can be reciprocal, Robertsonian translocations, inversions, deletions and insertions <ref name="PMID26168107"/>. . Data from ESHRE collected between 2010 and 2011 has shown that the most common chromosomal abnormality confronted in PGD are reciprocal chromosomal abnormalities <ref name"PMID26071418"><pubmed>26071418</pubmed></ref>. PGD has also been used successfully for Robertsonian translocations (RT), a type of structural translocation. Children who carry RT are phenotypically normal, however in their later years it is found that they will suffer from infertility and repeated miscarriages due to the high frequency of abnormal embryos <ref name="PMID22081077"><pubmed>22081077</pubmed></ref>. PCR and FISH are the two main techniques used for chromosomal disorders. To be able to conduct the examinations the cells are required to be at the metaphase stage <ref name="PMID26168107"/>. <br />
[[File:Reasons_for_PGD.jpg|600px|thumb|Reasons for PGD<ref name= "PMID24764761"><pubmed><24764761</pubmed></ref>]]<br />
==Preimplantation Genetic Screening==<br />
PGS involves an array of methods or ideas that aim to segregate embryos that have genetic flaws and those that are healthy <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. The occurrence of aneuploidy is high around the stages of early embryonic development and they are the most common cause if miscarriages and congenital birth defects <ref name= "PMID26085841"><pubmed>26085841</pubmed></ref>. They have little effect on the morphology of the embryo making them difficult to identify thus identification heavily relies on genetic testing <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. <br />
Genetic sampling is most commonly conducted using Microarray Comparative Genomic Hybridisation (aCGH) as well as FISH, Quantitative PCR and Single Nucleotide Polymorphism (SNP) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. These methods collectively aim to assess numeral and structural chromosomal errors <ref name= "PMID26085841"/>. Studies have also introduced Next- Generation Sequencing (NGS) <ref name= "PMID26085841"/> and Whole Genome Amplification used to screen imbalances in the complete 24-chromosomes <ref name="PMID25953353"><pubmed>25953353</pubmed></ref><br />
Statistics from ESHRE have shown that the most common indications for PGS is advanced age, followed by repeated implantation failure or recurrent miscarriage and male infertility <ref name="PMID26071418"><pubmed>26071418</pubmed></ref>.<br />
===Indications===<br />
A low percentage of structural abnormalities in chromosomes are responsible for the cause of miscarriages. Despite this, they are the most prevalent type of chromosomal abnormality accounted for in PGD <ref name="PMID20638568"/>. The presence of specific gene cycles, initiation of embryonic protein synthesis and evident physiological development are all indicative of a successful in vitro fertilisation procedure <ref name="PMID11576737"><pubmed>11576737</pubmed></ref>. To eliminate further errors from occurring during the PGD procedure it is recommended to undertake further prenatal testing such as amniocentesis in the later stages <ref name="PMID20638568"/>. <br />
====Advanced maternal age====<br />
Data provided by the ESHRE has shown that the mean age of women undergoing PGS is 39 years <ref name="PMID26071418"/>. Women of advanced age have been shown to have a lower rate of pregnancies reaching childbirth <ref name="PMID18583331"><pubmed>18583331</pubmed></ref>. The highlighted concern revolves around the increased occurrence of aneuploidy following maternal age. The optimal age range for the lowest aneuploidy incidence was found to be between 27 to 37 years of age (6%) then progressively higher in women aged up to 42 (33%) and most common in those 44 and above (53%) <ref name="PMID24355045"><pubmed>24355045</pubmed></ref>. <br />
====Recurrent pregnancy loss / IVF failure====<br />
Recurrent pregnancy loss is defined as three or more IVF failures after cumulative transfer of more than 10 good-quality embryos. These are primarily caused by two main factors, reduced endometrium receptivity or embryonic defects. Endometrium receptivity can be negatively influences by instances including uterine pathologies such as thin endometrium, altered expression of adhesive molecules and immunological factors. Additionally, embryonic defects may be due to genetic abnormalities, embryonic aneuploidy or zona hardening. Endometriosis and hydrosalpinx has been known to effect both the endometrium and embryo <ref name="PMID23260857"><pubmed>23260857</pubmed></ref>.<br />
====Human leukocyte antigen matching====<br />
First used in 2001, HLA matching is an option given to parents to save a child with haematological or immunological disease through conceiving another child who would potentially be able to donate cord blood or haematopoietic stem cells from the bone marrow for transplantation. The process namely PGD-HLA has shown to improve haematopoietic stem cell transplant (HSCT). PGD-HLA can only be performed when HSCT is not needed urgently due to the time needed to conceive and delivery the baby <ref name="PMID25500181"><pubmed>25500181</pubmed></ref>. It is most commonly applied to children suffering from relapsed leukaemia <ref name="PMID22524201"><pubmed>22524201</pubmed></ref>. In a case study PGD-HLA was proven to successfully cure 10 diseases including Fanconi anaemia, Diamond-Blackfan anaemia and beta thalassemia <ref name="PMID25066893><pubmed>25066893</pubmed></ref>.<br />
==Biopsy Methods==<br />
Biopsy, the removal of genetic materials, from oocytes or embryos in the preimplantation stage is the primary step in PGD. For the past two decades these biopsies have been performed at three stages, the polar body, blastomere, and blastocyst, and the methodologies optimized to ensure the embryo’s viability. The most common approach involves biopsies at the cleavage stage. However, polar body and blastocyst biopsies are increasingly more often tested and applied. Approached for opening the zona pellucida involve next to the traditional mechanical and chemical means, novel approaches such as noncontact lasers. Their application may simplify and secure the procedure significantly. The most challenging question about PGD procedures remains at what stage biopsies should be taken. Much controversy has developed around this topic, highlighting the varying disadvantages and advantages of temporal biopsies. <ref name="PMID22723007"><pubmed>22723007</pubmed></ref><br />
<br />
[[File:Polar_Body,_Blastomere,_and_Trophectoderm_Biopsy.jpeg|400px|thumb|Polar body (A), blastomere (B) and trophectoderm (C) biopsies<ref name="PMID25625041"><pubmed>25625041</pubmed></ref>.]]<br />
{| class="wikitable"<br />
|- align="center" bgcolor="DDCEF2"<br />
|<br />
| Time of Biopsy<br />
| Advantages <br />
| Disadvantages<br />
|- bgcolor="FFFAFA"<br />
| Polar Body<br />
| Day 1<br />
| No harm to oocyte<br />
| Only maternal DNA is tested, often needs to be coupled with other biopsies, and there are difficulties distinguishing between the first and second PB.<br />
|- bgcolor="FFFAFA"<br />
| Blastomere<br />
| Day 3<br />
| …<br />
| … <br />
|- bgcolor="FFFAFA"<br />
| Trophectoderm<br />
| Day 5 and 6 <br />
| Little harm to the embryo and large amount of genetic material is extracted. <br />
| Opening of blastocyst necessary, small time window for procedure<br />
|}<br />
===Polar Body Analysis===<br />
Day 1<br />
====Description====<br />
Polar body (PB) biopsy offers a promising alternative to biopsies performed at the blastomere stage for PGD/S indications on legal and practical grounds. Consequent embryo development does not necessitate the presence of the first and second PB and their removal may not be crucial. PB biopsy requires precise timing. Keeping track of the meiotic cell cycle is necessary to perform a successful biopsy and, therefore, PB biopsy usually is applied in combination with intracytoplasmic sperm injection (ICSI). During the maturation from the germinal vesicle stage to the metaphase-II stage the first PB is formed. A cytoplasmic bridge containing spindle remnants, that are still in contact with the cellular genetic material, links this PB to the oolemma for about 90 minutes after extrusion. It is possible to visualize these remnants by polarization microscopy and it is crucial to not perform the biopsy until the first PB is no longer firmly attached to the oolemma as this indicates an immature embryo.The oocyte tolerates mechanical zona dissection best during hours four until six after ICSI as the oolemma has stabilized by that time because of the cortical granule reaction. Over time the first PB degenerates stressing a temporal biopsy and its optimal extraction time window is four to 12 hours after ICSI. The second PB forms around two to four hours after ICSI. Its optimal time window for biopsy is set to be eight to 16 hours after ICSI due to the second PB being attached to the oolemma with spindle remnants until six hours after ICSI. Biopsy at this point may cause enucleation of the oocyte. Studies have shown that the amplification efficiency of second PB’s DNA is worse if the PB is extracted prior to eight hours after ICSI. Thus, it is possible to perform sequential and simultaneous biopsies for the first and second PB. If performed, sequentially the first PB may be removed four to 12 hours and the second PB eight to 16 hours after ICSI. The optimal time window for a biopsy for both the first and second PB simultaneously is eight to 12 hours after ICSI. It is highly preferred to analyze both PBs due to potential aneuploidies in either PB and crossing overs during meiosis<ref name="PMID22723007"/>. <br />
====Procedure====<br />
Chemical opening achieved with for example acidic tyrode’s solution of the zona pellucida is not tolerated by the oocyte and may have detrimental effects on the embryo’s development. Therefore, the access to the perivitelline space of the oocyte is provided by mechanical zona dissection or by laser. Both techniques work well if performed by experienced embryologist. However, laser-assisted biopsy is less time consuming when compared to manual dissection. It is critical to consider the size of the introduced opening as it will remain permanent. If it is too large the blastomere may be lost during embryo development and if it is too small it may interfere with hatching of the embryo during blastocyst stage<ref name="PMID22723007"/>.<br />
[[File:Polar_Body_Biopsy.jpeg|left|thumb|The presence of a faint but clearly identifiable strand connecting PB2 to the oolemma. The biopsy was performed ∼9 h after ICSI<ref name="PMID21908464"><pubmed>21908464</pubmed></ref>.]]<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JTaQzszVr8o</html5media><br />
|-<br />
| Laser-assisted polar body biopsy<ref>RIUK, R. (2013, June 25) Polar Body Biopsy [Video file]. Retrieved from https://www.youtube.com/watch?v=JTaQzszVr8o</ref><br />
|}<br />
====Advantages & Disadvantages====<br />
PB biopsies can only investigate the maternal contributions to the embryo as they are of maternal origin. Thus, this procedure is appropriate for PGD solely for monogenetic diseases from the maternal side. Recessive diseases may be evaluated with PB biopsies on the basis that the embryo’s outcome will be determined by the paternal contribution. It may still be applied for PGS as it is a fairly safe biopsy option and most aneuploidies either arise during meiosis or origin from the maternal genome. However, diagnosis error has been reported due to the lack of considering paternal contributions.Because PB biopsies are performed very early it is not yet known whether the oocyte will develop into a viable embryo. Thus, PBs are commonly frozen or fixed after biopsy and depending on the state of the embryo only chosen PBs will be tested. This is primarily an economic issue as many genetic testing procedures are very cost-intensive<ref name="PMID22723007"/>[[File:Implantation_predictive_value_of_euploid_screening_results.jpeg|thumb|The sustained implantation predictive value (with 95 % confidence interval) of a euploid screening result obtained from the first polar body (PB1), PB1 and the second polar body (PB2), or a direct embryo biopsy for each stage of embryo transfer (cleavage-stage and blastocyst stage)<ref name="PMID25106935"><pubmed>25106935</pubmed></ref>.]] Generally the sustained implantation predictive value of screening of PBs is significantly lower than of for example biopsies of the blastocyst stage<ref name="PMID25106935"/>. Moreover, it is often difficult to distinguish between the first and the second PB. As the first one degenerates quicker, this may influence diagnostic procedures<ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
===Blastomere biopsy===<br />
Day 3 <br />
====Description====<br />
Blastomere biopsy has been the prevalent method for PGD and PGS in the last two decades. At least one, but up to two, blastomeres are biopsied on day three of the cleavage stage embryo. The right number of blastomeres removed is a controversial topic as two cells allow for more genetic material and more accurate results. However, removing two cells might be too invasive and damaging to the embryo. As PGS tries to improve implantation rates, whereas PGD sets out to avoid known genetic disorders, for the former only one cell is removed, while for the latter often two need to be removed, to ensure results as correct as possible<ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
====Procedure====<br />
Initially a hole was drilled into the zona pellucida using acid tyrodes with the consequent aspiration of blastomeres with a pipette. Nowadays the zona pellucida is largely opened using a laser and calcium and magnesium free media have been introduced to decrease junctions between blastomeres, which facilitates the biopsy<ref name="PMID21748341"/>.<br />
[[File:Aspiration_of_a_Blastomere.jpeg|thumb|Aspiration of a Blastomere into the biopsy pipette<ref name=" PMID24783200"><pubmed>24783200</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=TbridWVwipI</html5media><br />
|-<br />
| Laser-assisted blastomere biopsy<ref>Sukprasert, M. (2014, March 5) Day 3 Blastomere Biopsy 1 [Video file]. Retrieved from https://www.youtube.com/watch?v=TbridWVwipI</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
===Trophectoderm biopsy===<br />
Day 5 and 6<br />
====Description====<br />
The improvement of embryo culture media allowed the in vitro development of human embryos until the blastocyst stage and opened up the possibility to take blastocyst biopsies. During day three to day five the haploid maternal and paternal genomes work together for the first time to form the genome of the embryo. The maternal epigenetic control lessens significantly while preparing for implantation with precisely arranged events happening. The first event includes a rapid increase in the number of embryonic cells which are active in mitotic divisions and apoptosis of aberrant cells. This is followed by the formation of blastocoel (cavitation) which results from the flattening of cell located on the outside of the blastomere. Now the blastocyst will expand until the embryo hatches by rupturing the zona pellucida. The cells of the blastocyst will differentiate to form two distinct cell lineages, the outer trophectoderm and the inner cell mass<ref name="PMID22723007"/>.<br />
====Procedure====<br />
Trophectoderm biopsy is usually performed in Hepes buffered biopsy medium and opening approaches include needle cutting which has been replaced by lasers in past years. Different research groups report different timings of the opening to be the most successful. Some open the blastocyst on day three or four by creating a 25 µm which causes the trophectoderm to herniate through this hole and is, thus, accessible for biopsy. Others create this hole about four hours before biopsy which allows sufficient herniation of trophectoderm cells. It is also possible to open the blastocyst immediately before biopsy. This avoids an extra step and the inner cell mass usually is easy to locate. Blastocyst biopsies involve the removal of trophectoderm cells and the ideal time for the procedure is day five. Successful biopsies on day six have been performed, while little is known about the results of biopsies on day seven. However, since the window of implantation in humans is from day eight to ten after ovulation, day seven biopsies appear to be possible<ref name="PMID22723007"/>.<br />
-collapse of trophoblasts<br />
-possible: biopsy of hatched blastocyst, holding pipette careful mild suction force to hold embryo near ICM <br />
-Cryopreservation<br />
<br />
<br />
[[File:Microscopic images of human blastocysts for biopsy.jpeg|thumb|(A) Some trophectoderm cells in a blastocyst started to hatch and (B) the trophectoderm cells were biopsied with assisted laser cutting. Images in C–D show the blastocysts after vitrification and warming. Blastocysts had been cultured for 2–4 hrs after warming, showing good (ICM and trophectoderm cells) hatched (C) and hatching (D) blastocysts. The hatching blastocyst in (E) has good ICM but fair trophectoderm while the blastocyst in (F) has both fair ICM and trophectoderm. Arrows indicate ICMs and arrow heads indicate trophectoderm cells. Bar = 40 µm<ref name="PMID2190846"><pubmed>2190846</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JI_TQ8d8tNM</html5media><br />
|-<br />
| Laser-assisted blastocyst biopsy (at 00:50 min)<ref>Coco, R. (2014, April 30) Trophectoderm biopsy in a Hatching blastocyst protruding ICM [Video file]. Retrieved from https://www.youtube.com/watch?v=JI_TQ8d8tNM</ref><br />
|}<br />
<br />
====Advantages & Disadvantages====<br />
Blastocyst biopsies are believed to be less damaging to the embryo and appear to be unrelated to implantation rates. In addition, this biopsy method allows for a larger extraction of cells for genetic testing. However, since they are performed late in in vitro development, the time window for genetic testing is relatively small. Fast and accurate genetic testing methods are needed to ensure a successful and safe result from this biopsy. Thus, blastocyst biopsies may gain more popularity in the future whn such methods have been developed or improved<ref name="PMID22723007"/>. <br />
==Genetic Techniques==<br />
===Polymerase Chain Reaction===<br />
PCR amplifies DNA specific to genetic sequence of interest . PCR was developed by Kay Mullis in the 1980s, for which he was awarded the Nobel prize for chemistry in 1993. <ref> Pubmed Docs (2015) Polymerase Chain Reaction (PCR) Pubmen. Retrieved from [http://www.ncbi.nlm.nih.gov/probe/docs/techpcr/]</ref> This technique enables clinicians to monitor and diagnose diseases using minute samples such as embryonic cells, blood & tissue. <ref>Roche (2015) PCR: How We Copy DNA. Roche Molecular Systems Inc. retrieved From [http://molecular.roche.com/pcr/Pages/Process.aspx]</ref> PCR has many important applications like DNA fingerprinting, genetic mapping, detection of viruses and bacteria as well as being used to detect genetic disorders, as a part of PGD, in conjunction with IVF. It is used to detect molecular abnormalities such as single gene disorders like Tay Sach, Cycstic fibrosis, Duchenne Muscular Dystrophy, Thalassemia, Huntington disease, Spinal muscular atrophy and many more. Molecular and Genetic analysis require a significant amount of DNA, which we would not have without PCR. It revolutionized the study of DNA, replacing all previous recombinant DNA technology. <ref> Mullins, K., Francois, F.& Gibbs R.A. (1994 ) The Polymerase Chain Reaction. p3. Springer- Science +Business Media. Birkhauser, Boston<br />
Available at [https://books.google.com.au/books?hl=en&lr=&id=gjrTBwAAQBAJ&oi=fnd&pg=PR5&dq=kary+mullis+PCR&ots=mpzAyRh5ZY&sig=PQ4goNoKJ90tb3-MkPk62zrTGbw#v=onepage&q=kary%20mullis%20PCR&f=false] </ref> <br />
<br />
[[File:PCR.jpg|thumb|right|Polymerase chain reaction (PCR) amplifies DNA specific to genetic sequence of interest, enabling the monitoring and diagnose molecular abnormalities such as single gene disorders using minute samples such as embryonic cells, blood & tissue <ref>NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref>]]<br />
{|<br />
|- align="left" bgcolor="DDCEF2"<br />
|'''Procedure'''<br />
|}<br />
Samples are obtained from the the blastocyst, a polar body biopsy or the blastomeres stages of the embryo. <br />
*Stage 1 Denaturing: separating the target strands of DNA <br />
The obtained sample is heated to roughly 90 degrees celcius, this heat breaks the relatively weak bonds between nucleotides that form DNA. The double stranded DNA is split into two single strands of DNA that are used as templates.<br />
*Stage 2 Annealing: Binding the Primers to the target DNA sequence <br />
PCR will only copy the target sequence of DNA specified by specific PCR primer. These synthesized primers oligonucleotides are small artificial pieces of DNA. TAQ polymerase enzyme synthesize two new strands of DNA duplicate to the single sample DNA stand template indicated by these primers. During this stage the reaction is cooled to a temperature between 40-60 degrees Celsius. <br />
*Stage 3- Extension- making copies <br />
Each of these two copies are then used again as templates generating two further replications This cycle can occur as many 30 -40 times within a couple hours leading to billions of extra copies of the original DNA segment. The optimal temperature for the further replication is roughly 72 degrees Celsius. <br />
This process mediated by a thermocycler machine that is programmed to alter the temperature of the reaction every couple of minutes, perpetuating the cycle of DNA denaturing and synthesis. <br />
This process, generates exponentially exact copies of the original template DNA sequence. <br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
!PCR cycles<br />
|-<br />
| '''PCR Cycle'''<br />
| '''Target Copies'''<br />
|-<br />
| 1<br />
| 2<br />
|-<br />
| 2<br />
| 4<br />
|-<br />
| 3<br />
| 8<br />
|-<br />
| 4<br />
| 16<br />
|-"<br />
| 5 <br />
| 32<br />
|-<br />
| 6 <br />
| 64<br />
|-<br />
| 7 <br />
| 128<br />
|-<br />
| 8<br />
| 256<br />
|- <br />
| 9<br />
| 512 <br />
|-<br />
| 10<br />
| 1024<br />
|-<br />
| 15<br />
| 32,768<br />
|-<br />
| 20 <br />
| 1,048,578<br />
|-<br />
| 25<br />
| 33,554,432<br />
|-<br />
| 30 <br />
| 1,073,741,842<br />
|-<br />
|}<br />
<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="6" |'''Advantages'''<br />
|-bgcolor="FFFAFA"<br />
| Fast and inexpensive way of copying a target sequence of DNA<br />
|-bgcolor="FFFAFA"<br />
| Particularly useful for the diagnosis of single cell defects<br />
|-bgcolor="FFFAFA"<br />
| Rapid generation of results (within hours)<br />
|-bgcolor="FFFAFA"<br />
| Highly sensitive, a single molecule of DNA is sufficient for reaction<br />
|-bgcolor="FFFAFA"<br />
| Generates DNA copies exponentially<br />
|-bgcolor="FFFAFA"<br />
| This enables DNA amplification required for molecular and genetic diagnostic analysis<ref> Dreesen, J., Drusedaul, M., Smeets, H., Die-Smulders, C., Coonen, E., Dumoulin, J., Gielen, M., Evers, J., Herbergers, J. & Geradets, J. (2008) Validation of preimplantation genetic diagnosis by PCR analysis: genotype comparison of the blastomere and corresponding embryo, implications for clinical practice. Mol. Hum. Reprod. 14 (10):573-579.doi: 10.1093/molehr/gan052. Retrieved from [http://molehr.oxfordjournals.org/content/14/10/573.short] </ref> <ref><pubmed>20966460</pubmed></ref><br />
|-bgcolor="DDCEF2"<br />
| rowspan="4"|'''Disadvantages'''<br />
|-bgcolor="FFFAFA"<br />
| Only during the exponential DNA replication phase, the starting quantity sequence contained in the original sample (template DNA strand) can be determined<br />
|-bgcolor="FFFAFA"<br />
| PCR reaction is limited to by presence of inhibitors in the sample<br />
|-bgcolor="FFFAFA"<br />
| Self annealing due to the accumulation of the product -stopping exponential amplification for the target sequence and reach a plateau<br />
quantification of the end point of reaction of PCR products unreliable - therefore real time quantitative RT-PCR is necessary<br />
<ref> NIS (2015) Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref><br />
|-bgcolor="FFFAFA"<br />
| Not a diagnostic method on its own, requires further analysis<br />
|}<br />
===Fluorescent In Situ Hybridisation===<br />
FISH is the one of the most effective and rapid <ref name="PMID26338801"><pubmed>26338801</pubmed></ref> method of conducting PGD. This techniques used to locate a specific DNA sequences within a chromosome. FISH facilitates the clinical diagnosis of chromosomal abnormalities indicated by sequential duplications, deletions and rearrangements of chromosome, that are usually missed with microscopic analysis. This technique is especially relevant for female embryos with X-linked diseases,<ref name="PMID20809319"><pubmed>20809319</pubmed></ref> that have no other mutation specific tests [http://www.ncbi.nlm.nih.gov/pubmed/20809319] As part of PGD, samples are collected from various stages of the embyro,and they are able to conducted tests on the blastocyst, a polar body biopsy and the blastomeres <ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. FISH is 99% effective when used in conjunction with competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities<ref name="PMID26338801"/>.<br />
{|<br />
|- align="left" bgcolor="DDCEF2"<br />
|'''Procedure'''<br />
|}<br />
Samples are collected from either the blastocyst, a polar body biopsy or the blastomeres stages of the embryo <ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
DNA strands are heated and denatured causing their the individual DNA strands to break apart<br />
Probes are single complimentary stands of DNA a that have been tagged with small chemical agents that glow brightly in the presence of a specific region on a chromosome. These specific probes then hybridize and join to their complementary DNA strand. <br />
The fluorescent tags enable the researchers to correctly identify the presence or lack thereof and location of the specific chromosomes that they are testing for. <ref name="PMID17876073"><pubmed>17876073</pubmed></ref><br />
Researcher analyse the results by identifying the number and the relative location of the fluorescent dots generated by the FISH images.<ref name="PMID17970921"><pubmed>17970921</pubmed></ref><br />
The probe will not fully hybridise if there has been a duplication or a deletion of the DNA - indicating chromosomal and sex chromosomal anomalies like trisomies and aneuploidies. <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref><br />
Different probes are used for different purposes: <ref>Unique, Rare Chromosome Disorder Support Group (2013) Fluorescence in situ hybridisation (FISH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/Other/FISH%20FTNW.pdf]</ref><br />
*'''Locus specific tags''' detect very small imbalances, and locate isolated small portions <br />
of genes within a chromosome<br />
*'''Alphoid/Centomeric Repeat probes''' are developed from the repetitive sequence located in the middle region of each chromosome, useful in determining the number of chromosomes , detecting rearrangement and when used in conjunction with locus probes to determine the absence of genetic material on a chromosome. <br />
*'''Paint Probes''' are collections of smaller probes with their own stains that bind to a different section on the chromosome - allowing the full chromosome too be labeled a unique colour, this "full colour map" can be used to know the spectral karyotype- full chromosomal mapping is useful in examining chromosomal abnormalities. <br />
[[File:Fluorescent In Situ Hybridisation (FISH).jpg|thumb|right|'''FISH''' We are able to tag Specific DNA sequences using Probes which have been tagged with fluorescent Labels.This technique enables the clinical diagnosis of chromosomal abnormalities, indicated by sequential duplication, deletions and rearrangements of chromosome <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref>]]<br />
<br />
{|class="wikitable" align="center"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="7" |'''Advantages''' <br />
|-bgcolor="FFFAFA" <br />
| FISH is 99% effective when used in conjunction with Competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities.<ref><pubmed>26338801</pubmed></ref><br />
|-bgcolor="FFFAFA" <br />
| Rapid generation of results<br />
|-bgcolor="FFFAFA"<br />
| Identifies very small translocations and aneuploidies that occur within chromosomes, that would usually be missed under microscopic analysis<br />
|-bgcolor="FFFAFA" <br />
| Indicates whether the accessed chromosomes are normal <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|-bgcolor="FFFAFA" <br />
| Tests for the most common chromosomal abnormalities - down syndrome chromosomes 13,16,18,21 and 22 <ref><pubmed>21749752</pubmed></ref><br />
|-bgcolor="FFFAFA" <br />
| It may be used to compare the chromosomal gene arrangements in related species<br />
|-bgcolor="FFFAFA" <br />
| can be used to identify and remove inheritable X-linked disease or sex chromasome anomalies such as Duchennes Muscular Dystrophy, hemophilia, ectodermal dysplasia <ref><pubmed>17876073</pubmed></ref><br />
|-bgcolor="DDCEF2"<br />
| rowspan="4"|'''Disadvantages'''<br />
|-bgcolor="FFFAFA" <br />
| FISH destroys all cells tested <ref> O'Connor, C. (2008) Fluorescence in situ hybridization (FISH). Nature Education 1(1):171. retrieved from [http://www.nature.com/scitable/topicpage/fluorescence-in-situ-hybridization-fish-327] </ref><br />
|-bgcolor="FFFAFA" <br />
| It does not fully access all chromosomes (only ~ 12)<br />
|-bgcolor="FFFAFA" <br />
| Analysis of results is dependent upon the dot quality impacted by hybridisation efficiency or the camera sensitivity <ref><pubmed>17970921</pubmed></ref><br />
|-bgcolor="FFFAFA" <br />
| some studies indicate that using FISH on a day-3 embryo biopsy decreases the rate of live births <ref><pubmed>26168107</pubmed></ref><br />
|}<br />
<br />
===Array Comparative Genomic Hybridisation (aCGH)===<br />
aCGH also known as Microarray analysis efficiently scans the entire genome for chromosomal imbalances. CGH was initially developed to detect the number of changes in a solid tumor mass. It uses 2 genomes comparing the sample to the control, with each labeled in a different fluorescent dye<ref name="PMID1876176"><pubmed>1876176</pubmed></ref>. Earlier CGH techniques were limited by the resolution of the imaging <ref> Lichter, P., et al. Comparative genomic hybridization: Uses and limitations. Seminars in Hematology 37, 348–357 (2000)</ref> , these initial limitations were overcome by using Microarrays in conjunction with CGh to improve the resolution of the imaging, Array Comparative Genomic Hybridisation (aCGH). This method compares sample and control microarrayed slides containing small segments of DNA (probes). <ref> Lucito, R., et al. Representational oligonucleotide microarray analysis: A high-resolution method to detect genome copy number variation. Genome Research 13, 2291–2305 (2003) </ref> the Probes used will vary according from the small (25-85 base pairs) oligonucleotides manufactured to highlight different target sequences, to the very large genomic clones (80,000- 200,00 base pairs), and as these are significantly smaller than the traditional metaphase chromosomes used for CGH, generating a higher resolution of image. <ref name="PMID22467166"><pubmed>22467166</pubmed></ref>.aCGH is used as a diagnostic tool for prenatal detection f chromosomal abnormalities <ref name="PMID19012303"><pubmed>19012303</pubmed></ref>.<br />
{|<br />
|- align="left" bgcolor="DDCEF2"<br />
|'''Procedure'''<br />
|}<br />
<ref> Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432] </ref><br />
The sample is obtained (skin, blood or fetal cells) and DNA is obtained. <br />
As a part of PGD fetal cell samples are collected from; the fertilized egg polar bodies, the blastomere (day 3 embryo) or the blastocyst/tropoectoderm stage (day 5 embryo).<br />
Sample DNA is labeled with one fluorescent dye, and the control DNA is labeled with a different colored fluorescent dye. the control DNA is used as the base point of reference. <br />
heated and denatured single DNA strands then hybridize to their complementary single strand probes, which are then combined and applied to a microarray and the results are run through a computer program and a digital imaging system is used to quantify the results( fluorescent intensities of the labeled probes). <br />
<br />
[[File:aCGH.jpg|thumb|right|'''aCGH''' checks the entire genome for chromosomal imbalances, by comparing control and a sample slides contatining small segements of DNA sample microarrayed slides small segments of DNA. Illustrated by student z5020317 and adapted from <ref> NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation. retrieved from [http://www.phgfoundation.org/file/5237/]</ref> <ref>Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432]</ref>]]<br />
<br />
The fluorescent ratio and the hybridization signal at different locations on the genome of the control DNA are used to identify any variances present in the sample DNA. aCGH facilitates the clinical diagnosis of submicroscopic chromosomal duplication, deletion and rearrangements indicative of chromosomal disorders such as trisomies 1-22and specific sex linked disorders. <br />
Duplications in the DNA are displayed by the computer program as spikes/ peaks over an established threshold and deletions in DNA are displayed by the computer program as spikes/ toughs beneath this threshold <br />
<br />
{|class="wikitable" align="center"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="12" |'''Advantages''' <br />
|-bgcolor="FFFAFA"<br />
| Multiple applications: prenatal genetic diagnosis, cancer diagnosis, <ref name="PMID20193845"><pubmed>20193845</pubmed></ref> genetic screening for developmental delay (learning disabilities) <ref name="PMID17309648"><pubmed>17309648</pubmed></ref>. or congenital anomalies that are suspected to be genetic in origin <ref>NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation . retrieved from [http://www.phgfoundation.org/file/5237/]</ref><br />
|-bgcolor="FFFAFA"<br />
| trace represents all chromosomes present in the human genome chromosomes 1-22 and the X & Y chromosomes, and therefore is the most accurate method for testing whole embryo aneuploidy<br />
|-bgcolor="FFFAFA"<br />
| aCGH has been extensively tested, and Validated, and is now used world wide.<br />
|-bgcolor="FFFAFA"<br />
| Detects submicroscopic alterations<br />
|-bgcolor="FFFAFA"<br />
| Detects deletions and additions and rearrangements as well as amplification, of the WHOLE genome, simultaneously.<br />
|-bgcolor="FFFAFA"<br />
| Used as a diagnostic tool for prenatal detection of chromosomal abnormalities <ref name="PMID22034057"><pubmed>22034057</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Provides high resolution genomewide screening of segmental genomic copy number variations<br />
|-bgcolor="FFFAFA"<br />
| Very accurate when used in conjunction with FISH<br />
|-bgcolor="FFFAFA"<br />
| Alone is more reliable and in detecting chromosomal abnormalities, with a higher implantation success rate, than FISH <ref name="PMID20494259"><pubmed>20494259</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Allows an in depth research focus upon specific types of rearrangements within selected chromosomal regions, a recent particular area of interest is subtelomeric and pericentromeric rearrangements<br />
|-bgcolor="FFFAFA"<br />
| Reduces the risk of failed implantation and miscarriage, improving the chance of a healthy baby <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|-bgcolor="DDCEF2"<br />
| rowspan="9" |'''Disadvantages'''<br />
|-bgcolor="FFFAFA"<br />
| Translocations and inversions of DNA are not detected<br />
|-bgcolor="FFFAFA"<br />
| Limited ability diagnosing specific polyploidies such as triploidy <ref> Unique, Rare Chromosome Disorder Support Group (2013) Microarray-based Comparative Genomic Hybridiation (array CGH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/other/array%20cgh%20ftnw.pdf] </ref><br />
|-bgcolor="FFFAFA"<br />
| Will not detect mosaicism detection <20% (cultures where >1 of 5 cells are trisomy 12)<br />
|-bgcolor="FFFAFA"<br />
| Will not detect balanced chromosomal rearrangement<br />
|-bgcolor="FFFAFA"<br />
| Will not detect duplications or deletions <80kb<br />
|-bgcolor="FFFAFA"<br />
| Will not detect point mutations within genes <ref>Washington department of education (CGH- FAQ for physicians. Signature Genomic LAboratories, LLC. Retrieved from [https://depts.washington.edu/dbpeds/Lab%20Tests/SignatureCGH-physician_FAQ.pdf]</ref><br />
|-bgcolor="FFFAFA"<br />
| will not detect chromosomal position of genomic gains<br />
|-bgcolor="FFFAFA"<br />
| Will not detect loos of heterozygosity (LOH) or Absence of heterozygosity (AOH) <ref>WiCell Research Institute Inc. (2012) Comparative Genomic Hybridization Microarray. <br />
retrieved from [http://www.wicell.org/home/cytogenetic-services/cgh-microarray/array-comparative-genomic-hybridization-acgh.cmsx]</ref><br />
|}<br />
<br />
===Next Generation Sequencing===<br />
The development and advances within ART in the past 20 years, as well as the increasing popularity of IV, has lead to an influx of new technologies developed to screen embryos for chromosomal anomalies, which are covered by the umbrella term of Next generation Sequencing (NGS). NGS is a general term used to describe all of the new and emerging screening techniques currently being introduced and used as part of PGD for IVF . NGS screens for single gene disorders as well as conducting extensive and very comprehensive chromosome diagnosis by sequencing, counting, and accurately assembling millions of DNA reads, simultaneously. <ref name="PMID23499002"><pubmed>23499002</pubmed></ref> There is a movement for NGS to replace the other limited testing techniques and be used as the standard. <br />
{|<br />
|- align="left" bgcolor="DDCEF2"<br />
|'''Procedure'''<br />
|}<br />
Samples are collected from either blastomere or the blastocyst/tropoectoderm and processed for analysis by a computer system. <br />
The methodology of each process is unique to the technique being used. <br />
<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="14" |'''Advantages''' <br />
|-bgcolor="FFFAFA" <br />
| Cheaper<br />
|-bgcolor="FFFAFA"<br />
| Opens new diagnostic possibilities<br />
|-bgcolor="FFFAFA"<br />
| Accurately tests all 24 chromosomes<br />
|-bgcolor="FFFAFA"<br />
| Tests for the presence of monogenic diseases of known genetic background<br />
|-bgcolor="FFFAFA"<br />
| Reduces the number of biopsies required for diagnosis<br />
|-bgcolor="FFFAFA"<br />
| Higher detection rate of small translocations<br />
|-bgcolor="FFFAFA"<br />
| Highly accurate is testing for compound point mutations, chromosomal duplication, deletions and insertions <ref name="PMID23312231"><pubmed>23312231</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| It accurately detects chromosomal aneuploidy and unbalanced rearrangement <ref name="PMID25685330"><pubmed>25685330</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Higher detection rate of small translocations<br />
|-bgcolor="FFFAFA"<br />
| NGS single gene disorder screenings can conducted in conjunction with PCR comprehensive chromosomal screening<br />
|-bgcolor="FFFAFA"<br />
| Reduces human error <br />
|-bgcolor="FFFAFA"<br />
| Better detects the presence of mosaicism<br />
|-bgcolor="FFFAFA"<br />
| Work well in conjunction with CGH and aCGH as part of PGD, improving the chances of IVF. <ref> Morris, R. S. (2015 ) Next generation sequencing for PCG|PGS|CCS. IVF1 retrieved from [http://www.ivf1.com/next-generation-sequencing for-pgd] </ref><br />
|-bgcolor="DDCEF2"<br />
| rowspan "2" |'''Disadvantages''' <br />
|-bgcolor="FFFAFA"<br />
| There are limited information available to clinical applications of NGS <ref><pubmed>26100406</pubmed></ref><br />
|}<br />
<br />
==Diagnosis==<br />
There are a large amount of diseases that PGD can apply to, below are descriptions of the diseases that PGD are more commonly used for. Upon completion of the genetic testing for the genes of concern the cells the embryos are discarded and priority is given to those that are healthy. <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/><br />
===Cystic Fibrosis===<br />
Cystic fibrosis is a single gene disorder. It is autosomal recessive and involves mutations in the cystic fibrosis transmembrane conductance regulator (CTFR) gene. The CTFR gene is normally responsible for the decrease in chloride and the transport of bicarbonate in epithelial cells thus playing a major physiological role. In PGD procedures, identification of the gene is assisted by microsatellite markers that have similar composition to the CTFR gene itself. Biopsy of two cells at the blastocyst stage is recommended if markers are not available. There are many variations of cystic fibrosis the most common being P.Phe508del <ref name="PMID26014425"><pubmed>26014425</pubmed></ref>.<br />
===Duchenne Muscular Dystrophy ===<br />
Duchenne Muscular Dystrophy is an X-linked recessive disease. It involves the Xp21 gene where majority of the mutations are chromosomal deletions with a smaller percentage resulting from duplications <ref name="PMID18359022"><pubmed>18359022</pubmed></ref>.<br />
<br />
===Autosomal Recessive Meckel-Gruber Syndrome===<br />
Autosomal recessive genetic defect caused by the TMEM67 gene. It results in cystic dysplasia of the kidneys with fibrotic change in the liber and occipital encephalocele. Other malformations could also be present in the central nervous system. In PGD whole genome amplification of single blastomeres are taken to identify the gene, this is also coupled with PCR techniques. Maternal plasma can also be extracted for PGS. <ref><pubmed>24039893</pubmed></ref> <br />
===β – Thalassemia=== <br />
β – Thalassemia is known as the most common type of autosomal recessive inherited disorder among haemoglobinopathies. It involves the adult β-globin gene and is associated with the absent or decreased expression of the gene. This is commonly caused by a single nucleotide change in the gene. PGD has been used successfully worldwide to identify the β-globin gene where its application is usually performed on a single blastomere or polar body <ref name="PMID19064120">19064120</pubmed></ref>.<br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
! Applicable diseases for PGD <ref>Genoma Group (2014). Retrieved September 18th, 2015, from http://www.preimplantationgeneticdiagnosis.it/genetic-diseases-diagnosed-by-pgd.htm </ref>, <ref>Genesis Genetics (2015). Retrieved September 18th, 2015, from http://genesisgenetics.org/pgd/what-we-test-for/</ref>, <ref>Human Fertilisation & Embryology Authority (2015). Retrieved Septembr 18th, 2015, from http://guide.hfea.gov.uk/pgd/</ref><br />
|-<br />
| '''Disease'''<br />
| '''Involved Genes'''<br />
|-<br />
| 5 Alpha Reductase Deficiency (5ARD)<br />
| SRD5A2 <br />
|-<br />
| Achondroplasia<br />
|FGFR3 <br />
|-<br />
| Acute Intermittent Porphyria <br />
| ALAD, ALAS2, CPOX, FECH, HMBS, PPOX, UROD, or UROS<br />
|-<br />
| Adrenoleukodystrophy (Adrenomyeloneuropathy)<br />
| ABCD1 <br />
|-<br />
| Agammaglobulinaemia (x-linked) <br />
|BTK <br />
|-<br />
| Agammaglobulinemia Bruton Tyrosine Kinase (BTK) <br />
|BTK <br />
|-<br />
| Aicardi Goutieres Syndrome 1 (AGS1) <br />
|TREX1, RNASEH2A, RNASEH2B, RNASEH2C, SAMHD1<br />
|-<br />
| Alagille Syndrome<br />
|JAG1 or NOTCH2<br />
|- <br />
| Alpers-Huttenlocher Syndrome <br />
|POLG <br />
|-<br />
| Alpha-1-antitrypsin deficiency <br />
|SERPINA1 <br />
|-<br />
| Alpha-Mannosidosis<br />
| MAN2B1 <br />
|-<br />
| Alpha Thalassemia <br />
|HBA1 or HBA2 <br />
|-<br />
| Alports Syndrome<br />
|COL4A3, COL4A4, COL4A5<br />
|-<br />
| Alzheimer's Disease - early onset (Type 3 and 4) <br />
|APP, PSEN1, or PSEN2<br />
|-<br />
| Amyotrophic Lateral Sclerosis 1 (ALS1) <br />
|C9orf72, SOD1, TARDBP, FUS, ANG, ALS2, SETX, VAPB <br />
|-<br />
| Argininosuccinic Aciduria <br />
| ASL<br />
|-<br />
| Arrhythmogenic Right Ventricular Cardiomyopathy/ Dysplasia (ARVC/D)<br />
| DSG2; DSP; PKP2<br />
|-<br />
| Ataxia Telangiectasia<br />
| ATM<br />
|-<br />
| Autosomal Recessive Meckel-Gruber Syndrome<br />
| TMEM67<br />
|-<br />
| Bardet-Biedl Syndrome (BBS)<br />
| BBS1; BBS10<br />
|-<br />
| Barth Syndrome<br />
| TAZ<br />
|-<br />
| Beta Thalassaemia<br />
| HBB<br />
|-<br />
| Birt-Hogg-Dubé Syndrome<br />
| FLCN<br />
|-<br />
| Breast Ovarian Cancer Familial Susceptibility (BRCA2)<br />
| BRCA1; BRCA2<br />
|-<br />
| Canavan Disease <br />
| ASPA<br />
|-<br />
| Carnitine-Acylcarnitine Translocase Deficiency <br />
| SLC25A20<br />
|-<br />
| Cerebral Arteriopathy with Subcortical Infarcts & Leukoencephalopathy (CADASIL)<br />
| NOTCH3<br />
|-<br />
| Cerebral Cavernous Malformation<br />
| CCM1<br />
|-<br />
| Charcot-Marie-Tooth Disease<br />
| GJB1; MPZ; NEFL; PMP22<br />
|-<br />
| CHARGE Syndrome<br />
| CHD7<br />
|-<br />
| Cherubism<br />
| SH3BP2<br />
|-<br />
| Choroideremia<br />
| CHM<br />
|-<br />
| Chronic Granulomatous Disease<br />
| CYBB; NCF1<br />
|-<br />
| Ciliary Dyskinesia<br />
| DNAH5<br />
|-<br />
| Citrullinemia<br />
| ASS1<br />
|-<br />
| Cleidocranial Dysplasia<br />
| RUNX2<br />
|-<br />
| Cockayne Syndrome<br />
| ERCC6<br />
|-<br />
| Congenital Adrenal Hyperplasia<br />
| CYP21A2<br />
|-<br />
| Congenital Cataracts<br />
| GJA8; VSX2<br />
|-<br />
| Congenital Diarrhea, Syndromic<br />
| SPINT2<br />
|-<br />
| Congenital Disorders of Glycosylation (CDG)<br />
| ALG1; ALG6; CDG1C; DOLK; PMM2<br />
|-<br />
| Cornelia de Lange Syndrome <br />
| NIPBL<br />
|-<br />
| Craniosynostosis<br />
| TWIST1<br />
|-<br />
| Crouzon Syndrome<br />
| FGFR2<br />
|-<br />
| Cysteinyl Leukotriene Receptor 1 Deficiency <br />
| CYSLTR1<br />
|-<br />
| Cystic Fibrosis<br />
| CFTR<br />
|-<br />
| Diamond –Blackfan Anemia <br />
| RPS19<br />
|-<br />
| Duchenne Muscular Dystrophy <br />
| DMD<br />
|-<br />
| Dyskeratosis congenita (Male embryos only)<br />
| DKC1<br />
|-<br />
| Ectodermal dysplasia (Hypohidrotic)<br />
| EDA; EDA1; GJB6; IKBKG<br />
|-<br />
| Familial Adenomatous polyposis coli (FAP)<br />
| APC<br />
|-<br />
| Familial Dysautonomia<br />
| IKBKAP<br />
|-<br />
| Fanconi Anemia <br />
| FANCA; FANCC; FANCD2; FANCF; FANCG; FANCJ<br />
|-<br />
| Fragile X Syndrome (FRAX)<br />
| FMR1<br />
|-<br />
| Galactosemia <br />
| GALT<br />
|-<br />
| Gangliosidosis<br />
| GLB1<br />
|-<br />
| Glanzmann Thrombasthenia <br />
| ITGA2B<br />
|-<br />
| Glutaric Acidemia (aciduria)<br />
| GCDH <br />
|-<br />
| Glycogen Storage Disease <br />
| G6PC; GAA; SLC37A4<br />
|-<br />
| Haemophilia A<br />
| F8<br />
|-<br />
| Haemophilia B<br />
| F9<br />
|-<br />
| Hereditary Nonpolyposis Colorectal Cancer: Lynch Syndrome<br />
| MLH1; MSH2; MSH6<br />
|-<br />
| Holt Oram Syndrome<br />
| TBX5<br />
|-<br />
| Huntington Disease<br />
| HD<br />
|-<br />
| Hydrocephalus<br />
| L1CAM<br />
|-<br />
| Ichthyosis <br />
| ABCA12; STS<br />
|-<br />
| Incontinentia Pigmenti (IP)<br />
| NEMO<br />
|-<br />
| Joubert Syndrome 5<br />
| INPP5E<br />
|-<br />
| Krabbe Disease<br />
| GALC<br />
|-<br />
| Leber Congenital Amaurosis (LCA)<br />
| CEP290; GUCY2D<br />
|-<br />
| Leigh Syndrome (Infantile Subacute Necrotising Encephalopathy)<br />
| LRPPRC<br />
|-<br />
| Lesch Nyan Syndrome<br />
| HPRT1<br />
|-<br />
| Leukocyte Adhesion Deficiency (Type I)<br />
| ITGB2<br />
|-<br />
| Li-Fraumeni Syndrome<br />
| TP53<br />
|-<br />
| Macular Dystrophy Retinal <br />
| VMD2<br />
|-<br />
| Maple Syrup Urine Disorder (MSUD)<br />
| BCKDHB<br />
|-<br />
| Marfan Syndrome <br />
| FBN1<br />
|-<br />
| Menkes Syndrome<br />
| ATP7A<br />
|-<br />
| Mitochondrial DNA Depletion Syndrom <br />
| POLG; RRM2B; SUCLA2; TK2<br />
|-<br />
| Mucolipidosis type II<br />
| GNPTAB<br />
|-<br />
| Multiple Endocrine Neoplasia<br />
| MEN1; MEN2A; MEN2B<br />
|-<br />
| Multiple Exostoses<br />
| EXT1; EXT2 <br />
|-<br />
| Myotubular myopathy<br />
| MTM1 <br />
|-<br />
| Nail-Patella Syndrome<br />
| LMX1B<br />
|-<br />
| Neurofibromatosis Type 1<br />
| NF1<br />
|-<br />
| Neurofibromatosis Type 2 <br />
| NF2<br />
|-<br />
| Noonan Syndrome<br />
| KRAS, PTPN11; SOS1<br />
|-<br />
| Norrie Disease<br />
| NDP<br />
|-<br />
| Ocular Albinism <br />
| GPR143<br />
|-<br />
| Oculocutaneous Albinism <br />
| OCA2; TYR <br />
|-<br />
| Oculodentaldigital Dysplasia<br />
| GJA1<br />
|-<br />
| Optic Atrophy<br />
| OPA1<br />
|-<br />
| Ornithine Transcarbamylase Deficiency <br />
| OTC<br />
|-<br />
| Osteogenesis imperfeca <br />
| COL1A1; COL1A2<br />
|-<br />
| Osteopetrosis <br />
| CLCN7; OSTM1; TCIRG1<br />
|-<br />
| Pachyonychia Congenita <br />
| KRT16; KRT6A<br />
|-<br />
| Pancreatitis, Hereditary<br />
| PRSS1 <br />
|-<br />
| Papillorenal syndrome <br />
| PAX2<br />
|-<br />
| Phenylketonuria <br />
| PAH <br />
|-<br />
| This table does not cover the complete list of diseases that PGD can be applied to.<br />
|}<br />
<br />
==Laws & Legal status==<br />
<br />
{| class="wikitable" <br />
|-bgcolor="DDCEF2"<br />
|'''Country'''<br />
|'''Legislation'''<br />
|-bgcolor="FFFAFA" <br />
| Australia<br />
| PGD is currently used to detect serious genetic conditions to improve the outcome of Assisted Reproductive Technologies (ART). In very rare cases it may be used to select an embryo with compatible tissue for a sibling who has a life-threatening disease where other means of treatment is unavailable. This is with the conditions that the use of PGD will not affect the welfare and interests of the child to be born. The parents must also receive adequate counselling and have full understanding of the procedures of PGD. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"> National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art</ref><br />
The use of PGD for sex-selection is prohibited with the exception of reducing the risk of the transmission of serious sex-linked genetic conditions. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"/><br />
|-bgcolor="FFFAFA"<br />
| Brazil<br />
| The laws regarding PGD in Brazil are not strictly regulated. They are vague and there is limited information surround the activities of assisted reproduction in general in the country <ref name="PMID25493379"><pubmed>25493379</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| Czech Republic<br />
| The laws in the Czech Republic allow those with a “defined indication in order to exclude risk of serous genetically conditioned disease and defects with embryos before they are implanted into the cavity of the uterus”. Couples that undergo any assisted reproductive treatment including PGD have to be married. Sex-selection is illegal except in regards to serious sex-linked genetic diseases <ref name="PMID24777348"><pubmed>24777348</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| Greece<br />
| In Greece, ART is open to those up to the age of 50 with written consent. It can only be used if a medical necessity is present such as the susceptibility of serious hereditary diseases. Sex selection is banned apart from cases of sex-linked diseases and sexually transmitted diseases <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| India<br />
| In India there is a cultural preference for boys thus the Prenatal Diagnostic Techniques (Regulation and Prevention of Misuse) Act was introduced in 1994. This law limits the use of PGD for sex determination except in cases of specific congenital diseases. These laws however are not strictly enforced. <ref>World Health Organisation (2015) Gender and Genetics Retrieved on October 21st 2015 from:http://www.who.int/genomics/gender/en/index4.html</ref><br />
|-bgcolor="FFFAFA"<br />
| Portugal <br />
| ART is only available to those who are married or have a similar type of relationship for at least two years. The couples cannot be of the same sex and must be at least 18 years of age. Sex selection is illegal except in cases of sex-linked diseases. The use of PGD is illegal if the predictive value of genetic tests are very low <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| Spain<br />
| PGD can be applied to “serious hereditary diseases not amenable to postnatal curative treatment” and “detection of other abnormalities which may compromise the viability of the pre-embryo”. If PGD is to be used for any other purpose authorisation must be acquired <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| Sweden <br />
| The use of PGD is strictly regulated and couples must achieve authorisation of the National Board of Health and Welfare. It can only be used it can only be used if the child is at risk to inheriting a serious chromosomal or monogenetic disease. It cannot be used for selection of specific characteristics <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| United Kingdom<br />
| Those involved with carrying out the IVF treatment must have a license from the Human Fertilisation and Embryology Authority (HFEA). Only embryos that are approved by the HFEA can be implanted where the embryonic nuclear or mitochondrial DNA cannot be altered with the exception of preventing mitochondrial diseases <ref name="PMID24777348"/>. <br />
|}<br />
<br />
==Future/Current Research==<br />
===Noninvasive Preimplantation Genetic Testing without Embryo Biopsy===<br />
Different parameters of gametes, zygotes, embryos (“vacuoles in sperm heads, spindle position in mature oocytes, cleavage intervals of zygote, and embryo developmental dynamics”) may correlate with aneuploidy rates. This knowledge may be applied in potential noninvasive preimplantation diagnostic methods. Several methods have been proposed and are currently further researched<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Sperm Selection====<br />
Intracytoplasmic morphologically selected sperm injection (IMSI) is common procedure in IVF treatment to improve fertilization rates in patients with poor semen quality. In addition, studies have found that IMSI improves embryo development and that spermatozoa with large vacuoles in their heads correlate with increased aneuploidy rates and disturbed chromosomal structures. Thus, selecting spermatozoa based on morphological hallmarks may decrease aneuploidy rates in the fertilized embryos. As with polar body biopsies, however, this approach will solely be applicable if evidence for severe male detrimental contribution is given<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Blastocoel Fluid Extraction====<br />
In addition, a less invasive retrieval of material for diagnosis could include the extraction of the blastocoel fluid. The cavity of the blastocyst, lined by the trophectoderm, is filled with this blastocoel fluid, which contains metabolites of both trophectoderm and inner cell mass origin. The retrieval does not require a biopsy but merely a small opening to extract the fluid and, thus, causes less harm to the embryo. Multiple studies have applied this method<ref name="PMID22020776"><pubmed>22020776</pubmed></ref> <ref name="PMID23148560"><pubmed>23148560</pubmed></ref> and it may in the future become of clinical relevance.<br />
<br />
<br />
[[File:Aspiration_of_the_Blastocoel_Fluid.jpeg|thumb|Aspiration of the Blastocoel Fluid using a ICSI pipette<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.]]<br />
<br />
<br />
Next to metabolites, the blastocoel fluid can contain DNA. Studies have shown that genomic DNA is present in about 90% of the blastocoel fluid samples tested. Typically the fluid is removed with an ICSI pipette from a day five blastocyst through its mural trophectoderm until the blastocyst fully collapses around the embryo. Several concerns regarding this method in a clinical setting have been raised. The collected DNA may be contaminated by the culture media that contains DNA fractions. The DNA may also be least representative of the actual embryos genome as the DNA may originate from abnormal or degenerated cells. Even though labelled noninvasive, the blastocyst still undergoes manipulation to some degree which may affect its viability. Thus, more research is required until this method can evolve from research to clinical use<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
====Proteomics====<br />
The protein secretome of blastocysts may be representative of its chromosome constitution Recent studies have found biomarkers such as lipocalin-1, interleukin-10, tumor necrosis factor, stem cell factor, and chemokine ligand 13 to be differently secreted by aneuploid blastocyst than by euploid ones. The most significant biomarker appears to be interleukin-10. Paired with novel proteomic technologies and mass spectrometry this knowledge when extended may contribute to a new invasive PGD method<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Embryo Morphology====<br />
Using time lapse imaging the embryo’s morphology can be closely observed and potential aneuploidy characteristics detected. Such characteristics may include the time of division to five cells, the time between the division from three to four cells, and the duration of the division from one to two and subsequently to three. In addition, the morphological quality of ICM an TE has been positively associated with aneuploidy or euploidy prognosis<ref name="PMID26246880"><pubmed>26246880</pubmed></ref>. These may give rise to an embryo quality screening prior to implantation<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
==Glossary==<br />
'''CTFR''' Cystic Fibrosis Transmembrane Conductance Regulator <br />
<br />
'''ESHRE'''The European Society for Human Reproduction and Embryology<br />
<br />
'''FISH''' Fluorescence in situ hybridisation<br />
<br />
'''ICSI''' Intracytoplasmic Sperm Injection<br />
<br />
'''IMSI''' Intracytoplasmic Morphologically Selected Sperm Injection<br />
<br />
'''NGS''' Next Generation Sequencing <br />
<br />
'''PB''' Polar Body<br />
<br />
'''PGD''' Preimplantation Genetic Diagnosis <br />
<br />
'''PGS''' Preimplantation Genetic Screening<br />
<br />
'''PCR''' Polymerase Chain Reaction<br />
<br />
'''RT''' Robertsonian translocations<br />
<br />
''SNP''' Single Nucleotide Polymorphism <br />
==References==<br />
<br />
<references/><br />
<br />
<br />
{{StudentPage2015}}</div>Z5017878https://embryology.med.unsw.edu.au/embryology/index.php?title=2015_Group_Project_6&diff=2071732015 Group Project 62015-10-22T03:44:24Z<p>Z5017878: </p>
<hr />
<div>{{ANAT2341Project2015header}}<br />
<br />
<br />
=Preimplantation Genetic Diagnosis and Preimplantation Genetic Screening=<br />
==Introduction==<br />
Preimplantation genetic diagnosis (PGD) and preimplantation genetic screening (PGS) are reproductive options for couples with known family histories of genetic disease or couples undergoing IVF procedures due to infertility issues. PGD can diagnose many genetic disorders caused by known chromosomal abnormalities (number and/or structure) or single gene mutations, and, thus decrease the risk of termination of pregnancy or miscarriages and enable such couples to have an unaffected child<ref name="PMID24907939"><pubmed>24907939</pubmed></ref>. Through major improvements in PGD/S and general laboratory technology, the testing for abnormalities in fetuses has shifted from prenatal diagnosis during the first 2 trimesters <ref> Blackburn, S.L. (2003) '''Maternal, Fetal & Neonatal physiology: a Clinical perspective''' (2nd ed.). Seattle: Saudners </ref>, testing for overall fetal growth, complications of pregnancy, and birth defects<ref> Sadler T.W.(2012) '''Langman's Medical Embryology''' (12th ed.) Philadelphia: Lipincott, Wiliams & Wilkins, a Wolters Kluwer Business </ref>, to an embryonic focus especially in advancements in Artificial Reproductive Technologies (ART)<ref><pubmed>20638568</pubmed></ref>. In 1990 PGD for a recessive X-linked disease resulted in the first live birth<ref><pubmed>2330030</pubmed></ref> and has since been incorporated in clinical routine and applied for a variety of genetic diseases, such as sickle cell anemia, thalassemia, or cystic fibrosis<ref name="PMID24907939"/>.<br />
[[File:Preimplantation Genetic Diagnosis Procedure.jpeg|600px|left|thumb| Simplified steps for PGD<ref name="PMID24907939"/>]]<br />
{|class="wikitable"align="right" <br />
| <html5media height="400" width="533">https://www.youtube.com/watch?v=0e-79qKllqk</html5media><br />
|-<br />
| Preimplantation Genetic Diagnosis<ref>IVF Florida (2011, December 11) IVF Florida - South Florida Fertility Specialists - Pre-Implantation Genetic Diagnosis [Video file]. Retrieved from https://www.youtube.com/watch?v=0e-79qKllqk</ref><br />
|}<br />
<br />
==History==<br />
The advances in reproductive technology during the second half of the 20th century, led to PGD's first clinical application in 1990 <ref>Harper, J. (n.d.). The history of PGD. Lecture. UCL Centre for PG&D and CRGH.University College London</ref>.<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
|Year<br />
|<br />
|- bgcolor="FFFAFA"<br />
| '''1967''' <br />
|First PGD on rabbit blastocysts (Gardner& Edwards) <ref name="PMID6036172"><pubmed>6036172</pubmed></ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1986''' <br />
|First Cleavage Biopsy (Wilton & Trounson)<ref>Wilton, L. J., & Trounson, A. O. (1986). Viability of mouse embryos and blastomeres following biopsy of a single cell. In Proceedings of the 18th Annual Conference of the Australian Society for Reproductive Biology, Brisbane, Australia.</ref><br />
|- bgcolor="FFFAFA"<br />
|'''1987''' <br />
|First Blastocyst Biopsy (Muggleton-Harris, Monk, Rawlings, & Whittingham)<ref name="PMID3372699"><pubmed>3372699</pubmed></ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1988''' <br />
|First Polar Body Biopsy (Yury Verlinksy)<ref> Verlinsky, Y., Pergament, E., Andresen, P., Enriquez, G., & Strom, C. (1989). Genetic analysis of polar body DNA: A new approach to preimplantation genetic diagnosis. Am J Hum Genet, 45(4), A272.</ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1990''' <br />
|First Clinical PGD using PCR testing for X-linked (Handyside, Kontogianni, Hardy, & Winston)<ref name="PMID2330030"><pubmed>2330030</pubmed></ref> <br />
|} <br />
==Preimplantation Genetic Diagnosis==<br />
PGD is used to test the genetic makeup of embryos to detect single gene disorders, chromosomal abnormalities and mitochondrial disorders. It also has applications in gender selection for diseases with unequal gender distributions <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Some diseases commonly involved with PGD include cystic fibrosis, spinal muscular atrophy and beta – thalassaemia <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press.">Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press</ref> <ref name="PMID17823145"><pubmed>17823145</pubmed></ref>. It was first used in the United Kingdom in the 1980s of arenoleucodystrophy and primarily focusing on sex- linked disorders <ref name="PMID17823145"/><ref name="PMID23150080"><pubmed>23150080</pubmed></ref>. PGD is now capable of detecting single cell defects (molecular) and chromosomal disorders resulting from the inversion, translocation or deletion of chromosomes (cytogenic) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>,<ref name="PMID11325751"><pubmed>11325751</pubmed></ref>. PGD can be applied to the embryo at different stages. That is on polar bodies, blastomeres or blastocyst <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>.<br />
Depending on the type of genetic disorder, PGD utilises different methods of genetic testing. These include Fluorescence in situ hybridisation (FISH) which is used for sex – linked disorders and detects chromosomal rearrangements <ref name="PMID11325751"/><ref name="PMID17876073"><pubmed>17876073</pubmed></ref> and Embryo halotyping which allows the identification of chromosomes causing the inherited disorder through knowledge of the pattern of closely linked markers <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. Polymerase chain reaction (PCR) is also widely used to detect molecular abnormalities <ref name="PMID11325751"/>.<br />
PGD is tightly regulated and supported by large organisations namely The American Society for Reproductive Medicine, The European Society for Human Reproduction and Embryology (ESHRE), The European Society of Human Genetics and the Preimplantation Genetic Diagnosis International Society <ref name="PMID25500181><pubmed>25500181</pubmed></ref>.<br />
===Sex-linked disorders===<br />
The determination of a disease as gender specific usually correlates with the presence or absence of specific genes such as SRY on the Y chromosome. It is known that females have two X chromosomes and males have an X and a Y chromosome where abnormalities are more prevalent on the X chromosome. PGD can be used for sex selection where only male embryos are transferred to reduce the chance of inheriting X-linked disorders. However, this does not completely eradicate the problem as male embryos remain susceptible to inheriting an affected X chromosome. Sex determination is only used when the specific mutation is unknown and has yet to be discovered <ref name="PMID24866878"><pubmed>24866878</pubmed></ref>.<br />
===Single gene defects===<br />
Single gene defects can be dominant, recessive, autosomal or X-linked. They are commonly diagnosed using PCR and although the PCR available today is complex and capable of combatting a large range of disease the development of new protocols has been proven to be difficult due to the small DNA sample available <ref name="PMID26168107"><pubmed>26168107</pubmed></ref><br />
===Mitochondrial disorders===<br />
Mitochondrial disorders also known as oxidative phosphorylation disorders arise from mutations in the nuclear DNA or mitochondrial DNA <ref name="PMID26312584"><pubmed>26312584</pubmed></ref>. They pose as a problem because they are unrecognisable until the mutations in the cell reach a detrimental level <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Mitochondrial disorders cause miscarriages and stillbirths as well as death in children and young adults. The effects can either be contained in a single organ or more commonly involve multiple organ failure where organs with high energy demands such as the brain, liver muscle and heart and heavily influenced. They are usually occur spontaneously or result from inheritance from the mother. Since mitochondria are solely inherited from the mother oocyte donations have been used as a solution to combat mitochondrial disorders. Additionally, there has been an increasing use in PGD where embryos that stay under the given threshold of 18% gene-mutations are allowed to be transferred and result in normal development. New technology in the areas of nuclear gene transfer and genome editing are also being experimented with <ref name="PMID26312584"/>. <br />
===Chromosomal disorders===<br />
Chromosomal disorders can be reciprocal, Robertsonian translocations, inversions, deletions and insertions <ref name="PMID26168107"/>. . Data from ESHRE collected between 2010 and 2011 has shown that the most common chromosomal abnormality confronted in PGD are reciprocal chromosomal abnormalities <ref name"PMID26071418"><pubmed>26071418</pubmed></ref>. PGD has also been used successfully for Robertsonian translocations (RT), a type of structural translocation. Children who carry RT are phenotypically normal, however in their later years it is found that they will suffer from infertility and repeated miscarriages due to the high frequency of abnormal embryos <ref name="PMID22081077"><pubmed>22081077</pubmed></ref>. PCR and FISH are the two main techniques used for chromosomal disorders. To be able to conduct the examinations the cells are required to be at the metaphase stage <ref name="PMID26168107"/>. <br />
[[File:Reasons_for_PGD.jpg|600px|thumb|Reasons for PGD<ref name= "PMID24764761"><pubmed><24764761</pubmed></ref>]]<br />
==Preimplantation Genetic Screening==<br />
PGS involves an array of methods or ideas that aim to segregate embryos that have genetic flaws and those that are healthy <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. The occurrence of aneuploidy is high around the stages of early embryonic development and they are the most common cause if miscarriages and congenital birth defects <ref name= "PMID26085841"><pubmed>26085841</pubmed></ref>. They have little effect on the morphology of the embryo making them difficult to identify thus identification heavily relies on genetic testing <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. <br />
Genetic sampling is most commonly conducted using Microarray Comparative Genomic Hybridisation (aCGH) as well as FISH, Quantitative PCR and Single Nucleotide Polymorphism (SNP) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. These methods collectively aim to assess numeral and structural chromosomal errors <ref name= "PMID26085841"/>. Studies have also introduced Next- Generation Sequencing (NGS) <ref name= "PMID26085841"/> and Whole Genome Amplification used to screen imbalances in the complete 24-chromosomes <ref name="PMID25953353"><pubmed>25953353</pubmed></ref><br />
Statistics from ESHRE have shown that the most common indications for PGS is advanced age, followed by repeated implantation failure or recurrent miscarriage and male infertility <ref name="PMID26071418"><pubmed>26071418</pubmed></ref>.<br />
===Indications===<br />
A low percentage of structural abnormalities in chromosomes are responsible for the cause of miscarriages. Despite this, they are the most prevalent type of chromosomal abnormality accounted for in PGD <ref name="PMID20638568"/>. The presence of specific gene cycles, initiation of embryonic protein synthesis and evident physiological development are all indicative of a successful in vitro fertilisation procedure <ref name="PMID11576737"><pubmed>11576737</pubmed></ref>. To eliminate further errors from occurring during the PGD procedure it is recommended to undertake further prenatal testing such as amniocentesis in the later stages <ref name="PMID20638568"/>. <br />
====Advanced maternal age====<br />
Data provided by the ESHRE has shown that the mean age of women undergoing PGS is 39 years <ref name="PMID26071418"/>. Women of advanced age have been shown to have a lower rate of pregnancies reaching childbirth <ref name="PMID18583331"><pubmed>18583331</pubmed></ref>. The highlighted concern revolves around the increased occurrence of aneuploidy following maternal age. The optimal age range for the lowest aneuploidy incidence was found to be between 27 to 37 years of age (6%) then progressively higher in women aged up to 42 (33%) and most common in those 44 and above (53%) <ref name="PMID24355045"><pubmed>24355045</pubmed></ref>. <br />
====Recurrent pregnancy loss / IVF failure====<br />
Recurrent pregnancy loss is defined as three or more IVF failures after cumulative transfer of more than 10 good-quality embryos. These are primarily caused by two main factors, reduced endometrium receptivity or embryonic defects. Endometrium receptivity can be negatively influences by instances including uterine pathologies such as thin endometrium, altered expression of adhesive molecules and immunological factors. Additionally, embryonic defects may be due to genetic abnormalities, embryonic aneuploidy or zona hardening. Endometriosis and hydrosalpinx has been known to effect both the endometrium and embryo <ref name="PMID23260857"><pubmed>23260857</pubmed></ref>.<br />
====Human leukocyte antigen matching====<br />
First used in 2001, HLA matching is an option given to parents to save a child with haematological or immunological disease through conceiving another child who would potentially be able to donate cord blood or haematopoietic stem cells from the bone marrow for transplantation. The process namely PGD-HLA has shown to improve haematopoietic stem cell transplant (HSCT). PGD-HLA can only be performed when HSCT is not needed urgently due to the time needed to conceive and delivery the baby <ref name="PMID25500181"><pubmed>25500181</pubmed></ref>. It is most commonly applied to children suffering from relapsed leukaemia <ref name="PMID22524201"><pubmed>22524201</pubmed></ref>. In a case study PGD-HLA was proven to successfully cure 10 diseases including Fanconi anaemia, Diamond-Blackfan anaemia and beta thalassemia <ref name="PMID25066893><pubmed>25066893</pubmed></ref>.<br />
==Biopsy Methods==<br />
Biopsy, the removal of genetic materials, from oocytes or embryos in the preimplantation stage is the primary step in PGD. For the past two decades these biopsies have been performed at three stages, the polar body, blastomere, and blastocyst, and the methodologies optimized to ensure the embryo’s viability. The most common approach involves biopsies at the cleavage stage. However, polar body and blastocyst biopsies are increasingly more often tested and applied. Approached for opening the zona pellucida involve next to the traditional mechanical and chemical means, novel approaches such as noncontact lasers. Their application may simplify and secure the procedure significantly. The most challenging question about PGD procedures remains at what stage biopsies should be taken. Much controversy has developed around this topic, highlighting the varying disadvantages and advantages of temporal biopsies. <ref name="PMID22723007"><pubmed>22723007</pubmed></ref><br />
<br />
[[File:Polar_Body,_Blastomere,_and_Trophectoderm_Biopsy.jpeg|thumb|Polar body (A), blastomere (B) and trophectoderm (C) biopsies<ref name="PMID25625041"><pubmed>25625041</pubmed></ref>.]]<br />
{| class="wikitable"<br />
|- align="center" bgcolor="DDCEF2"<br />
|<br />
| Time of Biopsy<br />
| Advantages <br />
| Disadvantages<br />
|- bgcolor="FFFAFA"<br />
| Polar Body<br />
| Day 1<br />
| No harm to oocyte<br />
| Only maternal DNA is tested, often needs to be coupled with other biopsies, and there are difficulties distinguishing between the first and second PB.<br />
|- bgcolor="FFFAFA"<br />
| Blastomere<br />
| Day 3<br />
| …<br />
| … <br />
|- bgcolor="FFFAFA"<br />
| Trophectoderm<br />
| Day 5 and 6 <br />
| Little harm to the embryo and large amount of genetic material is extracted. <br />
| Opening of blastocyst necessary, small time window for procedure<br />
|}<br />
===Polar Body Analysis===<br />
Day 1<br />
====Description====<br />
Polar body (PB) biopsy offers a promising alternative to biopsies performed at the blastomere stage for PGD/S indications on legal and practical grounds. Consequent embryo development does not necessitate the presence of the first and second PB and their removal may not be crucial. PB biopsy requires precise timing. Keeping track of the meiotic cell cycle is necessary to perform a successful biopsy and, therefore, PB biopsy usually is applied in combination with intracytoplasmic sperm injection (ICSI). During the maturation from the germinal vesicle stage to the metaphase-II stage the first PB is formed. A cytoplasmic bridge containing spindle remnants, that are still in contact with the cellular genetic material, links this PB to the oolemma for about 90 minutes after extrusion. It is possible to visualize these remnants by polarization microscopy and it is crucial to not perform the biopsy until the first PB is no longer firmly attached to the oolemma as this indicates an immature embryo.The oocyte tolerates mechanical zona dissection best during hours four until six after ICSI as the oolemma has stabilized by that time because of the cortical granule reaction. Over time the first PB degenerates stressing a temporal biopsy and its optimal extraction time window is four to 12 hours after ICSI. The second PB forms around two to four hours after ICSI. Its optimal time window for biopsy is set to be eight to 16 hours after ICSI due to the second PB being attached to the oolemma with spindle remnants until six hours after ICSI. Biopsy at this point may cause enucleation of the oocyte. Studies have shown that the amplification efficiency of second PB’s DNA is worse if the PB is extracted prior to eight hours after ICSI. Thus, it is possible to perform sequential and simultaneous biopsies for the first and second PB. If performed, sequentially the first PB may be removed four to 12 hours and the second PB eight to 16 hours after ICSI. The optimal time window for a biopsy for both the first and second PB simultaneously is eight to 12 hours after ICSI. It is highly preferred to analyze both PBs due to potential aneuploidies in either PB and crossing overs during meiosis<ref name="PMID22723007"/>. <br />
====Procedure====<br />
Chemical opening achieved with for example acidic tyrode’s solution of the zona pellucida is not tolerated by the oocyte and may have detrimental effects on the embryo’s development. Therefore, the access to the perivitelline space of the oocyte is provided by mechanical zona dissection or by laser. Both techniques work well if performed by experienced embryologist. However, laser-assisted biopsy is less time consuming when compared to manual dissection. It is critical to consider the size of the introduced opening as it will remain permanent. If it is too large the blastomere may be lost during embryo development and if it is too small it may interfere with hatching of the embryo during blastocyst stage<ref name="PMID22723007"/>.<br />
[[File:Polar_Body_Biopsy.jpeg|left|thumb|The presence of a faint but clearly identifiable strand connecting PB2 to the oolemma. The biopsy was performed ∼9 h after ICSI<ref name="PMID21908464"><pubmed>21908464</pubmed></ref>.]]<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JTaQzszVr8o</html5media><br />
|-<br />
| Laser-assisted polar body biopsy<ref>RIUK, R. (2013, June 25) Polar Body Biopsy [Video file]. Retrieved from https://www.youtube.com/watch?v=JTaQzszVr8o</ref><br />
|}<br />
====Advantages & Disadvantages====<br />
PB biopsies can only investigate the maternal contributions to the embryo as they are of maternal origin. Thus, this procedure is appropriate for PGD solely for monogenetic diseases from the maternal side. Recessive diseases may be evaluated with PB biopsies on the basis that the embryo’s outcome will be determined by the paternal contribution. It may still be applied for PGS as it is a fairly safe biopsy option and most aneuploidies either arise during meiosis or origin from the maternal genome. However, diagnosis error has been reported due to the lack of considering paternal contributions.Because PB biopsies are performed very early it is not yet known whether the oocyte will develop into a viable embryo. Thus, PBs are commonly frozen or fixed after biopsy and depending on the state of the embryo only chosen PBs will be tested. This is primarily an economic issue as many genetic testing procedures are very cost-intensive<ref name="PMID22723007"/>[[File:Implantation_predictive_value_of_euploid_screening_results.jpeg|thumb|The sustained implantation predictive value (with 95 % confidence interval) of a euploid screening result obtained from the first polar body (PB1), PB1 and the second polar body (PB2), or a direct embryo biopsy for each stage of embryo transfer (cleavage-stage and blastocyst stage)<ref name="PMID25106935"><pubmed>25106935</pubmed></ref>.]] Generally the sustained implantation predictive value of screening of PBs is significantly lower than of for example biopsies of the blastocyst stage<ref name="PMID25106935"/>. Moreover, it is often difficult to distinguish between the first and the second PB. As the first one degenerates quicker, this may influence diagnostic procedures<ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
===Blastomere biopsy===<br />
Day 3 <br />
====Description====<br />
Blastomere biopsy has been the prevalent method for PGD and PGS in the last two decades. At least one, but up to two, blastomeres are biopsied on day three of the cleavage stage embryo. The right number of blastomeres removed is a controversial topic as two cells allow for more genetic material and more accurate results. However, removing two cells might be too invasive and damaging to the embryo. As PGS tries to improve implantation rates, whereas PGD sets out to avoid known genetic disorders, for the former only one cell is removed, while for the latter often two need to be removed, to ensure results as correct as possible<ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
====Procedure====<br />
Initially a hole was drilled into the zona pellucida using acid tyrodes with the consequent aspiration of blastomeres with a pipette. Nowadays the zona pellucida is largely opened using a laser and calcium and magnesium free media have been introduced to decrease junctions between blastomeres, which facilitates the biopsy<ref name="PMID21748341"/>.<br />
[[File:Aspiration_of_a_Blastomere.jpeg|thumb|Aspiration of a Blastomere into the biopsy pipette<ref name=" PMID24783200"><pubmed>24783200</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=TbridWVwipI</html5media><br />
|-<br />
| Laser-assisted blastomere biopsy<ref>Sukprasert, M. (2014, March 5) Day 3 Blastomere Biopsy 1 [Video file]. Retrieved from https://www.youtube.com/watch?v=TbridWVwipI</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
===Trophectoderm biopsy===<br />
Day 5 and 6<br />
====Description====<br />
The improvement of embryo culture media allowed the in vitro development of human embryos until the blastocyst stage and opened up the possibility to take blastocyst biopsies. During day three to day five the haploid maternal and paternal genomes work together for the first time to form the genome of the embryo. The maternal epigenetic control lessens significantly while preparing for implantation with precisely arranged events happening. The first event includes a rapid increase in the number of embryonic cells which are active in mitotic divisions and apoptosis of aberrant cells. This is followed by the formation of blastocoel (cavitation) which results from the flattening of cell located on the outside of the blastomere. Now the blastocyst will expand until the embryo hatches by rupturing the zona pellucida. The cells of the blastocyst will differentiate to form two distinct cell lineages, the outer trophectoderm and the inner cell mass<ref name="PMID22723007"/>.<br />
====Procedure====<br />
Trophectoderm biopsy is usually performed in Hepes buffered biopsy medium and opening approaches include needle cutting which has been replaced by lasers in past years. Different research groups report different timings of the opening to be the most successful. Some open the blastocyst on day three or four by creating a 25 µm which causes the trophectoderm to herniate through this hole and is, thus, accessible for biopsy. Others create this hole about four hours before biopsy which allows sufficient herniation of trophectoderm cells. It is also possible to open the blastocyst immediately before biopsy. This avoids an extra step and the inner cell mass usually is easy to locate. Blastocyst biopsies involve the removal of trophectoderm cells and the ideal time for the procedure is day five. Successful biopsies on day six have been performed, while little is known about the results of biopsies on day seven. However, since the window of implantation in humans is from day eight to ten after ovulation, day seven biopsies appear to be possible<ref name="PMID22723007"/>.<br />
-collapse of trophoblasts<br />
-possible: biopsy of hatched blastocyst, holding pipette careful mild suction force to hold embryo near ICM <br />
-Cryopreservation<br />
<br />
<br />
[[File:Microscopic images of human blastocysts for biopsy.jpeg|thumb|(A) Some trophectoderm cells in a blastocyst started to hatch and (B) the trophectoderm cells were biopsied with assisted laser cutting. Images in C–D show the blastocysts after vitrification and warming. Blastocysts had been cultured for 2–4 hrs after warming, showing good (ICM and trophectoderm cells) hatched (C) and hatching (D) blastocysts. The hatching blastocyst in (E) has good ICM but fair trophectoderm while the blastocyst in (F) has both fair ICM and trophectoderm. Arrows indicate ICMs and arrow heads indicate trophectoderm cells. Bar = 40 µm<ref name="PMID2190846"><pubmed>2190846</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JI_TQ8d8tNM</html5media><br />
|-<br />
| Laser-assisted blastocyst biopsy (at 00:50 min)<ref>Coco, R. (2014, April 30) Trophectoderm biopsy in a Hatching blastocyst protruding ICM [Video file]. Retrieved from https://www.youtube.com/watch?v=JI_TQ8d8tNM</ref><br />
|}<br />
<br />
====Advantages & Disadvantages====<br />
Blastocyst biopsies are believed to be less damaging to the embryo and appear to be unrelated to implantation rates. In addition, this biopsy method allows for a larger extraction of cells for genetic testing. However, since they are performed late in in vitro development, the time window for genetic testing is relatively small. Fast and accurate genetic testing methods are needed to ensure a successful and safe result from this biopsy. Thus, blastocyst biopsies may gain more popularity in the future whn such methods have been developed or improved<ref name="PMID22723007"/>. <br />
==Genetic Techniques==<br />
===Polymerase Chain Reaction===<br />
PCR amplifies DNA specific to genetic sequence of interest . PCR was developed by Kay Mullis in the 1980s, for which he was awarded the Nobel prize for chemistry in 1993. <ref> Pubmed Docs (2015) Polymerase Chain Reaction (PCR) Pubmen. Retrieved from [http://www.ncbi.nlm.nih.gov/probe/docs/techpcr/]</ref> This technique enables clinicians to monitor and diagnose diseases using minute samples such as embryonic cells, blood & tissue. <ref>Roche (2015) PCR: How We Copy DNA. Roche Molecular Systems Inc. retrieved From [http://molecular.roche.com/pcr/Pages/Process.aspx]</ref> PCR has many important applications like DNA fingerprinting, genetic mapping, detection of viruses and bacteria as well as being used to detect genetic disorders, as a part of PGD, in conjunction with IVF. It is used to detect molecular abnormalities such as single gene disorders like Tay Sach, Cycstic fibrosis, Duchenne Muscular Dystrophy, Thalassemia, Huntington disease, Spinal muscular atrophy and many more. Molecular and Genetic analysis require a significant amount of DNA, which we would not have without PCR. It revolutionized the study of DNA, replacing all previous recombinant DNA technology. <ref> Mullins, K., Francois, F.& Gibbs R.A. (1994 ) The Polymerase Chain Reaction. p3. Springer- Science +Business Media. Birkhauser, Boston<br />
Available at [https://books.google.com.au/books?hl=en&lr=&id=gjrTBwAAQBAJ&oi=fnd&pg=PR5&dq=kary+mullis+PCR&ots=mpzAyRh5ZY&sig=PQ4goNoKJ90tb3-MkPk62zrTGbw#v=onepage&q=kary%20mullis%20PCR&f=false] </ref> <br />
<br />
[[File:PCR.jpg|thumb|right|Polymerase chain reaction (PCR) amplifies DNA specific to genetic sequence of interest, enabling the monitoring and diagnose molecular abnormalities such as single gene disorders using minute samples such as embryonic cells, blood & tissue <ref>NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref>]]<br />
{|<br />
|- align="left" bgcolor="DDCEF2"<br />
|'''Procedure'''<br />
|}<br />
Samples are obtained from the the blastocyst, a polar body biopsy or the blastomeres stages of the embryo. <br />
*Stage 1 Denaturing: separating the target strands of DNA <br />
The obtained sample is heated to roughly 90 degrees celcius, this heat breaks the relatively weak bonds between nucleotides that form DNA. The double stranded DNA is split into two single strands of DNA that are used as templates.<br />
*Stage 2 Annealing: Binding the Primers to the target DNA sequence <br />
PCR will only copy the target sequence of DNA specified by specific PCR primer. These synthesized primers oligonucleotides are small artificial pieces of DNA. TAQ polymerase enzyme synthesize two new strands of DNA duplicate to the single sample DNA stand template indicated by these primers. During this stage the reaction is cooled to a temperature between 40-60 degrees Celsius. <br />
*Stage 3- Extension- making copies <br />
Each of these two copies are then used again as templates generating two further replications This cycle can occur as many 30 -40 times within a couple hours leading to billions of extra copies of the original DNA segment. The optimal temperature for the further replication is roughly 72 degrees Celsius. <br />
This process mediated by a thermocycler machine that is programmed to alter the temperature of the reaction every couple of minutes, perpetuating the cycle of DNA denaturing and synthesis. <br />
This process, generates exponentially exact copies of the original template DNA sequence. <br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
!PCR cycles<br />
|-<br />
| '''PCR Cycle'''<br />
| '''Target Copies'''<br />
|-<br />
| 1<br />
| 2<br />
|-<br />
| 2<br />
| 4<br />
|-<br />
| 3<br />
| 8<br />
|-<br />
| 4<br />
| 16<br />
|-"<br />
| 5 <br />
| 32<br />
|-<br />
| 6 <br />
| 64<br />
|-<br />
| 7 <br />
| 128<br />
|-<br />
| 8<br />
| 256<br />
|- <br />
| 9<br />
| 512 <br />
|-<br />
| 10<br />
| 1024<br />
|-<br />
| 15<br />
| 32,768<br />
|-<br />
| 20 <br />
| 1,048,578<br />
|-<br />
| 25<br />
| 33,554,432<br />
|-<br />
| 30 <br />
| 1,073,741,842<br />
|-<br />
|}<br />
<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="6" |'''Advantages'''<br />
|-bgcolor="FFFAFA"<br />
| Fast and inexpensive way of copying a target sequence of DNA<br />
|-bgcolor="FFFAFA"<br />
| Particularly useful for the diagnosis of single cell defects<br />
|-bgcolor="FFFAFA"<br />
| Rapid generation of results (within hours)<br />
|-bgcolor="FFFAFA"<br />
| Highly sensitive, a single molecule of DNA is sufficient for reaction<br />
|-bgcolor="FFFAFA"<br />
| Generates DNA copies exponentially<br />
|-bgcolor="FFFAFA"<br />
| This enables DNA amplification required for molecular and genetic diagnostic analysis<ref> Dreesen, J., Drusedaul, M., Smeets, H., Die-Smulders, C., Coonen, E., Dumoulin, J., Gielen, M., Evers, J., Herbergers, J. & Geradets, J. (2008) Validation of preimplantation genetic diagnosis by PCR analysis: genotype comparison of the blastomere and corresponding embryo, implications for clinical practice. Mol. Hum. Reprod. 14 (10):573-579.doi: 10.1093/molehr/gan052. Retrieved from [http://molehr.oxfordjournals.org/content/14/10/573.short] </ref> <ref><pubmed>20966460</pubmed></ref><br />
|-bgcolor="DDCEF2"<br />
| rowspan="4"|'''Disadvantages'''<br />
|-bgcolor="FFFAFA"<br />
| Only during the exponential DNA replication phase, the starting quantity sequence contained in the original sample (template DNA strand) can be determined<br />
|-bgcolor="FFFAFA"<br />
| PCR reaction is limited to by presence of inhibitors in the sample<br />
|-bgcolor="FFFAFA"<br />
| Self annealing due to the accumulation of the product -stopping exponential amplification for the target sequence and reach a plateau<br />
quantification of the end point of reaction of PCR products unreliable - therefore real time quantitative RT-PCR is necessary<br />
<ref> NIS (2015) Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref><br />
|-bgcolor="FFFAFA"<br />
| Not a diagnostic method on its own, requires further analysis<br />
|}<br />
===Fluorescent In Situ Hybridisation===<br />
FISH is the one of the most effective and rapid <ref name="PMID26338801"><pubmed>26338801</pubmed></ref> method of conducting PGD. This techniques used to locate a specific DNA sequences within a chromosome. FISH facilitates the clinical diagnosis of chromosomal abnormalities indicated by sequential duplications, deletions and rearrangements of chromosome, that are usually missed with microscopic analysis. This technique is especially relevant for female embryos with X-linked diseases,<ref name="PMID20809319"><pubmed>20809319</pubmed></ref> that have no other mutation specific tests [http://www.ncbi.nlm.nih.gov/pubmed/20809319] As part of PGD, samples are collected from various stages of the embyro,and they are able to conducted tests on the blastocyst, a polar body biopsy and the blastomeres <ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. FISH is 99% effective when used in conjunction with competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities<ref name="PMID26338801"/>.<br />
{|<br />
|- align="left" bgcolor="DDCEF2"<br />
|'''Procedure'''<br />
|}<br />
Samples are collected from either the blastocyst, a polar body biopsy or the blastomeres stages of the embryo <ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
DNA strands are heated and denatured causing their the individual DNA strands to break apart<br />
Probes are single complimentary stands of DNA a that have been tagged with small chemical agents that glow brightly in the presence of a specific region on a chromosome. These specific probes then hybridize and join to their complementary DNA strand. <br />
The fluorescent tags enable the researchers to correctly identify the presence or lack thereof and location of the specific chromosomes that they are testing for. <ref name="PMID17876073"><pubmed>17876073</pubmed></ref><br />
Researcher analyse the results by identifying the number and the relative location of the fluorescent dots generated by the FISH images.<ref name="PMID17970921"><pubmed>17970921</pubmed></ref><br />
The probe will not fully hybridise if there has been a duplication or a deletion of the DNA - indicating chromosomal and sex chromosomal anomalies like trisomies and aneuploidies. <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref><br />
Different probes are used for different purposes: <ref>Unique, Rare Chromosome Disorder Support Group (2013) Fluorescence in situ hybridisation (FISH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/Other/FISH%20FTNW.pdf]</ref><br />
*'''Locus specific tags''' detect very small imbalances, and locate isolated small portions <br />
of genes within a chromosome<br />
*'''Alphoid/Centomeric Repeat probes''' are developed from the repetitive sequence located in the middle region of each chromosome, useful in determining the number of chromosomes , detecting rearrangement and when used in conjunction with locus probes to determine the absence of genetic material on a chromosome. <br />
*'''Paint Probes''' are collections of smaller probes with their own stains that bind to a different section on the chromosome - allowing the full chromosome too be labeled a unique colour, this "full colour map" can be used to know the spectral karyotype- full chromosomal mapping is useful in examining chromosomal abnormalities. <br />
[[File:Fluorescent In Situ Hybridisation (FISH).jpg|thumb|right|'''FISH''' We are able to tag Specific DNA sequences using Probes which have been tagged with fluorescent Labels.This technique enables the clinical diagnosis of chromosomal abnormalities, indicated by sequential duplication, deletions and rearrangements of chromosome <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref>]]<br />
<br />
{|class="wikitable" align="center"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="8" |'''Advantages''' <br />
|-bgcolor="FFFAFA" <br />
| FISH is 99% effective when used in conjunction with Competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities.<ref><pubmed>26338801</pubmed></ref><br />
|-bgcolor="FFFAFA" <br />
| Rapid generation of results<br />
|-bgcolor="FFFAFA"<br />
| Identifies very small translocations and aneuploidies that occur within chromosomes, that would usually be missed under microscopic analysis<br />
|-bgcolor="FFFAFA" <br />
| Indicates whether the accessed chromosomes are normal <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|-bgcolor="FFFAFA" <br />
| Tests for the most common chromosomal abnormalities - down syndrome chromosomes 13,16,18,21 and 22 <ref><pubmed>21749752</pubmed></ref><br />
|-bgcolor="FFFAFA" <br />
| It may be used to compare the chromosomal gene arrangements in related species<br />
|-bgcolor="FFFAFA" <br />
| can be used to identify and remove inheritable X-linked disease or sex chromasome anomalies such as Duchennes Muscular Dystrophy, hemophilia, ectodermal dysplasia <ref><pubmed>17876073</pubmed></ref><br />
|-bgcolor="DDCEF2"<br />
| rowspan="5"|'''Disadvantages'''<br />
|-bgcolor="FFFAFA" <br />
| FISH destroys all cells tested <ref> O'Connor, C. (2008) Fluorescence in situ hybridization (FISH). Nature Education 1(1):171. retrieved from [http://www.nature.com/scitable/topicpage/fluorescence-in-situ-hybridization-fish-327] </ref><br />
|-bgcolor="FFFAFA" <br />
| It does not fully access all chromosomes (only ~ 12)<br />
|-bgcolor="FFFAFA" <br />
| Analysis of results is dependent upon the dot quality impacted by hybridisation efficiency or the camera sensitivity <ref><pubmed>17970921</pubmed></ref><br />
|-bgcolor="FFFAFA" <br />
| some studies indicate that using FISH on a day-3 embryo biopsy decreases the rate of live births <ref><pubmed>26168107</pubmed></ref><br />
|}<br />
<br />
===Array Comparative Genomic Hybridisation (aCGH)===<br />
aCGH also known as Microarray analysis efficiently scans the entire genome for chromosomal imbalances. CGH was initially developed to detect the number of changes in a solid tumor mass. It uses 2 genomes comparing the sample to the control, with each labeled in a different fluorescent dye<ref name="PMID1876176"><pubmed>1876176</pubmed></ref>. Earlier CGH techniques were limited by the resolution of the imaging <ref> Lichter, P., et al. Comparative genomic hybridization: Uses and limitations. Seminars in Hematology 37, 348–357 (2000)</ref> , these initial limitations were overcome by using Microarrays in conjunction with CGh to improve the resolution of the imaging, Array Comparative Genomic Hybridisation (aCGH). This method compares sample and control microarrayed slides containing small segments of DNA (probes). <ref> Lucito, R., et al. Representational oligonucleotide microarray analysis: A high-resolution method to detect genome copy number variation. Genome Research 13, 2291–2305 (2003) </ref> the Probes used will vary according from the small (25-85 base pairs) oligonucleotides manufactured to highlight different target sequences, to the very large genomic clones (80,000- 200,00 base pairs), and as these are significantly smaller than the traditional metaphase chromosomes used for CGH, generating a higher resolution of image. <ref name="PMID22467166"><pubmed>22467166</pubmed></ref>.aCGH is used as a diagnostic tool for prenatal detection f chromosomal abnormalities <ref name="PMID19012303"><pubmed>19012303</pubmed></ref>.<br />
{|<br />
|- align="left" bgcolor="DDCEF2"<br />
|'''Procedure'''<br />
|}<br />
<ref> Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432] </ref><br />
The sample is obtained (skin, blood or fetal cells) and DNA is obtained. <br />
As a part of PGD fetal cell samples are collected from; the fertilized egg polar bodies, the blastomere (day 3 embryo) or the blastocyst/tropoectoderm stage (day 5 embryo).<br />
Sample DNA is labeled with one fluorescent dye, and the control DNA is labeled with a different colored fluorescent dye. the control DNA is used as the base point of reference. <br />
heated and denatured single DNA strands then hybridize to their complementary single strand probes, which are then combined and applied to a microarray and the results are run through a computer program and a digital imaging system is used to quantify the results( fluorescent intensities of the labeled probes). <br />
<br />
[[File:aCGH.jpg|thumb|right|'''aCGH''' checks the entire genome for chromosomal imbalances, by comparing control and a sample slides contatining small segements of DNA sample microarrayed slides small segments of DNA. Illustrated by student z5020317 and adapted from <ref> NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation. retrieved from [http://www.phgfoundation.org/file/5237/]</ref> <ref>Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432]</ref>]]<br />
<br />
The fluorescent ratio and the hybridization signal at different locations on the genome of the control DNA are used to identify any variances present in the sample DNA. aCGH facilitates the clinical diagnosis of submicroscopic chromosomal duplication, deletion and rearrangements indicative of chromosomal disorders such as trisomies 1-22and specific sex linked disorders. <br />
Duplications in the DNA are displayed by the computer program as spikes/ peaks over an established threshold and deletions in DNA are displayed by the computer program as spikes/ toughs beneath this threshold <br />
<br />
{|class="wikitable" align="center"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="12" |'''Advantages''' <br />
|-bgcolor="FFFAFA"<br />
| Multiple applications: prenatal genetic diagnosis, cancer diagnosis, <ref name="PMID20193845"><pubmed>20193845</pubmed></ref> genetic screening for developmental delay (learning disabilities) <ref name="PMID17309648"><pubmed>17309648</pubmed></ref>. or congenital anomalies that are suspected to be genetic in origin <ref>NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation . retrieved from [http://www.phgfoundation.org/file/5237/]</ref><br />
|-bgcolor="FFFAFA"<br />
| trace represents all chromosomes present in the human genome chromosomes 1-22 and the X & Y chromosomes, and therefore is the most accurate method for testing whole embryo aneuploidy<br />
|-bgcolor="FFFAFA"<br />
| aCGH has been extensively tested, and Validated, and is now used world wide.<br />
|-bgcolor="FFFAFA"<br />
| Detects submicroscopic alterations<br />
|-bgcolor="FFFAFA"<br />
| Detects deletions and additions and rearrangements as well as amplification, of the WHOLE genome, simultaneously.<br />
|-bgcolor="FFFAFA"<br />
| Used as a diagnostic tool for prenatal detection of chromosomal abnormalities <ref name="PMID22034057"><pubmed>22034057</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Provides high resolution genomewide screening of segmental genomic copy number variations<br />
|-bgcolor="FFFAFA"<br />
| Very accurate when used in conjunction with FISH<br />
|-bgcolor="FFFAFA"<br />
| Alone is more reliable and in detecting chromosomal abnormalities, with a higher implantation success rate, than FISH <ref name="PMID20494259"><pubmed>20494259</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Allows an in depth research focus upon specific types of rearrangements within selected chromosomal regions, a recent particular area of interest is subtelomeric and pericentromeric rearrangements<br />
|-bgcolor="FFFAFA"<br />
| Reduces the risk of failed implantation and miscarriage, improving the chance of a healthy baby <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|-bgcolor="DDCEF2"<br />
| rowspan="9" |'''Disadvantages'''<br />
|-bgcolor="FFFAFA"<br />
| Translocations and inversions of DNA are not detected<br />
|-bgcolor="FFFAFA"<br />
| Limited ability diagnosing specific polyploidies such as triploidy <ref> Unique, Rare Chromosome Disorder Support Group (2013) Microarray-based Comparative Genomic Hybridiation (array CGH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/other/array%20cgh%20ftnw.pdf] </ref><br />
|-bgcolor="FFFAFA"<br />
| Will not detect mosaicism detection <20% (cultures where >1 of 5 cells are trisomy 12)<br />
|-bgcolor="FFFAFA"<br />
| Will not detect balanced chromosomal rearrangement<br />
|-bgcolor="FFFAFA"<br />
| Will not detect duplications or deletions <80kb<br />
|-bgcolor="FFFAFA"<br />
| Will not detect point mutations within genes <ref>Washington department of education (CGH- FAQ for physicians. Signature Genomic LAboratories, LLC. Retrieved from [https://depts.washington.edu/dbpeds/Lab%20Tests/SignatureCGH-physician_FAQ.pdf]</ref><br />
|-bgcolor="FFFAFA"<br />
| will not detect chromosomal position of genomic gains<br />
|-bgcolor="FFFAFA"<br />
| Will not detect loos of heterozygosity (LOH) or Absence of heterozygosity (AOH) <ref>WiCell Research Institute Inc. (2012) Comparative Genomic Hybridization Microarray. <br />
retrieved from [http://www.wicell.org/home/cytogenetic-services/cgh-microarray/array-comparative-genomic-hybridization-acgh.cmsx]</ref><br />
|}<br />
<br />
===Next Generation Sequencing===<br />
The development and advances within ART in the past 20 years, as well as the increasing popularity of IV, has lead to an influx of new technologies developed to screen embryos for chromosomal anomalies, which are covered by the umbrella term of Next generation Sequencing (NGS). NGS is a general term used to describe all of the new and emerging screening techniques currently being introduced and used as part of PGD for IVF . NGS screens for single gene disorders as well as conducting extensive and very comprehensive chromosome diagnosis by sequencing, counting, and accurately assembling millions of DNA reads, simultaneously. <ref name="PMID23499002"><pubmed>23499002</pubmed></ref> There is a movement for NGS to replace the other limited testing techniques and be used as the standard. <br />
{|<br />
|- align="left" bgcolor="DDCEF2"<br />
|'''Procedure'''<br />
|}<br />
Samples are collected from either blastomere or the blastocyst/tropoectoderm and processed for analysis by a computer system. <br />
The methodology of each process is unique to the technique being used. <br />
<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="14" |'''Advantages''' <br />
|-bgcolor="FFFAFA" <br />
| Cheaper<br />
|-bgcolor="FFFAFA"<br />
| Opens new diagnostic possibilities<br />
|-bgcolor="FFFAFA"<br />
| Accurately tests all 24 chromosomes<br />
|-bgcolor="FFFAFA"<br />
| Tests for the presence of monogenic diseases of known genetic background<br />
|-bgcolor="FFFAFA"<br />
| Reduces the number of biopsies required for diagnosis<br />
|-bgcolor="FFFAFA"<br />
| Higher detection rate of small translocations<br />
|-bgcolor="FFFAFA"<br />
| Highly accurate is testing for compound point mutations, chromosomal duplication, deletions and insertions <ref name="PMID23312231"><pubmed>23312231</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| It accurately detects chromosomal aneuploidy and unbalanced rearrangement <ref name="PMID25685330"><pubmed>25685330</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Higher detection rate of small translocations<br />
|-bgcolor="FFFAFA"<br />
| NGS single gene disorder screenings can conducted in conjunction with PCR comprehensive chromosomal screening<br />
|-bgcolor="FFFAFA"<br />
| Reduces human error <br />
|-bgcolor="FFFAFA"<br />
| Better detects the presence of mosaicism<br />
|-bgcolor="FFFAFA"<br />
| Work well in conjunction with CGH and aCGH as part of PGD, improving the chances of IVF. <ref> Morris, R. S. (2015 ) Next generation sequencing for PCG|PGS|CCS. IVF1 retrieved from [http://www.ivf1.com/next-generation-sequencing for-pgd] </ref><br />
|-bgcolor="DDCEF2"<br />
| rowspan "2" |'''Disadvantages''' <br />
|-bgcolor="FFFAFA"<br />
| There are limited information available to clinical applications of NGS <ref><pubmed>26100406</pubmed></ref><br />
|}<br />
<br />
==Diagnosis==<br />
There are a large amount of diseases that PGD can apply to, below are descriptions of the diseases that PGD are more commonly used for. Utilization of Diseased Cell Lines<br />
===Cystic Fibrosis===<br />
Cystic fibrosis is a single gene disorder. It is autosomal recessive and involves mutations in the cystic fibrosis transmembrane conductance regulator (CTFR) gene. The CTFR gene is normally responsible for the decrease in chloride and the transport of bicarbonate in epithelial cells thus playing a major physiological role. In PGD procedures, identification of the gene is assisted by microsatellite markers that have similar composition to the CTFR gene itself. Biopsy of two cells at the blastocyst stage is recommended if markers are not available. There are many variations of cystic fibrosis the most common being P.Phe508del <ref name="PMID26014425"><pubmed>26014425</pubmed></ref>.<br />
===Duchenne Muscular Dystrophy ===<br />
Duchenne Muscular Dystrophy is an X-linked recessive disease. It involves the Xp21 gene where majority of the mutations are chromosomal deletions with a smaller percentage resulting from duplications <ref name="PMID18359022"><pubmed>18359022</pubmed></ref>.<br />
<br />
===Autosomal Recessive MEckel-Gruber Syndrome===<br />
Autosomal recessive genetic defect caused by the TMEM67 gene. It results in cystic dysplasia of the kidneys with fibrotic change in the liber and occipital encephalocele. Other malformations could also be present in the central nervous system. In PGD whole genome amplification of single blastomeres are taken to identify the gene, this is also coupled with PCR techniques. Maternal plasma can also be extracted for PGS. <ref><pubmed>24039893</pubmed></ref> <br />
===β – Thalassemia=== <br />
β – Thalassemia is known as the most common type of autosomal recessive inherited disorder among haemoglobinopathies. It involves the adult β-globin gene and is associated with the absent or decreased expression of the gene. This is commonly caused by a single nucleotide change in the gene. PGD has been used successfully worldwide to identify the β-globin gene where its application is usually performed on a single blastomere or polar body <ref name="PMID19064120">19064120</pubmed></ref>.<br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
! Applicable diseases for PGD <ref>Genoma Group (2014). Retrieved September 18th, 2015, from http://www.preimplantationgeneticdiagnosis.it/genetic-diseases-diagnosed-by-pgd.htm </ref>, <ref>Genesis Genetics (2015). Retrieved September 18th, 2015, from http://genesisgenetics.org/pgd/what-we-test-for/</ref>, <ref>Human Fertilisation & Embryology Authority (2015). Retrieved Septembr 18th, 2015, from http://guide.hfea.gov.uk/pgd/</ref><br />
|-<br />
| '''Disease'''<br />
| '''Involved Genes'''<br />
|-<br />
| 5 Alpha Reductase Deficiency (5ARD)<br />
| SRD5A2 <br />
|-<br />
| Achondroplasia<br />
|FGFR3 <br />
|-<br />
| Acute Intermittent Porphyria <br />
| ALAD, ALAS2, CPOX, FECH, HMBS, PPOX, UROD, or UROS<br />
|-<br />
| Adrenoleukodystrophy (Adrenomyeloneuropathy)<br />
| ABCD1 <br />
|-<br />
| Agammaglobulinaemia (x-linked) <br />
|BTK <br />
|-<br />
| Agammaglobulinemia Bruton Tyrosine Kinase (BTK) <br />
|BTK <br />
|-<br />
| Aicardi Goutieres Syndrome 1 (AGS1) <br />
|TREX1, RNASEH2A, RNASEH2B, RNASEH2C, SAMHD1<br />
|-<br />
| Alagille Syndrome<br />
|JAG1 or NOTCH2<br />
|- <br />
| Alpers-Huttenlocher Syndrome <br />
|POLG <br />
|-<br />
| Alpha-1-antitrypsin deficiency <br />
|SERPINA1 <br />
|-<br />
| Alpha-Mannosidosis<br />
| MAN2B1 <br />
|-<br />
| Alpha Thalassemia <br />
|HBA1 or HBA2 <br />
|-<br />
| Alports Syndrome<br />
|COL4A3, COL4A4, COL4A5<br />
|-<br />
| Alzheimer's Disease - early onset (Type 3 and 4) <br />
|APP, PSEN1, or PSEN2<br />
|-<br />
| Amyotrophic Lateral Sclerosis 1 (ALS1) <br />
|C9orf72, SOD1, TARDBP, FUS, ANG, ALS2, SETX, VAPB <br />
|-<br />
| Argininosuccinic Aciduria <br />
| ASL<br />
|-<br />
| Arrhythmogenic Right Ventricular Cardiomyopathy/ Dysplasia (ARVC/D)<br />
| DSG2; DSP; PKP2<br />
|-<br />
| Ataxia Telangiectasia<br />
| ATM<br />
|-<br />
| Autosomal Recessive Meckel-Gruber Syndrome<br />
| TMEM67<br />
|-<br />
| Bardet-Biedl Syndrome (BBS)<br />
| BBS1; BBS10<br />
|-<br />
| Barth Syndrome<br />
| TAZ<br />
|-<br />
| Beta Thalassaemia<br />
| HBB<br />
|-<br />
| Birt-Hogg-Dubé Syndrome<br />
| FLCN<br />
|-<br />
| Breast Ovarian Cancer Familial Susceptibility (BRCA2)<br />
| BRCA1; BRCA2<br />
|-<br />
| Canavan Disease <br />
| ASPA<br />
|-<br />
| Carnitine-Acylcarnitine Translocase Deficiency <br />
| SLC25A20<br />
|-<br />
| Cerebral Arteriopathy with Subcortical Infarcts & Leukoencephalopathy (CADASIL)<br />
| NOTCH3<br />
|-<br />
| Cerebral Cavernous Malformation<br />
| CCM1<br />
|-<br />
| Charcot-Marie-Tooth Disease<br />
| GJB1; MPZ; NEFL; PMP22<br />
|-<br />
| CHARGE Syndrome<br />
| CHD7<br />
|-<br />
| Cherubism<br />
| SH3BP2<br />
|-<br />
| Choroideremia<br />
| CHM<br />
|-<br />
| Chronic Granulomatous Disease<br />
| CYBB; NCF1<br />
|-<br />
| Ciliary Dyskinesia<br />
| DNAH5<br />
|-<br />
| Citrullinemia<br />
| ASS1<br />
|-<br />
| Cleidocranial Dysplasia<br />
| RUNX2<br />
|-<br />
| Cockayne Syndrome<br />
| ERCC6<br />
|-<br />
| Congenital Adrenal Hyperplasia<br />
| CYP21A2<br />
|-<br />
| Congenital Cataracts<br />
| GJA8; VSX2<br />
|-<br />
| Congenital Diarrhea, Syndromic<br />
| SPINT2<br />
|-<br />
| Congenital Disorders of Glycosylation (CDG)<br />
| ALG1; ALG6; CDG1C; DOLK; PMM2<br />
|-<br />
| Cornelia de Lange Syndrome <br />
| NIPBL<br />
|-<br />
| Craniosynostosis<br />
| TWIST1<br />
|-<br />
| Crouzon Syndrome<br />
| FGFR2<br />
|-<br />
| Cysteinyl Leukotriene Receptor 1 Deficiency <br />
| CYSLTR1<br />
|-<br />
| Cystic Fibrosis<br />
| CFTR<br />
|-<br />
| Diamond –Blackfan Anemia <br />
| RPS19<br />
|-<br />
| Duchenne Muscular Dystrophy <br />
| DMD<br />
|-<br />
| Dyskeratosis congenita (Male embryos only)<br />
| DKC1<br />
|-<br />
| Ectodermal dysplasia (Hypohidrotic)<br />
| EDA; EDA1; GJB6; IKBKG<br />
|-<br />
| Familial Adenomatous polyposis coli (FAP)<br />
| APC<br />
|-<br />
| Familial Dysautonomia<br />
| IKBKAP<br />
|-<br />
| Fanconi Anemia <br />
| FANCA; FANCC; FANCD2; FANCF; FANCG; FANCJ<br />
|-<br />
| Fragile X Syndrome (FRAX)<br />
| FMR1<br />
|-<br />
| Galactosemia <br />
| GALT<br />
|-<br />
| Gangliosidosis<br />
| GLB1<br />
|-<br />
| Glanzmann Thrombasthenia <br />
| ITGA2B<br />
|-<br />
| Glutaric Acidemia (aciduria)<br />
| GCDH <br />
|-<br />
| Glycogen Storage Disease <br />
| G6PC; GAA; SLC37A4<br />
|-<br />
| Haemophilia A<br />
| F8<br />
|-<br />
| Haemophilia B<br />
| F9<br />
|-<br />
| Hereditary Nonpolyposis Colorectal Cancer: Lynch Syndrome<br />
| MLH1; MSH2; MSH6<br />
|-<br />
| Holt Oram Syndrome<br />
| TBX5<br />
|-<br />
| Huntington Disease<br />
| HD<br />
|-<br />
| Hydrocephalus<br />
| L1CAM<br />
|-<br />
| Ichthyosis <br />
| ABCA12; STS<br />
|-<br />
| Incontinentia Pigmenti (IP)<br />
| NEMO<br />
|-<br />
| Joubert Syndrome 5<br />
| INPP5E<br />
|-<br />
| Krabbe Disease<br />
| GALC<br />
|-<br />
| Leber Congenital Amaurosis (LCA)<br />
| CEP290; GUCY2D<br />
|-<br />
| Leigh Syndrome (Infantile Subacute Necrotising Encephalopathy)<br />
| LRPPRC<br />
|-<br />
| Lesch Nyan Syndrome<br />
| HPRT1<br />
|-<br />
| Leukocyte Adhesion Deficiency (Type I)<br />
| ITGB2<br />
|-<br />
| Li-Fraumeni Syndrome<br />
| TP53<br />
|-<br />
| Macular Dystrophy Retinal <br />
| VMD2<br />
|-<br />
| Maple Syrup Urine Disorder (MSUD)<br />
| BCKDHB<br />
|-<br />
| Marfan Syndrome <br />
| FBN1<br />
|-<br />
| Menkes Syndrome<br />
| ATP7A<br />
|-<br />
| Mitochondrial DNA Depletion Syndrom <br />
| POLG; RRM2B; SUCLA2; TK2<br />
|-<br />
| Mucolipidosis type II<br />
| GNPTAB<br />
|-<br />
| Multiple Endocrine Neoplasia<br />
| MEN1; MEN2A; MEN2B<br />
|-<br />
| Multiple Exostoses<br />
| EXT1; EXT2 <br />
|-<br />
| Myotubular myopathy<br />
| MTM1 <br />
|-<br />
| Nail-Patella Syndrome<br />
| LMX1B<br />
|-<br />
| Neurofibromatosis Type 1<br />
| NF1<br />
|-<br />
| Neurofibromatosis Type 2 <br />
| NF2<br />
|-<br />
| Noonan Syndrome<br />
| KRAS, PTPN11; SOS1<br />
|-<br />
| Norrie Disease<br />
| NDP<br />
|-<br />
| Ocular Albinism <br />
| GPR143<br />
|-<br />
| Oculocutaneous Albinism <br />
| OCA2; TYR <br />
|-<br />
| Oculodentaldigital Dysplasia<br />
| GJA1<br />
|-<br />
| Optic Atrophy<br />
| OPA1<br />
|-<br />
| Ornithine Transcarbamylase Deficiency <br />
| OTC<br />
|-<br />
| Osteogenesis imperfeca <br />
| COL1A1; COL1A2<br />
|-<br />
| Osteopetrosis <br />
| CLCN7; OSTM1; TCIRG1<br />
|-<br />
| Pachyonychia Congenita <br />
| KRT16; KRT6A<br />
|-<br />
| Pancreatitis, Hereditary<br />
| PRSS1 <br />
|-<br />
| Papillorenal syndrome <br />
| PAX2<br />
|-<br />
| Phenylketonuria <br />
| PAH <br />
|-<br />
| This table does not cover the complete list of diseases that PGD can be applied to.<br />
|}<br />
<br />
==Laws & Legal status==<br />
<br />
{| class="wikitable" <br />
|-bgcolor="DDCEF2"<br />
|'''Country'''<br />
|'''Legislation'''<br />
|-bgcolor="FFFAFA" <br />
| Australia<br />
| PGD is currently used to detect serious genetic conditions to improve the outcome of Assisted Reproductive Technologies (ART). In very rare cases it may be used to select an embryo with compatible tissue for a sibling who has a life-threatening disease where other means of treatment is unavailable. This is with the conditions that the use of PGD will not affect the welfare and interests of the child to be born. The parents must also receive adequate counselling and have full understanding of the procedures of PGD. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"> National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art</ref><br />
The use of PGD for sex-selection is prohibited with the exception of reducing the risk of the transmission of serious sex-linked genetic conditions. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"/><br />
|-bgcolor="FFFAFA"<br />
| Brazil<br />
| The laws regarding PGD in Brazil are not strictly regulated. They are vague and there is limited information surround the activities of assisted reproduction in general in the country <ref name="PMID25493379"><pubmed>25493379</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| Czech Republic<br />
| The laws in the Czech Republic allow those with a “defined indication in order to exclude risk of serous genetically conditioned disease and defects with embryos before they are implanted into the cavity of the uterus”. Couples that undergo any assisted reproductive treatment including PGD have to be married. Sex-selection is illegal except in regards to serious sex-linked genetic diseases <ref name="PMID24777348"><pubmed>24777348</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| Greece<br />
| In Greece, ART is open to those up to the age of 50 with written consent. It can only be used if a medical necessity is present such as the susceptibility of serious hereditary diseases. Sex selection is banned apart from cases of sex-linked diseases and sexually transmitted diseases <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| India<br />
| In India there is a cultural preference for boys thus the Prenatal Diagnostic Techniques (Regulation and Prevention of Misuse) Act was introduced in 1994. This law limits the use of PGD for sex determination except in cases of specific congenital diseases. These laws however are not strictly enforced. <ref>World Health Organisation (2015) Gender and Genetics Retrieved on October 21st 2015 from:http://www.who.int/genomics/gender/en/index4.html</ref><br />
|-bgcolor="FFFAFA"<br />
| Portugal <br />
| ART is only available to those who are married or have a similar type of relationship for at least two years. The couples cannot be of the same sex and must be at least 18 years of age. Sex selection is illegal except in cases of sex-linked diseases. The use of PGD is illegal if the predictive value of genetic tests are very low <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| Spain<br />
| PGD can be applied to “serious hereditary diseases not amenable to postnatal curative treatment” and “detection of other abnormalities which may compromise the viability of the pre-embryo”. If PGD is to be used for any other purpose authorisation must be acquired <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| Sweden <br />
| The use of PGD is strictly regulated and couples must achieve authorisation of the National Board of Health and Welfare. It can only be used it can only be used if the child is at risk to inheriting a serious chromosomal or monogenetic disease. It cannot be used for selection of specific characteristics <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| United Kingdom<br />
| Those involved with carrying out the IVF treatment must have a license from the Human Fertilisation and Embryology Authority (HFEA). Only embryos that are approved by the HFEA can be implanted where the embryonic nuclear or mitochondrial DNA cannot be altered with the exception of preventing mitochondrial diseases <ref name="PMID24777348"/>. <br />
|}<br />
<br />
==Future/Current Research==<br />
===Noninvasive Preimplantation Genetic Testing without Embryo Biopsy===<br />
Different parameters of gametes, zygotes, embryos (“vacuoles in sperm heads, spindle position in mature oocytes, cleavage intervals of zygote, and embryo developmental dynamics”) may correlate with aneuploidy rates. This knowledge may be applied in potential noninvasive preimplantation diagnostic methods. Several methods have been proposed and are currently further researched<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Sperm Selection====<br />
Intracytoplasmic morphologically selected sperm injection (IMSI) is common procedure in IVF treatment to improve fertilization rates in patients with poor semen quality. In addition, studies have found that IMSI improves embryo development and that spermatozoa with large vacuoles in their heads correlate with increased aneuploidy rates and disturbed chromosomal structures. Thus, selecting spermatozoa based on morphological hallmarks may decrease aneuploidy rates in the fertilized embryos. As with polar body biopsies, however, this approach will solely be applicable if evidence for severe male detrimental contribution is given<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Blastocoel Fluid Extraction====<br />
In addition, a less invasive retrieval of material for diagnosis could include the extraction of the blastocoel fluid. The cavity of the blastocyst, lined by the trophectoderm, is filled with this blastocoel fluid, which contains metabolites of both trophectoderm and inner cell mass origin. The retrieval does not require a biopsy but merely a small opening to extract the fluid and, thus, causes less harm to the embryo. Multiple studies have applied this method<ref name="PMID22020776"><pubmed>22020776</pubmed></ref> <ref name="PMID23148560"><pubmed>23148560</pubmed></ref> and it may in the future become of clinical relevance.<br />
<br />
<br />
[[File:Aspiration_of_the_Blastocoel_Fluid.jpeg|thumb|Aspiration of the Blastocoel Fluid using a ICSI pipette<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.]]<br />
<br />
<br />
Next to metabolites, the blastocoel fluid can contain DNA. Studies have shown that genomic DNA is present in about 90% of the blastocoel fluid samples tested. Typically the fluid is removed with an ICSI pipette from a day five blastocyst through its mural trophectoderm until the blastocyst fully collapses around the embryo. Several concerns regarding this method in a clinical setting have been raised. The collected DNA may be contaminated by the culture media that contains DNA fractions. The DNA may also be least representative of the actual embryos genome as the DNA may originate from abnormal or degenerated cells. Even though labelled noninvasive, the blastocyst still undergoes manipulation to some degree which may affect its viability. Thus, more research is required until this method can evolve from research to clinical use<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
====Proteomics====<br />
The protein secretome of blastocysts may be representative of its chromosome constitution Recent studies have found biomarkers such as lipocalin-1, interleukin-10, tumor necrosis factor, stem cell factor, and chemokine ligand 13 to be differently secreted by aneuploid blastocyst than by euploid ones. The most significant biomarker appears to be interleukin-10. Paired with novel proteomic technologies and mass spectrometry this knowledge when extended may contribute to a new invasive PGD method<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Embryo Morphology====<br />
Using time lapse imaging the embryo’s morphology can be closely observed and potential aneuploidy characteristics detected. Such characteristics may include the time of division to five cells, the time between the division from three to four cells, and the duration of the division from one to two and subsequently to three. In addition, the morphological quality of ICM an TE has been positively associated with aneuploidy or euploidy prognosis<ref name="PMID26246880"><pubmed>26246880</pubmed></ref>. These may give rise to an embryo quality screening prior to implantation<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
==Glossary==<br />
'''CTFR''' Cystic Fibrosis Transmembrane Conductance Regulator <br />
<br />
'''ESHRE'''The European Society for Human Reproduction and Embryology<br />
<br />
'''FISH''' Fluorescence in situ hybridisation<br />
<br />
'''ICSI''' Intracytoplasmic Sperm Injection<br />
<br />
'''IMSI''' Intracytoplasmic Morphologically Selected Sperm Injection<br />
<br />
'''NGS''' Next Generation Sequencing <br />
<br />
'''PB''' Polar Body<br />
<br />
'''PGD''' Preimplantation Genetic Diagnosis <br />
<br />
'''PGS''' Preimplantation Genetic Screening<br />
<br />
'''PCR''' Polymerase Chain Reaction<br />
<br />
'''RT''' Robertsonian translocations<br />
<br />
''SNP''' Single Nucleotide Polymorphism <br />
==References==<br />
<br />
<references/><br />
<br />
<br />
{{StudentPage2015}}</div>Z5017878https://embryology.med.unsw.edu.au/embryology/index.php?title=2015_Group_Project_6&diff=2071672015 Group Project 62015-10-22T03:41:44Z<p>Z5017878: </p>
<hr />
<div>{{ANAT2341Project2015header}}<br />
<br />
<br />
=Preimplantation Genetic Diagnosis and Preimplantation Genetic Screening=<br />
==Introduction==<br />
Preimplantation genetic diagnosis (PGD) and preimplantation genetic screening (PGS) are reproductive options for couples with known family histories of genetic disease or couples undergoing IVF procedures due to infertility issues. PGD can diagnose many genetic disorders caused by known chromosomal abnormalities (number and/or structure) or single gene mutations, and, thus decrease the risk of termination of pregnancy or miscarriages and enable such couples to have an unaffected child<ref name="PMID24907939"><pubmed>24907939</pubmed></ref>. Through major improvements in PGD/S and general laboratory technology, the testing for abnormalities in fetuses has shifted from prenatal diagnosis during the first 2 trimesters <ref> Blackburn, S.L. (2003) '''Maternal, Fetal & Neonatal physiology: a Clinical perspective''' (2nd ed.). Seattle: Saudners </ref>, testing for overall fetal growth, complications of pregnancy, and birth defects<ref> Sadler T.W.(2012) '''Langman's Medical Embryology''' (12th ed.) Philadelphia: Lipincott, Wiliams & Wilkins, a Wolters Kluwer Business </ref>, to an embryonic focus especially in advancements in Artificial Reproductive Technologies (ART)<ref><pubmed>20638568</pubmed></ref>. In 1990 PGD for a recessive X-linked disease resulted in the first live birth<ref><pubmed>2330030</pubmed></ref> and has since been incorporated in clinical routine and applied for a variety of genetic diseases, such as sickle cell anemia, thalassemia, or cystic fibrosis<ref name="PMID24907939"/>.<br />
[[File:Preimplantation Genetic Diagnosis Procedure.jpeg|600px|left|thumb| Simplified steps for PGD<ref name="PMID24907939"/>]]<br />
{|class="wikitable"align="right" <br />
| <html5media height="400" width="533">https://www.youtube.com/watch?v=0e-79qKllqk</html5media><br />
|-<br />
| Preimplantation Genetic Diagnosis<ref>IVF Florida (2011, December 11) IVF Florida - South Florida Fertility Specialists - Pre-Implantation Genetic Diagnosis [Video file]. Retrieved from https://www.youtube.com/watch?v=0e-79qKllqk</ref><br />
|}<br />
<br />
==History==<br />
The advances in reproductive technology during the second half of the 20th century, led to PGD's first clinical application in 1990 <ref>Harper, J. (n.d.). The history of PGD. Lecture. UCL Centre for PG&D and CRGH.University College London</ref>.<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
|Year<br />
|<br />
|- bgcolor="FFFAFA"<br />
| '''1967''' <br />
|First PGD on rabbit blastocysts (Gardner& Edwards) <ref name="PMID6036172"><pubmed>6036172</pubmed></ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1986''' <br />
|First Cleavage Biopsy (Wilton & Trounson)<ref>Wilton, L. J., & Trounson, A. O. (1986). Viability of mouse embryos and blastomeres following biopsy of a single cell. In Proceedings of the 18th Annual Conference of the Australian Society for Reproductive Biology, Brisbane, Australia.</ref><br />
|- bgcolor="FFFAFA"<br />
|'''1987''' <br />
|First Blastocyst Biopsy (Muggleton-Harris, Monk, Rawlings, & Whittingham)<ref name="PMID3372699"><pubmed>3372699</pubmed></ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1988''' <br />
|First Polar Body Biopsy (Yury Verlinksy)<ref> Verlinsky, Y., Pergament, E., Andresen, P., Enriquez, G., & Strom, C. (1989). Genetic analysis of polar body DNA: A new approach to preimplantation genetic diagnosis. Am J Hum Genet, 45(4), A272.</ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1990''' <br />
|First Clinical PGD using PCR testing for X-linked (Handyside, Kontogianni, Hardy, & Winston)<ref name="PMID2330030"><pubmed>2330030</pubmed></ref> <br />
|} <br />
==Preimplantation Genetic Diagnosis==<br />
PGD is used to test the genetic makeup of embryos to detect single gene disorders, chromosomal abnormalities and mitochondrial disorders. It also has applications in gender selection for diseases with unequal gender distributions <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Some diseases commonly involved with PGD include cystic fibrosis, spinal muscular atrophy and beta – thalassaemia <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press.">Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press</ref> <ref name="PMID17823145"><pubmed>17823145</pubmed></ref>. It was first used in the United Kingdom in the 1980s of arenoleucodystrophy and primarily focusing on sex- linked disorders <ref name="PMID17823145"/><ref name="PMID23150080"><pubmed>23150080</pubmed></ref>. PGD is now capable of detecting single cell defects (molecular) and chromosomal disorders resulting from the inversion, translocation or deletion of chromosomes (cytogenic) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>,<ref name="PMID11325751"><pubmed>11325751</pubmed></ref>. PGD can be applied to the embryo at different stages. That is on polar bodies, blastomeres or blastocyst <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>.<br />
Depending on the type of genetic disorder, PGD utilises different methods of genetic testing. These include Fluorescence in situ hybridisation (FISH) which is used for sex – linked disorders and detects chromosomal rearrangements <ref name="PMID11325751"/><ref name="PMID17876073"><pubmed>17876073</pubmed></ref> and Embryo halotyping which allows the identification of chromosomes causing the inherited disorder through knowledge of the pattern of closely linked markers <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. Polymerase chain reaction (PCR) is also widely used to detect molecular abnormalities <ref name="PMID11325751"/>.<br />
PGD is tightly regulated and supported by large organisations namely The American Society for Reproductive Medicine, The European Society for Human Reproduction and Embryology (ESHRE), The European Society of Human Genetics and the Preimplantation Genetic Diagnosis International Society <ref name="PMID25500181><pubmed>25500181</pubmed></ref>.<br />
===Sex-linked disorders===<br />
The determination of a disease as gender specific usually correlates with the presence or absence of specific genes such as SRY on the Y chromosome. It is known that females have two X chromosomes and males have an X and a Y chromosome where abnormalities are more prevalent on the X chromosome. PGD can be used for sex selection where only male embryos are transferred to reduce the chance of inheriting X-linked disorders. However, this does not completely eradicate the problem as male embryos remain susceptible to inheriting an affected X chromosome. Sex determination is only used when the specific mutation is unknown and has yet to be discovered <ref name="PMID24866878"><pubmed>24866878</pubmed></ref>.<br />
===Single gene defects===<br />
Single gene defects can be dominant, recessive, autosomal or X-linked. They are commonly diagnosed using PCR and although the PCR available today is complex and capable of combatting a large range of disease the development of new protocols has been proven to be difficult due to the small DNA sample available <ref name="PMID26168107"><pubmed>26168107</pubmed></ref><br />
===Mitochondrial disorders===<br />
Mitochondrial disorders also known as oxidative phosphorylation disorders arise from mutations in the nuclear DNA or mitochondrial DNA <ref name="PMID26312584"><pubmed>26312584</pubmed></ref>. They pose as a problem because they are unrecognisable until the mutations in the cell reach a detrimental level <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Mitochondrial disorders cause miscarriages and stillbirths as well as death in children and young adults. The effects can either be contained in a single organ or more commonly involve multiple organ failure where organs with high energy demands such as the brain, liver muscle and heart and heavily influenced. They are usually occur spontaneously or result from inheritance from the mother. Since mitochondria are solely inherited from the mother oocyte donations have been used as a solution to combat mitochondrial disorders. Additionally, there has been an increasing use in PGD where embryos that stay under the given threshold of 18% gene-mutations are allowed to be transferred and result in normal development. New technology in the areas of nuclear gene transfer and genome editing are also being experimented with <ref name="PMID26312584"/>. <br />
===Chromosomal disorders===<br />
Chromosomal disorders can be reciprocal, Robertsonian translocations, inversions, deletions and insertions <ref name="PMID26168107"/>. . Data from ESHRE collected between 2010 and 2011 has shown that the most common chromosomal abnormality confronted in PGD are reciprocal chromosomal abnormalities <ref name"PMID26071418"><pubmed>26071418</pubmed></ref>. PGD has also been used successfully for Robertsonian translocations (RT), a type of structural translocation. Children who carry RT are phenotypically normal, however in their later years it is found that they will suffer from infertility and repeated miscarriages due to the high frequency of abnormal embryos <ref name="PMID22081077"><pubmed>22081077</pubmed></ref>. PCR and FISH are the two main techniques used for chromosomal disorders. To be able to conduct the examinations the cells are required to be at the metaphase stage <ref name="PMID26168107"/>. <br />
[[File:Reasons_for_PGD.jpg|600px|thumb|Reasons for PGD<ref name= "PMID24764761"><pubmed><24764761</pubmed></ref>]]<br />
==Preimplantation Genetic Screening==<br />
PGS involves an array of methods or ideas that aim to segregate embryos that have genetic flaws and those that are healthy <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. The occurrence of aneuploidy is high around the stages of early embryonic development and they are the most common cause if miscarriages and congenital birth defects <ref name= "PMID26085841"><pubmed>26085841</pubmed></ref>. They have little effect on the morphology of the embryo making them difficult to identify thus identification heavily relies on genetic testing <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. <br />
Genetic sampling is most commonly conducted using Microarray Comparative Genomic Hybridisation (aCGH) as well as FISH, Quantitative PCR and Single Nucleotide Polymorphism (SNP) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. These methods collectively aim to assess numeral and structural chromosomal errors <ref name= "PMID26085841"/>. Studies have also introduced Next- Generation Sequencing (NGS) <ref name= "PMID26085841"/> and Whole Genome Amplification used to screen imbalances in the complete 24-chromosomes <ref name="PMID25953353"><pubmed>25953353</pubmed></ref><br />
Statistics from ESHRE have shown that the most common indications for PGS is advanced age, followed by repeated implantation failure or recurrent miscarriage and male infertility <ref name="PMID26071418"><pubmed>26071418</pubmed></ref>.<br />
===Indications===<br />
A low percentage of structural abnormalities in chromosomes are responsible for the cause of miscarriages. Despite this, they are the most prevalent type of chromosomal abnormality accounted for in PGD <ref name="PMID20638568"/>. The presence of specific gene cycles, initiation of embryonic protein synthesis and evident physiological development are all indicative of a successful in vitro fertilisation procedure <ref name="PMID11576737"><pubmed>11576737</pubmed></ref>. To eliminate further errors from occurring during the PGD procedure it is recommended to undertake further prenatal testing such as amniocentesis in the later stages <ref name="PMID20638568"/>. <br />
====Advanced maternal age====<br />
Data provided by the ESHRE has shown that the mean age of women undergoing PGS is 39 years <ref name="PMID26071418"/>. Women of advanced age have been shown to have a lower rate of pregnancies reaching childbirth <ref name="PMID18583331"><pubmed>18583331</pubmed></ref>. The highlighted concern revolves around the increased occurrence of aneuploidy following maternal age. The optimal age range for the lowest aneuploidy incidence was found to be between 27 to 37 years of age (6%) then progressively higher in women aged up to 42 (33%) and most common in those 44 and above (53%) <ref name="PMID24355045"><pubmed>24355045</pubmed></ref>. <br />
====Recurrent pregnancy loss / IVF failure====<br />
Recurrent pregnancy loss is defined as three or more IVF failures after cumulative transfer of more than 10 good-quality embryos. These are primarily caused by two main factors, reduced endometrium receptivity or embryonic defects. Endometrium receptivity can be negatively influences by instances including uterine pathologies such as thin endometrium, altered expression of adhesive molecules and immunological factors. Additionally, embryonic defects may be due to genetic abnormalities, embryonic aneuploidy or zona hardening. Endometriosis and hydrosalpinx has been known to effect both the endometrium and embryo <ref name="PMID23260857"><pubmed>23260857</pubmed></ref>.<br />
====Human leukocyte antigen matching====<br />
First used in 2001, HLA matching is an option given to parents to save a child with haematological or immunological disease through conceiving another child who would potentially be able to donate cord blood or haematopoietic stem cells from the bone marrow for transplantation. The process namely PGD-HLA has shown to improve haematopoietic stem cell transplant (HSCT). PGD-HLA can only be performed when HSCT is not needed urgently due to the time needed to conceive and delivery the baby <ref name="PMID25500181"><pubmed>25500181</pubmed></ref>. It is most commonly applied to children suffering from relapsed leukaemia <ref name="PMID22524201"><pubmed>22524201</pubmed></ref>. In a case study PGD-HLA was proven to successfully cure 10 diseases including Fanconi anaemia, Diamond-Blackfan anaemia and beta thalassemia <ref name="PMID25066893><pubmed>25066893</pubmed></ref>.<br />
==Biopsy Methods==<br />
Biopsy, the removal of genetic materials, from oocytes or embryos in the preimplantation stage is the primary step in PGD. For the past two decades these biopsies have been performed at three stages, the polar body, blastomere, and blastocyst, and the methodologies optimized to ensure the embryo’s viability. The most common approach involves biopsies at the cleavage stage. However, polar body and blastocyst biopsies are increasingly more often tested and applied. Approached for opening the zona pellucida involve next to the traditional mechanical and chemical means, novel approaches such as noncontact lasers. Their application may simplify and secure the procedure significantly. The most challenging question about PGD procedures remains at what stage biopsies should be taken. Much controversy has developed around this topic, highlighting the varying disadvantages and advantages of temporal biopsies. <ref name="PMID22723007"><pubmed>22723007</pubmed></ref><br />
<br />
[[File:Polar_Body,_Blastomere,_and_Trophectoderm_Biopsy.jpeg|thumb|Polar body (A), blastomere (B) and trophectoderm (C) biopsies<ref name="PMID25625041"><pubmed>25625041</pubmed></ref>.]]<br />
{| class="wikitable"<br />
|- align="center" bgcolor="DDCEF2"<br />
|<br />
| Time of Biopsy<br />
| Advantages <br />
| Disadvantages<br />
|- bgcolor="FFFAFA"<br />
| Polar Body<br />
| Day 1<br />
| No harm to oocyte<br />
| Only maternal DNA is tested, often needs to be coupled with other biopsies, and there are difficulties distinguishing between the first and second PB.<br />
|- bgcolor="FFFAFA"<br />
| Blastomere<br />
| Day 3<br />
| …<br />
| … <br />
|- bgcolor="FFFAFA"<br />
| Trophectoderm<br />
| Day 5 and 6 <br />
| Little harm to the embryo and large amount of genetic material is extracted. <br />
| Opening of blastocyst necessary, small time window for procedure<br />
|}<br />
===Polar Body Analysis===<br />
Day 1<br />
====Description====<br />
Polar body (PB) biopsy offers a promising alternative to biopsies performed at the blastomere stage for PGD/S indications on legal and practical grounds. Consequent embryo development does not necessitate the presence of the first and second PB and their removal may not be crucial. PB biopsy requires precise timing. Keeping track of the meiotic cell cycle is necessary to perform a successful biopsy and, therefore, PB biopsy usually is applied in combination with intracytoplasmic sperm injection (ICSI). During the maturation from the germinal vesicle stage to the metaphase-II stage the first PB is formed. A cytoplasmic bridge containing spindle remnants, that are still in contact with the cellular genetic material, links this PB to the oolemma for about 90 minutes after extrusion. It is possible to visualize these remnants by polarization microscopy and it is crucial to not perform the biopsy until the first PB is no longer firmly attached to the oolemma as this indicates an immature embryo.The oocyte tolerates mechanical zona dissection best during hours four until six after ICSI as the oolemma has stabilized by that time because of the cortical granule reaction. Over time the first PB degenerates stressing a temporal biopsy and its optimal extraction time window is four to 12 hours after ICSI. The second PB forms around two to four hours after ICSI. Its optimal time window for biopsy is set to be eight to 16 hours after ICSI due to the second PB being attached to the oolemma with spindle remnants until six hours after ICSI. Biopsy at this point may cause enucleation of the oocyte. Studies have shown that the amplification efficiency of second PB’s DNA is worse if the PB is extracted prior to eight hours after ICSI. Thus, it is possible to perform sequential and simultaneous biopsies for the first and second PB. If performed, sequentially the first PB may be removed four to 12 hours and the second PB eight to 16 hours after ICSI. The optimal time window for a biopsy for both the first and second PB simultaneously is eight to 12 hours after ICSI. It is highly preferred to analyze both PBs due to potential aneuploidies in either PB and crossing overs during meiosis<ref name="PMID22723007"/>. <br />
====Procedure====<br />
Chemical opening achieved with for example acidic tyrode’s solution of the zona pellucida is not tolerated by the oocyte and may have detrimental effects on the embryo’s development. Therefore, the access to the perivitelline space of the oocyte is provided by mechanical zona dissection or by laser. Both techniques work well if performed by experienced embryologist. However, laser-assisted biopsy is less time consuming when compared to manual dissection. It is critical to consider the size of the introduced opening as it will remain permanent. If it is too large the blastomere may be lost during embryo development and if it is too small it may interfere with hatching of the embryo during blastocyst stage<ref name="PMID22723007"/>.<br />
[[File:Polar_Body_Biopsy.jpeg|left|thumb|The presence of a faint but clearly identifiable strand connecting PB2 to the oolemma. The biopsy was performed ∼9 h after ICSI<ref name="PMID21908464"><pubmed>21908464</pubmed></ref>.]]<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JTaQzszVr8o</html5media><br />
|-<br />
| Laser-assisted polar body biopsy<ref>RIUK, R. (2013, June 25) Polar Body Biopsy [Video file]. Retrieved from https://www.youtube.com/watch?v=JTaQzszVr8o</ref><br />
|}<br />
====Advantages & Disadvantages====<br />
PB biopsies can only investigate the maternal contributions to the embryo as they are of maternal origin. Thus, this procedure is appropriate for PGD solely for monogenetic diseases from the maternal side. Recessive diseases may be evaluated with PB biopsies on the basis that the embryo’s outcome will be determined by the paternal contribution. It may still be applied for PGS as it is a fairly safe biopsy option and most aneuploidies either arise during meiosis or origin from the maternal genome. However, diagnosis error has been reported due to the lack of considering paternal contributions.Because PB biopsies are performed very early it is not yet known whether the oocyte will develop into a viable embryo. Thus, PBs are commonly frozen or fixed after biopsy and depending on the state of the embryo only chosen PBs will be tested. This is primarily an economic issue as many genetic testing procedures are very cost-intensive<ref name="PMID22723007"/>[[File:Implantation_predictive_value_of_euploid_screening_results.jpeg|thumb|The sustained implantation predictive value (with 95 % confidence interval) of a euploid screening result obtained from the first polar body (PB1), PB1 and the second polar body (PB2), or a direct embryo biopsy for each stage of embryo transfer (cleavage-stage and blastocyst stage)<ref name="PMID25106935"><pubmed>25106935</pubmed></ref>.]] Generally the sustained implantation predictive value of screening of PBs is significantly lower than of for example biopsies of the blastocyst stage<ref name="PMID25106935"/>. Moreover, it is often difficult to distinguish between the first and the second PB. As the first one degenerates quicker, this may influence diagnostic procedures<ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
===Blastomere biopsy===<br />
Day 3 <br />
====Description====<br />
Blastomere biopsy has been the prevalent method for PGD and PGS in the last two decades. At least one, but up to two, blastomeres are biopsied on day three of the cleavage stage embryo. The right number of blastomeres removed is a controversial topic as two cells allow for more genetic material and more accurate results. However, removing two cells might be too invasive and damaging to the embryo. As PGS tries to improve implantation rates, whereas PGD sets out to avoid known genetic disorders, for the former only one cell is removed, while for the latter often two need to be removed, to ensure results as correct as possible<ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
====Procedure====<br />
Initially a hole was drilled into the zona pellucida using acid tyrodes with the consequent aspiration of blastomeres with a pipette. Nowadays the zona pellucida is largely opened using a laser and calcium and magnesium free media have been introduced to decrease junctions between blastomeres, which facilitates the biopsy<ref name="PMID21748341"/>.<br />
[[File:Aspiration_of_a_Blastomere.jpeg|thumb|Aspiration of a Blastomere into the biopsy pipette<ref name=" PMID24783200"><pubmed>24783200</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=TbridWVwipI</html5media><br />
|-<br />
| Laser-assisted blastomere biopsy<ref>Sukprasert, M. (2014, March 5) Day 3 Blastomere Biopsy 1 [Video file]. Retrieved from https://www.youtube.com/watch?v=TbridWVwipI</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
===Trophectoderm biopsy===<br />
Day 5 and 6<br />
====Description====<br />
The improvement of embryo culture media allowed the in vitro development of human embryos until the blastocyst stage and opened up the possibility to take blastocyst biopsies. During day three to day five the haploid maternal and paternal genomes work together for the first time to form the genome of the embryo. The maternal epigenetic control lessens significantly while preparing for implantation with precisely arranged events happening. The first event includes a rapid increase in the number of embryonic cells which are active in mitotic divisions and apoptosis of aberrant cells. This is followed by the formation of blastocoel (cavitation) which results from the flattening of cell located on the outside of the blastomere. Now the blastocyst will expand until the embryo hatches by rupturing the zona pellucida. The cells of the blastocyst will differentiate to form two distinct cell lineages, the outer trophectoderm and the inner cell mass<ref name="PMID22723007"/>.<br />
====Procedure====<br />
Trophectoderm biopsy is usually performed in Hepes buffered biopsy medium and opening approaches include needle cutting which has been replaced by lasers in past years. Different research groups report different timings of the opening to be the most successful. Some open the blastocyst on day three or four by creating a 25 µm which causes the trophectoderm to herniate through this hole and is, thus, accessible for biopsy. Others create this hole about four hours before biopsy which allows sufficient herniation of trophectoderm cells. It is also possible to open the blastocyst immediately before biopsy. This avoids an extra step and the inner cell mass usually is easy to locate. Blastocyst biopsies involve the removal of trophectoderm cells and the ideal time for the procedure is day five. Successful biopsies on day six have been performed, while little is known about the results of biopsies on day seven. However, since the window of implantation in humans is from day eight to ten after ovulation, day seven biopsies appear to be possible<ref name="PMID22723007"/>.<br />
-collapse of trophoblasts<br />
-possible: biopsy of hatched blastocyst, holding pipette careful mild suction force to hold embryo near ICM <br />
-Cryopreservation<br />
<br />
<br />
[[File:Microscopic images of human blastocysts for biopsy.jpeg|thumb|(A) Some trophectoderm cells in a blastocyst started to hatch and (B) the trophectoderm cells were biopsied with assisted laser cutting. Images in C–D show the blastocysts after vitrification and warming. Blastocysts had been cultured for 2–4 hrs after warming, showing good (ICM and trophectoderm cells) hatched (C) and hatching (D) blastocysts. The hatching blastocyst in (E) has good ICM but fair trophectoderm while the blastocyst in (F) has both fair ICM and trophectoderm. Arrows indicate ICMs and arrow heads indicate trophectoderm cells. Bar = 40 µm<ref name="PMID2190846"><pubmed>2190846</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JI_TQ8d8tNM</html5media><br />
|-<br />
| Laser-assisted blastocyst biopsy (at 00:50 min)<ref>Coco, R. (2014, April 30) Trophectoderm biopsy in a Hatching blastocyst protruding ICM [Video file]. Retrieved from https://www.youtube.com/watch?v=JI_TQ8d8tNM</ref><br />
|}<br />
<br />
====Advantages & Disadvantages====<br />
Blastocyst biopsies are believed to be less damaging to the embryo and appear to be unrelated to implantation rates. In addition, this biopsy method allows for a larger extraction of cells for genetic testing. However, since they are performed late in in vitro development, the time window for genetic testing is relatively small. Fast and accurate genetic testing methods are needed to ensure a successful and safe result from this biopsy. Thus, blastocyst biopsies may gain more popularity in the future whn such methods have been developed or improved<ref name="PMID22723007"/>. <br />
==Genetic Techniques==<br />
===Polymerase Chain Reaction===<br />
PCR amplifies DNA specific to genetic sequence of interest . PCR was developed by Kay Mullis in the 1980s, for which he was awarded the Nobel prize for chemistry in 1993. <ref> Pubmed Docs (2015) Polymerase Chain Reaction (PCR) Pubmen. Retrieved from [http://www.ncbi.nlm.nih.gov/probe/docs/techpcr/]</ref> This technique enables clinicians to monitor and diagnose diseases using minute samples such as embryonic cells, blood & tissue. <ref>Roche (2015) PCR: How We Copy DNA. Roche Molecular Systems Inc. retrieved From [http://molecular.roche.com/pcr/Pages/Process.aspx]</ref> PCR has many important applications like DNA fingerprinting, genetic mapping, detection of viruses and bacteria as well as being used to detect genetic disorders, as a part of PGD, in conjunction with IVF. It is used to detect molecular abnormalities such as single gene disorders like Tay Sach, Cycstic fibrosis, Duchenne Muscular Dystrophy, Thalassemia, Huntington disease, Spinal muscular atrophy and many more. Molecular and Genetic analysis require a significant amount of DNA, which we would not have without PCR. It revolutionized the study of DNA, replacing all previous recombinant DNA technology. <ref> Mullins, K., Francois, F.& Gibbs R.A. (1994 ) The Polymerase Chain Reaction. p3. Springer- Science +Business Media. Birkhauser, Boston<br />
Available at [https://books.google.com.au/books?hl=en&lr=&id=gjrTBwAAQBAJ&oi=fnd&pg=PR5&dq=kary+mullis+PCR&ots=mpzAyRh5ZY&sig=PQ4goNoKJ90tb3-MkPk62zrTGbw#v=onepage&q=kary%20mullis%20PCR&f=false] </ref> <br />
<br />
[[File:PCR.jpg|thumb|right|Polymerase chain reaction (PCR) amplifies DNA specific to genetic sequence of interest, enabling the monitoring and diagnose molecular abnormalities such as single gene disorders using minute samples such as embryonic cells, blood & tissue <ref>NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref>]]<br />
{|<br />
|- align="left" bgcolor="DDCEF2"<br />
|'''Procedure'''<br />
|}<br />
Samples are obtained from the the blastocyst, a polar body biopsy or the blastomeres stages of the embryo. <br />
*Stage 1 Denaturing: separating the target strands of DNA <br />
The obtained sample is heated to roughly 90 degrees celcius, this heat breaks the relatively weak bonds between nucleotides that form DNA. The double stranded DNA is split into two single strands of DNA that are used as templates.<br />
*Stage 2 Annealing: Binding the Primers to the target DNA sequence <br />
PCR will only copy the target sequence of DNA specified by specific PCR primer. These synthesized primers oligonucleotides are small artificial pieces of DNA. TAQ polymerase enzyme synthesize two new strands of DNA duplicate to the single sample DNA stand template indicated by these primers. During this stage the reaction is cooled to a temperature between 40-60 degrees Celsius. <br />
*Stage 3- Extension- making copies <br />
Each of these two copies are then used again as templates generating two further replications This cycle can occur as many 30 -40 times within a couple hours leading to billions of extra copies of the original DNA segment. The optimal temperature for the further replication is roughly 72 degrees Celsius. <br />
This process mediated by a thermocycler machine that is programmed to alter the temperature of the reaction every couple of minutes, perpetuating the cycle of DNA denaturing and synthesis. <br />
This process, generates exponentially exact copies of the original template DNA sequence. <br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
!PCR cycles<br />
<br />
{|<br />
|-<br />
| '''PCR Cycle'''<br />
| '''Target Copies'''<br />
|-<br />
| 1<br />
| 2<br />
|-<br />
| 2<br />
| 4<br />
|-<br />
| 3<br />
| 8<br />
|-<br />
| 4<br />
| 16<br />
|-"<br />
| 5 <br />
| 32<br />
|-<br />
| 6 <br />
| 64<br />
|-<br />
| 7 <br />
| 128<br />
|-<br />
| 8<br />
| 256<br />
|- <br />
| 9<br />
| 512 <br />
|-<br />
| 10<br />
| 1024<br />
|-<br />
| 15<br />
| 32,768<br />
|-<br />
| 20 <br />
| 1,048,578<br />
|-<br />
| 25<br />
| 33,554,432<br />
|-<br />
| 30 <br />
| 1,073,741,842<br />
|-<br />
|}<br />
<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="6" |'''Advantages'''<br />
|-bgcolor="FFFAFA"<br />
| Fast and inexpensive way of copying a target sequence of DNA<br />
|-bgcolor="FFFAFA"<br />
| Particularly useful for the diagnosis of single cell defects<br />
|-bgcolor="FFFAFA"<br />
| Rapid generation of results (within hours)<br />
|-bgcolor="FFFAFA"<br />
| Highly sensitive, a single molecule of DNA is sufficient for reaction<br />
|-bgcolor="FFFAFA"<br />
| Generates DNA copies exponentially<br />
|-bgcolor="FFFAFA"<br />
| This enables DNA amplification required for molecular and genetic diagnostic analysis<ref> Dreesen, J., Drusedaul, M., Smeets, H., Die-Smulders, C., Coonen, E., Dumoulin, J., Gielen, M., Evers, J., Herbergers, J. & Geradets, J. (2008) Validation of preimplantation genetic diagnosis by PCR analysis: genotype comparison of the blastomere and corresponding embryo, implications for clinical practice. Mol. Hum. Reprod. 14 (10):573-579.doi: 10.1093/molehr/gan052. Retrieved from [http://molehr.oxfordjournals.org/content/14/10/573.short] </ref> <ref><pubmed>20966460</pubmed></ref><br />
|-bgcolor="DDCEF2"<br />
| rowspan="4"|'''Disadvantages'''<br />
|-bgcolor="FFFAFA"<br />
| Only during the exponential DNA replication phase, the starting quantity sequence contained in the original sample (template DNA strand) can be determined<br />
|-bgcolor="FFFAFA"<br />
| PCR reaction is limited to by presence of inhibitors in the sample<br />
|-bgcolor="FFFAFA"<br />
| Self annealing due to the accumulation of the product -stopping exponential amplification for the target sequence and reach a plateau<br />
quantification of the end point of reaction of PCR products unreliable - therefore real time quantitative RT-PCR is necessary<br />
<ref> NIS (2015) Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref><br />
|-bgcolor="FFFAFA"<br />
| Not a diagnostic method on its own, requires further analysis<br />
|}<br />
===Fluorescent In Situ Hybridisation===<br />
FISH is the one of the most effective and rapid <ref name="PMID26338801"><pubmed>26338801</pubmed></ref> method of conducting PGD. This techniques used to locate a specific DNA sequences within a chromosome. FISH facilitates the clinical diagnosis of chromosomal abnormalities indicated by sequential duplications, deletions and rearrangements of chromosome, that are usually missed with microscopic analysis. This technique is especially relevant for female embryos with X-linked diseases,<ref name="PMID20809319"><pubmed>20809319</pubmed></ref> that have no other mutation specific tests [http://www.ncbi.nlm.nih.gov/pubmed/20809319] As part of PGD, samples are collected from various stages of the embyro,and they are able to conducted tests on the blastocyst, a polar body biopsy and the blastomeres <ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. FISH is 99% effective when used in conjunction with competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities<ref name="PMID26338801"/>.<br />
{|<br />
|- align="left" bgcolor="DDCEF2"<br />
|'''Procedure'''<br />
|}<br />
Samples are collected from either the blastocyst, a polar body biopsy or the blastomeres stages of the embryo <ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
DNA strands are heated and denatured causing their the individual DNA strands to break apart<br />
Probes are single complimentary stands of DNA a that have been tagged with small chemical agents that glow brightly in the presence of a specific region on a chromosome. These specific probes then hybridize and join to their complementary DNA strand. <br />
The fluorescent tags enable the researchers to correctly identify the presence or lack thereof and location of the specific chromosomes that they are testing for. <ref name="PMID17876073"><pubmed>17876073</pubmed></ref><br />
Researcher analyse the results by identifying the number and the relative location of the fluorescent dots generated by the FISH images.<ref name="PMID17970921"><pubmed>17970921</pubmed></ref><br />
The probe will not fully hybridise if there has been a duplication or a deletion of the DNA - indicating chromosomal and sex chromosomal anomalies like trisomies and aneuploidies. <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref><br />
Different probes are used for different purposes: <ref>Unique, Rare Chromosome Disorder Support Group (2013) Fluorescence in situ hybridisation (FISH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/Other/FISH%20FTNW.pdf]</ref><br />
*'''Locus specific tags''' detect very small imbalances, and locate isolated small portions <br />
of genes within a chromosome<br />
*'''Alphoid/Centomeric Repeat probes''' are developed from the repetitive sequence located in the middle region of each chromosome, useful in determining the number of chromosomes , detecting rearrangement and when used in conjunction with locus probes to determine the absence of genetic material on a chromosome. <br />
*'''Paint Probes''' are collections of smaller probes with their own stains that bind to a different section on the chromosome - allowing the full chromosome too be labeled a unique colour, this "full colour map" can be used to know the spectral karyotype- full chromosomal mapping is useful in examining chromosomal abnormalities. <br />
[[File:Fluorescent In Situ Hybridisation (FISH).jpg|thumb|right|'''FISH''' We are able to tag Specific DNA sequences using Probes which have been tagged with fluorescent Labels.This technique enables the clinical diagnosis of chromosomal abnormalities, indicated by sequential duplication, deletions and rearrangements of chromosome <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref>]]<br />
<br />
{|class="wikitable" align="center"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="8" |'''Advantages''' <br />
|-bgcolor="FFFAFA" <br />
| FISH is 99% effective when used in conjunction with Competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities.<ref><pubmed>26338801</pubmed></ref><br />
|-bgcolor="FFFAFA" <br />
| Rapid generation of results<br />
|-bgcolor="FFFAFA"<br />
| Identifies very small translocations and aneuploidies that occur within chromosomes, that would usually be missed under microscopic analysis<br />
|-bgcolor="FFFAFA" <br />
| Indicates whether the accessed chromosomes are normal <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|-bgcolor="FFFAFA" <br />
| Tests for the most common chromosomal abnormalities - down syndrome chromosomes 13,16,18,21 and 22 <ref><pubmed>21749752</pubmed></ref><br />
|-bgcolor="FFFAFA" <br />
| It may be used to compare the chromosomal gene arrangements in related species<br />
|-bgcolor="FFFAFA" <br />
| can be used to identify and remove inheritable X-linked disease or sex chromasome anomalies such as Duchennes Muscular Dystrophy, hemophilia, ectodermal dysplasia <ref><pubmed>17876073</pubmed></ref><br />
|-bgcolor="DDCEF2"<br />
| rowspan="5"|'''Disadvantages'''<br />
|-bgcolor="FFFAFA" <br />
| FISH destroys all cells tested <ref> O'Connor, C. (2008) Fluorescence in situ hybridization (FISH). Nature Education 1(1):171. retrieved from [http://www.nature.com/scitable/topicpage/fluorescence-in-situ-hybridization-fish-327] </ref><br />
|-bgcolor="FFFAFA" <br />
| It does not fully access all chromosomes (only ~ 12)<br />
|-bgcolor="FFFAFA" <br />
| Analysis of results is dependent upon the dot quality impacted by hybridisation efficiency or the camera sensitivity <ref><pubmed>17970921</pubmed></ref><br />
|-bgcolor="FFFAFA" <br />
| some studies indicate that using FISH on a day-3 embryo biopsy decreases the rate of live births <ref><pubmed>26168107</pubmed></ref><br />
|}<br />
<br />
===Array Comparative Genomic Hybridisation (aCGH)===<br />
aCGH also known as Microarray analysis efficiently scans the entire genome for chromosomal imbalances. CGH was initially developed to detect the number of changes in a solid tumor mass. It uses 2 genomes comparing the sample to the control, with each labeled in a different fluorescent dye<ref name="PMID1876176"><pubmed>1876176</pubmed></ref>. Earlier CGH techniques were limited by the resolution of the imaging <ref> Lichter, P., et al. Comparative genomic hybridization: Uses and limitations. Seminars in Hematology 37, 348–357 (2000)</ref> , these initial limitations were overcome by using Microarrays in conjunction with CGh to improve the resolution of the imaging, Array Comparative Genomic Hybridisation (aCGH). This method compares sample and control microarrayed slides containing small segments of DNA (probes). <ref> Lucito, R., et al. Representational oligonucleotide microarray analysis: A high-resolution method to detect genome copy number variation. Genome Research 13, 2291–2305 (2003) </ref> the Probes used will vary according from the small (25-85 base pairs) oligonucleotides manufactured to highlight different target sequences, to the very large genomic clones (80,000- 200,00 base pairs), and as these are significantly smaller than the traditional metaphase chromosomes used for CGH, generating a higher resolution of image. <ref name="PMID22467166"><pubmed>22467166</pubmed></ref>.aCGH is used as a diagnostic tool for prenatal detection f chromosomal abnormalities <ref name="PMID19012303"><pubmed>19012303</pubmed></ref>.<br />
{|<br />
|- align="left" bgcolor="DDCEF2"<br />
|'''Procedure'''<br />
|}<br />
<ref> Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432] </ref><br />
The sample is obtained (skin, blood or fetal cells) and DNA is obtained. <br />
As a part of PGD fetal cell samples are collected from; the fertilized egg polar bodies, the blastomere (day 3 embryo) or the blastocyst/tropoectoderm stage (day 5 embryo).<br />
Sample DNA is labeled with one fluorescent dye, and the control DNA is labeled with a different colored fluorescent dye. the control DNA is used as the base point of reference. <br />
heated and denatured single DNA strands then hybridize to their complementary single strand probes, which are then combined and applied to a microarray and the results are run through a computer program and a digital imaging system is used to quantify the results( fluorescent intensities of the labeled probes). <br />
<br />
[[File:aCGH.jpg|thumb|right|'''aCGH''' checks the entire genome for chromosomal imbalances, by comparing control and a sample slides contatining small segements of DNA sample microarrayed slides small segments of DNA. Illustrated by student z5020317 and adapted from <ref> NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation. retrieved from [http://www.phgfoundation.org/file/5237/]</ref> <ref>Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432]</ref>]]<br />
<br />
The fluorescent ratio and the hybridization signal at different locations on the genome of the control DNA are used to identify any variances present in the sample DNA. aCGH facilitates the clinical diagnosis of submicroscopic chromosomal duplication, deletion and rearrangements indicative of chromosomal disorders such as trisomies 1-22and specific sex linked disorders. <br />
Duplications in the DNA are displayed by the computer program as spikes/ peaks over an established threshold and deletions in DNA are displayed by the computer program as spikes/ toughs beneath this threshold <br />
<br />
{|class="wikitable" align="center"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="12" |'''Advantages''' <br />
|-bgcolor="FFFAFA"<br />
| Multiple applications: prenatal genetic diagnosis, cancer diagnosis, <ref name="PMID20193845"><pubmed>20193845</pubmed></ref> genetic screening for developmental delay (learning disabilities) <ref name="PMID17309648"><pubmed>17309648</pubmed></ref>. or congenital anomalies that are suspected to be genetic in origin <ref>NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation . retrieved from [http://www.phgfoundation.org/file/5237/]</ref><br />
|-bgcolor="FFFAFA"<br />
| trace represents all chromosomes present in the human genome chromosomes 1-22 and the X & Y chromosomes, and therefore is the most accurate method for testing whole embryo aneuploidy<br />
|-bgcolor="FFFAFA"<br />
| aCGH has been extensively tested, and Validated, and is now used world wide.<br />
|-bgcolor="FFFAFA"<br />
| Detects submicroscopic alterations<br />
|-bgcolor="FFFAFA"<br />
| Detects deletions and additions and rearrangements as well as amplification, of the WHOLE genome, simultaneously.<br />
|-bgcolor="FFFAFA"<br />
| Used as a diagnostic tool for prenatal detection of chromosomal abnormalities <ref name="PMID22034057"><pubmed>22034057</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Provides high resolution genomewide screening of segmental genomic copy number variations<br />
|-bgcolor="FFFAFA"<br />
| Very accurate when used in conjunction with FISH<br />
|-bgcolor="FFFAFA"<br />
| Alone is more reliable and in detecting chromosomal abnormalities, with a higher implantation success rate, than FISH <ref name="PMID20494259"><pubmed>20494259</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Allows an in depth research focus upon specific types of rearrangements within selected chromosomal regions, a recent particular area of interest is subtelomeric and pericentromeric rearrangements<br />
|-bgcolor="FFFAFA"<br />
| Reduces the risk of failed implantation and miscarriage, improving the chance of a healthy baby <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|-bgcolor="DDCEF2"<br />
| rowspan="9" |'''Disadvantages'''<br />
|-bgcolor="FFFAFA"<br />
| Translocations and inversions of DNA are not detected<br />
|-bgcolor="FFFAFA"<br />
| Limited ability diagnosing specific polyploidies such as triploidy <ref> Unique, Rare Chromosome Disorder Support Group (2013) Microarray-based Comparative Genomic Hybridiation (array CGH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/other/array%20cgh%20ftnw.pdf] </ref><br />
|-bgcolor="FFFAFA"<br />
| Will not detect mosaicism detection <20% (cultures where >1 of 5 cells are trisomy 12)<br />
|-bgcolor="FFFAFA"<br />
| Will not detect balanced chromosomal rearrangement<br />
|-bgcolor="FFFAFA"<br />
| Will not detect duplications or deletions <80kb<br />
|-bgcolor="FFFAFA"<br />
| Will not detect point mutations within genes <ref>Washington department of education (CGH- FAQ for physicians. Signature Genomic LAboratories, LLC. Retrieved from [https://depts.washington.edu/dbpeds/Lab%20Tests/SignatureCGH-physician_FAQ.pdf]</ref><br />
|-bgcolor="FFFAFA"<br />
| will not detect chromosomal position of genomic gains<br />
|-bgcolor="FFFAFA"<br />
| Will not detect loos of heterozygosity (LOH) or Absence of heterozygosity (AOH) <ref>WiCell Research Institute Inc. (2012) Comparative Genomic Hybridization Microarray. <br />
retrieved from [http://www.wicell.org/home/cytogenetic-services/cgh-microarray/array-comparative-genomic-hybridization-acgh.cmsx]</ref><br />
|}<br />
<br />
===Next Generation Sequencing===<br />
The development and advances within ART in the past 20 years, as well as the increasing popularity of IV, has lead to an influx of new technologies developed to screen embryos for chromosomal anomalies, which are covered by the umbrella term of Next generation Sequencing (NGS). NGS is a general term used to describe all of the new and emerging screening techniques currently being introduced and used as part of PGD for IVF . NGS screens for single gene disorders as well as conducting extensive and very comprehensive chromosome diagnosis by sequencing, counting, and accurately assembling millions of DNA reads, simultaneously. <ref name="PMID23499002"><pubmed>23499002</pubmed></ref> There is a movement for NGS to replace the other limited testing techniques and be used as the standard. <br />
{|<br />
|- align="left" bgcolor="DDCEF2"<br />
|'''Procedure'''<br />
|}<br />
Samples are collected from either blastomere or the blastocyst/tropoectoderm and processed for analysis by a computer system. <br />
The methodology of each process is unique to the technique being used. <br />
<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="14" |'''Advantages''' <br />
|-bgcolor="FFFAFA" <br />
| Cheaper<br />
|-bgcolor="FFFAFA"<br />
| Opens new diagnostic possibilities<br />
|-bgcolor="FFFAFA"<br />
| Accurately tests all 24 chromosomes<br />
|-bgcolor="FFFAFA"<br />
| Tests for the presence of monogenic diseases of known genetic background<br />
|-bgcolor="FFFAFA"<br />
| Reduces the number of biopsies required for diagnosis<br />
|-bgcolor="FFFAFA"<br />
| Higher detection rate of small translocations<br />
|-bgcolor="FFFAFA"<br />
| Highly accurate is testing for compound point mutations, chromosomal duplication, deletions and insertions <ref name="PMID23312231"><pubmed>23312231</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| It accurately detects chromosomal aneuploidy and unbalanced rearrangement <ref name="PMID25685330"><pubmed>25685330</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Higher detection rate of small translocations<br />
|-bgcolor="FFFAFA"<br />
| NGS single gene disorder screenings can conducted in conjunction with PCR comprehensive chromosomal screening<br />
|-bgcolor="FFFAFA"<br />
| Reduces human error <br />
|-bgcolor="FFFAFA"<br />
| Better detects the presence of mosaicism<br />
|-bgcolor="FFFAFA"<br />
| Work well in conjunction with CGH and aCGH as part of PGD, improving the chances of IVF. <ref> Morris, R. S. (2015 ) Next generation sequencing for PCG|PGS|CCS. IVF1 retrieved from [http://www.ivf1.com/next-generation-sequencing for-pgd] </ref><br />
|-bgcolor="DDCEF2"<br />
| rowspan "2" |'''Disadvantages''' <br />
|-bgcolor="FFFAFA"<br />
| There are limited information available to clinical applications of NGS <ref><pubmed>26100406</pubmed></ref><br />
|}<br />
<br />
==Diagnosis==<br />
There are a large amount of diseases that PGD can apply to, below are descriptions of the diseases that PGD are more commonly used for. Utilization of Diseased Cell Lines<br />
===Cystic Fibrosis===<br />
Cystic fibrosis is a single gene disorder. It is autosomal recessive and involves mutations in the cystic fibrosis transmembrane conductance regulator (CTFR) gene. The CTFR gene is normally responsible for the decrease in chloride and the transport of bicarbonate in epithelial cells thus playing a major physiological role. In PGD procedures, identification of the gene is assisted by microsatellite markers that have similar composition to the CTFR gene itself. Biopsy of two cells at the blastocyst stage is recommended if markers are not available. There are many variations of cystic fibrosis the most common being P.Phe508del <ref name="PMID26014425"><pubmed>26014425</pubmed></ref>.<br />
===Duchenne Muscular Dystrophy ===<br />
Duchenne Muscular Dystrophy is an X-linked recessive disease. It involves the Xp21 gene where majority of the mutations are chromosomal deletions with a smaller percentage resulting from duplications <ref name="PMID18359022"><pubmed>18359022</pubmed></ref>.<br />
<br />
===Autosomal Recessive MEckel-Gruber Syndrome===<br />
Autosomal recessive genetic defect caused by the TMEM67 gene. It results in cystic dysplasia of the kidneys with fibrotic change in the liber and occipital encephalocele. Other malformations could also be present in the central nervous system. In PGD whole genome amplification of single blastomeres are taken to identify the gene, this is also coupled with PCR techniques. Maternal plasma can also be extracted for PGS. <ref><pubmed>24039893</pubmed></ref> <br />
===β – Thalassemia=== <br />
β – Thalassemia is known as the most common type of autosomal recessive inherited disorder among haemoglobinopathies. It involves the adult β-globin gene and is associated with the absent or decreased expression of the gene. This is commonly caused by a single nucleotide change in the gene. PGD has been used successfully worldwide to identify the β-globin gene where its application is usually performed on a single blastomere or polar body <ref name="PMID19064120">19064120</pubmed></ref>.<br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
! Applicable diseases for PGD <ref>Genoma Group (2014). Retrieved September 18th, 2015, from http://www.preimplantationgeneticdiagnosis.it/genetic-diseases-diagnosed-by-pgd.htm </ref>, <ref>Genesis Genetics (2015). Retrieved September 18th, 2015, from http://genesisgenetics.org/pgd/what-we-test-for/</ref>, <ref>Human Fertilisation & Embryology Authority (2015). Retrieved Septembr 18th, 2015, from http://guide.hfea.gov.uk/pgd/</ref><br />
|-<br />
| '''Disease'''<br />
| '''Involved Genes'''<br />
|-<br />
| 5 Alpha Reductase Deficiency (5ARD)<br />
| SRD5A2 <br />
|-<br />
| Achondroplasia<br />
|FGFR3 <br />
|-<br />
| Acute Intermittent Porphyria <br />
| ALAD, ALAS2, CPOX, FECH, HMBS, PPOX, UROD, or UROS<br />
|-<br />
| Adrenoleukodystrophy (Adrenomyeloneuropathy)<br />
| ABCD1 <br />
|-<br />
| Agammaglobulinaemia (x-linked) <br />
|BTK <br />
|-<br />
| Agammaglobulinemia Bruton Tyrosine Kinase (BTK) <br />
|BTK <br />
|-<br />
| Aicardi Goutieres Syndrome 1 (AGS1) <br />
|TREX1, RNASEH2A, RNASEH2B, RNASEH2C, SAMHD1<br />
|-<br />
| Alagille Syndrome<br />
|JAG1 or NOTCH2<br />
|- <br />
| Alpers-Huttenlocher Syndrome <br />
|POLG <br />
|-<br />
| Alpha-1-antitrypsin deficiency <br />
|SERPINA1 <br />
|-<br />
| Alpha-Mannosidosis<br />
| MAN2B1 <br />
|-<br />
| Alpha Thalassemia <br />
|HBA1 or HBA2 <br />
|-<br />
| Alports Syndrome<br />
|COL4A3, COL4A4, COL4A5<br />
|-<br />
| Alzheimer's Disease - early onset (Type 3 and 4) <br />
|APP, PSEN1, or PSEN2<br />
|-<br />
| Amyotrophic Lateral Sclerosis 1 (ALS1) <br />
|C9orf72, SOD1, TARDBP, FUS, ANG, ALS2, SETX, VAPB <br />
|-<br />
| Argininosuccinic Aciduria <br />
| ASL<br />
|-<br />
| Arrhythmogenic Right Ventricular Cardiomyopathy/ Dysplasia (ARVC/D)<br />
| DSG2; DSP; PKP2<br />
|-<br />
| Ataxia Telangiectasia<br />
| ATM<br />
|-<br />
| Autosomal Recessive Meckel-Gruber Syndrome<br />
| TMEM67<br />
|-<br />
| Bardet-Biedl Syndrome (BBS)<br />
| BBS1; BBS10<br />
|-<br />
| Barth Syndrome<br />
| TAZ<br />
|-<br />
| Beta Thalassaemia<br />
| HBB<br />
|-<br />
| Birt-Hogg-Dubé Syndrome<br />
| FLCN<br />
|-<br />
| Breast Ovarian Cancer Familial Susceptibility (BRCA2)<br />
| BRCA1; BRCA2<br />
|-<br />
| Canavan Disease <br />
| ASPA<br />
|-<br />
| Carnitine-Acylcarnitine Translocase Deficiency <br />
| SLC25A20<br />
|-<br />
| Cerebral Arteriopathy with Subcortical Infarcts & Leukoencephalopathy (CADASIL)<br />
| NOTCH3<br />
|-<br />
| Cerebral Cavernous Malformation<br />
| CCM1<br />
|-<br />
| Charcot-Marie-Tooth Disease<br />
| GJB1; MPZ; NEFL; PMP22<br />
|-<br />
| CHARGE Syndrome<br />
| CHD7<br />
|-<br />
| Cherubism<br />
| SH3BP2<br />
|-<br />
| Choroideremia<br />
| CHM<br />
|-<br />
| Chronic Granulomatous Disease<br />
| CYBB; NCF1<br />
|-<br />
| Ciliary Dyskinesia<br />
| DNAH5<br />
|-<br />
| Citrullinemia<br />
| ASS1<br />
|-<br />
| Cleidocranial Dysplasia<br />
| RUNX2<br />
|-<br />
| Cockayne Syndrome<br />
| ERCC6<br />
|-<br />
| Congenital Adrenal Hyperplasia<br />
| CYP21A2<br />
|-<br />
| Congenital Cataracts<br />
| GJA8; VSX2<br />
|-<br />
| Congenital Diarrhea, Syndromic<br />
| SPINT2<br />
|-<br />
| Congenital Disorders of Glycosylation (CDG)<br />
| ALG1; ALG6; CDG1C; DOLK; PMM2<br />
|-<br />
| Cornelia de Lange Syndrome <br />
| NIPBL<br />
|-<br />
| Craniosynostosis<br />
| TWIST1<br />
|-<br />
| Crouzon Syndrome<br />
| FGFR2<br />
|-<br />
| Cysteinyl Leukotriene Receptor 1 Deficiency <br />
| CYSLTR1<br />
|-<br />
| Cystic Fibrosis<br />
| CFTR<br />
|-<br />
| Diamond –Blackfan Anemia <br />
| RPS19<br />
|-<br />
| Duchenne Muscular Dystrophy <br />
| DMD<br />
|-<br />
| Dyskeratosis congenita (Male embryos only)<br />
| DKC1<br />
|-<br />
| Ectodermal dysplasia (Hypohidrotic)<br />
| EDA; EDA1; GJB6; IKBKG<br />
|-<br />
| Familial Adenomatous polyposis coli (FAP)<br />
| APC<br />
|-<br />
| Familial Dysautonomia<br />
| IKBKAP<br />
|-<br />
| Fanconi Anemia <br />
| FANCA; FANCC; FANCD2; FANCF; FANCG; FANCJ<br />
|-<br />
| Fragile X Syndrome (FRAX)<br />
| FMR1<br />
|-<br />
| Galactosemia <br />
| GALT<br />
|-<br />
| Gangliosidosis<br />
| GLB1<br />
|-<br />
| Glanzmann Thrombasthenia <br />
| ITGA2B<br />
|-<br />
| Glutaric Acidemia (aciduria)<br />
| GCDH <br />
|-<br />
| Glycogen Storage Disease <br />
| G6PC; GAA; SLC37A4<br />
|-<br />
| Haemophilia A<br />
| F8<br />
|-<br />
| Haemophilia B<br />
| F9<br />
|-<br />
| Hereditary Nonpolyposis Colorectal Cancer: Lynch Syndrome<br />
| MLH1; MSH2; MSH6<br />
|-<br />
| Holt Oram Syndrome<br />
| TBX5<br />
|-<br />
| Huntington Disease<br />
| HD<br />
|-<br />
| Hydrocephalus<br />
| L1CAM<br />
|-<br />
| Ichthyosis <br />
| ABCA12; STS<br />
|-<br />
| Incontinentia Pigmenti (IP)<br />
| NEMO<br />
|-<br />
| Joubert Syndrome 5<br />
| INPP5E<br />
|-<br />
| Krabbe Disease<br />
| GALC<br />
|-<br />
| Leber Congenital Amaurosis (LCA)<br />
| CEP290; GUCY2D<br />
|-<br />
| Leigh Syndrome (Infantile Subacute Necrotising Encephalopathy)<br />
| LRPPRC<br />
|-<br />
| Lesch Nyan Syndrome<br />
| HPRT1<br />
|-<br />
| Leukocyte Adhesion Deficiency (Type I)<br />
| ITGB2<br />
|-<br />
| Li-Fraumeni Syndrome<br />
| TP53<br />
|-<br />
| Macular Dystrophy Retinal <br />
| VMD2<br />
|-<br />
| Maple Syrup Urine Disorder (MSUD)<br />
| BCKDHB<br />
|-<br />
| Marfan Syndrome <br />
| FBN1<br />
|-<br />
| Menkes Syndrome<br />
| ATP7A<br />
|-<br />
| Mitochondrial DNA Depletion Syndrom <br />
| POLG; RRM2B; SUCLA2; TK2<br />
|-<br />
| Mucolipidosis type II<br />
| GNPTAB<br />
|-<br />
| Multiple Endocrine Neoplasia<br />
| MEN1; MEN2A; MEN2B<br />
|-<br />
| Multiple Exostoses<br />
| EXT1; EXT2 <br />
|-<br />
| Myotubular myopathy<br />
| MTM1 <br />
|-<br />
| Nail-Patella Syndrome<br />
| LMX1B<br />
|-<br />
| Neurofibromatosis Type 1<br />
| NF1<br />
|-<br />
| Neurofibromatosis Type 2 <br />
| NF2<br />
|-<br />
| Noonan Syndrome<br />
| KRAS, PTPN11; SOS1<br />
|-<br />
| Norrie Disease<br />
| NDP<br />
|-<br />
| Ocular Albinism <br />
| GPR143<br />
|-<br />
| Oculocutaneous Albinism <br />
| OCA2; TYR <br />
|-<br />
| Oculodentaldigital Dysplasia<br />
| GJA1<br />
|-<br />
| Optic Atrophy<br />
| OPA1<br />
|-<br />
| Ornithine Transcarbamylase Deficiency <br />
| OTC<br />
|-<br />
| Osteogenesis imperfeca <br />
| COL1A1; COL1A2<br />
|-<br />
| Osteopetrosis <br />
| CLCN7; OSTM1; TCIRG1<br />
|-<br />
| Pachyonychia Congenita <br />
| KRT16; KRT6A<br />
|-<br />
| Pancreatitis, Hereditary<br />
| PRSS1 <br />
|-<br />
| Papillorenal syndrome <br />
| PAX2<br />
|-<br />
| Phenylketonuria <br />
| PAH <br />
|-<br />
| This table does not cover the complete list of diseases that PGD can be applied to.<br />
|}<br />
<br />
==Laws & Legal status==<br />
<br />
{| class="wikitable" <br />
|-bgcolor="DDCEF2"<br />
|'''Country'''<br />
|'''Legislation'''<br />
|-bgcolor="FFFAFA" <br />
| Australia<br />
| PGD is currently used to detect serious genetic conditions to improve the outcome of Assisted Reproductive Technologies (ART). In very rare cases it may be used to select an embryo with compatible tissue for a sibling who has a life-threatening disease where other means of treatment is unavailable. This is with the conditions that the use of PGD will not affect the welfare and interests of the child to be born. The parents must also receive adequate counselling and have full understanding of the procedures of PGD. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"> National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art</ref><br />
The use of PGD for sex-selection is prohibited with the exception of reducing the risk of the transmission of serious sex-linked genetic conditions. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"/><br />
|-bgcolor="FFFAFA"<br />
| Brazil<br />
| The laws regarding PGD in Brazil are not strictly regulated. They are vague and there is limited information surround the activities of assisted reproduction in general in the country <ref name="PMID25493379"><pubmed>25493379</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| Czech Republic<br />
| The laws in the Czech Republic allow those with a “defined indication in order to exclude risk of serous genetically conditioned disease and defects with embryos before they are implanted into the cavity of the uterus”. Couples that undergo any assisted reproductive treatment including PGD have to be married. Sex-selection is illegal except in regards to serious sex-linked genetic diseases <ref name="PMID24777348"><pubmed>24777348</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| Greece<br />
| In Greece, ART is open to those up to the age of 50 with written consent. It can only be used if a medical necessity is present such as the susceptibility of serious hereditary diseases. Sex selection is banned apart from cases of sex-linked diseases and sexually transmitted diseases <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| India<br />
| In India there is a cultural preference for boys thus the Prenatal Diagnostic Techniques (Regulation and Prevention of Misuse) Act was introduced in 1994. This law limits the use of PGD for sex determination except in cases of specific congenital diseases. These laws however are not strictly enforced. <ref>World Health Organisation (2015) Gender and Genetics Retrieved on October 21st 2015 from:http://www.who.int/genomics/gender/en/index4.html</ref><br />
|-bgcolor="FFFAFA"<br />
| Portugal <br />
| ART is only available to those who are married or have a similar type of relationship for at least two years. The couples cannot be of the same sex and must be at least 18 years of age. Sex selection is illegal except in cases of sex-linked diseases. The use of PGD is illegal if the predictive value of genetic tests are very low <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| Spain<br />
| PGD can be applied to “serious hereditary diseases not amenable to postnatal curative treatment” and “detection of other abnormalities which may compromise the viability of the pre-embryo”. If PGD is to be used for any other purpose authorisation must be acquired <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| Sweden <br />
| The use of PGD is strictly regulated and couples must achieve authorisation of the National Board of Health and Welfare. It can only be used it can only be used if the child is at risk to inheriting a serious chromosomal or monogenetic disease. It cannot be used for selection of specific characteristics <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| United Kingdom<br />
| Those involved with carrying out the IVF treatment must have a license from the Human Fertilisation and Embryology Authority (HFEA). Only embryos that are approved by the HFEA can be implanted where the embryonic nuclear or mitochondrial DNA cannot be altered with the exception of preventing mitochondrial diseases <ref name="PMID24777348"/>. <br />
|}<br />
<br />
==Future/Current Research==<br />
===Noninvasive Preimplantation Genetic Testing without Embryo Biopsy===<br />
Different parameters of gametes, zygotes, embryos (“vacuoles in sperm heads, spindle position in mature oocytes, cleavage intervals of zygote, and embryo developmental dynamics”) may correlate with aneuploidy rates. This knowledge may be applied in potential noninvasive preimplantation diagnostic methods. Several methods have been proposed and are currently further researched<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Sperm Selection====<br />
Intracytoplasmic morphologically selected sperm injection (IMSI) is common procedure in IVF treatment to improve fertilization rates in patients with poor semen quality. In addition, studies have found that IMSI improves embryo development and that spermatozoa with large vacuoles in their heads correlate with increased aneuploidy rates and disturbed chromosomal structures. Thus, selecting spermatozoa based on morphological hallmarks may decrease aneuploidy rates in the fertilized embryos. As with polar body biopsies, however, this approach will solely be applicable if evidence for severe male detrimental contribution is given<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Blastocoel Fluid Extraction====<br />
In addition, a less invasive retrieval of material for diagnosis could include the extraction of the blastocoel fluid. The cavity of the blastocyst, lined by the trophectoderm, is filled with this blastocoel fluid, which contains metabolites of both trophectoderm and inner cell mass origin. The retrieval does not require a biopsy but merely a small opening to extract the fluid and, thus, causes less harm to the embryo. Multiple studies have applied this method<ref name="PMID22020776"><pubmed>22020776</pubmed></ref> <ref name="PMID23148560"><pubmed>23148560</pubmed></ref> and it may in the future become of clinical relevance.<br />
<br />
<br />
[[File:Aspiration_of_the_Blastocoel_Fluid.jpeg|thumb|Aspiration of the Blastocoel Fluid using a ICSI pipette<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.]]<br />
<br />
<br />
Next to metabolites, the blastocoel fluid can contain DNA. Studies have shown that genomic DNA is present in about 90% of the blastocoel fluid samples tested. Typically the fluid is removed with an ICSI pipette from a day five blastocyst through its mural trophectoderm until the blastocyst fully collapses around the embryo. Several concerns regarding this method in a clinical setting have been raised. The collected DNA may be contaminated by the culture media that contains DNA fractions. The DNA may also be least representative of the actual embryos genome as the DNA may originate from abnormal or degenerated cells. Even though labelled noninvasive, the blastocyst still undergoes manipulation to some degree which may affect its viability. Thus, more research is required until this method can evolve from research to clinical use<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
====Proteomics====<br />
The protein secretome of blastocysts may be representative of its chromosome constitution Recent studies have found biomarkers such as lipocalin-1, interleukin-10, tumor necrosis factor, stem cell factor, and chemokine ligand 13 to be differently secreted by aneuploid blastocyst than by euploid ones. The most significant biomarker appears to be interleukin-10. Paired with novel proteomic technologies and mass spectrometry this knowledge when extended may contribute to a new invasive PGD method<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Embryo Morphology====<br />
Using time lapse imaging the embryo’s morphology can be closely observed and potential aneuploidy characteristics detected. Such characteristics may include the time of division to five cells, the time between the division from three to four cells, and the duration of the division from one to two and subsequently to three. In addition, the morphological quality of ICM an TE has been positively associated with aneuploidy or euploidy prognosis<ref name="PMID26246880"><pubmed>26246880</pubmed></ref>. These may give rise to an embryo quality screening prior to implantation<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
==Glossary==<br />
'''CTFR''' Cystic Fibrosis Transmembrane Conductance Regulator <br />
<br />
'''ESHRE'''The European Society for Human Reproduction and Embryology<br />
<br />
'''FISH''' Fluorescence in situ hybridisation<br />
<br />
'''ICSI''' Intracytoplasmic Sperm Injection<br />
<br />
'''IMSI''' Intracytoplasmic Morphologically Selected Sperm Injection<br />
<br />
'''NGS''' Next Generation Sequencing <br />
<br />
'''PB''' Polar Body<br />
<br />
'''PGD''' Preimplantation Genetic Diagnosis <br />
<br />
'''PGS''' Preimplantation Genetic Screening<br />
<br />
'''PCR''' Polymerase Chain Reaction<br />
<br />
'''RT''' Robertsonian translocations<br />
<br />
''SNP''' Single Nucleotide Polymorphism <br />
==References==<br />
<br />
<references/><br />
<br />
<br />
{{StudentPage2015}}</div>Z5017878https://embryology.med.unsw.edu.au/embryology/index.php?title=2015_Group_Project_6&diff=2071572015 Group Project 62015-10-22T03:30:10Z<p>Z5017878: </p>
<hr />
<div>{{ANAT2341Project2015header}}<br />
<br />
<br />
=Preimplantation Genetic Diagnosis and Screening=<br />
==Introduction==<br />
Preimplantation genetic diagnosis (PGD) and screening (PGS) are reproductive options for couples with known family histories of genetic disease or couples undergoing IVF procedures due to infertility issues. PGD can diagnose many genetic disorders caused by known chromosomal abnormalities (number and/or structure) or single gene mutations, and, thus decrease the risk of termination of pregnancy or miscarriages and enable such couples to have an unaffected child<ref name="PMID24907939"><pubmed>24907939</pubmed></ref>. Through major improvements in PGD/S and general laboratory technology, the testing for abnormalities in fetuses has shifted from prenatal diagnosis during the first 2 trimesters <ref> Blackburn, S.L. (2003) '''Maternal, Fetal & Neonatal physiology: a Clinical perspective''' (2nd ed.). Seattle: Saudners </ref>, testing for overall fetal growth, complications of pregnancy, and birth defects<ref> Sadler T.W.(2012) '''Langman's Medical Embryology''' (12th ed.) Philadelphia: Lipincott, Wiliams & Wilkins, a Wolters Kluwer Business </ref>, to an embryonic focus especially in advancements in Artificial Reproductive Technologies (ART)<ref><pubmed>20638568</pubmed></ref>. In 1990 PGD for a recessive X-linked disease resulted in the first live birth<ref><pubmed>2330030</pubmed></ref> and has since been incorporated in clinical routine and applied for a variety of genetic diseases, such as sickle cell anemia, thalassemia, or cystic fibrosis<ref name="PMID24907939"/>.<br />
[[File:Preimplantation Genetic Diagnosis Procedure.jpeg|600px|left|thumb| Simplified steps for PGD<ref name="PMID24907939"/>]]<br />
{|class="wikitable"align="right" <br />
| <html5media height="400" width="533">https://www.youtube.com/watch?v=0e-79qKllqk</html5media><br />
|-<br />
| Preimplantation Genetic Diagnosis<ref>IVF Florida (2011, December 11) IVF Florida - South Florida Fertility Specialists - Pre-Implantation Genetic Diagnosis [Video file]. Retrieved from https://www.youtube.com/watch?v=0e-79qKllqk</ref><br />
|}<br />
<br />
==History==<br />
The advances in reproductive technology during the second half of the 20th century, led to PGD's first clinical application in 1990 <ref>Harper, J. (n.d.). The history of PGD. Lecture. UCL Centre for PG&D and CRGH.University College London</ref>.<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
|Year<br />
|<br />
|- bgcolor="FFFAFA"<br />
| '''1967''' <br />
|First PGD on rabbit blastocysts (Gardner& Edwards) <ref name="PMID6036172"><pubmed>6036172</pubmed></ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1986''' <br />
|First Cleavage Biopsy (Wilton & Trounson)<ref>Wilton, L. J., & Trounson, A. O. (1986). Viability of mouse embryos and blastomeres following biopsy of a single cell. In Proceedings of the 18th Annual Conference of the Australian Society for Reproductive Biology, Brisbane, Australia.</ref><br />
|- bgcolor="FFFAFA"<br />
|'''1987''' <br />
|First Blastocyst Biopsy (Muggleton-Harris, Monk, Rawlings, & Whittingham)<ref name="PMID3372699"><pubmed>3372699</pubmed></ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1988''' <br />
|First Polar Body Biopsy (Yury Verlinksy)<ref> Verlinsky, Y., Pergament, E., Andresen, P., Enriquez, G., & Strom, C. (1989). Genetic analysis of polar body DNA: A new approach to preimplantation genetic diagnosis. Am J Hum Genet, 45(4), A272.</ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1990''' <br />
|First Clinical PGD using PCR testing for X-linked (Handyside, Kontogianni, Hardy, & Winston)<ref name="PMID2330030"><pubmed>2330030</pubmed></ref> <br />
|} <br />
==Preimplantation Genetic Diagnosis==<br />
Preimplantation genetic diagnosis (PGD) is used to test the genetic makeup of embryos to detect single gene disorders, chromosomal abnormalities and mitochondrial disorders. It also has applications in gender selection for diseases with unequal gender distributions <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Some diseases commonly involved with PGD include cystic fibrosis, spinal muscular atrophy and beta – thalassaemia <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press.">Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press</ref> <ref name="PMID17823145"><pubmed>17823145</pubmed></ref>. It was first used in the United Kingdom in the 1980s of arenoleucodystrophy and primarily focusing on sex- linked disorders <ref name="PMID17823145"/><ref name="PMID23150080"><pubmed>23150080</pubmed></ref>. PGD is now capable of detecting single cell defects (molecular) and chromosomal disorders resulting from the inversion, translocation or deletion of chromosomes (cytogenic) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>,<ref name="PMID11325751"><pubmed>11325751</pubmed></ref>. PGD can be applied to the embryo at different stages. That is on polar bodies, blastomeres or blastocyst <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>.<br />
Depending on the type of genetic disorder, PGD utilises different methods of genetic testing. These include Fluorescence in situ hybridisation (FISH) which is used for sex – linked disorders and detects chromosomal rearrangements <ref name="PMID11325751"/><ref name="PMID17876073"><pubmed>17876073</pubmed></ref> and Embryo halotyping which allows the identification of chromosomes causing the inherited disorder through knowledge of the pattern of closely linked markers <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. Polymerase chain reaction (PCR) is also widely used to detect molecular abnormalities <ref name="PMID11325751"/>.<br />
PGD is tightly regulated and supported by large organisations namely The American Society for Reproductive Medicine, The European Society for Human Reproduction and Embryology (ESHRE), The European Society of Human Genetics and the Preimplantation Genetic Diagnosis International Society <ref name="PMID25500181><pubmed>25500181</pubmed></ref>.<br />
===Sex-linked disorders===<br />
The determination of a disease as gender specific usually correlates with the presence or absence of specific genes such as SRY on the Y chromosome. It is known that females have two X chromosomes and males have an X and a Y chromosome where abnormalities are more prevalent on the X chromosome. PGD can be used for sex selection where only male embryos are transferred to reduce the chance of inheriting X-linked disorders. However, this does not completely eradicate the problem as male embryos remain susceptible to inheriting an affected X chromosome. Sex determination is only used when the specific mutation is unknown and has yet to be discovered <ref name="PMID24866878"><pubmed>24866878</pubmed></ref>.<br />
===Single gene defects===<br />
Single gene defects can be dominant, recessive, autosomal or X-linked. They are commonly diagnosed using PCR and although the PCR available today is complex and capable of combatting a large range of disease the development of new protocols has been proven to be difficult due to the small DNA sample available <ref name="PMID26168107"><pubmed>26168107</pubmed></ref><br />
===Mitochondrial disorders===<br />
Mitochondrial disorders also known as oxidative phosphorylation disorders arise from mutations in the nuclear DNA or mitochondrial DNA <ref name="PMID26312584"><pubmed>26312584</pubmed></ref>. They pose as a problem because they are unrecognisable until the mutations in the cell reach a detrimental level <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Mitochondrial disorders cause miscarriages and stillbirths as well as death in children and young adults. The effects can either be contained in a single organ or more commonly involve multiple organ failure where organs with high energy demands such as the brain, liver muscle and heart and heavily influenced. They are usually occur spontaneously or result from inheritance from the mother. Since mitochondria are solely inherited from the mother oocyte donations have been used as a solution to combat mitochondrial disorders. Additionally, there has been an increasing use in PGD where embryos that stay under the given threshold of 18% gene-mutations are allowed to be transferred and result in normal development. New technology in the areas of nuclear gene transfer and genome editing are also being experimented with <ref name="PMID26312584"/>. <br />
===Chromosomal disorders===<br />
Chromosomal disorders can be reciprocal, Robertsonian translocations, inversions, deletions and insertions <ref name="PMID26168107"/>. . Data from ESHRE collected between 2010 and 2011 has shown that the most common chromosomal abnormality confronted in PGD are reciprocal chromosomal abnormalities <ref name"PMID26071418"><pubmed>26071418</pubmed></ref>. PGD has also been used successfully for Robertsonian translocations (RT), a type of structural translocation. Children who carry RT are phenotypically normal, however in their later years it is found that they will suffer from infertility and repeated miscarriages due to the high frequency of abnormal embryos <ref name="PMID22081077"><pubmed>22081077</pubmed></ref>. PCR and FISH are the two main techniques used for chromosomal disorders. To be able to conduct the examinations the cells are required to be at the metaphase stage <ref name="PMID26168107"/>. <br />
[[File:Reasons_for_PGD.jpg|600px|thumb|Reasons for PGD<ref name= "PMID24764761"><pubmed><24764761</pubmed></ref>]]<br />
==Preimplantation Genetic Screening==<br />
Prenatal Genetic Screening (PGS) involves an array of methods or ideas that aim to segregate embryos that have genetic flaws and those that are healthy <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. The occurrence of aneuploidy is high around the stages of early embryonic development and they are the most common cause if miscarriages and congenital birth defects <ref name= "PMID26085841"><pubmed>26085841</pubmed></ref>. They have little effect on the morphology of the embryo making them difficult to identify thus identification heavily relies on genetic testing <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. <br />
Genetic sampling is most commonly conducted using Microarray Comparative Genomic Hybridisation (aCGH) as well as FISH, Quantitative PCR and Single Nucleotide Polymorphism (SNP) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. These methods collectively aim to assess numeral and structural chromosomal errors <ref name= "PMID26085841"/>. Studies have also introduced Next- Generation Sequencing (NGS) <ref name= "PMID26085841"/> and Whole Genome Amplification used to screen imbalances in the complete 24-chromosomes <ref name="PMID25953353"><pubmed>25953353</pubmed></ref><br />
Statistics from ESHRE have shown that the most common indications for PGS is advanced age, followed by repeated implantation failure or recurrent miscarriage and male infertility <ref name="PMID26071418"><pubmed>26071418</pubmed></ref>.<br />
===Indications===<br />
A low percentage of structural abnormalities in chromosomes are responsible for the cause of miscarriages. Despite this, they are the most prevalent type of chromosomal abnormality accounted for in PGD <ref name="PMID20638568"/>. The presence of specific gene cycles, initiation of embryonic protein synthesis and evident physiological development are all indicative of a successful in vitro fertilisation procedure <ref name="PMID11576737"><pubmed>11576737</pubmed></ref>. To eliminate further errors from occurring during the PGD procedure it is recommended to undertake further prenatal testing such as amniocentesis in the later stages <ref name="PMID20638568"/>. <br />
====Advanced maternal age====<br />
Data provided by the ESHRE has shown that the mean age of women undergoing PGS is 39 years <ref name="PMID26071418"/>. Women of advanced age have been shown to have a lower rate of pregnancies reaching childbirth <ref name="PMID18583331"><pubmed>18583331</pubmed></ref>. The highlighted concern revolves around the increased occurrence of aneuploidy following maternal age. The optimal age range for the lowest aneuploidy incidence was found to be between 27 to 37 years of age (6%) then progressively higher in women aged up to 42 (33%) and most common in those 44 and above (53%) <ref name="PMID24355045"><pubmed>24355045</pubmed></ref>. <br />
====Recurrent pregnancy loss / IVF failure====<br />
Recurrent pregnancy loss is defined as three or more IVF failures after cumulative transfer of more than 10 good-quality embryos. These are primarily caused by two main factors, reduced endometrium receptivity or embryonic defects. Endometrium receptivity can be negatively influences by instances including uterine pathologies such as thin endometrium, altered expression of adhesive molecules and immunological factors. Additionally, embryonic defects may be due to genetic abnormalities, embryonic aneuploidy or zona hardening. Endometriosis and hydrosalpinx has been known to effect both the endometrium and embryo <ref name="PMID23260857"><pubmed>23260857</pubmed></ref>.<br />
====Human leukocyte antigen matching====<br />
First used in 2001, HLA matching is an option given to parents to save a child with haematological or immunological disease through conceiving another child who would potentially be able to donate cord blood or haematopoietic stem cells from the bone marrow for transplantation. The process namely PGD-HLA has shown to improve haematopoietic stem cell transplant (HSCT). PGD-HLA can only be performed when HSCT is not needed urgently due to the time needed to conceive and delivery the baby <ref name="PMID25500181"><pubmed>25500181</pubmed></ref>. It is most commonly applied to children suffering from relapsed leukaemia <ref name="PMID22524201"><pubmed>22524201</pubmed></ref>. In a case study PGD-HLA was proven to successfully cure 10 diseases including Fanconi anaemia, Diamond-Blackfan anaemia and beta thalassemia <ref name="PMID25066893><pubmed>25066893</pubmed></ref>.<br />
==Biopsy Methods==<br />
Biopsy, the removal of genetic materials, from oocytes or embryos in the preimplantation stage is the primary step in PGD. For the past two decades these biopsies have been performed at three stages, the polar body, blastomere, and blastocyst, and the methodologies optimized to ensure the embryo’s viability. The most common approach involves biopsies at the cleavage stage. However, polar body and blastocyst biopsies are increasingly more often tested and applied. Approached for opening the zona pellucida involve next to the traditional mechanical and chemical means, novel approaches such as noncontact lasers. Their application may simplify and secure the procedure significantly. The most challenging question about PGD procedures remains at what stage biopsies should be taken. Much controversy has developed around this topic, highlighting the varying disadvantages and advantages of temporal biopsies. <ref name="PMID22723007"><pubmed>22723007</pubmed></ref><br />
<br />
[[File:Polar_Body,_Blastomere,_and_Trophectoderm_Biopsy.jpeg|thumb|Polar body (A), blastomere (B) and trophectoderm (C) biopsies<ref name="PMID25625041"><pubmed>25625041</pubmed></ref>.]]<br />
{| class="wikitable"<br />
|- align="center" bgcolor="DDCEF2"<br />
|<br />
| Time of Biopsy<br />
| Advantages <br />
| Disadvantages<br />
|- bgcolor="FFFAFA"<br />
| Polar Body<br />
| Day 1<br />
| No harm to oocyte<br />
| Only maternal DNA is tested, often needs to be coupled with other biopsies, and there are difficulties distinguishing between the first and second PB.<br />
|- bgcolor="FFFAFA"<br />
| Blastomere<br />
| Day 3<br />
| …<br />
| … <br />
|- bgcolor="FFFAFA"<br />
| Trophectoderm<br />
| Day 5 and 6 <br />
| Little harm to the embryo and large amount of genetic material is extracted. <br />
| Opening of blastocyst necessary, small time window for procedure<br />
|}<br />
===Polar Body Analysis===<br />
Day 1<br />
====Description====<br />
Polar body (PB) biopsy offers a promising alternative to biopsies performed at the blastomere stage for PGD/S indications on legal and practical grounds. Consequent embryo development does not necessitate the presence of the first and second PB and their removal may not be crucial. PB biopsy requires precise timing. Keeping track of the meiotic cell cycle is necessary to perform a successful biopsy and, therefore, PB biopsy usually is applied in combination with intracytoplasmic sperm injection (ICSI). During the maturation from the germinal vesicle stage to the metaphase-II stage the first PB is formed. A cytoplasmic bridge containing spindle remnants, that are still in contact with the cellular genetic material, links this PB to the oolemma for about 90 minutes after extrusion. It is possible to visualize these remnants by polarization microscopy and it is crucial to not perform the biopsy until the first PB is no longer firmly attached to the oolemma as this indicates an immature embryo.The oocyte tolerates mechanical zona dissection best during hours four until six after ICSI as the oolemma has stabilized by that time because of the cortical granule reaction. Over time the first PB degenerates stressing a temporal biopsy and its optimal extraction time window is four to 12 hours after ICSI. The second PB forms around two to four hours after ICSI. Its optimal time window for biopsy is set to be eight to 16 hours after ICSI due to the second PB being attached to the oolemma with spindle remnants until six hours after ICSI. Biopsy at this point may cause enucleation of the oocyte. Studies have shown that the amplification efficiency of second PB’s DNA is worse if the PB is extracted prior to eight hours after ICSI. Thus, it is possible to perform sequential and simultaneous biopsies for the first and second PB. If performed, sequentially the first PB may be removed four to 12 hours and the second PB eight to 16 hours after ICSI. The optimal time window for a biopsy for both the first and second PB simultaneously is eight to 12 hours after ICSI. It is highly preferred to analyze both PBs due to potential aneuploidies in either PB and crossing overs during meiosis<ref name="PMID22723007"/>. <br />
====Procedure====<br />
Chemical opening achieved with for example acidic tyrode’s solution of the zona pellucida is not tolerated by the oocyte and may have detrimental effects on the embryo’s development. Therefore, the access to the perivitelline space of the oocyte is provided by mechanical zona dissection or by laser. Both techniques work well if performed by experienced embryologist. However, laser-assisted biopsy is less time consuming when compared to manual dissection. It is critical to consider the size of the introduced opening as it will remain permanent. If it is too large the blastomere may be lost during embryo development and if it is too small it may interfere with hatching of the embryo during blastocyst stage<ref name="PMID22723007"/>.<br />
[[File:Polar_Body_Biopsy.jpeg|left|thumb|The presence of a faint but clearly identifiable strand connecting PB2 to the oolemma. The biopsy was performed ∼9 h after ICSI<ref name="PMID21908464"><pubmed>21908464</pubmed></ref>.]]<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JTaQzszVr8o</html5media><br />
|-<br />
| Laser-assisted polar body biopsy<ref>RIUK, R. (2013, June 25) Polar Body Biopsy [Video file]. Retrieved from https://www.youtube.com/watch?v=JTaQzszVr8o</ref><br />
|}<br />
====Advantages & Disadvantages====<br />
PB biopsies can only investigate the maternal contributions to the embryo as they are of maternal origin. Thus, this procedure is appropriate for PGD solely for monogenetic diseases from the maternal side. Recessive diseases may be evaluated with PB biopsies on the basis that the embryo’s outcome will be determined by the paternal contribution. It may still be applied for PGS as it is a fairly safe biopsy option and most aneuploidies either arise during meiosis or origin from the maternal genome. However, diagnosis error has been reported due to the lack of considering paternal contributions.Because PB biopsies are performed very early it is not yet known whether the oocyte will develop into a viable embryo. Thus, PBs are commonly frozen or fixed after biopsy and depending on the state of the embryo only chosen PBs will be tested. This is primarily an economic issue as many genetic testing procedures are very cost-intensive<ref name="PMID22723007"/>[[File:Implantation_predictive_value_of_euploid_screening_results.jpeg|thumb|The sustained implantation predictive value (with 95 % confidence interval) of a euploid screening result obtained from the first polar body (PB1), PB1 and the second polar body (PB2), or a direct embryo biopsy for each stage of embryo transfer (cleavage-stage and blastocyst stage)<ref name="PMID25106935"><pubmed>25106935</pubmed></ref>.]] Generally the sustained implantation predictive value of screening of PBs is significantly lower than of for example biopsies of the blastocyst stage<ref name="PMID25106935"/>. Moreover, it is often difficult to distinguish between the first and the second PB. As the first one degenerates quicker, this may influence diagnostic procedures<ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
===Blastomere biopsy===<br />
Day 3 <br />
====Description====<br />
Blastomere biopsy has been the prevalent method for PGD and PGS in the last two decades. At least one, but up to two, blastomeres are biopsied on day three of the cleavage stage embryo. The right number of blastomeres removed is a controversial topic as two cells allow for more genetic material and more accurate results. However, removing two cells might be too invasive and damaging to the embryo. As PGS tries to improve implantation rates, whereas PGD sets out to avoid known genetic disorders, for the former only one cell is removed, while for the latter often two need to be removed, to ensure results as correct as possible<ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
====Procedure====<br />
Initially a hole was drilled into the zona pellucida using acid tyrodes with the consequent aspiration of blastomeres with a pipette. Nowadays the zona pellucida is largely opened using a laser and calcium and magnesium free media have been introduced to decrease junctions between blastomeres, which facilitates the biopsy<ref name="PMID21748341"/>.<br />
[[File:Aspiration_of_a_Blastomere.jpeg|thumb|Aspiration of a Blastomere into the biopsy pipette<ref name=" PMID24783200"><pubmed>24783200</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=TbridWVwipI</html5media><br />
|-<br />
| Laser-assisted blastomere biopsy<ref>Sukprasert, M. (2014, March 5) Day 3 Blastomere Biopsy 1 [Video file]. Retrieved from https://www.youtube.com/watch?v=TbridWVwipI</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
===Trophectoderm biopsy===<br />
Day 5 and 6<br />
====Description====<br />
The improvement of embryo culture media allowed the in vitro development of human embryos until the blastocyst stage and opened up the possibility to take blastocyst biopsies. During day three to day five the haploid maternal and paternal genomes work together for the first time to form the genome of the embryo. The maternal epigenetic control lessens significantly while preparing for implantation with precisely arranged events happening. The first event includes a rapid increase in the number of embryonic cells which are active in mitotic divisions and apoptosis of aberrant cells. This is followed by the formation of blastocoel (cavitation) which results from the flattening of cell located on the outside of the blastomere. Now the blastocyst will expand until the embryo hatches by rupturing the zona pellucida. The cells of the blastocyst will differentiate to form two distinct cell lineages, the outer trophectoderm and the inner cell mass<ref name="PMID22723007"/>.<br />
====Procedure====<br />
Trophectoderm biopsy is usually performed in Hepes buffered biopsy medium and opening approaches include needle cutting which has been replaced by lasers in past years. Different research groups report different timings of the opening to be the most successful. Some open the blastocyst on day three or four by creating a 25 µm which causes the trophectoderm to herniate through this hole and is, thus, accessible for biopsy. Others create this hole about four hours before biopsy which allows sufficient herniation of trophectoderm cells. It is also possible to open the blastocyst immediately before biopsy. This avoids an extra step and the inner cell mass usually is easy to locate. Blastocyst biopsies involve the removal of trophectoderm cells and the ideal time for the procedure is day five. Successful biopsies on day six have been performed, while little is known about the results of biopsies on day seven. However, since the window of implantation in humans is from day eight to ten after ovulation, day seven biopsies appear to be possible<ref name="PMID22723007"/>.<br />
-collapse of trophoblasts<br />
-possible: biopsy of hatched blastocyst, holding pipette careful mild suction force to hold embryo near ICM <br />
-Cryopreservation<br />
<br />
<br />
[[File:Microscopic images of human blastocysts for biopsy.jpeg|thumb|(A) Some trophectoderm cells in a blastocyst started to hatch and (B) the trophectoderm cells were biopsied with assisted laser cutting. Images in C–D show the blastocysts after vitrification and warming. Blastocysts had been cultured for 2–4 hrs after warming, showing good (ICM and trophectoderm cells) hatched (C) and hatching (D) blastocysts. The hatching blastocyst in (E) has good ICM but fair trophectoderm while the blastocyst in (F) has both fair ICM and trophectoderm. Arrows indicate ICMs and arrow heads indicate trophectoderm cells. Bar = 40 µm<ref name="PMID2190846"><pubmed>2190846</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JI_TQ8d8tNM</html5media><br />
|-<br />
| Laser-assisted blastocyst biopsy (at 00:50 min)<ref>Coco, R. (2014, April 30) Trophectoderm biopsy in a Hatching blastocyst protruding ICM [Video file]. Retrieved from https://www.youtube.com/watch?v=JI_TQ8d8tNM</ref><br />
|}<br />
<br />
====Advantages & Disadvantages====<br />
Blastocyst biopsies are believed to be less damaging to the embryo and appear to be unrelated to implantation rates. In addition, this biopsy method allows for a larger extraction of cells for genetic testing. However, since they are performed late in in vitro development, the time window for genetic testing is relatively small. Fast and accurate genetic testing methods are needed to ensure a successful and safe result from this biopsy. Thus, blastocyst biopsies may gain more popularity in the future whn such methods have been developed or improved<ref name="PMID22723007"/>. <br />
==Genetic Techniques==<br />
===PCR===<br />
Polymerase chain reaction (PCR) amplifies DNA specific to genetic sequence of interest . PCR was developed by Kay Mullis in the 1980s, for which he was awarded the Nobel prize for chemistry in 1993. <ref> Pubmed Docs (2015) Polymerase Chain Reaction (PCR) Pubmen. Retrieved from [http://www.ncbi.nlm.nih.gov/probe/docs/techpcr/]</ref> This technique enables clinicians to monitor and diagnose diseases using minute samples such as embryonic cells, blood & tissue. <ref>Roche (2015) PCR: How We Copy DNA. Roche Molecular Systems Inc. retrieved From [http://molecular.roche.com/pcr/Pages/Process.aspx]</ref> PCR has many important applications like DNA fingerprinting, genetic mapping, detection of viruses and bacteria as well as being used to detect genetic disorders, as a part of PGD, in conjunction with IVF. It is used to detect molecular abnormalities such as single gene disorders like Tay Sach, Cycstic fibrosis, Duchenne Muscular Dystrophy, Thalassemia, Huntington disease, Spinal muscular atrophy and many more. Molecular and Genetic analysis require a significant amount of DNA, which we would not have without PCR. It revolutionized the study of DNA, replacing all previous recombinant DNA technology. <ref> Mullins, K., Francois, F.& Gibbs R.A. (1994 ) The Polymerase Chain Reaction. p3. Springer- Science +Business Media. Birkhauser, Boston<br />
Available at [https://books.google.com.au/books?hl=en&lr=&id=gjrTBwAAQBAJ&oi=fnd&pg=PR5&dq=kary+mullis+PCR&ots=mpzAyRh5ZY&sig=PQ4goNoKJ90tb3-MkPk62zrTGbw#v=onepage&q=kary%20mullis%20PCR&f=false] </ref> <br />
<br />
[[File:PCR.jpg|thumb|right|Polymerase chain reaction (PCR) amplifies DNA specific to genetic sequence of interest, enabling the monitoring and diagnose molecular abnormalities such as single gene disorders using minute samples such as embryonic cells, blood & tissue <ref>NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref>]]<br />
{|<br />
|- align="left" bgcolor="DDCEF2"<br />
|'''Procedure'''<br />
|}<br />
Samples are obtained from the the blastocyst, a polar body biopsy or the blastomeres stages of the embryo. <br />
*Stage 1 Denaturing: separating the target strands of DNA <br />
The obtained sample is heated to roughly 90 degrees celcius, this heat breaks the relatively weak bonds between nucleotides that form DNA. The double stranded DNA is split into two single strands of DNA that are used as templates.<br />
*Stage 2 Annealing: Binding the Primers to the target DNA sequence <br />
PCR will only copy the target sequence of DNA specified by specific PCR primer. These synthesized primers oligonucleotides are small artificial pieces of DNA. TAQ polymerase enzyme synthesize two new strands of DNA duplicate to the single sample DNA stand template indicated by these primers. During this stage the reaction is cooled to a temperature between 40-60 degrees Celsius. <br />
*Stage 3- Extension- making copies <br />
Each of these two copies are then used again as templates generating two further replications This cycle can occur as many 30 -40 times within a couple hours leading to billions of extra copies of the original DNA segment. The optimal temperature for the further replication is roughly 72 degrees Celsius. <br />
This process mediated by a thermocycler machine that is programmed to alter the temperature of the reaction every couple of minutes, perpetuating the cycle of DNA denaturing and synthesis. <br />
This process, generates exponentially exact copies of the original template DNA sequence. <br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
!PCR cycles<br />
<br />
{|<br />
|-<br />
| '''PCR Cycle'''<br />
| '''Target Copies'''<br />
|-<br />
| 1<br />
| 2<br />
|-<br />
| 2<br />
| 4<br />
|-<br />
| 3<br />
| 8<br />
|-<br />
| 4<br />
| 16<br />
|-"<br />
| 5 <br />
| 32<br />
|-<br />
| 6 <br />
| 64<br />
|-<br />
| 7 <br />
| 128<br />
|-<br />
| 8<br />
| 256<br />
|- <br />
| 9<br />
| 512 <br />
|-<br />
| 10<br />
| 1024<br />
|-<br />
| 15<br />
| 32,768<br />
|-<br />
| 20 <br />
| 1,048,578<br />
|-<br />
| 25<br />
| 33,554,432<br />
|-<br />
| 30 <br />
| 1,073,741,842<br />
|-<br />
|}<br />
<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="6" |'''Advantages'''<br />
|-bgcolor="FFFAFA"<br />
| Fast and inexpensive way of copying a target sequence of DNA<br />
|-bgcolor="FFFAFA"<br />
| Particularly useful for the diagnosis of single cell defects<br />
|-bgcolor="FFFAFA"<br />
| Rapid generation of results (within hours)<br />
|-bgcolor="FFFAFA"<br />
| Highly sensitive, a single molecule of DNA is sufficient for reaction<br />
|-bgcolor="FFFAFA"<br />
| Generates DNA copies exponentially<br />
|-bgcolor="FFFAFA"<br />
| This enables DNA amplification required for molecular and genetic diagnostic analysis<ref> Dreesen, J., Drusedaul, M., Smeets, H., Die-Smulders, C., Coonen, E., Dumoulin, J., Gielen, M., Evers, J., Herbergers, J. & Geradets, J. (2008) Validation of preimplantation genetic diagnosis by PCR analysis: genotype comparison of the blastomere and corresponding embryo, implications for clinical practice. Mol. Hum. Reprod. 14 (10):573-579.doi: 10.1093/molehr/gan052. Retrieved from [http://molehr.oxfordjournals.org/content/14/10/573.short] </ref> <ref><pubmed>20966460</pubmed></ref><br />
|-bgcolor="DDCEF2"<br />
| rowspan="4"|'''Disadvantages'''<br />
|-bgcolor="FFFAFA"<br />
| Only during the exponential DNA replication phase, the starting quantity sequence contained in the original sample (template DNA strand) can be determined<br />
|-bgcolor="FFFAFA"<br />
| PCR reaction is limited to by presence of inhibitors in the sample<br />
|-bgcolor="FFFAFA"<br />
| Self annealing due to the accumulation of the product -stopping exponential amplification for the target sequence and reach a plateau<br />
quantification of the end point of reaction of PCR products unreliable - therefore real time quantitative RT-PCR is necessary<br />
<ref> NIS (2015) Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref><br />
|-bgcolor="FFFAFA"<br />
| Not a diagnostic method on its own, requires further analysis<br />
|}<br />
===Fluorescent In Situ Hybridisation (FISH)===<br />
Fluorescence in situ hybridization (FISH) the one of the most effective and rapid <ref name="PMID26338801"><pubmed>26338801</pubmed></ref> Preimplantation Genetic Diagnosis (PGD). This techniques used to locate a specific DNA sequences within a chromosome. FISH facilitates the clinical diagnosis of chromosomal abnormalities indicated by sequential duplications, deletions and rearrangements of chromosome, that are usually missed with microscopic analysis. This technique is especially relevant for female embryos with X-linked diseases,<ref name="PMID20809319"><pubmed>20809319</pubmed></ref> that have no other mutation specific tests [http://www.ncbi.nlm.nih.gov/pubmed/20809319] As part of PGD, samples are collected from various stages of the embyro,and they are able to conducted tests on the blastocyst, a polar body biopsy and the blastomeres <ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. FISH is 99% effective when used in conjunction with competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities<ref name="PMID26338801"/>.<br />
{|<br />
|- align="left" bgcolor="DDCEF2"<br />
|'''Procedure'''<br />
|}<br />
Samples are collected from either the blastocyst, a polar body biopsy or the blastomeres stages of the embryo <ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
DNA strands are heated and denatured causing their the individual DNA strands to break apart<br />
Probes are single complimentary stands of DNA a that have been tagged with small chemical agents that glow brightly in the presence of a specific region on a chromosome. These specific probes then hybridize and join to their complementary DNA strand. <br />
The fluorescent tags enable the researchers to correctly identify the presence or lack thereof and location of the specific chromosomes that they are testing for. <ref name="PMID17876073"><pubmed>17876073</pubmed></ref><br />
Researcher analyse the results by identifying the number and the relative location of the fluorescent dots generated by the FISH images.<ref name="PMID17970921"><pubmed>17970921</pubmed></ref><br />
The probe will not fully hybridise if there has been a duplication or a deletion of the DNA - indicating chromosomal and sex chromosomal anomalies like trisomies and aneuploidies. <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref><br />
Different probes are used for different purposes: <ref>Unique, Rare Chromosome Disorder Support Group (2013) Fluorescence in situ hybridisation (FISH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/Other/FISH%20FTNW.pdf]</ref><br />
*'''Locus specific tags''' detect very small imbalances, and locate isolated small portions <br />
of genes within a chromosome<br />
*'''Alphoid/Centomeric Repeat probes''' are developed from the repetitive sequence located in the middle region of each chromosome, useful in determining the number of chromosomes , detecting rearrangement and when used in conjunction with locus probes to determine the absence of genetic material on a chromosome. <br />
*'''Paint Probes''' are collections of smaller probes with their own stains that bind to a different section on the chromosome - allowing the full chromosome too be labeled a unique colour, this "full colour map" can be used to know the spectral karyotype- full chromosomal mapping is useful in examining chromosomal abnormalities. <br />
[[File:Fluorescent In Situ Hybridisation (FISH).jpg|thumb|right|'''FISH''' We are able to tag Specific DNA sequences using Probes which have been tagged with fluorescent Labels.This technique enables the clinical diagnosis of chromosomal abnormalities, indicated by sequential duplication, deletions and rearrangements of chromosome <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref>]]<br />
<br />
{|class="wikitable" align="center"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="8" |'''Advantages''' <br />
|-bgcolor="FFFAFA" <br />
| FISH is 99% effective when used in conjunction with Competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities.<ref><pubmed>26338801</pubmed></ref><br />
|-bgcolor="FFFAFA" <br />
| Rapid generation of results<br />
|-bgcolor="FFFAFA"<br />
| Identifies very small translocations and aneuploidies that occur within chromosomes, that would usually be missed under microscopic analysis<br />
|-bgcolor="FFFAFA" <br />
| Indicates whether the accessed chromosomes are normal <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|-bgcolor="FFFAFA" <br />
| Tests for the most common chromosomal abnormalities - down syndrome chromosomes 13,16,18,21 and 22 <ref><pubmed>21749752</pubmed></ref><br />
|-bgcolor="FFFAFA" <br />
| It may be used to compare the chromosomal gene arrangements in related species<br />
|-bgcolor="FFFAFA" <br />
| can be used to identify and remove inheritable X-linked disease or sex chromasome anomalies such as Duchennes Muscular Dystrophy, hemophilia, ectodermal dysplasia <ref><pubmed>17876073</pubmed></ref><br />
|-bgcolor="DDCEF2"<br />
| rowspan="5"|'''Disadvantages'''<br />
|-bgcolor="FFFAFA" <br />
| FISH destroys all cells tested <ref> O'Connor, C. (2008) Fluorescence in situ hybridization (FISH). Nature Education 1(1):171. retrieved from [http://www.nature.com/scitable/topicpage/fluorescence-in-situ-hybridization-fish-327] </ref><br />
|-bgcolor="FFFAFA" <br />
| It does not fully access all chromosomes (only ~ 12)<br />
|-bgcolor="FFFAFA" <br />
| Analysis of results is dependent upon the dot quality impacted by hybridisation efficiency or the camera sensitivity <ref><pubmed>17970921</pubmed></ref><br />
|-bgcolor="FFFAFA" <br />
| some studies indicate that using FISH on a day-3 embryo biopsy decreases the rate of live births <ref><pubmed>26168107</pubmed></ref><br />
|}<br />
<br />
===Array Comparative Genomic Hybridisation (aCGH)===<br />
aCGH also known as Microarray analysis efficiently scans the entire genome for chromosomal imbalances. CGH was initially developed to detect the number of changes in a solid tumor mass. It uses 2 genomes comparing the sample to the control, with each labeled in a different fluorescent dye<ref name="PMID1876176"><pubmed>1876176</pubmed></ref>. Earlier CGH techniques were limited by the resolution of the imaging <ref> Lichter, P., et al. Comparative genomic hybridization: Uses and limitations. Seminars in Hematology 37, 348–357 (2000)</ref> , these initial limitations were overcome by using Microarrays in conjunction with CGh to improve the resolution of the imaging, Array Comparative Genomic Hybridisation (aCGH). This method compares sample and control microarrayed slides containing small segments of DNA (probes). <ref> Lucito, R., et al. Representational oligonucleotide microarray analysis: A high-resolution method to detect genome copy number variation. Genome Research 13, 2291–2305 (2003) </ref> the Probes used will vary according from the small (25-85 base pairs) oligonucleotides manufactured to highlight different target sequences, to the very large genomic clones (80,000- 200,00 base pairs), and as these are significantly smaller than the traditional metaphase chromosomes used for CGH, generating a higher resolution of image. <ref name="PMID22467166"><pubmed>22467166</pubmed></ref>.aCGH is used as a diagnostic tool for prenatal detection f chromosomal abnormalities <ref name="PMID19012303"><pubmed>19012303</pubmed></ref>.<br />
{|<br />
|- align="left" bgcolor="DDCEF2"<br />
|'''Procedure'''<br />
|}<br />
<ref> Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432] </ref><br />
The sample is obtained (skin, blood or fetal cells) and DNA is obtained. <br />
As a part of PGD fetal cell samples are collected from; the fertilized egg polar bodies, the blastomere (day 3 embryo) or the blastocyst/tropoectoderm stage (day 5 embryo).<br />
Sample DNA is labeled with one fluorescent dye, and the control DNA is labeled with a different colored fluorescent dye. the control DNA is used as the base point of reference. <br />
heated and denatured single DNA strands then hybridize to their complementary single strand probes, which are then combined and applied to a microarray and the results are run through a computer program and a digital imaging system is used to quantify the results( fluorescent intensities of the labeled probes). <br />
<br />
[[File:aCGH.jpg|thumb|right|'''aCGH''' checks the entire genome for chromosomal imbalances, by comparing control and a sample slides contatining small segements of DNA sample microarrayed slides small segments of DNA. Illustrated by student z5020317 and adapted from <ref> NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation. retrieved from [http://www.phgfoundation.org/file/5237/]</ref> <ref>Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432]</ref>]]<br />
<br />
The fluorescent ratio and the hybridization signal at different locations on the genome of the control DNA are used to identify any variances present in the sample DNA. aCGH facilitates the clinical diagnosis of submicroscopic chromosomal duplication, deletion and rearrangements indicative of chromosomal disorders such as trisomies 1-22and specific sex linked disorders. <br />
Duplications in the DNA are displayed by the computer program as spikes/ peaks over an established threshold and deletions in DNA are displayed by the computer program as spikes/ toughs beneath this threshold <br />
<br />
{|class="wikitable" align="center"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="12" |'''Advantages''' <br />
|-bgcolor="FFFAFA"<br />
| Multiple applications: prenatal genetic diagnosis, cancer diagnosis, <ref name="PMID20193845"><pubmed>20193845</pubmed></ref> genetic screening for developmental delay (learning disabilities) <ref name="PMID17309648"><pubmed>17309648</pubmed></ref>. or congenital anomalies that are suspected to be genetic in origin <ref>NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation . retrieved from [http://www.phgfoundation.org/file/5237/]</ref><br />
|-bgcolor="FFFAFA"<br />
| trace represents all chromosomes present in the human genome chromosomes 1-22 and the X & Y chromosomes, and therefore is the most accurate method for testing whole embryo aneuploidy<br />
|-bgcolor="FFFAFA"<br />
| aCGH has been extensively tested, and Validated, and is now used world wide.<br />
|-bgcolor="FFFAFA"<br />
| Detects submicroscopic alterations<br />
|-bgcolor="FFFAFA"<br />
| Detects deletions and additions and rearrangements as well as amplification, of the WHOLE genome, simultaneously.<br />
|-bgcolor="FFFAFA"<br />
| Used as a diagnostic tool for prenatal detection of chromosomal abnormalities <ref name="PMID22034057"><pubmed>22034057</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Provides high resolution genomewide screening of segmental genomic copy number variations<br />
|-bgcolor="FFFAFA"<br />
| Very accurate when used in conjunction with FISH<br />
|-bgcolor="FFFAFA"<br />
| Alone is more reliable and in detecting chromosomal abnormalities, with a higher implantation success rate, than FISH <ref name="PMID20494259"><pubmed>20494259</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Allows an in depth research focus upon specific types of rearrangements within selected chromosomal regions, a recent particular area of interest is subtelomeric and pericentromeric rearrangements<br />
|-bgcolor="FFFAFA"<br />
| Reduces the risk of failed implantation and miscarriage, improving the chance of a healthy baby <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|-bgcolor="DDCEF2"<br />
| rowspan="9" |'''Disadvantages'''<br />
|-bgcolor="FFFAFA"<br />
| Translocations and inversions of DNA are not detected<br />
|-bgcolor="FFFAFA"<br />
| Limited ability diagnosing specific polyploidies such as triploidy <ref> Unique, Rare Chromosome Disorder Support Group (2013) Microarray-based Comparative Genomic Hybridiation (array CGH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/other/array%20cgh%20ftnw.pdf] </ref><br />
|-bgcolor="FFFAFA"<br />
| Will not detect mosaicism detection <20% (cultures where >1 of 5 cells are trisomy 12)<br />
|-bgcolor="FFFAFA"<br />
| Will not detect balanced chromosomal rearrangement<br />
|-bgcolor="FFFAFA"<br />
| Will not detect duplications or deletions <80kb<br />
|-bgcolor="FFFAFA"<br />
| Will not detect point mutations within genes <ref>Washington department of education (CGH- FAQ for physicians. Signature Genomic LAboratories, LLC. Retrieved from [https://depts.washington.edu/dbpeds/Lab%20Tests/SignatureCGH-physician_FAQ.pdf]</ref><br />
|-bgcolor="FFFAFA"<br />
| will not detect chromosomal position of genomic gains<br />
|-bgcolor="FFFAFA"<br />
| Will not detect loos of heterozygosity (LOH) or Absence of heterozygosity (AOH) <ref>WiCell Research Institute Inc. (2012) Comparative Genomic Hybridization Microarray. <br />
retrieved from [http://www.wicell.org/home/cytogenetic-services/cgh-microarray/array-comparative-genomic-hybridization-acgh.cmsx]</ref><br />
|}<br />
<br />
===Next Generation Sequencing===<br />
The development and advances within ART in the past 20 years, as well as the increasing popularity of IV, has lead to an influx of new technologies developed to screen embryos for chromosomal anomalies, which are covered by the umbrella term of Next generation Sequencing (NGS). NGS is a general term used to describe all of the new and emerging screening techniques currently being introduced and used as part of PGD for IVF . NGS screens for single gene disorders as well as conducting extensive and very comprehensive chromosome diagnosis by sequencing, counting, and accurately assembling millions of DNA reads, simultaneously. <ref name="PMID23499002"><pubmed>23499002</pubmed></ref> There is a movement for NGS to replace the other limited testing techniques and be used as the standard. <br />
{|<br />
|- align="left" bgcolor="DDCEF2"<br />
|'''Procedure'''<br />
|}<br />
Samples are collected from either blastomere or the blastocyst/tropoectoderm and processed for analysis by a computer system. <br />
The methodology of each process is unique to the technique being used. <br />
<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="14" |'''Advantages''' <br />
|-bgcolor="FFFAFA" <br />
| Cheaper<br />
|-bgcolor="FFFAFA"<br />
| Opens new diagnostic possibilities<br />
|-bgcolor="FFFAFA"<br />
| Accurately tests all 24 chromosomes<br />
|-bgcolor="FFFAFA"<br />
| Tests for the presence of monogenic diseases of known genetic background<br />
|-bgcolor="FFFAFA"<br />
| Reduces the number of biopsies required for diagnosis<br />
|-bgcolor="FFFAFA"<br />
| Higher detection rate of small translocations<br />
|-bgcolor="FFFAFA"<br />
| Highly accurate is testing for compound point mutations, chromosomal duplication, deletions and insertions <ref name="PMID23312231"><pubmed>23312231</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| It accurately detects chromosomal aneuploidy and unbalanced rearrangement <ref name="PMID25685330"><pubmed>25685330</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Higher detection rate of small translocations<br />
|-bgcolor="FFFAFA"<br />
| NGS single gene disorder screenings can conducted in conjunction with PCR comprehensive chromosomal screening<br />
|-bgcolor="FFFAFA"<br />
| Reduces human error <br />
|-bgcolor="FFFAFA"<br />
| Better detects the presence of mosaicism<br />
|-bgcolor="FFFAFA"<br />
| Work well in conjunction with CGH and aCGH as part of PGD, improving the chances of IVF. <ref> Morris, R. S. (2015 ) Next generation sequencing for PCG|PGS|CCS. IVF1 retrieved from [http://www.ivf1.com/next-generation-sequencing for-pgd] </ref><br />
|-bgcolor="DDCEF2"<br />
| rowspan "2" |'''Disadvantages''' <br />
|-bgcolor="FFFAFA"<br />
| There are limited information available to clinical applications of NGS <ref><pubmed>26100406</pubmed></ref><br />
|}<br />
<br />
==Diagnosis==<br />
There are a large amount of diseases that PGD can apply to, below are descriptions of the diseases that PGD are more commonly used for. Utilization of Diseased Cell Lines<br />
===Cystic Fibrosis===<br />
Cystic fibrosis is a single gene disorder. It is autosomal recessive and involves mutations in the cystic fibrosis transmembrane conductance regulator (CTFR) gene. The CTFR gene is normally responsible for the decrease in chloride and the transport of bicarbonate in epithelial cells thus playing a major physiological role. In PGD procedures, identification of the gene is assisted by microsatellite markers that have similar composition to the CTFR gene itself. Biopsy of two cells at the blastocyst stage is recommended if markers are not available. There are many variations of cystic fibrosis the most common being P.Phe508del <ref name="PMID26014425"><pubmed>26014425</pubmed></ref>.<br />
===Duchenne Muscular Dystrophy ===<br />
Duchenne Muscular Dystrophy is an X-linked recessive disease. It involves the Xp21 gene where majority of the mutations are chromosomal deletions with a smaller percentage resulting from duplications <ref name="PMID18359022"><pubmed>18359022</pubmed></ref>.<br />
<br />
===Autosomal Recessive MEckel-Gruber Syndrome===<br />
Autosomal recessive genetic defect caused by the TMEM67 gene. It results in cystic dysplasia of the kidneys with fibrotic change in the liber and occipital encephalocele. Other malformations could also be present in the central nervous system. In PGD whole genome amplification of single blastomeres are taken to identify the gene, this is also coupled with PCR techniques. Maternal plasma can also be extracted for PGS. <ref><pubmed>24039893</pubmed></ref> <br />
===β – Thalassemia=== <br />
β – Thalassemia is known as the most common type of autosomal recessive inherited disorder among haemoglobinopathies. It involves the adult β-globin gene and is associated with the absent or decreased expression of the gene. This is commonly caused by a single nucleotide change in the gene. PGD has been used successfully worldwide to identify the β-globin gene where its application is usually performed on a single blastomere or polar body <ref name="PMID19064120">19064120</pubmed></ref>.<br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
! Applicable diseases for PGD <ref>Genoma Group (2014). Retrieved September 18th, 2015, from http://www.preimplantationgeneticdiagnosis.it/genetic-diseases-diagnosed-by-pgd.htm </ref>, <ref>Genesis Genetics (2015). Retrieved September 18th, 2015, from http://genesisgenetics.org/pgd/what-we-test-for/</ref>, <ref>Human Fertilisation & Embryology Authority (2015). Retrieved Septembr 18th, 2015, from http://guide.hfea.gov.uk/pgd/</ref><br />
|-<br />
| '''Disease'''<br />
| '''Involved Genes'''<br />
|-<br />
| 5 Alpha Reductase Deficiency (5ARD)<br />
| SRD5A2 <br />
|-<br />
| Achondroplasia<br />
|FGFR3 <br />
|-<br />
| Acute Intermittent Porphyria <br />
| ALAD, ALAS2, CPOX, FECH, HMBS, PPOX, UROD, or UROS<br />
|-<br />
| Adrenoleukodystrophy (Adrenomyeloneuropathy)<br />
| ABCD1 <br />
|-<br />
| Agammaglobulinaemia (x-linked) <br />
|BTK <br />
|-<br />
| Agammaglobulinemia Bruton Tyrosine Kinase (BTK) <br />
|BTK <br />
|-<br />
| Aicardi Goutieres Syndrome 1 (AGS1) <br />
|TREX1, RNASEH2A, RNASEH2B, RNASEH2C, SAMHD1<br />
|-<br />
| Alagille Syndrome<br />
|JAG1 or NOTCH2<br />
|- <br />
| Alpers-Huttenlocher Syndrome <br />
|POLG <br />
|-<br />
| Alpha-1-antitrypsin deficiency <br />
|SERPINA1 <br />
|-<br />
| Alpha-Mannosidosis<br />
| MAN2B1 <br />
|-<br />
| Alpha Thalassemia <br />
|HBA1 or HBA2 <br />
|-<br />
| Alports Syndrome<br />
|COL4A3, COL4A4, COL4A5<br />
|-<br />
| Alzheimer's Disease - early onset (Type 3 and 4) <br />
|APP, PSEN1, or PSEN2<br />
|-<br />
| Amyotrophic Lateral Sclerosis 1 (ALS1) <br />
|C9orf72, SOD1, TARDBP, FUS, ANG, ALS2, SETX, VAPB <br />
|-<br />
| Argininosuccinic Aciduria <br />
| ASL<br />
|-<br />
| Arrhythmogenic Right Ventricular Cardiomyopathy/ Dysplasia (ARVC/D)<br />
| DSG2; DSP; PKP2<br />
|-<br />
| Ataxia Telangiectasia<br />
| ATM<br />
|-<br />
| Autosomal Recessive Meckel-Gruber Syndrome<br />
| TMEM67<br />
|-<br />
| Bardet-Biedl Syndrome (BBS)<br />
| BBS1; BBS10<br />
|-<br />
| Barth Syndrome<br />
| TAZ<br />
|-<br />
| Beta Thalassaemia<br />
| HBB<br />
|-<br />
| Birt-Hogg-Dubé Syndrome<br />
| FLCN<br />
|-<br />
| Breast Ovarian Cancer Familial Susceptibility (BRCA2)<br />
| BRCA1; BRCA2<br />
|-<br />
| Canavan Disease <br />
| ASPA<br />
|-<br />
| Carnitine-Acylcarnitine Translocase Deficiency <br />
| SLC25A20<br />
|-<br />
| Cerebral Arteriopathy with Subcortical Infarcts & Leukoencephalopathy (CADASIL)<br />
| NOTCH3<br />
|-<br />
| Cerebral Cavernous Malformation<br />
| CCM1<br />
|-<br />
| Charcot-Marie-Tooth Disease<br />
| GJB1; MPZ; NEFL; PMP22<br />
|-<br />
| CHARGE Syndrome<br />
| CHD7<br />
|-<br />
| Cherubism<br />
| SH3BP2<br />
|-<br />
| Choroideremia<br />
| CHM<br />
|-<br />
| Chronic Granulomatous Disease<br />
| CYBB; NCF1<br />
|-<br />
| Ciliary Dyskinesia<br />
| DNAH5<br />
|-<br />
| Citrullinemia<br />
| ASS1<br />
|-<br />
| Cleidocranial Dysplasia<br />
| RUNX2<br />
|-<br />
| Cockayne Syndrome<br />
| ERCC6<br />
|-<br />
| Congenital Adrenal Hyperplasia<br />
| CYP21A2<br />
|-<br />
| Congenital Cataracts<br />
| GJA8; VSX2<br />
|-<br />
| Congenital Diarrhea, Syndromic<br />
| SPINT2<br />
|-<br />
| Congenital Disorders of Glycosylation (CDG)<br />
| ALG1; ALG6; CDG1C; DOLK; PMM2<br />
|-<br />
| Cornelia de Lange Syndrome <br />
| NIPBL<br />
|-<br />
| Craniosynostosis<br />
| TWIST1<br />
|-<br />
| Crouzon Syndrome<br />
| FGFR2<br />
|-<br />
| Cysteinyl Leukotriene Receptor 1 Deficiency <br />
| CYSLTR1<br />
|-<br />
| Cystic Fibrosis<br />
| CFTR<br />
|-<br />
| Diamond –Blackfan Anemia <br />
| RPS19<br />
|-<br />
| Duchenne Muscular Dystrophy <br />
| DMD<br />
|-<br />
| Dyskeratosis congenita (Male embryos only)<br />
| DKC1<br />
|-<br />
| Ectodermal dysplasia (Hypohidrotic)<br />
| EDA; EDA1; GJB6; IKBKG<br />
|-<br />
| Familial Adenomatous polyposis coli (FAP)<br />
| APC<br />
|-<br />
| Familial Dysautonomia<br />
| IKBKAP<br />
|-<br />
| Fanconi Anemia <br />
| FANCA; FANCC; FANCD2; FANCF; FANCG; FANCJ<br />
|-<br />
| Fragile X Syndrome (FRAX)<br />
| FMR1<br />
|-<br />
| Galactosemia <br />
| GALT<br />
|-<br />
| Gangliosidosis<br />
| GLB1<br />
|-<br />
| Glanzmann Thrombasthenia <br />
| ITGA2B<br />
|-<br />
| Glutaric Acidemia (aciduria)<br />
| GCDH <br />
|-<br />
| Glycogen Storage Disease <br />
| G6PC; GAA; SLC37A4<br />
|-<br />
| Haemophilia A<br />
| F8<br />
|-<br />
| Haemophilia B<br />
| F9<br />
|-<br />
| Hereditary Nonpolyposis Colorectal Cancer: Lynch Syndrome<br />
| MLH1; MSH2; MSH6<br />
|-<br />
| Holt Oram Syndrome<br />
| TBX5<br />
|-<br />
| Huntington Disease<br />
| HD<br />
|-<br />
| Hydrocephalus<br />
| L1CAM<br />
|-<br />
| Ichthyosis <br />
| ABCA12; STS<br />
|-<br />
| Incontinentia Pigmenti (IP)<br />
| NEMO<br />
|-<br />
| Joubert Syndrome 5<br />
| INPP5E<br />
|-<br />
| Krabbe Disease<br />
| GALC<br />
|-<br />
| Leber Congenital Amaurosis (LCA)<br />
| CEP290; GUCY2D<br />
|-<br />
| Leigh Syndrome (Infantile Subacute Necrotising Encephalopathy)<br />
| LRPPRC<br />
|-<br />
| Lesch Nyan Syndrome<br />
| HPRT1<br />
|-<br />
| Leukocyte Adhesion Deficiency (Type I)<br />
| ITGB2<br />
|-<br />
| Li-Fraumeni Syndrome<br />
| TP53<br />
|-<br />
| Macular Dystrophy Retinal <br />
| VMD2<br />
|-<br />
| Maple Syrup Urine Disorder (MSUD)<br />
| BCKDHB<br />
|-<br />
| Marfan Syndrome <br />
| FBN1<br />
|-<br />
| Menkes Syndrome<br />
| ATP7A<br />
|-<br />
| Mitochondrial DNA Depletion Syndrom <br />
| POLG; RRM2B; SUCLA2; TK2<br />
|-<br />
| Mucolipidosis type II<br />
| GNPTAB<br />
|-<br />
| Multiple Endocrine Neoplasia<br />
| MEN1; MEN2A; MEN2B<br />
|-<br />
| Multiple Exostoses<br />
| EXT1; EXT2 <br />
|-<br />
| Myotubular myopathy<br />
| MTM1 <br />
|-<br />
| Nail-Patella Syndrome<br />
| LMX1B<br />
|-<br />
| Neurofibromatosis Type 1<br />
| NF1<br />
|-<br />
| Neurofibromatosis Type 2 <br />
| NF2<br />
|-<br />
| Noonan Syndrome<br />
| KRAS, PTPN11; SOS1<br />
|-<br />
| Norrie Disease<br />
| NDP<br />
|-<br />
| Ocular Albinism <br />
| GPR143<br />
|-<br />
| Oculocutaneous Albinism <br />
| OCA2; TYR <br />
|-<br />
| Oculodentaldigital Dysplasia<br />
| GJA1<br />
|-<br />
| Optic Atrophy<br />
| OPA1<br />
|-<br />
| Ornithine Transcarbamylase Deficiency <br />
| OTC<br />
|-<br />
| Osteogenesis imperfeca <br />
| COL1A1; COL1A2<br />
|-<br />
| Osteopetrosis <br />
| CLCN7; OSTM1; TCIRG1<br />
|-<br />
| Pachyonychia Congenita <br />
| KRT16; KRT6A<br />
|-<br />
| Pancreatitis, Hereditary<br />
| PRSS1 <br />
|-<br />
| Papillorenal syndrome <br />
| PAX2<br />
|-<br />
| Phenylketonuria <br />
| PAH <br />
|-<br />
| This table does not cover the complete list of diseases that PGD can be applied to.<br />
|}<br />
<br />
==Laws & Legal status==<br />
<br />
{| class="wikitable" <br />
|-bgcolor="DDCEF2"<br />
|'''Country'''<br />
|'''Legislation'''<br />
|-bgcolor="FFFAFA" <br />
| Australia<br />
| PGD is currently used to detect serious genetic conditions to improve the outcome of Assisted Reproductive Technologies (ART). In very rare cases it may be used to select an embryo with compatible tissue for a sibling who has a life-threatening disease where other means of treatment is unavailable. This is with the conditions that the use of PGD will not affect the welfare and interests of the child to be born. The parents must also receive adequate counselling and have full understanding of the procedures of PGD. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"> National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art</ref><br />
The use of PGD for sex-selection is prohibited with the exception of reducing the risk of the transmission of serious sex-linked genetic conditions. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"/><br />
|-bgcolor="FFFAFA"<br />
| Brazil<br />
| The laws regarding PGD in Brazil are not strictly regulated. They are vague and there is limited information surround the activities of assisted reproduction in general in the country <ref name="PMID25493379"><pubmed>25493379</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| Czech Republic<br />
| The laws in the Czech Republic allow those with a “defined indication in order to exclude risk of serous genetically conditioned disease and defects with embryos before they are implanted into the cavity of the uterus”. Couples that undergo any assisted reproductive treatment including PGD have to be married. Sex-selection is illegal except in regards to serious sex-linked genetic diseases <ref name="PMID24777348"><pubmed>24777348</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| Greece<br />
| In Greece, ART is open to those up to the age of 50 with written consent. It can only be used if a medical necessity is present such as the susceptibility of serious hereditary diseases. Sex selection is banned apart from cases of sex-linked diseases and sexually transmitted diseases <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| India<br />
| In India there is a cultural preference for boys thus the Prenatal Diagnostic Techniques (Regulation and Prevention of Misuse) Act was introduced in 1994. This law limits the use of PGD for sex determination except in cases of specific congenital diseases. These laws however are not strictly enforced. <ref>World Health Organisation (2015) Gender and Genetics Retrieved on October 21st 2015 from:http://www.who.int/genomics/gender/en/index4.html</ref><br />
|-bgcolor="FFFAFA"<br />
| Portugal <br />
| ART is only available to those who are married or have a similar type of relationship for at least two years. The couples cannot be of the same sex and must be at least 18 years of age. Sex selection is illegal except in cases of sex-linked diseases. The use of PGD is illegal if the predictive value of genetic tests are very low <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| Spain<br />
| PGD can be applied to “serious hereditary diseases not amenable to postnatal curative treatment” and “detection of other abnormalities which may compromise the viability of the pre-embryo”. If PGD is to be used for any other purpose authorisation must be acquired <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| Sweden <br />
| The use of PGD is strictly regulated and couples must achieve authorisation of the National Board of Health and Welfare. It can only be used it can only be used if the child is at risk to inheriting a serious chromosomal or monogenetic disease. It cannot be used for selection of specific characteristics <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| United Kingdom<br />
| Those involved with carrying out the IVF treatment must have a license from the Human Fertilisation and Embryology Authority (HFEA). Only embryos that are approved by the HFEA can be implanted where the embryonic nuclear or mitochondrial DNA cannot be altered with the exception of preventing mitochondrial diseases <ref name="PMID24777348"/>. <br />
|}<br />
<br />
==Future/Current Research==<br />
===Noninvasive Preimplantation Genetic Testing without Embryo Biopsy===<br />
Different parameters of gametes, zygotes, embryos (“vacuoles in sperm heads, spindle position in mature oocytes, cleavage intervals of zygote, and embryo developmental dynamics”) may correlate with aneuploidy rates. This knowledge may be applied in potential noninvasive preimplantation diagnostic methods. Several methods have been proposed and are currently further researched<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Sperm Selection====<br />
Intracytoplasmic morphologically selected sperm injection (IMSI) is common procedure in IVF treatment to improve fertilization rates in patients with poor semen quality. In addition, studies have found that IMSI improves embryo development and that spermatozoa with large vacuoles in their heads correlate with increased aneuploidy rates and disturbed chromosomal structures. Thus, selecting spermatozoa based on morphological hallmarks may decrease aneuploidy rates in the fertilized embryos. As with polar body biopsies, however, this approach will solely be applicable if evidence for severe male detrimental contribution is given<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Blastocoel Fluid Extraction====<br />
In addition, a less invasive retrieval of material for diagnosis could include the extraction of the blastocoel fluid. The cavity of the blastocyst, lined by the trophectoderm, is filled with this blastocoel fluid, which contains metabolites of both trophectoderm and inner cell mass origin. The retrieval does not require a biopsy but merely a small opening to extract the fluid and, thus, causes less harm to the embryo. Multiple studies have applied this method<ref name="PMID22020776"><pubmed>22020776</pubmed></ref> <ref name="PMID23148560"><pubmed>23148560</pubmed></ref> and it may in the future become of clinical relevance.<br />
<br />
<br />
[[File:Aspiration_of_the_Blastocoel_Fluid.jpeg|thumb|Aspiration of the Blastocoel Fluid using a ICSI pipette<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.]]<br />
<br />
<br />
Next to metabolites, the blastocoel fluid can contain DNA. Studies have shown that genomic DNA is present in about 90% of the blastocoel fluid samples tested. Typically the fluid is removed with an ICSI pipette from a day five blastocyst through its mural trophectoderm until the blastocyst fully collapses around the embryo. Several concerns regarding this method in a clinical setting have been raised. The collected DNA may be contaminated by the culture media that contains DNA fractions. The DNA may also be least representative of the actual embryos genome as the DNA may originate from abnormal or degenerated cells. Even though labelled noninvasive, the blastocyst still undergoes manipulation to some degree which may affect its viability. Thus, more research is required until this method can evolve from research to clinical use<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
====Proteomics====<br />
The protein secretome of blastocysts may be representative of its chromosome constitution Recent studies have found biomarkers such as lipocalin-1, interleukin-10, tumor necrosis factor, stem cell factor, and chemokine ligand 13 to be differently secreted by aneuploid blastocyst than by euploid ones. The most significant biomarker appears to be interleukin-10. Paired with novel proteomic technologies and mass spectrometry this knowledge when extended may contribute to a new invasive preimplantation genetic diagnosis method<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Embryo Morphology====<br />
Using time lapse imaging the embryo’s morphology can be closely observed and potential aneuploidy characteristics detected. Such characteristics may include the time of division to five cells, the time between the division from three to four cells, and the duration of the division from one to two and subsequently to three. In addition, the morphological quality of ICM an TE has been positively associated with aneuploidy or euploidy prognosis<ref name="PMID26246880"><pubmed>26246880</pubmed></ref>. These may give rise to an embryo quality screening prior to implantation<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
==Glossary==<br />
'''CTFR''' Cystic Fibrosis Transmembrane Conductance Regulator <br />
<br />
'''ESHRE'''The European Society for Human Reproduction and Embryology<br />
<br />
'''FISH''' Fluorescence in situ hybridisation<br />
<br />
'''ICSI''' Intracytoplasmic Sperm Injection<br />
<br />
'''IMSI''' Intracytoplasmic Morphologically Selected Sperm Injection<br />
<br />
'''NGS''' Next Generation Sequencing <br />
<br />
'''PB''' Polar Body<br />
<br />
'''PGD''' Preimplantation Genetic Diagnosis <br />
<br />
'''PGS''' Preimplantation Genetic Screening<br />
<br />
'''PCR''' Polymerase Chain Reaction<br />
<br />
'''RT''' Robertsonian translocations<br />
<br />
''SNP''' Single Nucleotide Polymorphism <br />
==References==<br />
<br />
<references/><br />
<br />
<br />
{{StudentPage2015}}</div>Z5017878https://embryology.med.unsw.edu.au/embryology/index.php?title=2015_Group_Project_6&diff=2070392015 Group Project 62015-10-21T07:55:51Z<p>Z5017878: </p>
<hr />
<div>{{ANAT2341Project2015header}}<br />
<br />
<br />
=Preimplantation Genetic Diagnosis and Screening=<br />
==Introduction==<br />
Preimplantation genetic diagnosis (PGD) and screening (PGS) are reproductive options for couples with known family histories of genetic disease or couples undergoing IVF procedures due to infertility issues. PGD can diagnose many genetic disorders caused by known chromosomal abnormalities (number and/or structure) or single gene mutations, and, thus decrease the risk of termination of pregnancy or miscarriages and enable such couples to have an unaffected child<ref name="PMID24907939"><pubmed>24907939</pubmed></ref>. Through major improvements in PGD/S and general laboratory technology, the testing for abnormalities in fetuses has shifted from prenatal diagnosis during the first 2 trimesters <ref> Blackburn, S.L. (2003) '''Maternal, Fetal & Neonatal physiology: a Clinical perspective''' (2nd ed.). Seattle: Saudners </ref>, testing for overall fetal growth, complications of pregnancy, and birth defects<ref> Sadler T.W.(2012) '''Langman's Medical Embryology''' (12th ed.) Philadelphia: Lipincott, Wiliams & Wilkins, a Wolters Kluwer Business </ref>, to an embryonic focus especially in advancements in Artificial Reproductive Technologies (ART)<ref><pubmed>20638568</pubmed></ref>. In 1990 PGD for a recessive X-linked disease resulted in the first live birth<ref><pubmed>2330030</pubmed></ref> and has since been incorporated in clinical routine and applied for a variety of genetic diseases, such as sickle cell anemia, thalassemia, or cystic fibrosis<ref name="PMID24907939"/>.<br />
[[File:Preimplantation Genetic Diagnosis Procedure.jpeg|700px|thumb| Simplified steps for PGD<ref name="PMID24907939"/>]]<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=0e-79qKllqk</html5media><br />
|-<br />
| Preimplantation Genetic Diagnosis<ref>IVF Florida (2011, December 11) IVF Florida - South Florida Fertility Specialists - Pre-Implantation Genetic Diagnosis [Video file]. Retrieved from https://www.youtube.com/watch?v=0e-79qKllqk</ref><br />
|}<br />
<br />
==History==<br />
The advances in reproductive technology during the second half of the 20th century, led to PGD's first clinical application in 1990 <ref>Harper, J. (n.d.). The history of PGD. Lecture. UCL Centre for PG&D and CRGH.University College London</ref>.<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
|Year<br />
|<br />
|- bgcolor="FFFAFA"<br />
| '''1967''' <br />
|First PGD on rabbit blastocysts (Gardner& Edwards) <ref name="PMID6036172"><pubmed>6036172</pubmed></ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1986''' <br />
|First Cleavage Biopsy (Wilton & Trounson)<ref>Wilton, L. J., & Trounson, A. O. (1986). Viability of mouse embryos and blastomeres following biopsy of a single cell. In Proceedings of the 18th Annual Conference of the Australian Society for Reproductive Biology, Brisbane, Australia.</ref><br />
|- bgcolor="FFFAFA"<br />
|'''1987''' <br />
|First Blastocyst Biopsy (Muggleton-Harris, Monk, Rawlings, & Whittingham)<ref name="PMID3372699"><pubmed>3372699</pubmed></ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1988''' <br />
|First Polar Body Biopsy (Yury Verlinksy)<ref> Verlinsky, Y., Pergament, E., Andresen, P., Enriquez, G., & Strom, C. (1989). Genetic analysis of polar body DNA: A new approach to preimplantation genetic diagnosis. Am J Hum Genet, 45(4), A272.</ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1990''' <br />
|First Clinical PGD using PCR testing for X-linked (Handyside, Kontogianni, Hardy, & Winston)<ref name="PMID2330030"><pubmed>2330030</pubmed></ref> <br />
|} <br />
==Preimplantation Genetic Diagnosis==<br />
Preimplantation genetic diagnosis (PGD) is used to test the genetic makeup of embryos to detect single gene disorders, chromosomal abnormalities and mitochondrial disorders. It also has applications in gender selection for diseases with unequal gender distributions <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Some diseases commonly involved with PGD include cystic fibrosis, spinal muscular atrophy and beta – thalassaemia <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press.">Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press</ref> <ref name="PMID17823145"><pubmed>17823145</pubmed></ref>. It was first used in the United Kingdom in the 1980s of arenoleucodystrophy and primarily focusing on sex- linked disorders <ref name="PMID17823145"/><ref name="PMID23150080"><pubmed>23150080</pubmed></ref>. PGD is now capable of detecting single cell defects (molecular) and chromosomal disorders resulting from the inversion, translocation or deletion of chromosomes (cytogenic) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>,<ref name="PMID11325751"><pubmed>11325751</pubmed></ref>. PGD can be applied to the embryo at different stages. That is on polar bodies, blastomeres or blastocyst <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>.<br />
Depending on the type of genetic disorder, PGD utilises different methods of genetic testing. These include Fluorescence in situ hybridisation (FISH) which is used for sex – linked disorders and detects chromosomal rearrangements <ref name="PMID11325751"/><ref name="PMID17876073"><pubmed>17876073</pubmed></ref> and Embryo halotyping which allows the identification of chromosomes causing the inherited disorder through knowledge of the pattern of closely linked markers <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. Polymerase chain reaction (PCR) is also widely used to detect molecular abnormalities <ref name="PMID11325751"/>.<br />
PGD is tightly regulated and supported by large organisations namely The American Society for Reproductive Medicine, The European Society for Human Reproduction and Embryology (ESHRE), The European Society of Human Genetics and the Preimplantation Genetic Diagnosis International Society <ref name="PMID25500181><pubmed>25500181</pubmed></ref>.<br />
===Sex-linked disorders===<br />
The determination of a disease as gender specific usually correlates with the presence or absence of specific genes such as SRY on the Y chromosome. It is known that females have two X chromosomes and males have an X and a Y chromosome where abnormalities are more prevalent on the X chromosome. PGD can be used for sex selection where only male embryos are transferred to reduce the chance of inheriting X-linked disorders. However, this does not completely eradicate the problem as male embryos remain susceptible to inheriting an affected X chromosome. Sex determination is only used when the specific mutation is unknown and has yet to be discovered <ref name="PMID24866878"><pubmed>24866878</pubmed></ref>.<br />
===Single gene defects===<br />
Single gene defects can be dominant, recessive, autosomal or X-linked. They are commonly diagnosed using PCR and although the PCR available today is complex and capable of combatting a large range of disease the development of new protocols has been proven to be difficult due to the small DNA sample available <ref name="PMID26168107"><pubmed>26168107</pubmed></ref><br />
===Mitochondrial disorders===<br />
Mitochondrial disorders also known as oxidative phosphorylation disorders arise from mutations in the nuclear DNA or mitochondrial DNA <ref name="PMID26312584"><pubmed>26312584</pubmed></ref>. They pose as a problem because they are unrecognisable until the mutations in the cell reach a detrimental level <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Mitochondrial disorders cause miscarriages and stillbirths as well as death in children and young adults. The effects can either be contained in a single organ or more commonly involve multiple organ failure where organs with high energy demands such as the brain, liver muscle and heart and heavily influenced. They are usually occur spontaneously or result from inheritance from the mother. Since mitochondria are solely inherited from the mother oocyte donations have been used as a solution to combat mitochondrial disorders. Additionally, there has been an increasing use in PGD where embryos that stay under the given threshold of 18% gene-mutations are allowed to be transferred and result in normal development. New technology in the areas of nuclear gene transfer and genome editing are also being experimented with <ref name="PMID26312584"/>. <br />
===Chromosomal disorders===<br />
Chromosomal disorders can be reciprocal, Robertsonian translocations, inversions, deletions and insertions <ref name="PMID26168107"/>. . Data from ESHRE collected between 2010 and 2011 has shown that the most common chromosomal abnormality confronted in PGD are reciprocal chromosomal abnormalities <ref name"PMID26071418"><pubmed>26071418</pubmed></ref>. PGD has also been used successfully for Robertsonian translocations (RT), a type of structural translocation. Children who carry RT are phenotypically normal, however in their later years it is found that they will suffer from infertility and repeated miscarriages due to the high frequency of abnormal embryos <ref name="PMID22081077"><pubmed>22081077</pubmed></ref>. PCR and FISH are the two main techniques used for chromosomal disorders. To be able to conduct the examinations the cells are required to be at the metaphase stage <ref name="PMID26168107"/>. <br />
[[File:Reasons_for_PGD.jpg|600px|thumb|Reasons for PGD<ref name= "PMID24764761"><pubmed><24764761</pubmed></ref>]]<br />
==Preimplantation Genetic Screening==<br />
Prenatal Genetic Screening (PGS) involves an array of methods or ideas that aim to segregate embryos that have genetic flaws and those that are healthy <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. The occurrence of aneuploidy is high around the stages of early embryonic development and they are the most common cause if miscarriages and congenital birth defects <ref name= "PMID26085841"><pubmed>26085841</pubmed></ref>. They have little effect on the morphology of the embryo making them difficult to identify thus identification heavily relies on genetic testing <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. <br />
Genetic sampling is most commonly conducted using Microarray Comparative Genomic Hybridisation (aCGH) as well as FISH, Quantitative PCR and Single Nucleotide Polymorphism (SNP) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. These methods collectively aim to assess numeral and structural chromosomal errors <ref name= "PMID26085841"/>. Studies have also introduced Next- Generation Sequencing (NGS) <ref name= "PMID26085841"/> and Whole Genome Amplification used to screen imbalances in the complete 24-chromosomes <ref name="PMID25953353"><pubmed>25953353</pubmed></ref><br />
Statistics from ESHRE have shown that the most common indications for PGS is advanced age, followed by repeated implantation failure or recurrent miscarriage and male infertility <ref name="PMID26071418"><pubmed>26071418</pubmed></ref>.<br />
===Indications===<br />
A low percentage of structural abnormalities in chromosomes are responsible for the cause of miscarriages. Despite this, they are the most prevalent type of chromosomal abnormality accounted for in PGD <ref name="PMID20638568"/>. The presence of specific gene cycles, initiation of embryonic protein synthesis and evident physiological development are all indicative of a successful in vitro fertilisation procedure <ref name="PMID11576737"><pubmed>11576737</pubmed></ref>. To eliminate further errors from occurring during the PGD procedure it is recommended to undertake further prenatal testing such as amniocentesis in the later stages <ref name="PMID20638568"/>. <br />
====Advanced maternal age====<br />
Data provided by the ESHRE has shown that the mean age of women undergoing PGS is 39 years <ref name="PMID26071418"/>. Women of advanced age have been shown to have a lower rate of pregnancies reaching childbirth <ref name="PMID18583331"><pubmed>18583331</pubmed></ref>. The highlighted concern revolves around the increased occurrence of aneuploidy following maternal age. The optimal age range for the lowest aneuploidy incidence was found to be between 27 to 37 years of age (6%) then progressively higher in women aged up to 42 (33%) and most common in those 44 and above (53%) <ref name="PMID24355045"><pubmed>24355045</pubmed></ref>. <br />
====Recurrent pregnancy loss / IVF failure====<br />
Recurrent pregnancy loss is defined as three or more IVF failures after cumulative transfer of more than 10 good-quality embryos. These are primarily caused by two main factors, reduced endometrium receptivity or embryonic defects. Endometrium receptivity can be negatively influences by instances including uterine pathologies such as thin endometrium, altered expression of adhesive molecules and immunological factors. Additionally, embryonic defects may be due to genetic abnormalities, embryonic aneuploidy or zona hardening. Endometriosis and hydrosalpinx has been known to effect both the endometrium and embryo <ref name="PMID23260857"><pubmed>23260857</pubmed></ref>.<br />
====Human leukocyte antigen matching====<br />
First used in 2001, HLA matching is an option given to parents to save a child with haematological or immunological disease through conceiving another child who would potentially be able to donate cord blood or haematopoietic stem cells from the bone marrow for transplantation. The process namely PGD-HLA has shown to improve haematopoietic stem cell transplant (HSCT). PGD-HLA can only be performed when HSCT is not needed urgently due to the time needed to conceive and delivery the baby <ref name="PMID25500181"><pubmed>25500181</pubmed></ref>. It is most commonly applied to children suffering from relapsed leukaemia <ref name="PMID22524201"><pubmed>22524201</pubmed></ref>. In a case study PGD-HLA was proven to successfully cure 10 diseases including Fanconi anaemia, Diamond-Blackfan anaemia and beta thalassemia <ref name="PMID25066893><pubmed>25066893</pubmed></ref>.<br />
==Biopsy Methods==<br />
Biopsy, the removal of genetic materials, from oocytes or embryos in the preimplantation stage is the primary step in PGD. For the past two decades these biopsies have been performed at three stages, the polar body, blastomere, and blastocyst, and the methodologies optimized to ensure the embryo’s viability. The most common approach involves biopsies at the cleavage stage. However, polar body and blastocyst biopsies are increasingly more often tested and applied. Approached for opening the zona pellucida involve next to the traditional mechanical and chemical means, novel approaches such as noncontact lasers. Their application may simplify and secure the procedure significantly. The most challenging question about PGD procedures remains at what stage biopsies should be taken. Much controversy has developed around this topic, highlighting the varying disadvantages and advantages of temporal biopsies. <ref name="PMID22723007"><pubmed>22723007</pubmed></ref><br />
<br />
{| class="wikitable"<br />
|- align="center" bgcolor="DDCEF2"<br />
|<br />
| Time of Biopsy<br />
| Advantages <br />
| Disadvantages<br />
|- bgcolor="FFFAFA"<br />
| Polar Body<br />
| Day 1<br />
| No harm to oocyte<br />
| Only maternal DNA is tested, often needs to be coupled with other biopsies<br />
|- bgcolor="FFFAFA"<br />
| Blastomere<br />
| Day 3<br />
| …<br />
| … <br />
|- bgcolor="FFFAFA"<br />
| Trophectoderm<br />
| Day 5 and 6 <br />
| Little harm, large amount of genetic material<br />
| Opening of blastocyst necessary, small time window for procedure<br />
|}<br />
<br />
<br />
[[File:Polar_Body,_Blastomere,_and_Trophectoderm_Biopsy.jpeg|thumb|Polar body (A), blastomere (B) and trophectoderm (C) biopsies<ref name="PMID25625041"><pubmed>25625041</pubmed></ref>.]]<br />
<br />
<br />
<br />
PMID 24305177<br />
===Polar Body Analysis===<br />
Day 1<br />
====Description====<br />
Polar body (PB) biopsy, which was introduced in 1990, offers a promising alternative to biopsies performed at the blastomere stage for PGD/S indications on legal and practical grounds. <br />
Description: Consequent embryo development does not necessitate the presence of the first and second PB and their removal may not be crucial. PB biopsy requires precise timing. Keeping track of the meiotic cell cycle is necessary to perform a successful biopsy and, therefore, PB biopsy usually is applied in combination with intracytoplasmic sperm injection (ICSI). During the maturation from the germinal vesicle stage to the metaphase-II stage the first PB is formed. A cytoplasmic bridge containing spindle remnants, that are still in contact with the cellular genetic material, links this PB to the oolemma for about 90 minutes after extrusion. It is possible to visualize these remnants by polarization microscopy and it is crucial to not perform the biopsy until the first PB is no longer firmly attached to the oolemma as this indicates an immature embryo.The oocyte tolerates mechanical zona dissection best during hours four until six after ICSI as the oolemma has stabilized by that time because of the cortical granule reaction. Over time the first PB degenerates stressing a temporal biopsy and its optimal extraction time window is four to 12 hours after ICSI. The second PB forms around two to four hours after ICSI. However, its optimal time window for biopsy is set to be eight to 16 hours after ICSI. This is due to the second PB being attached to the oolemma with spindle remnants until six hours after ICSI. Biopsy at this point may cause enucleation of the oocyte. In addition, studies have shown that the amplification efficiency of second PB’s DNA is worse if the PB is extracted prior to eight hours after ICSI. <br />
Thus, it is possible to perform sequential and simultaneous biopsies for the first and second PB. If performed, sequentially the first PB may be removed four to 12 hours and the second PB eight to 16 hours after ICSI. The optimal time window for a biopsy for both the first and second PB simultaneously is eight to 12 hours after ICSI. It is highly preferred to analyze both PBs due to potential aneuploidies in either PB and crossing overs during meiosis<ref name="PMID22723007"/>. <br />
====Procedure====<br />
Chemical opening achieved with for example acidic tyrode’s solution of the zona pellucida is not tolerated by the oocyte and may have detrimental effects on the embryo’s development. Therefore, the access to the perivitelline space of the oocyte is provided by mechanical zona dissection or by laser. Both techniques work well if performed by experienced embryologist. However, laser-assisted biopsy is less time consuming when compared to manual dissection. It is critical to consider the size of the introduced opening as it will remain permanent. If it is too large the blastomere may be lost during embryo development and if it is too small it may interfere with hatching of the embryo during blastocyst stage<ref name="PMID22723007"/><br />
<br />
[[File:Polar_Body_Biopsy.jpeg|thumb|The presence of a faint but clearly identifiable strand connecting PB2 to the <br />
oolemma. The biopsy was performed ∼9 h after ICSI<ref name="PMID21908464"><pubmed>21908464</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JTaQzszVr8o</html5media><br />
|-<br />
| Laser-assisted polar body biopsy<ref>RIUK, R. (2013, June 25) Polar Body Biopsy [Video file]. Retrieved from https://www.youtube.com/watch?v=JTaQzszVr8o</ref><br />
|}<br />
<br />
====Advantages & Disadvantages====<br />
PB biopsies can only investigate the maternal contributions to the embryo as they are of maternal origin. Thus, this procedure is appropriate for PGD solely for monogenetic diseases from the maternal side. Recessive diseases may be evaluated with PB biopsies on the basis that the embryo’s outcome will be determined by the paternal contribution. (...) It may still be applied for PGS as most aneuploidies either arise during meiosis or origin from the maternal genome. However, diagnosis error has been reported due to the lack of considering paternal contributions. <br />
Because PB biopsies are performed very early it is not yet known whether the oocyte will develop into a viable embryo. Thus, PBs are commonly frozen or fixed after biopsy and depending on the state of the embryo only chosen PBs will be tested. This is primarily an economic issue as many genetic testing procedures are very cost-intensive<ref name="PMID22723007"/>.<br />
<br />
[[File:Implantation_predictive_value_of_euploid_screening_results.jpeg|thumb|The sustained implantation predictive value (with 95 % confidence interval) of a euploid screening result obtained from the first polar body (PB1), PB1 and the second polar body (PB2), or a direct embryo biopsy for each stage of embryo transfer (cleavage-stage and blastocyst stage)<ref name="PMID25106935"><pubmed>25106935</pubmed></ref>.]]<br />
<br />
===Blastomere biopsy===<br />
Day 3 <br />
====Description====<br />
Blastomere biopsy has been the prevalent method for PGD and PGS in the last two decades. At least one, but up to two, blastomeres are biopsied on day three of the cleavage stage embryo. The right number of blastomeres removed is a controversial topic as two cells allow for more genetic material and more accurate results. However, removing two cells might be too invasive and damaging to the embryo. (Study)<ref name="PMID21748341"><pubmed>21748341</pubmed></ref><br />
====Procedure====<br />
Initially a hole was drilled into the zona pellucida using acid tyrodes and the blastomeres are removed via aspiration with a pipette<ref name="PMID21748341"/>.<br />
<br />
<br />
[[File:Aspiration_of_a_Blastomere.jpeg|thumb|Aspiration of a Blastomere into the biopsy pipette<ref name=" PMID24783200"><pubmed>24783200</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=TbridWVwipI</html5media><br />
|-<br />
| Laser-assisted blastomere biopsy<ref>Sukprasert, M. (2014, March 5) Day 3 Blastomere Biopsy 1 [Video file]. Retrieved from https://www.youtube.com/watch?v=TbridWVwipI</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
===Trophectoderm biopsy===<br />
Day 5 and 6<br />
====Description====<br />
The improvement of embryo culture media allowed the in vitro development of human embryos until the blastocyst stage and opened up the possibility to take blastocyst biopsies. During day three to day five the haploid maternal and paternal genomes work together for the first time to form the genome of the embryo. The maternal epigenetic control lessens significantly while preparing for implantation with precisely arranged events happening. The first event includes a rapid increase in the number of embryonic cells which are active in mitotic divisions and apoptosis of aberrant cells. This is followed by the formation of blastocoel (cavitation) which results from the flattening of cell located on the outside of the blastomere. Now the blastocyst will expand until the embryo hatches by rupturing the zona pellucida. The cells of the blastocyst will differentiate to form two distinct cell lineages, the outer trophectoderm and the inner cell mass<ref name="PMID22723007"/>.<br />
====Procedure====<br />
Trophectoderm biopsy is usually performed in Hepes buffered biopsy medium and opening approaches include needle cutting which has been replaced by lasers in past years. Different research groups report different timings of the opening to be the most successful. Some open the blastocyst on day three or four by creating a 25 µm which causes the trophectoderm to herniate through this hole and is, thus, accessible for biopsy. Others create this hole about four hours before biopsy which allows sufficient herniation of trophectoderm cells. It is also possible to open the blastocyst immediately before biopsy. This avoids an extra step and the inner cell mass usually is easy to locate. Blastocyst biopsies involve the removal of trophectoderm cells and the ideal time for the procedure is day five. Successful biopsies on day six have been performed, while little is known about the results of biopsies on day seven. However, since the window of implantation in humans is from day eight to ten after ovulation, day seven biopsies appear to be possible<ref name="PMID22723007"/>.<br />
-collapse of trophoblasts<br />
-possible: biopsy of hatched blastocyst, holding pipette careful mild suction force to hold embryo near ICM <br />
-Cryopreservation<br />
<br />
<br />
[[File:Microscopic images of human blastocysts for biopsy.jpeg|thumb|(A) Some trophectoderm cells in a blastocyst started to hatch and (B) the trophectoderm cells were biopsied with assisted laser cutting. Images in C–D show the blastocysts after vitrification and warming. Blastocysts had been cultured for 2–4 hrs after warming, showing good (ICM and trophectoderm cells) hatched (C) and hatching (D) blastocysts. The hatching blastocyst in (E) has good ICM but fair trophectoderm while the blastocyst in (F) has both fair ICM and trophectoderm. Arrows indicate ICMs and arrow heads indicate trophectoderm cells. Bar = 40 µm<ref name="PMID2190846"><pubmed>2190846</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JI_TQ8d8tNM</html5media><br />
|-<br />
| Laser-assisted blastocyst biopsy (at 00:50 min)<ref>Coco, R. (2014, April 30) Trophectoderm biopsy in a Hatching blastocyst protruding ICM [Video file]. Retrieved from https://www.youtube.com/watch?v=JI_TQ8d8tNM</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
Blastocyst biopsies are believed to be less damaging to the embryo and appear to be unrelated to implantation rates. In addition, this biopsy method allows for a larger extraction of cells for genetic testing. However, since they are performed late in in vitro development, the time window for genetic testing is relatively small. Fast and accurate genetic testing methods are needed to ensure a successful and safe result from this biopsy. Thus, blastocyst biopsies may gain more popularity in the future whn such methods have been developed or improved<ref name="PMID22723007"/>. <br />
<br />
<br />
==Genetic Techniques==<br />
<br />
===PCR===<br />
====Description====<br />
Polymerase chain reaction (PCR) amplifies DNA specific to genetic sequence of interest . PCR was developed by Kay Mullis in the 1980s, for which he was awarded the Nobel prize for chemistry in 1993. <ref> Pubmed Docs (2015) Polymerase Chain Reaction (PCR) Pubmen. Retrieved from [http://www.ncbi.nlm.nih.gov/probe/docs/techpcr/]</ref> This technique enables clinicians to monitor and diagnose diseases using minute samples such as embryonic cells, blood & tissue. <ref>Roche (2015) PCR: How We Copy DNA. Roche Molecular Systems Inc. retrieved From [http://molecular.roche.com/pcr/Pages/Process.aspx]</ref> PCR has many important applications like DNA fingerprinting, genetic mapping, detection of viruses and bacteria as well as being used to detect genetic disorders, as a part of PGD, in conjunction with IVF. It is used to detect molecular abnormalities such as single gene disorders like Tay Sach, Cycstic fibrosis, Duchenne Muscular Dystrophy, Thalassemia, Huntington disease, Spinal muscular atrophy and many more. Molecular and Genetic analysis require a significant amount of DNA, which we would not have without PCR. It revolutionized the study of DNA, replacing all previous recombinant DNA technology. <ref> Mullins, K., Francois, F.& Gibbs R.A. (1994 ) The Polymerase Chain Reaction. p3. Springer- Science +Business Media. Birkhauser, Boston<br />
Available at [https://books.google.com.au/books?hl=en&lr=&id=gjrTBwAAQBAJ&oi=fnd&pg=PR5&dq=kary+mullis+PCR&ots=mpzAyRh5ZY&sig=PQ4goNoKJ90tb3-MkPk62zrTGbw#v=onepage&q=kary%20mullis%20PCR&f=false] </ref> <br />
<br />
[[File:PCR.jpg|thumb|right|Polymerase chain reaction (PCR) amplifies DNA specific to genetic sequence of interest, enabling the monitoring and diagnose molecular abnormalities such as single gene disorders using minute samples such as embryonic cells, blood & tissue <ref>NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref>]]<br />
<br />
====Procedure====<br />
<br />
Sample are obtained from the the blastocyst, a polar body biopsy or the blastomeres stages of the embryo. <br />
Stage 1 Denaturing: separating the target strands of DNA <br />
The obtained sample is heated to roughly 90 degrees celcius, this heat causes breaks the relatively weak bonds between nucleotides that form DNA. the double stranded DNA to split into 2 single strands of DNA that are used as templates.<br />
Stage 2 Annealing: Binding the Primers to the target DNA sequence <br />
PCR will only copy the target sequence of DNA specified by specific PCR primer. These synthesized primers Oligonucleotides are small artificial pieces of DNA. <br />
TAQ polymerase enzyme synthesize 2 new strands of DNA duplicate to the single sample DNA stand template indicated by these primers. During this stage the reaction is cooled to a temperature between 40-60 degrees Celsius. <br />
Stage 3- Extension- making copies <br />
Each of these 2 copies are then used again as templates generating 2 further replications This cycle can occur as many 30 -40 times within a couple hours leading to billions of extra copies of the original DNA segment. The optimal temperature for the further replication is roughly 72 degrees Celsius. <br />
<br />
This process mediated by a thermocycler machine that is programmed to alter the temperature of the reaction every couple of minutes, perpetuating the cycle of DNA denaturing and synthesis. <br />
This process, generates exponential exact copy of the original template DNA sequence. <br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
!PCR cycles<br />
<br />
|{|<br />
|-<br />
| '''PCR Cycle'''<br />
| '''Target Copies'''<br />
|-<br />
| 1<br />
| 2<br />
|-<br />
| 2<br />
| 4<br />
|-<br />
| 3<br />
| 8<br />
|-<br />
| 4<br />
| 16<br />
|-"<br />
| 5 <br />
| 32<br />
|-<br />
| 6 <br />
| 64<br />
|-<br />
| 7 <br />
| 128<br />
|-<br />
| 8<br />
| 256<br />
|- <br />
| 9<br />
| 512 <br />
|-<br />
| 10<br />
| 1024<br />
|-<br />
| 15<br />
| 32,768<br />
|-<br />
| 20 <br />
| 1,048,578<br />
|-<br />
| 25<br />
| 33,554,432<br />
|-<br />
| 30 <br />
| 1,073,741,842<br />
|-<br />
|}<br />
<br />
<br />
<br />
{|class="wikitable" align="center"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="10" |'''Advantages'''<br />
|-bgcolor="FFFAFA"<br />
| fast and inexpensive way of copying a target sequence of DNA<br />
|-bgcolor="FFFAFA"<br />
| aids the diagnosis of single cell defects<br />
|-bgcolor="FFFAFA"<br />
| rapid generation of results within a couple hours<br />
|-bgcolor="FFFAFA"<br />
| can start from a single molecule of DNA, therefore is more sensitive <br />
|-bgcolor="FFFAFA"<br />
| has a flexible primer design enabling<br />
|-bgcolor="FFFAFA"<br />
| overcame previous issues associated with the limited availability of sites of end<br />
|-bgcolor="FFFAFA"<br />
| generates the DNA copies exponentially<br />
|-bgcolor="FFFAFA"<br />
| enables DNA amplification required for molecular and genetic analysis<br />
|-bgcolor="FFFAFA"<br />
|Valid diagnostic method in selecting unaffected embryos for embryo transfer <ref> Dreesen, J., Drusedaul, M., Smeets, H., Die-Smulders, C., Coonen, E., Dumoulin, J., Gielen, M., Evers, J., Herbergers, J. & Geradets, J. (2008) Validation of preimplantation genetic diagnosis by PCR analysis: genotype comparison of the blastomere and corresponding embryo, implications for clinical practice. Mol. Hum. Reprod. 14 (10):573-579.doi: 10.1093/molehr/gan052. Retrieved from [http://molehr.oxfordjournals.org/content/14/10/573.short] </ref> <ref><pubmed>20966460</pubmed></ref><br />
|-bgcolor="DDCEF2"<br />
| rowspan="5"|'''Disadvantages'''<br />
|-bgcolor="FFFAFA"<br />
| only during this exponential DNA replication phase can we determine the starting quantity sequence contained in the original sample ( template DNA strand)<br />
|-bgcolor="FFFAFA"<br />
| PCR reaction is limited by the presence of inhibitors present in the sample : reagent inhibitors <br />
|-bgcolor="FFFAFA"<br />
| self annealing due to the accumulation of the product -stopping exponential amplification for the target sequence and reach a plateau<br />
quantification of the end point of reaction of PCR products unreliable - therefore that is why we require real time quantitative RT-PCR necessary<br />
<ref> NIS (2015) Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref><br />
|}<br />
<br />
<br />
===Fluorescent In Situ Hybridisation (FISH)===<br />
<br />
<br />
====Description====<br />
Fluorescence in situ hybridization (FISH) the one of the most effective and rapid <ref name="PMID26338801"><pubmed>26338801</pubmed></ref> Preimplantation Genetic Diagnosis (PGD). This techniques used to locate a specific DNA sequences within a chromosome. FISH facilitates the clinical diagnosis of chromosomal abnormalities indicated by sequential duplications, deletions and rearrangements of chromosome, that are usually missed with microscopic analysis. This technique is especially relevant for female embryos with X-linked diseases,<ref name="PMID20809319"><pubmed>20809319</pubmed></ref> that have no other mutation specific tests [http://www.ncbi.nlm.nih.gov/pubmed/20809319] As part of PGD, samples are collected from various stages of the embyro,and they are able to conducted tests on the blastocyst, a polar body biopsy and the blastomeres <ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. FISH is 99% effective when used in conjunction with competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities<ref name="PMID26338801"/>.<br />
<br />
====Procedure==== <br />
<br />
Samples are collected from either the blastocyst, a polar body biopsy or the blastomeres stages of the embryo <ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
DNA strands are heated and denatured causing their the individual DNA strands to break apart<br />
Probes are single complimentary stands of DNA a that have been tagged with small chemical agents that glow brightly in the presence of a specific region on a chromosome. These specific probes then hybridize and join to their complementary DNA strand. <br />
The fluorescent tags enable the researchers to correctly identify the presence or lack thereof and location of the specific chromosomes that they are testing for. <ref name="PMID17876073"><pubmed>17876073</pubmed></ref><br />
Researcher analyse the results by identifying the number and the relative location of the fluorescent dots generated by the FISH images.<ref name="PMID17970921"><pubmed>17970921</pubmed></ref><br />
The probe will not fully hybridise if there has been a duplication or a deletion of the DNA - indicating chromosomal and sex chromosomal anomalies like trisomies and aneuploidies. <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref><br />
<br />
<br />
Different probes are used for different purposes: <ref>Unique, Rare Chromosome Disorder Support Group (2013) Fluorescence in situ hybridisation (FISH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/Other/FISH%20FTNW.pdf]</ref><br />
*'''Locus specific tags''' detect very small imbalances, and locate isolated small portions <br />
of genes within a chromosome<br />
*'''Alphoid/Centomeric Repeat probes''' are developed from the repetitive sequence located in the middle region of each chromosome, useful in determining the number of chromosomes , detecting rearrangement and when used in conjunction with locus probes to determine the absence of genetic material on a chromosome. <br />
*'''Paint Probes''' are collections of smaller probes with their own stains that bind to a different section on the chromosome - allowing the full chromosome too be labeled a unique colour, this "full colour map" can be used to know the spectral karyotype- full chromosomal mapping is useful in examining chromosomal abnormalities. <br />
<br />
[[File:Fluorescent In Situ Hybridisation (FISH).jpg|thumb|right|'''FISH''' We are able to tag Specific DNA sequences using Probes which have been tagged with fluorescent Labels.This technique enables the clinical diagnosis of chromosomal abnormalities, indicated by sequential duplication, deletions and rearrangements of chromosome <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref>]]<br />
<br />
{|class="wikitable" align="center"<br />
|-bgcolor="pink" <br />
| rowspan="8" |'''Advantages''' <br />
|-bgcolor="#FDE1F2" <br />
| FISH is 99% effective when used in conjunction with Competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities.<ref><pubmed>26338801</pubmed></ref><br />
|-bgcolor="#FDE1F2" <br />
| Rapid generation of results<br />
|-bgcolor="#FDE1F2" <br />
| Identifies very small translocations and aneuploidies that occur within chromosomes, that would usually be missed under microscopic analysis<br />
|-bgcolor="#FDE1F2" <br />
| Indicates whether the accessed chromosomes are normal <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|-bgcolor="#FDE1F2" <br />
| Tests for the most common chromosomal abnormalities - down syndrome chromosomes 13,16,18,21 and 22 <ref><pubmed>21749752</pubmed></ref><br />
|-bgcolor="#FDE1F2" <br />
| It may be used to compare the chromosomal gene arrangements in related species<br />
|-bgcolor="#FDE1F2" <br />
| can be used to identify and remove inheritable X-linked disease or sex chromasome anomalies such as Duchennes Muscular Dystrophy, hemophilia, ectodermal dysplasia <ref><pubmed>17876073</pubmed></ref><br />
|-bgcolor="#FEB745"<br />
| rowspan="5"|'''Disadvantages'''<br />
|-bgcolor="#FE1C5EA"<br />
| FISH destroys all cells tested <ref> O'Connor, C. (2008) Fluorescence in situ hybridization (FISH). Nature Education 1(1):171. retrieved from [http://www.nature.com/scitable/topicpage/fluorescence-in-situ-hybridization-fish-327] </ref><br />
|-bgcolor="#FE1C5EA"<br />
| It does not fully access all chromosomes (only ~ 12)<br />
|-bgcolor="#FE1C5EA"<br />
| Analysis of results is dependent upon the dot quality impacted by hybridisation efficiency or the camera sensitivity <ref><pubmed>17970921</pubmed></ref><br />
|-bgcolor="#FE1C5EA"<br />
| some studies indicate that using FISH on a day-3 embryo biopsy decreases the rate of live births <ref><pubmed>26168107</pubmed></ref><br />
|}<br />
<br />
===Array Comparative Genomic Hybridisation (aCGH)===<br />
====Description====<br />
<br />
aCGH also known as Microarray analysis efficiently scans the entire genome for chromosomal imbalances. CGH was initially developed to detect the number of changes in a solid tumor mass. It uses 2 genomes comparing the sample to the control, with each labeled in a different fluorescent dye<ref name="PMID1876176"><pubmed>1876176</pubmed></ref>. Earlier CGH techniques were limited by the resolution of the imaging <ref> Lichter, P., et al. Comparative genomic hybridization: Uses and limitations. Seminars in Hematology 37, 348–357 (2000)</ref> , these initial limitations were overcome by using Microarrays in conjunction with CGh to improve the resolution of the imaging, Array Comparative Genomic Hybridisation (aCGH). This method compares sample and control microarrayed slides containing small segments of DNA (probes). <ref> Lucito, R., et al. Representational oligonucleotide microarray analysis: A high-resolution method to detect genome copy number variation. Genome Research 13, 2291–2305 (2003) </ref> the Probes used will vary according from the small (25-85 base pairs) oligonucleotides manufactured to highlight different target sequences, to the very large genomic clones (80,000- 200,00 base pairs), and as these are significantly smaller than the traditional metaphase chromosomes used for CGH, generating a higher resolution of image. <ref name="PMID22467166"><pubmed>22467166</pubmed></ref>.aCGH is used as a diagnostic tool for prenatal detection f chromosomal abnormalities <ref name="PMID19012303"><pubmed>19012303</pubmed></ref>.<br />
<br />
<br />
====Procedure====<br />
<ref> Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432] </ref><br />
The sample is obtained (skin, blood or fetal cells) and DNA is obtained. <br />
As a part of PGD fetal cell samples are collected from; the fertilized egg polar bodies, the blastomere (day 3 embryo) or the blastocyst/tropoectoderm stage (day 5 embryo).<br />
Sample DNA is labeled with one fluorescent dye, and the control DNA is labeled with a different colored fluorescent dye. the control DNA is used as the base point of reference. <br />
heated and denatured single DNA strands then hybridize to their complementary single strand probes, which are then combined and applied to a microarray and the results are run through a computer program and a digital imaging system is used to quantify the results( fluorescent intensities of the labeled probes). <br />
<br />
[[File:aCGH.jpg|thumb|right|'''aCGH''' checks the entire genome for chromosomal imbalances, by comparing control and a sample slides contatining small segements of DNA sample microarrayed slides small segments of DNA. Illustrated by student z5020317 and adapted from <ref> NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation. retrieved from [http://www.phgfoundation.org/file/5237/]</ref> <ref>Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432]</ref>]]<br />
<br />
The fluorescent ratio and the hybridization signal at different locations on the genome of the control DNA are used to identify any variances present in the sample DNA. aCGH facilitates the clinical diagnosis of submicroscopic chromosomal duplication, deletion and rearrangements indicative of chromosomal disorders such as trisomies 1-22and specific sex linked disorders. <br />
Duplications in the DNA are displayed by the computer program as spikes/ peaks over an established threshold and deletions in DNA are displayed by the computer program as spikes/ toughs beneath this threshold <br />
<br />
{|class="wikitable" align="center"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="12" |'''Advantages''' <br />
|-bgcolor="FFFAFA"<br />
| Multiple applications: prenatal genetic diagnosis, cancer diagnosis, <ref name="PMID20193845"><pubmed>20193845</pubmed></ref> genetic screening for developmental delay (learning disabilities) <ref name="PMID17309648"><pubmed>17309648</pubmed></ref>. or congenital anomalies that are suspected to be genetic in origin <ref>NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation . retrieved from [http://www.phgfoundation.org/file/5237/]</ref><br />
|-bgcolor="FFFAFA"<br />
| trace represents all chromosomes present in the human genome chromosomes 1-22 and the X & Y chromosomes, and therefore is the most accurate method for testing whole embryo aneuploidy<br />
|-bgcolor="FFFAFA"<br />
| aCGH has been extensively tested, and Validated, and is now used world wide.<br />
|-bgcolor="FFFAFA"<br />
| Detects submicroscopic alterations<br />
|-bgcolor="FFFAFA"<br />
| Detects deletions and additions and rearrangements as well as amplification, of the WHOLE genome, simultaneously.<br />
|-bgcolor="FFFAFA"<br />
| Used as a diagnostic tool for prenatal detection of chromosomal abnormalities <ref name="PMID22034057"><pubmed>22034057</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Provides high resolution genomewide screening of segmental genomic copy number variations<br />
|-bgcolor="FFFAFA"<br />
| Very accurate when used in conjunction with FISH<br />
|-bgcolor="FFFAFA"<br />
| Alone is more reliable and in detecting chromosomal abnormalities, with a higher implantation success rate, than FISH <ref name="PMID20494259"><pubmed>20494259</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Allows an in depth research focus upon specific types of rearrangements within selected chromosomal regions, a recent particular area of interest is subtelomeric and pericentromeric rearrangements<br />
|-bgcolor="FFFAFA"<br />
| Reduces the risk of failed implantation and miscarriage, improving the chance of a healthy baby <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|-bgcolor="DDCEF2"<br />
| rowspan="9" |'''Disadvantages'''<br />
|-bgcolor="FFFAFA"<br />
| Translocations and inversions of DNA are not detected<br />
|-bgcolor="FFFAFA"<br />
| Limited ability diagnosing specific polyploidies such as triploidy <ref> Unique, Rare Chromosome Disorder Support Group (2013) Microarray-based Comparative Genomic Hybridiation (array CGH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/other/array%20cgh%20ftnw.pdf] </ref><br />
|-bgcolor="FFFAFA"<br />
| Will not detect mosaicism detection <20% (cultures where >1 of 5 cells are trisomy 12)<br />
|-bgcolor="FFFAFA"<br />
| Will not detect balanced chromosomal rearrangement<br />
|-bgcolor="FFFAFA"<br />
| Will not detect duplications or deletions <80kb<br />
|-bgcolor="FFFAFA"<br />
| Will not detect point mutations within genes <ref>Washington department of education (CGH- FAQ for physicians. Signature Genomic LAboratories, LLC. Retrieved from [https://depts.washington.edu/dbpeds/Lab%20Tests/SignatureCGH-physician_FAQ.pdf]</ref><br />
|-bgcolor="FFFAFA"<br />
| will not detect chromosomal position of genomic gains<br />
|-bgcolor="FFFAFA"<br />
| Will not detect loos of heterozygosity (LOH) or Absence of heterozygosity (AOH) <ref>WiCell Research Institute Inc. (2012) Comparative Genomic Hybridization Microarray. <br />
retrieved from [http://www.wicell.org/home/cytogenetic-services/cgh-microarray/array-comparative-genomic-hybridization-acgh.cmsx]</ref><br />
|}<br />
<br />
===Next Generation Sequencing===<br />
====Description====<br />
The development and advances within ART in the past 20 years, as well as the increasing popularity of IV, has lead to an influx of new technologies developed to screen embryos for chromosomal anomalies, which are covered by the umbrella term of Next generation Sequencing (NGS). NGS is a general term used to describe all of the new and emerging screening techniques currently being introduced and used as part of PGD for IVF . NGS screens for single gene disorders as well as conducting extensive and very comprehensive chromosome diagnosis by sequencing, counting, and accurately assembling millions of DNA reads, simultaneously. <ref name="PMID23499002"><pubmed>23499002</pubmed></ref> There is a movement for NGS to replace the other limited testing techniques and be used as the standard. <br />
====Procedure====<br />
Samples are collected from either blastomere or the blastocyst/tropoectoderm and processed for analysis by a computer system. <br />
The methodology of each process is unique to the technique being used. <br />
<br />
{|class="wikitable" align="center"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="14" |'''Advantages''' <br />
|-bgcolor="FFFAFA"<br />
| Cheaper<br />
|-bgcolor="FFFAFA"<br />
| Opens new diagnostic possibilities<br />
|-bgcolor="FFFAFA"<br />
| Accurately tests all 24 chromosomes<br />
|-bgcolor="FFFAFA"<br />
| Tests for the presence of monogenic diseases of known genetic background<br />
|-bgcolor="FFFAFA"<br />
| Reduces the number of biopsies required for diagnosis<br />
|-bgcolor="FFFAFA"<br />
| Higher detection rate of small translocations<br />
|-bgcolor="FFFAFA"<br />
| Highly accurate is testing for compound point mutations, chromosomal duplication, deletions and insertions <ref name="PMID23312231"><pubmed>23312231</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| It accurately detects chromosomal aneuploidy and unbalanced rearrangement <ref name="PMID25685330"><pubmed>25685330</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Higher detection rate of small translocations<br />
|-bgcolor="FFFAFA"<br />
| NGS single gene disorder screenings can conducted in conjunction with PCR comprehensive chromosomal screening<br />
|-bgcolor="FFFAFA"<br />
| Reduces human error <br />
|-bgcolor="FFFAFA"<br />
| Better detects the presence of mosaicism<br />
|-bgcolor="FFFAFA"<br />
| Work well in conjunction with CGH and aCGH as part of PGD, improving the chances of IVF. <ref> Morris, R. S. (2015 ) Next generation sequencing for PCG|PGS|CCS. IVF1 retrieved from [http://www.ivf1.com/next-generation-sequencing for-pgd] </ref><br />
|-bgcolor="DDCEF2"<br />
| rowspan "1" |'''Disadvantages''' <br />
|-bgcolor="FFFAFA"<br />
| There are limited information available to clinical applications of NGS <ref><pubmed>26100406</pubmed></ref><br />
|}<br />
<br />
==Diagnosis==<br />
There are a large amount of diseases that PGD can apply to, below are descriptions of the diseases that PGD are more commonly used for. Utilization of Diseased Cell Lines<br />
===Cystic Fibrosis===<br />
Cystic fibrosis is a single gene disorder. It is autosomal recessive and involves mutations in the cystic fibrosis transmembrane conductance regulator (CTFR) gene. The CTFR gene is normally responsible for the decrease in chloride and the transport of bicarbonate in epithelial cells thus playing a major physiological role. In PGD procedures, identification of the gene is assisted by microsatellite markers that have similar composition to the CTFR gene itself. Biopsy of two cells at the blastocyst stage is recommended if markers are not available. There are many variations of cystic fibrosis the most common being P.Phe508del <ref name="PMID26014425"><pubmed>26014425</pubmed></ref>.<br />
===Duchenne Muscular Dystrophy ===<br />
Duchenne Muscular Dystrophy is an X-linked recessive disease. It involves the Xp21 gene where majority of the mutations are chromosomal deletions with a smaller percentage resulting from duplications <ref name="PMID18359022"><pubmed>18359022</pubmed></ref>.<br />
<br />
===Autosomal Recessive MEckel-Gruber Syndrome===<br />
Autosomal recessive genetic defect caused by the TMEM67 gene. It results in cystic dysplasia of the kidneys with fibrotic change in the liber and occipital encephalocele. Other malformations could also be present in the central nervous system. In PGD whole genome amplification of single blastomeres are taken to identify the gene, this is also coupled with PCR techniques. Maternal plasma can also be extracted for PGS. <ref><pubmed>24039893</pubmed></ref> <br />
===β – Thalassemia=== <br />
β – Thalassemia is known as the most common type of autosomal recessive inherited disorder among haemoglobinopathies. It involves the adult β-globin gene and is associated with the absent or decreased expression of the gene. This is commonly caused by a single nucleotide change in the gene. PGD has been used successfully worldwide to identify the β-globin gene where its application is usually performed on a single blastomere or polar body <ref name="PMID19064120">19064120</pubmed></ref>.<br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
! Applicable diseases for PGD <ref>Genoma Group (2014). Retrieved September 18th, 2015, from http://www.preimplantationgeneticdiagnosis.it/genetic-diseases-diagnosed-by-pgd.htm </ref>, <ref>Genesis Genetics (2015). Retrieved September 18th, 2015, from http://genesisgenetics.org/pgd/what-we-test-for/</ref>, <ref>Human Fertilisation & Embryology Authority (2015). Retrieved Septembr 18th, 2015, from http://guide.hfea.gov.uk/pgd/</ref><br />
|-<br />
| '''Disease'''<br />
| '''Involved Genes'''<br />
|-<br />
| 5 Alpha Reductase Deficiency (5ARD)<br />
| SRD5A2 <br />
|-<br />
| Achondroplasia<br />
|FGFR3 <br />
|-<br />
| Acute Intermittent Porphyria <br />
| ALAD, ALAS2, CPOX, FECH, HMBS, PPOX, UROD, or UROS<br />
|-<br />
| Adrenoleukodystrophy (Adrenomyeloneuropathy)<br />
| ABCD1 <br />
|-<br />
| Agammaglobulinaemia (x-linked) <br />
|BTK <br />
|-<br />
| Agammaglobulinemia Bruton Tyrosine Kinase (BTK) <br />
|BTK <br />
|-<br />
| Aicardi Goutieres Syndrome 1 (AGS1) <br />
|TREX1, RNASEH2A, RNASEH2B, RNASEH2C, SAMHD1<br />
|-<br />
| Alagille Syndrome<br />
|JAG1 or NOTCH2<br />
|- <br />
| Alpers-Huttenlocher Syndrome <br />
|POLG <br />
|-<br />
| Alpha-1-antitrypsin deficiency <br />
|SERPINA1 <br />
|-<br />
| Alpha-Mannosidosis<br />
| MAN2B1 <br />
|-<br />
| Alpha Thalassemia <br />
|HBA1 or HBA2 <br />
|-<br />
| Alports Syndrome<br />
|COL4A3, COL4A4, COL4A5<br />
|-<br />
| Alzheimer's Disease - early onset (Type 3 and 4) <br />
|APP, PSEN1, or PSEN2<br />
|-<br />
| Amyotrophic Lateral Sclerosis 1 (ALS1) <br />
|C9orf72, SOD1, TARDBP, FUS, ANG, ALS2, SETX, VAPB <br />
|-<br />
| Argininosuccinic Aciduria <br />
| ASL<br />
|-<br />
| Arrhythmogenic Right Ventricular Cardiomyopathy/ Dysplasia (ARVC/D)<br />
| DSG2; DSP; PKP2<br />
|-<br />
| Ataxia Telangiectasia<br />
| ATM<br />
|-<br />
| Autosomal Recessive Meckel-Gruber Syndrome<br />
| TMEM67<br />
|-<br />
| Bardet-Biedl Syndrome (BBS)<br />
| BBS1; BBS10<br />
|-<br />
| Barth Syndrome<br />
| TAZ<br />
|-<br />
| Beta Thalassaemia<br />
| HBB<br />
|-<br />
| Birt-Hogg-Dubé Syndrome<br />
| FLCN<br />
|-<br />
| Breast Ovarian Cancer Familial Susceptibility (BRCA2)<br />
| BRCA1; BRCA2<br />
|-<br />
| Canavan Disease <br />
| ASPA<br />
|-<br />
| Carnitine-Acylcarnitine Translocase Deficiency <br />
| SLC25A20<br />
|-<br />
| Cerebral Arteriopathy with Subcortical Infarcts & Leukoencephalopathy (CADASIL)<br />
| NOTCH3<br />
|-<br />
| Cerebral Cavernous Malformation<br />
| CCM1<br />
|-<br />
| Charcot-Marie-Tooth Disease<br />
| GJB1; MPZ; NEFL; PMP22<br />
|-<br />
| CHARGE Syndrome<br />
| CHD7<br />
|-<br />
| Cherubism<br />
| SH3BP2<br />
|-<br />
| Choroideremia<br />
| CHM<br />
|-<br />
| Chronic Granulomatous Disease<br />
| CYBB; NCF1<br />
|-<br />
| Ciliary Dyskinesia<br />
| DNAH5<br />
|-<br />
| Citrullinemia<br />
| ASS1<br />
|-<br />
| Cleidocranial Dysplasia<br />
| RUNX2<br />
|-<br />
| Cockayne Syndrome<br />
| ERCC6<br />
|-<br />
| Congenital Adrenal Hyperplasia<br />
| CYP21A2<br />
|-<br />
| Congenital Cataracts<br />
| GJA8; VSX2<br />
|-<br />
| Congenital Diarrhea, Syndromic<br />
| SPINT2<br />
|-<br />
| Congenital Disorders of Glycosylation (CDG)<br />
| ALG1; ALG6; CDG1C; DOLK; PMM2<br />
|-<br />
| Cornelia de Lange Syndrome <br />
| NIPBL<br />
|-<br />
| Craniosynostosis<br />
| TWIST1<br />
|-<br />
| Crouzon Syndrome<br />
| FGFR2<br />
|-<br />
| Cysteinyl Leukotriene Receptor 1 Deficiency <br />
| CYSLTR1<br />
|-<br />
| Cystic Fibrosis<br />
| CFTR<br />
|-<br />
| Diamond –Blackfan Anemia <br />
| RPS19<br />
|-<br />
| Duchenne Muscular Dystrophy <br />
| DMD<br />
|-<br />
| Dyskeratosis congenita (Male embryos only)<br />
| DKC1<br />
|-<br />
| Ectodermal dysplasia (Hypohidrotic)<br />
| EDA; EDA1; GJB6; IKBKG<br />
|-<br />
| Familial Adenomatous polyposis coli (FAP)<br />
| APC<br />
|-<br />
| Familial Dysautonomia<br />
| IKBKAP<br />
|-<br />
| Fanconi Anemia <br />
| FANCA; FANCC; FANCD2; FANCF; FANCG; FANCJ<br />
|-<br />
| Fragile X Syndrome (FRAX)<br />
| FMR1<br />
|-<br />
| Galactosemia <br />
| GALT<br />
|-<br />
| Gangliosidosis<br />
| GLB1<br />
|-<br />
| Glanzmann Thrombasthenia <br />
| ITGA2B<br />
|-<br />
| Glutaric Acidemia (aciduria)<br />
| GCDH <br />
|-<br />
| Glycogen Storage Disease <br />
| G6PC; GAA; SLC37A4<br />
|-<br />
| Haemophilia A<br />
| F8<br />
|-<br />
| Haemophilia B<br />
| F9<br />
|-<br />
| Hereditary Nonpolyposis Colorectal Cancer: Lynch Syndrome<br />
| MLH1; MSH2; MSH6<br />
|-<br />
| Holt Oram Syndrome<br />
| TBX5<br />
|-<br />
| Huntington Disease<br />
| HD<br />
|-<br />
| Hydrocephalus<br />
| L1CAM<br />
|-<br />
| Ichthyosis <br />
| ABCA12; STS<br />
|-<br />
| Incontinentia Pigmenti (IP)<br />
| NEMO<br />
|-<br />
| Joubert Syndrome 5<br />
| INPP5E<br />
|-<br />
| Krabbe Disease<br />
| GALC<br />
|-<br />
| Leber Congenital Amaurosis (LCA)<br />
| CEP290; GUCY2D<br />
|-<br />
| Leigh Syndrome (Infantile Subacute Necrotising Encephalopathy)<br />
| LRPPRC<br />
|-<br />
| Lesch Nyan Syndrome<br />
| HPRT1<br />
|-<br />
| Leukocyte Adhesion Deficiency (Type I)<br />
| ITGB2<br />
|-<br />
| Li-Fraumeni Syndrome<br />
| TP53<br />
|-<br />
| Macular Dystrophy Retinal <br />
| VMD2<br />
|-<br />
| Maple Syrup Urine Disorder (MSUD)<br />
| BCKDHB<br />
|-<br />
| Marfan Syndrome <br />
| FBN1<br />
|-<br />
| Menkes Syndrome<br />
| ATP7A<br />
|-<br />
| Mitochondrial DNA Depletion Syndrom <br />
| POLG; RRM2B; SUCLA2; TK2<br />
|-<br />
| Mucolipidosis type II<br />
| GNPTAB<br />
|-<br />
| Multiple Endocrine Neoplasia<br />
| MEN1; MEN2A; MEN2B<br />
|-<br />
| Multiple Exostoses<br />
| EXT1; EXT2 <br />
|-<br />
| Myotubular myopathy<br />
| MTM1 <br />
|-<br />
| Nail-Patella Syndrome<br />
| LMX1B<br />
|-<br />
| Neurofibromatosis Type 1<br />
| NF1<br />
|-<br />
| Neurofibromatosis Type 2 <br />
| NF2<br />
|-<br />
| Noonan Syndrome<br />
| KRAS, PTPN11; SOS1<br />
|-<br />
| Norrie Disease<br />
| NDP<br />
|-<br />
| Ocular Albinism <br />
| GPR143<br />
|-<br />
| Oculocutaneous Albinism <br />
| OCA2; TYR <br />
|-<br />
| Oculodentaldigital Dysplasia<br />
| GJA1<br />
|-<br />
| Optic Atrophy<br />
| OPA1<br />
|-<br />
| Ornithine Transcarbamylase Deficiency <br />
| OTC<br />
|-<br />
| Osteogenesis imperfeca <br />
| COL1A1; COL1A2<br />
|-<br />
| Osteopetrosis <br />
| CLCN7; OSTM1; TCIRG1<br />
|-<br />
| Pachyonychia Congenita <br />
| KRT16; KRT6A<br />
|-<br />
| Pancreatitis, Hereditary<br />
| PRSS1 <br />
|-<br />
| Papillorenal syndrome <br />
| PAX2<br />
|-<br />
| Phenylketonuria <br />
| PAH <br />
|-<br />
| This table does not cover the complete list of diseases that PGD can be applied to.<br />
|}<br />
<br />
==Laws & Legal status==<br />
<br />
{| class="wikitable" <br />
|-bgcolor="DDCEF2"<br />
|'''Country'''<br />
|'''Legislation'''<br />
|-<br />
| Australia<br />
| PGD is currently used to detect serious genetic conditions to improve the outcome of Assisted Reproductive Technologies (ART). In very rare cases it may be used to select an embryo with compatible tissue for a sibling who has a life-threatening disease where other means of treatment is unavailable. This is with the conditions that the use of PGD will not affect the welfare and interests of the child to be born. The parents must also receive adequate counselling and have full understanding of the procedures of PGD. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"> National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art</ref><br />
The use of PGD for sex-selection is prohibited with the exception of reducing the risk of the transmission of serious sex-linked genetic conditions. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"/><br />
|-bgcolor="FFFAFA"<br />
| Brazil<br />
| The laws regarding PGD in Brazil are not strictly regulated. They are vague and there is limited information surround the activities of assisted reproduction in general in the country <ref name="PMID25493379"><pubmed>25493379</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| Czech Republic<br />
| The laws in the Czech Republic allow those with a “defined indication in order to exclude risk of serous genetically conditioned disease and defects with embryos before they are implanted into the cavity of the uterus”. Couples that undergo any assisted reproductive treatment including PGD have to be married. Sex-selection is illegal except in regards to serious sex-linked genetic diseases <ref name="PMID24777348"><pubmed>24777348</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| Greece<br />
| In Greece, ART is open to those up to the age of 50 with written consent. It can only be used if a medical necessity is present such as the susceptibility of serious hereditary diseases. Sex selection is banned apart from cases of sex-linked diseases and sexually transmitted diseases <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| India<br />
| In India there is a cultural preference for boys thus the Prenatal Diagnostic Techniques (Regulation and Prevention of Misuse) Act was introduced in 1994. This law limits the use of PGD for sex determination except in cases of specific congenital diseases. These laws however are not strictly enforced. <ref>World Health Organisation (2015) Gender and Genetics Retrieved on October 21st 2015 from:http://www.who.int/genomics/gender/en/index4.html</ref><br />
|-bgcolor="FFFAFA"<br />
| Portugal <br />
| ART is only available to those who are married or have a similar type of relationship for at least two years. The couples cannot be of the same sex and must be at least 18 years of age. Sex selection is illegal except in cases of sex-linked diseases. The use of PGD is illegal if the predictive value of genetic tests are very low <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| Spain<br />
| PGD can be applied to “serious hereditary diseases not amenable to postnatal curative treatment” and “detection of other abnormalities which may compromise the viability of the pre-embryo”. If PGD is to be used for any other purpose authorisation must be acquired <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| Sweden <br />
| The use of PGD is strictly regulated and couples must achieve authorisation of the National Board of Health and Welfare. It can only be used it can only be used if the child is at risk to inheriting a serious chromosomal or monogenetic disease. It cannot be used for selection of specific characteristics <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| United Kingdom<br />
| Those involved with carrying out the IVF treatment must have a license from the Human Fertilisation and Embryology Authority (HFEA). Only embryos that are approved by the HFEA can be implanted where the embryonic nuclear or mitochondrial DNA cannot be altered with the exception of preventing mitochondrial diseases <ref name="PMID24777348"/>. <br />
|}<br />
<br />
==Future/Current Research==<br />
===Noninvasive Preimplantation Genetic Testing without Embryo Biopsy===<br />
Different parameters of gametes, zygotes, embryos (“vacuoles in sperm heads, spindle position in mature oocytes, cleavage intervals of zygote, and embryo developmental dynamics”) may correlate with aneuploidy rates. This knowledge may be applied in potential noninvasive preimplantation diagnostic methods. Several methods have been proposed and are currently further researched<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Sperm Selection====<br />
Intracytoplasmic morphologically selected sperm injection (IMSI) is common procedure in IVF treatment to improve fertilization rates in patients with poor semen quality. In addition, studies have found that IMSI improves embryo development and that spermatozoa with large vacuoles in their heads correlate with increased aneuploidy rates and disturbed chromosomal structures. Thus, selecting spermatozoa based on morphological hallmarks may decrease aneuploidy rates in the fertilized embryos. As with polar body biopsies, however, this approach will solely be applicable if evidence for severe male detrimental contribution is given<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Blastocoel Fluid Extraction====<br />
In addition, a less invasive retrieval of material for diagnosis could include the extraction of the blastocoel fluid. The cavity of the blastocyst, lined by the trophectoderm, is filled with this blastocoel fluid, which contains metabolites of both trophectoderm and inner cell mass origin. The retrieval does not require a biopsy but merely a small opening to extract the fluid and, thus, causes less harm to the embryo. Multiple studies have applied this method<ref name="PMID22020776"><pubmed>22020776</pubmed></ref> <ref name="PMID23148560"><pubmed>23148560</pubmed></ref> and it may in the future become of clinical relevance.<br />
<br />
<br />
[[File:Aspiration_of_the_Blastocoel_Fluid.jpeg|thumb|Aspiration of the Blastocoel Fluid using a ICSI pipette<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.]]<br />
<br />
<br />
Next to metabolites, the blastocoel fluid can contain DNA. Studies have shown that genomic DNA is present in about 90% of the blastocoel fluid samples tested. Typically the fluid is removed with an ICSI pipette from a day five blastocyst through its mural trophectoderm until the blastocyst fully collapses around the embryo. Several concerns regarding this method in a clinical setting have been raised. The collected DNA may be contaminated by the culture media that contains DNA fractions. The DNA may also be least representative of the actual embryos genome as the DNA may originate from abnormal or degenerated cells. Even though labelled noninvasive, the blastocyst still undergoes manipulation to some degree which may affect its viability. Thus, more research is required until this method can evolve from research to clinical use<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
====Proteomics====<br />
The protein secretome of blastocysts may be representative of its chromosome constitution Recent studies have found biomarkers such as lipocalin-1, interleukin-10, tumor necrosis factor, stem cell factor, and chemokine ligand 13 to be differently secreted by aneuploid blastocyst than by euploid ones. The most significant biomarker appears to be interleukin-10. Paired with novel proteomic technologies and mass spectrometry this knowledge when extended may contribute to a new invasive preimplantation genetic diagnosis method<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Embryo Morphology====<br />
Using time lapse imaging the embryo’s morphology can be closely observed and potential aneuploidy characteristics detected. Such characteristics may include the time of division to five cells, the time between the division from three to four cells, and the duration of the division from one to two and subsequently to three. In addition, the morphological quality of ICM an TE has been positively associated with aneuploidy or euploidy prognosis<ref name="PMID26246880"><pubmed>26246880</pubmed></ref>. These may give rise to an embryo quality screening prior to implantation<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
==References==<br />
<br />
<references/><br />
<br />
<br />
{{StudentPage2015}}</div>Z5017878https://embryology.med.unsw.edu.au/embryology/index.php?title=2015_Group_Project_6&diff=2070372015 Group Project 62015-10-21T07:52:29Z<p>Z5017878: </p>
<hr />
<div>{{ANAT2341Project2015header}}<br />
<br />
<br />
=Preimplantation Genetic Diagnosis and Screening=<br />
==Introduction==<br />
Preimplantation genetic diagnosis (PGD) and screening (PGS) are reproductive options for couples with known family histories of genetic disease or couples undergoing IVF procedures due to infertility issues. PGD can diagnose many genetic disorders caused by known chromosomal abnormalities (number and/or structure) or single gene mutations, and, thus decrease the risk of termination of pregnancy or miscarriages and enable such couples to have an unaffected child<ref name="PMID24907939"><pubmed>24907939</pubmed></ref>. Through major improvements in PGD/S and general laboratory technology, the testing for abnormalities in fetuses has shifted from prenatal diagnosis during the first 2 trimesters <ref> Blackburn, S.L. (2003) '''Maternal, Fetal & Neonatal physiology: a Clinical perspective''' (2nd ed.). Seattle: Saudners </ref>, testing for overall fetal growth, complications of pregnancy, and birth defects<ref> Sadler T.W.(2012) '''Langman's Medical Embryology''' (12th ed.) Philadelphia: Lipincott, Wiliams & Wilkins, a Wolters Kluwer Business </ref>, to an embryonic focus especially in advancements in Artificial Reproductive Technologies (ART)<ref><pubmed>20638568</pubmed></ref>. In 1990 PGD for a recessive X-linked disease resulted in the first live birth<ref><pubmed>2330030</pubmed></ref> and has since been incorporated in clinical routine and applied for a variety of genetic diseases, such as sickle cell anemia, thalassemia, or cystic fibrosis<ref name="PMID24907939"/>.<br />
[[File:Preimplantation Genetic Diagnosis Procedure.jpeg|700px|thumb| Simplified steps for PGD<ref name="PMID24907939"/>]]<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=0e-79qKllqk</html5media><br />
|-<br />
| Preimplantation Genetic Diagnosis<ref>IVF Florida (2011, December 11) IVF Florida - South Florida Fertility Specialists - Pre-Implantation Genetic Diagnosis [Video file]. Retrieved from https://www.youtube.com/watch?v=0e-79qKllqk</ref><br />
|}<br />
<br />
==History==<br />
The advances in reproductive technology during the second half of the 20th century, led to PGD's first clinical application in 1990 <ref>Harper, J. (n.d.). The history of PGD. Lecture. UCL Centre for PG&D and CRGH.University College London</ref>.<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
|Year<br />
|<br />
|- bgcolor="FFFAFA"<br />
| '''1967''' <br />
|First PGD on rabbit blastocysts (Gardner& Edwards) <ref name="PMID6036172"><pubmed>6036172</pubmed></ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1986''' <br />
|First Cleavage Biopsy (Wilton & Trounson)<ref>Wilton, L. J., & Trounson, A. O. (1986). Viability of mouse embryos and blastomeres following biopsy of a single cell. In Proceedings of the 18th Annual Conference of the Australian Society for Reproductive Biology, Brisbane, Australia.</ref><br />
|- bgcolor="FFFAFA"<br />
|'''1987''' <br />
|First Blastocyst Biopsy (Muggleton-Harris, Monk, Rawlings, & Whittingham)<ref name="PMID3372699"><pubmed>3372699</pubmed></ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1988''' <br />
|First Polar Body Biopsy (Yury Verlinksy)<ref> Verlinsky, Y., Pergament, E., Andresen, P., Enriquez, G., & Strom, C. (1989). Genetic analysis of polar body DNA: A new approach to preimplantation genetic diagnosis. Am J Hum Genet, 45(4), A272.</ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1990''' <br />
|First Clinical PGD using PCR testing for X-linked (Handyside, Kontogianni, Hardy, & Winston)<ref name="PMID2330030"><pubmed>2330030</pubmed></ref> <br />
|} <br />
==Preimplantation Genetic Diagnosis==<br />
Preimplantation genetic diagnosis (PGD) is used to test the genetic makeup of embryos to detect single gene disorders, chromosomal abnormalities and mitochondrial disorders. It also has applications in gender selection for diseases with unequal gender distributions <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Some diseases commonly involved with PGD include cystic fibrosis, spinal muscular atrophy and beta – thalassaemia <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press.">Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press</ref> <ref name="PMID17823145"><pubmed>17823145</pubmed></ref>. It was first used in the United Kingdom in the 1980s of arenoleucodystrophy and primarily focusing on sex- linked disorders <ref name="PMID17823145"/><ref name="PMID23150080"><pubmed>23150080</pubmed></ref>. PGD is now capable of detecting single cell defects (molecular) and chromosomal disorders resulting from the inversion, translocation or deletion of chromosomes (cytogenic) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>,<ref name="PMID11325751"><pubmed>11325751</pubmed></ref>. PGD can be applied to the embryo at different stages. That is on polar bodies, blastomeres or blastocyst <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>.<br />
Depending on the type of genetic disorder, PGD utilises different methods of genetic testing. These include Fluorescence in situ hybridisation (FISH) which is used for sex – linked disorders and detects chromosomal rearrangements <ref name="PMID11325751"/><ref name="PMID17876073"><pubmed>17876073</pubmed></ref> and Embryo halotyping which allows the identification of chromosomes causing the inherited disorder through knowledge of the pattern of closely linked markers <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. Polymerase chain reaction (PCR) is also widely used to detect molecular abnormalities <ref name="PMID11325751"/>.<br />
PGD is tightly regulated and supported by large organisations namely The American Society for Reproductive Medicine, The European Society for Human Reproduction and Embryology (ESHRE), The European Society of Human Genetics and the Preimplantation Genetic Diagnosis International Society <ref name="PMID25500181><pubmed>25500181</pubmed></ref>.<br />
===Sex-linked disorders===<br />
The determination of a disease as gender specific usually correlates with the presence or absence of specific genes such as SRY on the Y chromosome. It is known that females have two X chromosomes and males have an X and a Y chromosome where abnormalities are more prevalent on the X chromosome. PGD can be used for sex selection where only male embryos are transferred to reduce the chance of inheriting X-linked disorders. However, this does not completely eradicate the problem as male embryos remain susceptible to inheriting an affected X chromosome. Sex determination is only used when the specific mutation is unknown and has yet to be discovered <ref name="PMID24866878"><pubmed>24866878</pubmed></ref>.<br />
===Single gene defects===<br />
Single gene defects can be dominant, recessive, autosomal or X-linked. They are commonly diagnosed using PCR and although the PCR available today is complex and capable of combatting a large range of disease the development of new protocols has been proven to be difficult due to the small DNA sample available <ref name="PMID26168107"><pubmed>26168107</pubmed></ref><br />
===Mitochondrial disorders===<br />
Mitochondrial disorders also known as oxidative phosphorylation disorders arise from mutations in the nuclear DNA or mitochondrial DNA <ref name="PMID26312584"><pubmed>26312584</pubmed></ref>. They pose as a problem because they are unrecognisable until the mutations in the cell reach a detrimental level <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Mitochondrial disorders cause miscarriages and stillbirths as well as death in children and young adults. The effects can either be contained in a single organ or more commonly involve multiple organ failure where organs with high energy demands such as the brain, liver muscle and heart and heavily influenced. They are usually occur spontaneously or result from inheritance from the mother. Since mitochondria are solely inherited from the mother oocyte donations have been used as a solution to combat mitochondrial disorders. Additionally, there has been an increasing use in PGD where embryos that stay under the given threshold of 18% gene-mutations are allowed to be transferred and result in normal development. New technology in the areas of nuclear gene transfer and genome editing are also being experimented with <ref name="PMID26312584"/>. <br />
===Chromosomal disorders===<br />
Chromosomal disorders can be reciprocal, Robertsonian translocations, inversions, deletions and insertions <ref name="PMID26168107"/>. . Data from ESHRE collected between 2010 and 2011 has shown that the most common chromosomal abnormality confronted in PGD are reciprocal chromosomal abnormalities <ref name"PMID26071418"><pubmed>26071418</pubmed></ref>. PGD has also been used successfully for Robertsonian translocations (RT), a type of structural translocation. Children who carry RT are phenotypically normal, however in their later years it is found that they will suffer from infertility and repeated miscarriages due to the high frequency of abnormal embryos <ref name="PMID22081077"><pubmed>22081077</pubmed></ref>. PCR and FISH are the two main techniques used for chromosomal disorders. To be able to conduct the examinations the cells are required to be at the metaphase stage <ref name="PMID26168107"/>. <br />
[[File:Reasons_for_PGD.jpg|600px|thumb|Reasons for PGD<ref name= "PMID24764761"><pubmed><24764761</pubmed></ref>]]<br />
==Preimplantation Genetic Screening==<br />
Prenatal Genetic Screening (PGS) involves an array of methods or ideas that aim to segregate embryos that have genetic flaws and those that are healthy <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. The occurrence of aneuploidy is high around the stages of early embryonic development and they are the most common cause if miscarriages and congenital birth defects <ref name= "PMID26085841"><pubmed>26085841</pubmed></ref>. They have little effect on the morphology of the embryo making them difficult to identify thus identification heavily relies on genetic testing <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. <br />
Genetic sampling is most commonly conducted using Microarray Comparative Genomic Hybridisation (aCGH) as well as FISH, Quantitative PCR and Single Nucleotide Polymorphism (SNP) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. These methods collectively aim to assess numeral and structural chromosomal errors <ref name= "PMID26085841"/>. Studies have also introduced Next- Generation Sequencing (NGS) <ref name= "PMID26085841"/> and Whole Genome Amplification used to screen imbalances in the complete 24-chromosomes <ref name="PMID25953353"><pubmed>25953353</pubmed></ref><br />
Statistics from ESHRE have shown that the most common indications for PGS is advanced age, followed by repeated implantation failure or recurrent miscarriage and male infertility <ref name="PMID26071418"><pubmed>26071418</pubmed></ref>.<br />
===Indications===<br />
A low percentage of structural abnormalities in chromosomes are responsible for the cause of miscarriages. Despite this, they are the most prevalent type of chromosomal abnormality accounted for in PGD <ref name="PMID20638568"/>. The presence of specific gene cycles, initiation of embryonic protein synthesis and evident physiological development are all indicative of a successful in vitro fertilisation procedure <ref name="PMID11576737"><pubmed>11576737</pubmed></ref>. To eliminate further errors from occurring during the PGD procedure it is recommended to undertake further prenatal testing such as amniocentesis in the later stages <ref name="PMID20638568"/>. <br />
====Advanced maternal age====<br />
Data provided by the ESHRE has shown that the mean age of women undergoing PGS is 39 years <ref name="PMID26071418"/>. Women of advanced age have been shown to have a lower rate of pregnancies reaching childbirth <ref name="PMID18583331"><pubmed>18583331</pubmed></ref>. The highlighted concern revolves around the increased occurrence of aneuploidy following maternal age. The optimal age range for the lowest aneuploidy incidence was found to be between 27 to 37 years of age (6%) then progressively higher in women aged up to 42 (33%) and most common in those 44 and above (53%) <ref name="PMID24355045"><pubmed>24355045</pubmed></ref>. <br />
====Recurrent pregnancy loss / IVF failure====<br />
Recurrent pregnancy loss is defined as three or more IVF failures after cumulative transfer of more than 10 good-quality embryos. These are primarily caused by two main factors, reduced endometrium receptivity or embryonic defects. Endometrium receptivity can be negatively influences by instances including uterine pathologies such as thin endometrium, altered expression of adhesive molecules and immunological factors. Additionally, embryonic defects may be due to genetic abnormalities, embryonic aneuploidy or zona hardening. Endometriosis and hydrosalpinx has been known to effect both the endometrium and embryo <ref name="PMID23260857"><pubmed>23260857</pubmed></ref>.<br />
====Human leukocyte antigen matching====<br />
First used in 2001, HLA matching is an option given to parents to save a child with haematological or immunological disease through conceiving another child who would potentially be able to donate cord blood or haematopoietic stem cells from the bone marrow for transplantation. The process namely PGD-HLA has shown to improve haematopoietic stem cell transplant (HSCT). PGD-HLA can only be performed when HSCT is not needed urgently due to the time needed to conceive and delivery the baby <ref name="PMID25500181"><pubmed>25500181</pubmed></ref>. It is most commonly applied to children suffering from relapsed leukaemia <ref name="PMID22524201"><pubmed>22524201</pubmed></ref>. In a case study PGD-HLA was proven to successfully cure 10 diseases including Fanconi anaemia, Diamond-Blackfan anaemia and beta thalassemia <ref name="PMID25066893><pubmed>25066893</pubmed></ref>.<br />
==Biopsy Methods==<br />
Biopsy, the removal of genetic materials, from oocytes or embryos in the preimplantation stage is the primary step in PGD. For the past two decades these biopsies have been performed at three stages, the polar body, blastomere, and blastocyst, and the methodologies optimized to ensure the embryo’s viability. The most common approach involves biopsies at the cleavage stage. However, polar body and blastocyst biopsies are increasingly more often tested and applied. Approached for opening the zona pellucida involve next to the traditional mechanical and chemical means, novel approaches such as noncontact lasers. Their application may simplify and secure the procedure significantly. The most challenging question about PGD procedures remains at what stage biopsies should be taken. Much controversy has developed around this topic, highlighting the varying disadvantages and advantages of temporal biopsies. <ref name="PMID22723007"><pubmed>22723007</pubmed></ref><br />
<br />
{| class="wikitable"<br />
|- align="center" bgcolor="DDCEF2"<br />
|<br />
| Time of Biopsy<br />
| Advantages <br />
| Disadvantages<br />
|- bgcolor="FFFAFA"<br />
| Polar Body<br />
| Day 1<br />
| No harm to oocyte<br />
| Only maternal DNA is tested, often needs to be coupled with other biopsies<br />
|- bgcolor="FFFAFA"<br />
| Blastomere<br />
| Day 3<br />
| …<br />
| … <br />
|- bgcolor="FFFAFA"<br />
| Trophectoderm<br />
| Day 5 and 6 <br />
| Little harm, large amount of genetic material<br />
| Opening of blastocyst necessary, small time window for procedure<br />
|}<br />
<br />
<br />
[[File:Polar_Body,_Blastomere,_and_Trophectoderm_Biopsy.jpeg|thumb|Polar body (A), blastomere (B) and trophectoderm (C) biopsies<ref name="PMID25625041"><pubmed>25625041</pubmed></ref>.]]<br />
<br />
<br />
<br />
PMID 24305177<br />
===Polar Body Analysis===<br />
Day 1<br />
====Description====<br />
Polar body (PB) biopsy, which was introduced in 1990, offers a promising alternative to biopsies performed at the blastomere stage for PGD/S indications on legal and practical grounds. <br />
Description: Consequent embryo development does not necessitate the presence of the first and second PB and their removal may not be crucial. PB biopsy requires precise timing. Keeping track of the meiotic cell cycle is necessary to perform a successful biopsy and, therefore, PB biopsy usually is applied in combination with intracytoplasmic sperm injection (ICSI). During the maturation from the germinal vesicle stage to the metaphase-II stage the first PB is formed. A cytoplasmic bridge containing spindle remnants, that are still in contact with the cellular genetic material, links this PB to the oolemma for about 90 minutes after extrusion. It is possible to visualize these remnants by polarization microscopy and it is crucial to not perform the biopsy until the first PB is no longer firmly attached to the oolemma as this indicates an immature embryo.The oocyte tolerates mechanical zona dissection best during hours four until six after ICSI as the oolemma has stabilized by that time because of the cortical granule reaction. Over time the first PB degenerates stressing a temporal biopsy and its optimal extraction time window is four to 12 hours after ICSI. The second PB forms around two to four hours after ICSI. However, its optimal time window for biopsy is set to be eight to 16 hours after ICSI. This is due to the second PB being attached to the oolemma with spindle remnants until six hours after ICSI. Biopsy at this point may cause enucleation of the oocyte. In addition, studies have shown that the amplification efficiency of second PB’s DNA is worse if the PB is extracted prior to eight hours after ICSI. <br />
Thus, it is possible to perform sequential and simultaneous biopsies for the first and second PB. If performed, sequentially the first PB may be removed four to 12 hours and the second PB eight to 16 hours after ICSI. The optimal time window for a biopsy for both the first and second PB simultaneously is eight to 12 hours after ICSI. It is highly preferred to analyze both PBs due to potential aneuploidies in either PB and crossing overs during meiosis<ref name="PMID22723007"/>. <br />
====Procedure====<br />
Chemical opening achieved with for example acidic tyrode’s solution of the zona pellucida is not tolerated by the oocyte and may have detrimental effects on the embryo’s development. Therefore, the access to the perivitelline space of the oocyte is provided by mechanical zona dissection or by laser. Both techniques work well if performed by experienced embryologist. However, laser-assisted biopsy is less time consuming when compared to manual dissection. It is critical to consider the size of the introduced opening as it will remain permanent. If it is too large the blastomere may be lost during embryo development and if it is too small it may interfere with hatching of the embryo during blastocyst stage<ref name="PMID22723007"/><br />
<br />
[[File:Polar_Body_Biopsy.jpeg|thumb|The presence of a faint but clearly identifiable strand connecting PB2 to the <br />
oolemma. The biopsy was performed ∼9 h after ICSI<ref name="PMID21908464"><pubmed>21908464</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JTaQzszVr8o</html5media><br />
|-<br />
| Laser-assisted polar body biopsy<ref>RIUK, R. (2013, June 25) Polar Body Biopsy [Video file]. Retrieved from https://www.youtube.com/watch?v=JTaQzszVr8o</ref><br />
|}<br />
<br />
====Advantages & Disadvantages====<br />
PB biopsies can only investigate the maternal contributions to the embryo as they are of maternal origin. Thus, this procedure is appropriate for PGD solely for monogenetic diseases from the maternal side. Recessive diseases may be evaluated with PB biopsies on the basis that the embryo’s outcome will be determined by the paternal contribution. (...) It may still be applied for PGS as most aneuploidies either arise during meiosis or origin from the maternal genome. However, diagnosis error has been reported due to the lack of considering paternal contributions. <br />
Because PB biopsies are performed very early it is not yet known whether the oocyte will develop into a viable embryo. Thus, PBs are commonly frozen or fixed after biopsy and depending on the state of the embryo only chosen PBs will be tested. This is primarily an economic issue as many genetic testing procedures are very cost-intensive<ref name="PMID22723007"/>.<br />
<br />
[[File:Implantation_predictive_value_of_euploid_screening_results.jpeg|thumb|The sustained implantation predictive value (with 95 % confidence interval) of a euploid screening result obtained from the first polar body (PB1), PB1 and the second polar body (PB2), or a direct embryo biopsy for each stage of embryo transfer (cleavage-stage and blastocyst stage)<ref name="PMID25106935"><pubmed>25106935</pubmed></ref>.]]<br />
<br />
===Blastomere biopsy===<br />
Day 3 <br />
====Description====<br />
Blastomere biopsy has been the prevalent method for PGD and PGS in the last two decades. At least one, but up to two, blastomeres are biopsied on day three of the cleavage stage embryo. The right number of blastomeres removed is a controversial topic as two cells allow for more genetic material and more accurate results. However, removing two cells might be too invasive and damaging to the embryo. (Study)<ref name="PMID21748341"><pubmed>21748341</pubmed></ref><br />
====Procedure====<br />
Initially a hole was drilled into the zona pellucida using acid tyrodes and the blastomeres are removed via aspiration with a pipette<ref name="PMID21748341"/>.<br />
<br />
<br />
[[File:Aspiration_of_a_Blastomere.jpeg|thumb|Aspiration of a Blastomere into the biopsy pipette<ref name=" PMID24783200"><pubmed>24783200</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=TbridWVwipI</html5media><br />
|-<br />
| Laser-assisted blastomere biopsy<ref>Sukprasert, M. (2014, March 5) Day 3 Blastomere Biopsy 1 [Video file]. Retrieved from https://www.youtube.com/watch?v=TbridWVwipI</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
===Trophectoderm biopsy===<br />
Day 5 and 6<br />
====Description====<br />
The improvement of embryo culture media allowed the in vitro development of human embryos until the blastocyst stage and opened up the possibility to take blastocyst biopsies. During day three to day five the haploid maternal and paternal genomes work together for the first time to form the genome of the embryo. The maternal epigenetic control lessens significantly while preparing for implantation with precisely arranged events happening. The first event includes a rapid increase in the number of embryonic cells which are active in mitotic divisions and apoptosis of aberrant cells. This is followed by the formation of blastocoel (cavitation) which results from the flattening of cell located on the outside of the blastomere. Now the blastocyst will expand until the embryo hatches by rupturing the zona pellucida. The cells of the blastocyst will differentiate to form two distinct cell lineages, the outer trophectoderm and the inner cell mass<ref name="PMID22723007"/>.<br />
====Procedure====<br />
Trophectoderm biopsy is usually performed in Hepes buffered biopsy medium and opening approaches include needle cutting which has been replaced by lasers in past years. Different research groups report different timings of the opening to be the most successful. Some open the blastocyst on day three or four by creating a 25 µm which causes the trophectoderm to herniate through this hole and is, thus, accessible for biopsy. Others create this hole about four hours before biopsy which allows sufficient herniation of trophectoderm cells. It is also possible to open the blastocyst immediately before biopsy. This avoids an extra step and the inner cell mass usually is easy to locate. Blastocyst biopsies involve the removal of trophectoderm cells and the ideal time for the procedure is day five. Successful biopsies on day six have been performed, while little is known about the results of biopsies on day seven. However, since the window of implantation in humans is from day eight to ten after ovulation, day seven biopsies appear to be possible<ref name="PMID22723007"/>.<br />
-collapse of trophoblasts<br />
-possible: biopsy of hatched blastocyst, holding pipette careful mild suction force to hold embryo near ICM <br />
-Cryopreservation<br />
<br />
<br />
[[File:Microscopic images of human blastocysts for biopsy.jpeg|thumb|(A) Some trophectoderm cells in a blastocyst started to hatch and (B) the trophectoderm cells were biopsied with assisted laser cutting. Images in C–D show the blastocysts after vitrification and warming. Blastocysts had been cultured for 2–4 hrs after warming, showing good (ICM and trophectoderm cells) hatched (C) and hatching (D) blastocysts. The hatching blastocyst in (E) has good ICM but fair trophectoderm while the blastocyst in (F) has both fair ICM and trophectoderm. Arrows indicate ICMs and arrow heads indicate trophectoderm cells. Bar = 40 µm<ref name="PMID2190846"><pubmed>2190846</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JI_TQ8d8tNM</html5media><br />
|-<br />
| Laser-assisted blastocyst biopsy (at 00:50 min)<ref>Coco, R. (2014, April 30) Trophectoderm biopsy in a Hatching blastocyst protruding ICM [Video file]. Retrieved from https://www.youtube.com/watch?v=JI_TQ8d8tNM</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
Blastocyst biopsies are believed to be less damaging to the embryo and appear to be unrelated to implantation rates. In addition, this biopsy method allows for a larger extraction of cells for genetic testing. However, since they are performed late in in vitro development, the time window for genetic testing is relatively small. Fast and accurate genetic testing methods are needed to ensure a successful and safe result from this biopsy. Thus, blastocyst biopsies may gain more popularity in the future whn such methods have been developed or improved<ref name="PMID22723007"/>. <br />
<br />
<br />
==Genetic Techniques==<br />
<br />
===PCR===<br />
====Description====<br />
Polymerase chain reaction (PCR) amplifies DNA specific to genetic sequence of interest . PCR was developed by Kay Mullis in the 1980s, for which he was awarded the Nobel prize for chemistry in 1993. <ref> Pubmed Docs (2015) Polymerase Chain Reaction (PCR) Pubmen. Retrieved from [http://www.ncbi.nlm.nih.gov/probe/docs/techpcr/]</ref> This technique enables clinicians to monitor and diagnose diseases using minute samples such as embryonic cells, blood & tissue. <ref>Roche (2015) PCR: How We Copy DNA. Roche Molecular Systems Inc. retrieved From [http://molecular.roche.com/pcr/Pages/Process.aspx]</ref> PCR has many important applications like DNA fingerprinting, genetic mapping, detection of viruses and bacteria as well as being used to detect genetic disorders, as a part of PGD, in conjunction with IVF. It is used to detect molecular abnormalities such as single gene disorders like Tay Sach, Cycstic fibrosis, Duchenne Muscular Dystrophy, Thalassemia, Huntington disease, Spinal muscular atrophy and many more. Molecular and Genetic analysis require a significant amount of DNA, which we would not have without PCR. It revolutionized the study of DNA, replacing all previous recombinant DNA technology. <ref> Mullins, K., Francois, F.& Gibbs R.A. (1994 ) The Polymerase Chain Reaction. p3. Springer- Science +Business Media. Birkhauser, Boston<br />
Available at [https://books.google.com.au/books?hl=en&lr=&id=gjrTBwAAQBAJ&oi=fnd&pg=PR5&dq=kary+mullis+PCR&ots=mpzAyRh5ZY&sig=PQ4goNoKJ90tb3-MkPk62zrTGbw#v=onepage&q=kary%20mullis%20PCR&f=false] </ref> <br />
<br />
[[File:PCR.jpg|thumb|right|Polymerase chain reaction (PCR) amplifies DNA specific to genetic sequence of interest, enabling the monitoring and diagnose molecular abnormalities such as single gene disorders using minute samples such as embryonic cells, blood & tissue <ref>NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref>]]<br />
<br />
====Procedure====<br />
<br />
Sample are obtained from the the blastocyst, a polar body biopsy or the blastomeres stages of the embryo. <br />
Stage 1 Denaturing: separating the target strands of DNA <br />
The obtained sample is heated to roughly 90 degrees celcius, this heat causes breaks the relatively weak bonds between nucleotides that form DNA. the double stranded DNA to split into 2 single strands of DNA that are used as templates.<br />
Stage 2 Annealing: Binding the Primers to the target DNA sequence <br />
PCR will only copy the target sequence of DNA specified by specific PCR primer. These synthesized primers Oligonucleotides are small artificial pieces of DNA. <br />
TAQ polymerase enzyme synthesize 2 new strands of DNA duplicate to the single sample DNA stand template indicated by these primers. During this stage the reaction is cooled to a temperature between 40-60 degrees Celsius. <br />
Stage 3- Extension- making copies <br />
Each of these 2 copies are then used again as templates generating 2 further replications This cycle can occur as many 30 -40 times within a couple hours leading to billions of extra copies of the original DNA segment. The optimal temperature for the further replication is roughly 72 degrees Celsius. <br />
<br />
This process mediated by a thermocycler machine that is programmed to alter the temperature of the reaction every couple of minutes, perpetuating the cycle of DNA denaturing and synthesis. <br />
This process, generates exponential exact copy of the original template DNA sequence. <br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
!PCR cycles<br />
<br />
|{|<br />
|-<br />
| '''PCR Cycle'''<br />
| '''Target Copies'''<br />
|-<br />
| 1<br />
| 2<br />
|-<br />
| 2<br />
| 4<br />
|-<br />
| 3<br />
| 8<br />
|-<br />
| 4<br />
| 16<br />
|-"<br />
| 5 <br />
| 32<br />
|-<br />
| 6 <br />
| 64<br />
|-<br />
| 7 <br />
| 128<br />
|-<br />
| 8<br />
| 256<br />
|- <br />
| 9<br />
| 512 <br />
|-<br />
| 10<br />
| 1024<br />
|-<br />
| 15<br />
| 32,768<br />
|-<br />
| 20 <br />
| 1,048,578<br />
|-<br />
| 25<br />
| 33,554,432<br />
|-<br />
| 30 <br />
| 1,073,741,842<br />
|-<br />
|}<br />
<br />
<br />
<br />
{|class="wikitable" align="center"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="10" |'''Advantages'''<br />
|-bgcolor="FFFAFA"<br />
| fast and inexpensive way of copying a target sequence of DNA<br />
|-bgcolor="FFFAFA"<br />
| aids the diagnosis of single cell defects<br />
|-bgcolor="FFFAFA"<br />
| rapid generation of results within a couple hours<br />
|-bgcolor="FFFAFA"<br />
| can start from a single molecule of DNA, therefore is more sensitive <br />
|-bgcolor="FFFAFA"<br />
| has a flexible primer design enabling<br />
|-bgcolor="FFFAFA"<br />
| overcame previous issues associated with the limited availability of sites of end<br />
|-bgcolor="FFFAFA"<br />
| generates the DNA copies exponentially<br />
|-bgcolor="FFFAFA"<br />
| enables DNA amplification required for molecular and genetic analysis<br />
|-bgcolor="FFFAFA"<br />
|Valid diagnostic method in selecting unaffected embryos for embryo transfer <ref> Dreesen, J., Drusedaul, M., Smeets, H., Die-Smulders, C., Coonen, E., Dumoulin, J., Gielen, M., Evers, J., Herbergers, J. & Geradets, J. (2008) Validation of preimplantation genetic diagnosis by PCR analysis: genotype comparison of the blastomere and corresponding embryo, implications for clinical practice. Mol. Hum. Reprod. 14 (10):573-579.doi: 10.1093/molehr/gan052. Retrieved from [http://molehr.oxfordjournals.org/content/14/10/573.short] </ref> <ref><pubmed>20966460</pubmed></ref><br />
|-bgcolor="DDCEF2"<br />
| rowspan="5"|'''Disadvantages'''<br />
|-bgcolor="FFFAFA"<br />
| only during this exponential DNA replication phase can we determine the starting quantity sequence contained in the original sample ( template DNA strand)<br />
|-bgcolor="FFFAFA"<br />
| PCR reaction is limited by the presence of inhibitors present in the sample : reagent inhibitors <br />
|-bgcolor="FFFAFA"<br />
| self annealing due to the accumulation of the product -stopping exponential amplification for the target sequence and reach a plateau<br />
quantification of the end point of reaction of PCR products unreliable - therefore that is why we require real time quantitative RT-PCR necessary<br />
<ref> NIS (2015) Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref><br />
|}<br />
<br />
<br />
===Fluorescent In Situ Hybridisation (FISH)===<br />
<br />
<br />
====Description====<br />
Fluorescence in situ hybridization (FISH) the one of the most effective and rapid <ref name="PMID26338801"><pubmed>26338801</pubmed></ref> Preimplantation Genetic Diagnosis (PGD). This techniques used to locate a specific DNA sequences within a chromosome. FISH facilitates the clinical diagnosis of chromosomal abnormalities indicated by sequential duplications, deletions and rearrangements of chromosome, that are usually missed with microscopic analysis. This technique is especially relevant for female embryos with X-linked diseases,<ref name="PMID20809319"><pubmed>20809319</pubmed></ref> that have no other mutation specific tests [http://www.ncbi.nlm.nih.gov/pubmed/20809319] As part of PGD, samples are collected from various stages of the embyro,and they are able to conducted tests on the blastocyst, a polar body biopsy and the blastomeres <ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. FISH is 99% effective when used in conjunction with competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities<ref name="PMID26338801"/>.<br />
<br />
====Procedure==== <br />
<br />
Samples are collected from either the blastocyst, a polar body biopsy or the blastomeres stages of the embryo <ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
DNA strands are heated and denatured causing their the individual DNA strands to break apart<br />
Probes are single complimentary stands of DNA a that have been tagged with small chemical agents that glow brightly in the presence of a specific region on a chromosome. These specific probes then hybridize and join to their complementary DNA strand. <br />
The fluorescent tags enable the researchers to correctly identify the presence or lack thereof and location of the specific chromosomes that they are testing for. <ref name="PMID17876073"><pubmed>17876073</pubmed></ref><br />
Researcher analyse the results by identifying the number and the relative location of the fluorescent dots generated by the FISH images.<ref name="PMID17970921"><pubmed>17970921</pubmed></ref><br />
The probe will not fully hybridise if there has been a duplication or a deletion of the DNA - indicating chromosomal and sex chromosomal anomalies like trisomies and aneuploidies. <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref><br />
<br />
<br />
Different probes are used for different purposes: <ref>Unique, Rare Chromosome Disorder Support Group (2013) Fluorescence in situ hybridisation (FISH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/Other/FISH%20FTNW.pdf]</ref><br />
*'''Locus specific tags''' detect very small imbalances, and locate isolated small portions <br />
of genes within a chromosome<br />
*'''Alphoid/Centomeric Repeat probes''' are developed from the repetitive sequence located in the middle region of each chromosome, useful in determining the number of chromosomes , detecting rearrangement and when used in conjunction with locus probes to determine the absence of genetic material on a chromosome. <br />
*'''Paint Probes''' are collections of smaller probes with their own stains that bind to a different section on the chromosome - allowing the full chromosome too be labeled a unique colour, this "full colour map" can be used to know the spectral karyotype- full chromosomal mapping is useful in examining chromosomal abnormalities. <br />
<br />
[[File:Fluorescent In Situ Hybridisation (FISH).jpg|thumb|right|'''FISH''' We are able to tag Specific DNA sequences using Probes which have been tagged with fluorescent Labels.This technique enables the clinical diagnosis of chromosomal abnormalities, indicated by sequential duplication, deletions and rearrangements of chromosome <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref>]]<br />
<br />
{|class="wikitable" align="center"<br />
|-bgcolor="pink" <br />
| rowspan="8" |'''Advantages''' <br />
|-bgcolor="#FDE1F2" <br />
| FISH is 99% effective when used in conjunction with Competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities.<ref><pubmed>26338801</pubmed></ref><br />
|-bgcolor="#FDE1F2" <br />
| Rapid generation of results<br />
|-bgcolor="#FDE1F2" <br />
| Identifies very small translocations and aneuploidies that occur within chromosomes, that would usually be missed under microscopic analysis<br />
|-bgcolor="#FDE1F2" <br />
| Indicates whether the accessed chromosomes are normal <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|-bgcolor="#FDE1F2" <br />
| Tests for the most common chromosomal abnormalities - down syndrome chromosomes 13,16,18,21 and 22 <ref><pubmed>21749752</pubmed></ref><br />
|-bgcolor="#FDE1F2" <br />
| It may be used to compare the chromosomal gene arrangements in related species<br />
|-bgcolor="#FDE1F2" <br />
| can be used to identify and remove inheritable X-linked disease or sex chromasome anomalies such as Duchennes Muscular Dystrophy, hemophilia, ectodermal dysplasia <ref><pubmed>17876073</pubmed></ref><br />
|-bgcolor="#FEB745"<br />
| rowspan="5"|'''Disadvantages'''<br />
|-bgcolor="#FE1C5EA"<br />
| FISH destroys all cells tested <ref> O'Connor, C. (2008) Fluorescence in situ hybridization (FISH). Nature Education 1(1):171. retrieved from [http://www.nature.com/scitable/topicpage/fluorescence-in-situ-hybridization-fish-327] </ref><br />
|-bgcolor="#FE1C5EA"<br />
| It does not fully access all chromosomes (only ~ 12)<br />
|-bgcolor="#FE1C5EA"<br />
| Analysis of results is dependent upon the dot quality impacted by hybridisation efficiency or the camera sensitivity <ref><pubmed>17970921</pubmed></ref><br />
|-bgcolor="#FE1C5EA"<br />
| some studies indicate that using FISH on a day-3 embryo biopsy decreases the rate of live births <ref><pubmed>26168107</pubmed></ref><br />
|}<br />
<br />
===Array Comparative Genomic Hybridisation (aCGH)===<br />
====Description====<br />
<br />
aCGH also known as Microarray analysis efficiently scans the entire genome for chromosomal imbalances. CGH was initially developed to detect the number of changes in a solid tumor mass. It uses 2 genomes comparing the sample to the control, with each labeled in a different fluorescent dye<ref name="PMID1876176"><pubmed>1876176</pubmed></ref>. Earlier CGH techniques were limited by the resolution of the imaging <ref> Lichter, P., et al. Comparative genomic hybridization: Uses and limitations. Seminars in Hematology 37, 348–357 (2000)</ref> , these initial limitations were overcome by using Microarrays in conjunction with CGh to improve the resolution of the imaging, Array Comparative Genomic Hybridisation (aCGH). This method compares sample and control microarrayed slides containing small segments of DNA (probes). <ref> Lucito, R., et al. Representational oligonucleotide microarray analysis: A high-resolution method to detect genome copy number variation. Genome Research 13, 2291–2305 (2003) </ref> the Probes used will vary according from the small (25-85 base pairs) oligonucleotides manufactured to highlight different target sequences, to the very large genomic clones (80,000- 200,00 base pairs), and as these are significantly smaller than the traditional metaphase chromosomes used for CGH, generating a higher resolution of image. <ref name="PMID22467166"><pubmed>22467166</pubmed></ref>.aCGH is used as a diagnostic tool for prenatal detection f chromosomal abnormalities <ref name="PMID19012303"><pubmed>19012303</pubmed></ref>.<br />
<br />
<br />
====Procedure====<br />
<ref> Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432] </ref><br />
The sample is obtained (skin, blood or fetal cells) and DNA is obtained. <br />
As a part of PGD fetal cell samples are collected from; the fertilized egg polar bodies, the blastomere (day 3 embryo) or the blastocyst/tropoectoderm stage (day 5 embryo).<br />
Sample DNA is labeled with one fluorescent dye, and the control DNA is labeled with a different colored fluorescent dye. the control DNA is used as the base point of reference. <br />
heated and denatured single DNA strands then hybridize to their complementary single strand probes, which are then combined and applied to a microarray and the results are run through a computer program and a digital imaging system is used to quantify the results( fluorescent intensities of the labeled probes). <br />
<br />
[[File:aCGH.jpg|thumb|right|'''aCGH''' checks the entire genome for chromosomal imbalances, by comparing control and a sample slides contatining small segements of DNA sample microarrayed slides small segments of DNA. Illustrated by student z5020317 and adapted from <ref> NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation. retrieved from [http://www.phgfoundation.org/file/5237/]</ref> <ref>Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432]</ref>]]<br />
<br />
The fluorescent ratio and the hybridization signal at different locations on the genome of the control DNA are used to identify any variances present in the sample DNA. aCGH facilitates the clinical diagnosis of submicroscopic chromosomal duplication, deletion and rearrangements indicative of chromosomal disorders such as trisomies 1-22and specific sex linked disorders. <br />
Duplications in the DNA are displayed by the computer program as spikes/ peaks over an established threshold and deletions in DNA are displayed by the computer program as spikes/ toughs beneath this threshold <br />
<br />
{|class="wikitable" align="center"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="12" |'''Advantages''' <br />
|-bgcolor="FFFAFA"<br />
| Multiple applications: prenatal genetic diagnosis, cancer diagnosis, <ref name="PMID20193845"><pubmed>20193845</pubmed></ref> genetic screening for developmental delay (learning disabilities) <ref name="PMID17309648"><pubmed>17309648</pubmed></ref>. or congenital anomalies that are suspected to be genetic in origin <ref>NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation . retrieved from [http://www.phgfoundation.org/file/5237/]</ref><br />
|-bgcolor="FFFAFA"<br />
| trace represents all chromosomes present in the human genome chromosomes 1-22 and the X & Y chromosomes, and therefore is the most accurate method for testing whole embryo aneuploidy<br />
|-bgcolor="FFFAFA"<br />
| aCGH has been extensively tested, and Validated, and is now used world wide.<br />
|-bgcolor="FFFAFA"<br />
| Detects submicroscopic alterations<br />
|-bgcolor="FFFAFA"<br />
| Detects deletions and additions and rearrangements as well as amplification, of the WHOLE genome, simultaneously.<br />
|-bgcolor="FFFAFA"<br />
| Used as a diagnostic tool for prenatal detection of chromosomal abnormalities <ref name="PMID22034057"><pubmed>22034057</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Provides high resolution genomewide screening of segmental genomic copy number variations<br />
|-bgcolor="FFFAFA"<br />
| Very accurate when used in conjunction with FISH<br />
|-bgcolor="FFFAFA"<br />
| Alone is more reliable and in detecting chromosomal abnormalities, with a higher implantation success rate, than FISH <ref name="PMID20494259"><pubmed>20494259</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Allows an in depth research focus upon specific types of rearrangements within selected chromosomal regions, a recent particular area of interest is subtelomeric and pericentromeric rearrangements<br />
|-bgcolor="FFFAFA"<br />
| Reduces the risk of failed implantation and miscarriage, improving the chance of a healthy baby <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|-bgcolor="DDCEF2"<br />
| rowspan="9" |'''Disadvantages'''<br />
|-bgcolor="FFFAFA"<br />
| Translocations and inversions of DNA are not detected<br />
|-bgcolor="FFFAFA"<br />
| Limited ability diagnosing specific polyploidies such as triploidy <ref> Unique, Rare Chromosome Disorder Support Group (2013) Microarray-based Comparative Genomic Hybridiation (array CGH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/other/array%20cgh%20ftnw.pdf] </ref><br />
|-bgcolor="FFFAFA"<br />
| Will not detect mosaicism detection <20% (cultures where >1 of 5 cells are trisomy 12)<br />
|-bgcolor="FFFAFA"<br />
| Will not detect balanced chromosomal rearrangement<br />
|-bgcolor="FFFAFA"<br />
| Will not detect duplications or deletions <80kb<br />
|-bgcolor="FFFAFA"<br />
| Will not detect point mutations within genes <ref>Washington department of education (CGH- FAQ for physicians. Signature Genomic LAboratories, LLC. Retrieved from [https://depts.washington.edu/dbpeds/Lab%20Tests/SignatureCGH-physician_FAQ.pdf]</ref><br />
|-bgcolor="FFFAFA"<br />
| will not detect chromosomal position of genomic gains<br />
|-bgcolor="FFFAFA"<br />
| Will not detect loos of heterozygosity (LOH) or Absence of heterozygosity (AOH) <ref>WiCell Research Institute Inc. (2012) Comparative Genomic Hybridization Microarray. <br />
retrieved from [http://www.wicell.org/home/cytogenetic-services/cgh-microarray/array-comparative-genomic-hybridization-acgh.cmsx]</ref><br />
|}<br />
<br />
===Next Generation Sequencing===<br />
====Description====<br />
The development and advances within ART in the past 20 years, as well as the increasing popularity of IV, has lead to an influx of new technologies developed to screen embryos for chromosomal anomalies, which are covered by the umbrella term of Next generation Sequencing (NGS). NGS is a general term used to describe all of the new and emerging screening techniques currently being introduced and used as part of PGD for IVF . NGS screens for single gene disorders as well as conducting extensive and very comprehensive chromosome diagnosis by sequencing, counting, and accurately assembling millions of DNA reads, simultaneously. <ref name="PMID23499002"><pubmed>23499002</pubmed></ref> There is a movement for NGS to replace the other limited testing techniques and be used as the standard. <br />
====Procedure====<br />
Samples are collected from either blastomere or the blastocyst/tropoectoderm and processed for analysis by a computer system. <br />
The methodology of each process is unique to the technique being used. <br />
<br />
{|class="wikitable" align="center"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="14" |'''Advantages''' <br />
|-bgcolor="FFFAFA"<br />
| Cheaper<br />
|-bgcolor="FFFAFA"<br />
| Opens new diagnostic possibilities<br />
|-bgcolor="FFFAFA"<br />
| Accurately tests all 24 chromosomes<br />
|-bgcolor="FFFAFA"<br />
| Tests for the presence of monogenic diseases of known genetic background<br />
|-bgcolor="FFFAFA"<br />
| Reduces the number of biopsies required for diagnosis<br />
|-bgcolor="FFFAFA"<br />
| Higher detection rate of small translocations<br />
|-bgcolor="FFFAFA"<br />
| Highly accurate is testing for compound point mutations, chromosomal duplication, deletions and insertions <ref name="PMID23312231"><pubmed>23312231</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| It accurately detects chromosomal aneuploidy and unbalanced rearrangement <ref name="PMID25685330"><pubmed>25685330</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Higher detection rate of small translocations<br />
|-bgcolor="FFFAFA"<br />
| NGS single gene disorder screenings can conducted in conjunction with PCR comprehensive chromosomal screening<br />
|-bgcolor="FFFAFA"<br />
| Reduces human error <br />
|-bgcolor="FFFAFA"<br />
| Better detects the presence of mosaicism<br />
|-bgcolor="FFFAFA"<br />
| Work well in conjunction with CGH and aCGH as part of PGD, improving the chances of IVF. <ref> Morris, R. S. (2015 ) Next generation sequencing for PCG|PGS|CCS. IVF1 retrieved from [http://www.ivf1.com/next-generation-sequencing for-pgd] </ref><br />
|-bgcolor="DDCEF2"<br />
| rowspan "2" |'''Disadvantages''' <br />
|-bgcolor="FFFAFA"<br />
| There are limited information available to clinical applications of NGS <ref><pubmed>26100406</pubmed></ref><br />
|}<br />
<br />
==Diagnosis==<br />
There are a large amount of diseases that PGD can apply to, below are descriptions of the diseases that PGD are more commonly used for. Utilization of Diseased Cell Lines<br />
===Cystic Fibrosis===<br />
Cystic fibrosis is a single gene disorder. It is autosomal recessive and involves mutations in the cystic fibrosis transmembrane conductance regulator (CTFR) gene. The CTFR gene is normally responsible for the decrease in chloride and the transport of bicarbonate in epithelial cells thus playing a major physiological role. In PGD procedures, identification of the gene is assisted by microsatellite markers that have similar composition to the CTFR gene itself. Biopsy of two cells at the blastocyst stage is recommended if markers are not available. There are many variations of cystic fibrosis the most common being P.Phe508del <ref name="PMID26014425"><pubmed>26014425</pubmed></ref>.<br />
===Duchenne Muscular Dystrophy ===<br />
Duchenne Muscular Dystrophy is an X-linked recessive disease. It involves the Xp21 gene where majority of the mutations are chromosomal deletions with a smaller percentage resulting from duplications <ref name="PMID18359022"><pubmed>18359022</pubmed></ref>.<br />
<br />
===Autosomal Recessive MEckel-Gruber Syndrome===<br />
Autosomal recessive genetic defect caused by the TMEM67 gene. It results in cystic dysplasia of the kidneys with fibrotic change in the liber and occipital encephalocele. Other malformations could also be present in the central nervous system. In PGD whole genome amplification of single blastomeres are taken to identify the gene, this is also coupled with PCR techniques. Maternal plasma can also be extracted for PGS. <ref><pubmed>24039893</pubmed></ref> <br />
===β – Thalassemia=== <br />
β – Thalassemia is known as the most common type of autosomal recessive inherited disorder among haemoglobinopathies. It involves the adult β-globin gene and is associated with the absent or decreased expression of the gene. This is commonly caused by a single nucleotide change in the gene. PGD has been used successfully worldwide to identify the β-globin gene where its application is usually performed on a single blastomere or polar body <ref name="PMID19064120">19064120</pubmed></ref>.<br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
! Applicable diseases for PGD <ref>Genoma Group (2014). Retrieved September 18th, 2015, from http://www.preimplantationgeneticdiagnosis.it/genetic-diseases-diagnosed-by-pgd.htm </ref>, <ref>Genesis Genetics (2015). Retrieved September 18th, 2015, from http://genesisgenetics.org/pgd/what-we-test-for/</ref>, <ref>Human Fertilisation & Embryology Authority (2015). Retrieved Septembr 18th, 2015, from http://guide.hfea.gov.uk/pgd/</ref><br />
|-<br />
| '''Disease'''<br />
| '''Involved Genes'''<br />
|-<br />
| 5 Alpha Reductase Deficiency (5ARD)<br />
| SRD5A2 <br />
|-<br />
| Achondroplasia<br />
|FGFR3 <br />
|-<br />
| Acute Intermittent Porphyria <br />
| ALAD, ALAS2, CPOX, FECH, HMBS, PPOX, UROD, or UROS<br />
|-<br />
| Adrenoleukodystrophy (Adrenomyeloneuropathy)<br />
| ABCD1 <br />
|-<br />
| Agammaglobulinaemia (x-linked) <br />
|BTK <br />
|-<br />
| Agammaglobulinemia Bruton Tyrosine Kinase (BTK) <br />
|BTK <br />
|-<br />
| Aicardi Goutieres Syndrome 1 (AGS1) <br />
|TREX1, RNASEH2A, RNASEH2B, RNASEH2C, SAMHD1<br />
|-<br />
| Alagille Syndrome<br />
|JAG1 or NOTCH2<br />
|- <br />
| Alpers-Huttenlocher Syndrome <br />
|POLG <br />
|-<br />
| Alpha-1-antitrypsin deficiency <br />
|SERPINA1 <br />
|-<br />
| Alpha-Mannosidosis<br />
| MAN2B1 <br />
|-<br />
| Alpha Thalassemia <br />
|HBA1 or HBA2 <br />
|-<br />
| Alports Syndrome<br />
|COL4A3, COL4A4, COL4A5<br />
|-<br />
| Alzheimer's Disease - early onset (Type 3 and 4) <br />
|APP, PSEN1, or PSEN2<br />
|-<br />
| Amyotrophic Lateral Sclerosis 1 (ALS1) <br />
|C9orf72, SOD1, TARDBP, FUS, ANG, ALS2, SETX, VAPB <br />
|-<br />
| Argininosuccinic Aciduria <br />
| ASL<br />
|-<br />
| Arrhythmogenic Right Ventricular Cardiomyopathy/ Dysplasia (ARVC/D)<br />
| DSG2; DSP; PKP2<br />
|-<br />
| Ataxia Telangiectasia<br />
| ATM<br />
|-<br />
| Autosomal Recessive Meckel-Gruber Syndrome<br />
| TMEM67<br />
|-<br />
| Bardet-Biedl Syndrome (BBS)<br />
| BBS1; BBS10<br />
|-<br />
| Barth Syndrome<br />
| TAZ<br />
|-<br />
| Beta Thalassaemia<br />
| HBB<br />
|-<br />
| Birt-Hogg-Dubé Syndrome<br />
| FLCN<br />
|-<br />
| Breast Ovarian Cancer Familial Susceptibility (BRCA2)<br />
| BRCA1; BRCA2<br />
|-<br />
| Canavan Disease <br />
| ASPA<br />
|-<br />
| Carnitine-Acylcarnitine Translocase Deficiency <br />
| SLC25A20<br />
|-<br />
| Cerebral Arteriopathy with Subcortical Infarcts & Leukoencephalopathy (CADASIL)<br />
| NOTCH3<br />
|-<br />
| Cerebral Cavernous Malformation<br />
| CCM1<br />
|-<br />
| Charcot-Marie-Tooth Disease<br />
| GJB1; MPZ; NEFL; PMP22<br />
|-<br />
| CHARGE Syndrome<br />
| CHD7<br />
|-<br />
| Cherubism<br />
| SH3BP2<br />
|-<br />
| Choroideremia<br />
| CHM<br />
|-<br />
| Chronic Granulomatous Disease<br />
| CYBB; NCF1<br />
|-<br />
| Ciliary Dyskinesia<br />
| DNAH5<br />
|-<br />
| Citrullinemia<br />
| ASS1<br />
|-<br />
| Cleidocranial Dysplasia<br />
| RUNX2<br />
|-<br />
| Cockayne Syndrome<br />
| ERCC6<br />
|-<br />
| Congenital Adrenal Hyperplasia<br />
| CYP21A2<br />
|-<br />
| Congenital Cataracts<br />
| GJA8; VSX2<br />
|-<br />
| Congenital Diarrhea, Syndromic<br />
| SPINT2<br />
|-<br />
| Congenital Disorders of Glycosylation (CDG)<br />
| ALG1; ALG6; CDG1C; DOLK; PMM2<br />
|-<br />
| Cornelia de Lange Syndrome <br />
| NIPBL<br />
|-<br />
| Craniosynostosis<br />
| TWIST1<br />
|-<br />
| Crouzon Syndrome<br />
| FGFR2<br />
|-<br />
| Cysteinyl Leukotriene Receptor 1 Deficiency <br />
| CYSLTR1<br />
|-<br />
| Cystic Fibrosis<br />
| CFTR<br />
|-<br />
| Diamond –Blackfan Anemia <br />
| RPS19<br />
|-<br />
| Duchenne Muscular Dystrophy <br />
| DMD<br />
|-<br />
| Dyskeratosis congenita (Male embryos only)<br />
| DKC1<br />
|-<br />
| Ectodermal dysplasia (Hypohidrotic)<br />
| EDA; EDA1; GJB6; IKBKG<br />
|-<br />
| Familial Adenomatous polyposis coli (FAP)<br />
| APC<br />
|-<br />
| Familial Dysautonomia<br />
| IKBKAP<br />
|-<br />
| Fanconi Anemia <br />
| FANCA; FANCC; FANCD2; FANCF; FANCG; FANCJ<br />
|-<br />
| Fragile X Syndrome (FRAX)<br />
| FMR1<br />
|-<br />
| Galactosemia <br />
| GALT<br />
|-<br />
| Gangliosidosis<br />
| GLB1<br />
|-<br />
| Glanzmann Thrombasthenia <br />
| ITGA2B<br />
|-<br />
| Glutaric Acidemia (aciduria)<br />
| GCDH <br />
|-<br />
| Glycogen Storage Disease <br />
| G6PC; GAA; SLC37A4<br />
|-<br />
| Haemophilia A<br />
| F8<br />
|-<br />
| Haemophilia B<br />
| F9<br />
|-<br />
| Hereditary Nonpolyposis Colorectal Cancer: Lynch Syndrome<br />
| MLH1; MSH2; MSH6<br />
|-<br />
| Holt Oram Syndrome<br />
| TBX5<br />
|-<br />
| Huntington Disease<br />
| HD<br />
|-<br />
| Hydrocephalus<br />
| L1CAM<br />
|-<br />
| Ichthyosis <br />
| ABCA12; STS<br />
|-<br />
| Incontinentia Pigmenti (IP)<br />
| NEMO<br />
|-<br />
| Joubert Syndrome 5<br />
| INPP5E<br />
|-<br />
| Krabbe Disease<br />
| GALC<br />
|-<br />
| Leber Congenital Amaurosis (LCA)<br />
| CEP290; GUCY2D<br />
|-<br />
| Leigh Syndrome (Infantile Subacute Necrotising Encephalopathy)<br />
| LRPPRC<br />
|-<br />
| Lesch Nyan Syndrome<br />
| HPRT1<br />
|-<br />
| Leukocyte Adhesion Deficiency (Type I)<br />
| ITGB2<br />
|-<br />
| Li-Fraumeni Syndrome<br />
| TP53<br />
|-<br />
| Macular Dystrophy Retinal <br />
| VMD2<br />
|-<br />
| Maple Syrup Urine Disorder (MSUD)<br />
| BCKDHB<br />
|-<br />
| Marfan Syndrome <br />
| FBN1<br />
|-<br />
| Menkes Syndrome<br />
| ATP7A<br />
|-<br />
| Mitochondrial DNA Depletion Syndrom <br />
| POLG; RRM2B; SUCLA2; TK2<br />
|-<br />
| Mucolipidosis type II<br />
| GNPTAB<br />
|-<br />
| Multiple Endocrine Neoplasia<br />
| MEN1; MEN2A; MEN2B<br />
|-<br />
| Multiple Exostoses<br />
| EXT1; EXT2 <br />
|-<br />
| Myotubular myopathy<br />
| MTM1 <br />
|-<br />
| Nail-Patella Syndrome<br />
| LMX1B<br />
|-<br />
| Neurofibromatosis Type 1<br />
| NF1<br />
|-<br />
| Neurofibromatosis Type 2 <br />
| NF2<br />
|-<br />
| Noonan Syndrome<br />
| KRAS, PTPN11; SOS1<br />
|-<br />
| Norrie Disease<br />
| NDP<br />
|-<br />
| Ocular Albinism <br />
| GPR143<br />
|-<br />
| Oculocutaneous Albinism <br />
| OCA2; TYR <br />
|-<br />
| Oculodentaldigital Dysplasia<br />
| GJA1<br />
|-<br />
| Optic Atrophy<br />
| OPA1<br />
|-<br />
| Ornithine Transcarbamylase Deficiency <br />
| OTC<br />
|-<br />
| Osteogenesis imperfeca <br />
| COL1A1; COL1A2<br />
|-<br />
| Osteopetrosis <br />
| CLCN7; OSTM1; TCIRG1<br />
|-<br />
| Pachyonychia Congenita <br />
| KRT16; KRT6A<br />
|-<br />
| Pancreatitis, Hereditary<br />
| PRSS1 <br />
|-<br />
| Papillorenal syndrome <br />
| PAX2<br />
|-<br />
| Phenylketonuria <br />
| PAH <br />
|-<br />
| This table does not cover the complete list of diseases that PGD can be applied to.<br />
|}<br />
<br />
==Laws & Legal status==<br />
<br />
{| class="wikitable" <br />
|-bgcolor="DDCEF2"<br />
|'''Country'''<br />
|'''Legislation'''<br />
|-<br />
| Australia<br />
| PGD is currently used to detect serious genetic conditions to improve the outcome of Assisted Reproductive Technologies (ART). In very rare cases it may be used to select an embryo with compatible tissue for a sibling who has a life-threatening disease where other means of treatment is unavailable. This is with the conditions that the use of PGD will not affect the welfare and interests of the child to be born. The parents must also receive adequate counselling and have full understanding of the procedures of PGD. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"> National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art</ref><br />
The use of PGD for sex-selection is prohibited with the exception of reducing the risk of the transmission of serious sex-linked genetic conditions. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"/><br />
|-bgcolor="FFFAFA"<br />
| Brazil<br />
| The laws regarding PGD in Brazil are not strictly regulated. They are vague and there is limited information surround the activities of assisted reproduction in general in the country <ref name="PMID25493379"><pubmed>25493379</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| Czech Republic<br />
| The laws in the Czech Republic allow those with a “defined indication in order to exclude risk of serous genetically conditioned disease and defects with embryos before they are implanted into the cavity of the uterus”. Couples that undergo any assisted reproductive treatment including PGD have to be married. Sex-selection is illegal except in regards to serious sex-linked genetic diseases <ref name="PMID24777348"><pubmed>24777348</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| Greece<br />
| In Greece, ART is open to those up to the age of 50 with written consent. It can only be used if a medical necessity is present such as the susceptibility of serious hereditary diseases. Sex selection is banned apart from cases of sex-linked diseases and sexually transmitted diseases <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| India<br />
| In India there is a cultural preference for boys thus the Prenatal Diagnostic Techniques (Regulation and Prevention of Misuse) Act was introduced in 1994. This law limits the use of PGD for sex determination except in cases of specific congenital diseases. These laws however are not strictly enforced. <ref>World Health Organisation (2015) Gender and Genetics Retrieved on October 21st 2015 from:http://www.who.int/genomics/gender/en/index4.html</ref><br />
|-bgcolor="FFFAFA"<br />
| Portugal <br />
| ART is only available to those who are married or have a similar type of relationship for at least two years. The couples cannot be of the same sex and must be at least 18 years of age. Sex selection is illegal except in cases of sex-linked diseases. The use of PGD is illegal if the predictive value of genetic tests are very low <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| Spain<br />
| PGD can be applied to “serious hereditary diseases not amenable to postnatal curative treatment” and “detection of other abnormalities which may compromise the viability of the pre-embryo”. If PGD is to be used for any other purpose authorisation must be acquired <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| Sweden <br />
| The use of PGD is strictly regulated and couples must achieve authorisation of the National Board of Health and Welfare. It can only be used it can only be used if the child is at risk to inheriting a serious chromosomal or monogenetic disease. It cannot be used for selection of specific characteristics <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| United Kingdom<br />
| Those involved with carrying out the IVF treatment must have a license from the Human Fertilisation and Embryology Authority (HFEA). Only embryos that are approved by the HFEA can be implanted where the embryonic nuclear or mitochondrial DNA cannot be altered with the exception of preventing mitochondrial diseases <ref name="PMID24777348"/>. <br />
|}<br />
<br />
==Future/Current Research==<br />
===Noninvasive Preimplantation Genetic Testing without Embryo Biopsy===<br />
Different parameters of gametes, zygotes, embryos (“vacuoles in sperm heads, spindle position in mature oocytes, cleavage intervals of zygote, and embryo developmental dynamics”) may correlate with aneuploidy rates. This knowledge may be applied in potential noninvasive preimplantation diagnostic methods. Several methods have been proposed and are currently further researched<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Sperm Selection====<br />
Intracytoplasmic morphologically selected sperm injection (IMSI) is common procedure in IVF treatment to improve fertilization rates in patients with poor semen quality. In addition, studies have found that IMSI improves embryo development and that spermatozoa with large vacuoles in their heads correlate with increased aneuploidy rates and disturbed chromosomal structures. Thus, selecting spermatozoa based on morphological hallmarks may decrease aneuploidy rates in the fertilized embryos. As with polar body biopsies, however, this approach will solely be applicable if evidence for severe male detrimental contribution is given<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Blastocoel Fluid Extraction====<br />
In addition, a less invasive retrieval of material for diagnosis could include the extraction of the blastocoel fluid. The cavity of the blastocyst, lined by the trophectoderm, is filled with this blastocoel fluid, which contains metabolites of both trophectoderm and inner cell mass origin. The retrieval does not require a biopsy but merely a small opening to extract the fluid and, thus, causes less harm to the embryo. Multiple studies have applied this method<ref name="PMID22020776"><pubmed>22020776</pubmed></ref> <ref name="PMID23148560"><pubmed>23148560</pubmed></ref> and it may in the future become of clinical relevance.<br />
<br />
<br />
[[File:Aspiration_of_the_Blastocoel_Fluid.jpeg|thumb|Aspiration of the Blastocoel Fluid using a ICSI pipette<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.]]<br />
<br />
<br />
Next to metabolites, the blastocoel fluid can contain DNA. Studies have shown that genomic DNA is present in about 90% of the blastocoel fluid samples tested. Typically the fluid is removed with an ICSI pipette from a day five blastocyst through its mural trophectoderm until the blastocyst fully collapses around the embryo. Several concerns regarding this method in a clinical setting have been raised. The collected DNA may be contaminated by the culture media that contains DNA fractions. The DNA may also be least representative of the actual embryos genome as the DNA may originate from abnormal or degenerated cells. Even though labelled noninvasive, the blastocyst still undergoes manipulation to some degree which may affect its viability. Thus, more research is required until this method can evolve from research to clinical use<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
====Proteomics====<br />
The protein secretome of blastocysts may be representative of its chromosome constitution Recent studies have found biomarkers such as lipocalin-1, interleukin-10, tumor necrosis factor, stem cell factor, and chemokine ligand 13 to be differently secreted by aneuploid blastocyst than by euploid ones. The most significant biomarker appears to be interleukin-10. Paired with novel proteomic technologies and mass spectrometry this knowledge when extended may contribute to a new invasive preimplantation genetic diagnosis method<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Embryo Morphology====<br />
Using time lapse imaging the embryo’s morphology can be closely observed and potential aneuploidy characteristics detected. Such characteristics may include the time of division to five cells, the time between the division from three to four cells, and the duration of the division from one to two and subsequently to three. In addition, the morphological quality of ICM an TE has been positively associated with aneuploidy or euploidy prognosis<ref name="PMID26246880"><pubmed>26246880</pubmed></ref>. These may give rise to an embryo quality screening prior to implantation<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
==References==<br />
<br />
<references/><br />
<br />
<br />
{{StudentPage2015}}</div>Z5017878https://embryology.med.unsw.edu.au/embryology/index.php?title=2015_Group_Project_6&diff=2070352015 Group Project 62015-10-21T07:50:16Z<p>Z5017878: </p>
<hr />
<div>{{ANAT2341Project2015header}}<br />
<br />
<br />
=Preimplantation Genetic Diagnosis and Screening=<br />
==Introduction==<br />
Preimplantation genetic diagnosis (PGD) and screening (PGS) are reproductive options for couples with known family histories of genetic disease or couples undergoing IVF procedures due to infertility issues. PGD can diagnose many genetic disorders caused by known chromosomal abnormalities (number and/or structure) or single gene mutations, and, thus decrease the risk of termination of pregnancy or miscarriages and enable such couples to have an unaffected child<ref name="PMID24907939"><pubmed>24907939</pubmed></ref>. Through major improvements in PGD/S and general laboratory technology, the testing for abnormalities in fetuses has shifted from prenatal diagnosis during the first 2 trimesters <ref> Blackburn, S.L. (2003) '''Maternal, Fetal & Neonatal physiology: a Clinical perspective''' (2nd ed.). Seattle: Saudners </ref>, testing for overall fetal growth, complications of pregnancy, and birth defects<ref> Sadler T.W.(2012) '''Langman's Medical Embryology''' (12th ed.) Philadelphia: Lipincott, Wiliams & Wilkins, a Wolters Kluwer Business </ref>, to an embryonic focus especially in advancements in Artificial Reproductive Technologies (ART)<ref><pubmed>20638568</pubmed></ref>. In 1990 PGD for a recessive X-linked disease resulted in the first live birth<ref><pubmed>2330030</pubmed></ref> and has since been incorporated in clinical routine and applied for a variety of genetic diseases, such as sickle cell anemia, thalassemia, or cystic fibrosis<ref name="PMID24907939"/>.<br />
[[File:Preimplantation Genetic Diagnosis Procedure.jpeg|700px|thumb| Simplified steps for PGD<ref name="PMID24907939"/>]]<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=0e-79qKllqk</html5media><br />
|-<br />
| Preimplantation Genetic Diagnosis<ref>IVF Florida (2011, December 11) IVF Florida - South Florida Fertility Specialists - Pre-Implantation Genetic Diagnosis [Video file]. Retrieved from https://www.youtube.com/watch?v=0e-79qKllqk</ref><br />
|}<br />
<br />
==History==<br />
The advances in reproductive technology during the second half of the 20th century, led to PGD's first clinical application in 1990 <ref>Harper, J. (n.d.). The history of PGD. Lecture. UCL Centre for PG&D and CRGH.University College London</ref>.<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
|Year<br />
|<br />
|- bgcolor="FFFAFA"<br />
| '''1967''' <br />
|First PGD on rabbit blastocysts (Gardner& Edwards) <ref name="PMID6036172"><pubmed>6036172</pubmed></ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1986''' <br />
|First Cleavage Biopsy (Wilton & Trounson)<ref>Wilton, L. J., & Trounson, A. O. (1986). Viability of mouse embryos and blastomeres following biopsy of a single cell. In Proceedings of the 18th Annual Conference of the Australian Society for Reproductive Biology, Brisbane, Australia.</ref><br />
|- bgcolor="FFFAFA"<br />
|'''1987''' <br />
|First Blastocyst Biopsy (Muggleton-Harris, Monk, Rawlings, & Whittingham)<ref name="PMID3372699"><pubmed>3372699</pubmed></ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1988''' <br />
|First Polar Body Biopsy (Yury Verlinksy)<ref> Verlinsky, Y., Pergament, E., Andresen, P., Enriquez, G., & Strom, C. (1989). Genetic analysis of polar body DNA: A new approach to preimplantation genetic diagnosis. Am J Hum Genet, 45(4), A272.</ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1990''' <br />
|First Clinical PGD using PCR testing for X-linked (Handyside, Kontogianni, Hardy, & Winston)<ref name="PMID2330030"><pubmed>2330030</pubmed></ref> <br />
|} <br />
==Preimplantation Genetic Diagnosis==<br />
Preimplantation genetic diagnosis (PGD) is used to test the genetic makeup of embryos to detect single gene disorders, chromosomal abnormalities and mitochondrial disorders. It also has applications in gender selection for diseases with unequal gender distributions <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Some diseases commonly involved with PGD include cystic fibrosis, spinal muscular atrophy and beta – thalassaemia <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press.">Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press</ref> <ref name="PMID17823145"><pubmed>17823145</pubmed></ref>. It was first used in the United Kingdom in the 1980s of arenoleucodystrophy and primarily focusing on sex- linked disorders <ref name="PMID17823145"/><ref name="PMID23150080"><pubmed>23150080</pubmed></ref>. PGD is now capable of detecting single cell defects (molecular) and chromosomal disorders resulting from the inversion, translocation or deletion of chromosomes (cytogenic) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>,<ref name="PMID11325751"><pubmed>11325751</pubmed></ref>. PGD can be applied to the embryo at different stages. That is on polar bodies, blastomeres or blastocyst <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>.<br />
Depending on the type of genetic disorder, PGD utilises different methods of genetic testing. These include Fluorescence in situ hybridisation (FISH) which is used for sex – linked disorders and detects chromosomal rearrangements <ref name="PMID11325751"/><ref name="PMID17876073"><pubmed>17876073</pubmed></ref> and Embryo halotyping which allows the identification of chromosomes causing the inherited disorder through knowledge of the pattern of closely linked markers <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. Polymerase chain reaction (PCR) is also widely used to detect molecular abnormalities <ref name="PMID11325751"/>.<br />
PGD is tightly regulated and supported by large organisations namely The American Society for Reproductive Medicine, The European Society for Human Reproduction and Embryology (ESHRE), The European Society of Human Genetics and the Preimplantation Genetic Diagnosis International Society <ref name="PMID25500181><pubmed>25500181</pubmed></ref>.<br />
===Sex-linked disorders===<br />
The determination of a disease as gender specific usually correlates with the presence or absence of specific genes such as SRY on the Y chromosome. It is known that females have two X chromosomes and males have an X and a Y chromosome where abnormalities are more prevalent on the X chromosome. PGD can be used for sex selection where only male embryos are transferred to reduce the chance of inheriting X-linked disorders. However, this does not completely eradicate the problem as male embryos remain susceptible to inheriting an affected X chromosome. Sex determination is only used when the specific mutation is unknown and has yet to be discovered <ref name="PMID24866878"><pubmed>24866878</pubmed></ref>.<br />
===Single gene defects===<br />
Single gene defects can be dominant, recessive, autosomal or X-linked. They are commonly diagnosed using PCR and although the PCR available today is complex and capable of combatting a large range of disease the development of new protocols has been proven to be difficult due to the small DNA sample available <ref name="PMID26168107"><pubmed>26168107</pubmed></ref><br />
===Mitochondrial disorders===<br />
Mitochondrial disorders also known as oxidative phosphorylation disorders arise from mutations in the nuclear DNA or mitochondrial DNA <ref name="PMID26312584"><pubmed>26312584</pubmed></ref>. They pose as a problem because they are unrecognisable until the mutations in the cell reach a detrimental level <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Mitochondrial disorders cause miscarriages and stillbirths as well as death in children and young adults. The effects can either be contained in a single organ or more commonly involve multiple organ failure where organs with high energy demands such as the brain, liver muscle and heart and heavily influenced. They are usually occur spontaneously or result from inheritance from the mother. Since mitochondria are solely inherited from the mother oocyte donations have been used as a solution to combat mitochondrial disorders. Additionally, there has been an increasing use in PGD where embryos that stay under the given threshold of 18% gene-mutations are allowed to be transferred and result in normal development. New technology in the areas of nuclear gene transfer and genome editing are also being experimented with <ref name="PMID26312584"/>. <br />
===Chromosomal disorders===<br />
Chromosomal disorders can be reciprocal, Robertsonian translocations, inversions, deletions and insertions <ref name="PMID26168107"/>. . Data from ESHRE collected between 2010 and 2011 has shown that the most common chromosomal abnormality confronted in PGD are reciprocal chromosomal abnormalities <ref name"PMID26071418"><pubmed>26071418</pubmed></ref>. PGD has also been used successfully for Robertsonian translocations (RT), a type of structural translocation. Children who carry RT are phenotypically normal, however in their later years it is found that they will suffer from infertility and repeated miscarriages due to the high frequency of abnormal embryos <ref name="PMID22081077"><pubmed>22081077</pubmed></ref>. PCR and FISH are the two main techniques used for chromosomal disorders. To be able to conduct the examinations the cells are required to be at the metaphase stage <ref name="PMID26168107"/>. <br />
[[File:Reasons_for_PGD.jpg|600px|thumb|Reasons for PGD<ref name= "PMID24764761"><pubmed><24764761</pubmed></ref>]]<br />
==Preimplantation Genetic Screening==<br />
Prenatal Genetic Screening (PGS) involves an array of methods or ideas that aim to segregate embryos that have genetic flaws and those that are healthy <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. The occurrence of aneuploidy is high around the stages of early embryonic development and they are the most common cause if miscarriages and congenital birth defects <ref name= "PMID26085841"><pubmed>26085841</pubmed></ref>. They have little effect on the morphology of the embryo making them difficult to identify thus identification heavily relies on genetic testing <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. <br />
Genetic sampling is most commonly conducted using Microarray Comparative Genomic Hybridisation (aCGH) as well as FISH, Quantitative PCR and Single Nucleotide Polymorphism (SNP) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. These methods collectively aim to assess numeral and structural chromosomal errors <ref name= "PMID26085841"/>. Studies have also introduced Next- Generation Sequencing (NGS) <ref name= "PMID26085841"/> and Whole Genome Amplification used to screen imbalances in the complete 24-chromosomes <ref name="PMID25953353"><pubmed>25953353</pubmed></ref><br />
Statistics from ESHRE have shown that the most common indications for PGS is advanced age, followed by repeated implantation failure or recurrent miscarriage and male infertility <ref name="PMID26071418"><pubmed>26071418</pubmed></ref>.<br />
===Indications===<br />
A low percentage of structural abnormalities in chromosomes are responsible for the cause of miscarriages. Despite this, they are the most prevalent type of chromosomal abnormality accounted for in PGD <ref name="PMID20638568"/>. The presence of specific gene cycles, initiation of embryonic protein synthesis and evident physiological development are all indicative of a successful in vitro fertilisation procedure <ref name="PMID11576737"><pubmed>11576737</pubmed></ref>. To eliminate further errors from occurring during the PGD procedure it is recommended to undertake further prenatal testing such as amniocentesis in the later stages <ref name="PMID20638568"/>. <br />
====Advanced maternal age====<br />
Data provided by the ESHRE has shown that the mean age of women undergoing PGS is 39 years <ref name="PMID26071418"/>. Women of advanced age have been shown to have a lower rate of pregnancies reaching childbirth <ref name="PMID18583331"><pubmed>18583331</pubmed></ref>. The highlighted concern revolves around the increased occurrence of aneuploidy following maternal age. The optimal age range for the lowest aneuploidy incidence was found to be between 27 to 37 years of age (6%) then progressively higher in women aged up to 42 (33%) and most common in those 44 and above (53%) <ref name="PMID24355045"><pubmed>24355045</pubmed></ref>. <br />
====Recurrent pregnancy loss / IVF failure====<br />
Recurrent pregnancy loss is defined as three or more IVF failures after cumulative transfer of more than 10 good-quality embryos. These are primarily caused by two main factors, reduced endometrium receptivity or embryonic defects. Endometrium receptivity can be negatively influences by instances including uterine pathologies such as thin endometrium, altered expression of adhesive molecules and immunological factors. Additionally, embryonic defects may be due to genetic abnormalities, embryonic aneuploidy or zona hardening. Endometriosis and hydrosalpinx has been known to effect both the endometrium and embryo <ref name="PMID23260857"><pubmed>23260857</pubmed></ref>.<br />
====Human leukocyte antigen matching====<br />
First used in 2001, HLA matching is an option given to parents to save a child with haematological or immunological disease through conceiving another child who would potentially be able to donate cord blood or haematopoietic stem cells from the bone marrow for transplantation. The process namely PGD-HLA has shown to improve haematopoietic stem cell transplant (HSCT). PGD-HLA can only be performed when HSCT is not needed urgently due to the time needed to conceive and delivery the baby <ref name="PMID25500181"><pubmed>25500181</pubmed></ref>. It is most commonly applied to children suffering from relapsed leukaemia <ref name="PMID22524201"><pubmed>22524201</pubmed></ref>. In a case study PGD-HLA was proven to successfully cure 10 diseases including Fanconi anaemia, Diamond-Blackfan anaemia and beta thalassemia <ref name="PMID25066893><pubmed>25066893</pubmed></ref>.<br />
==Biopsy Methods==<br />
Biopsy, the removal of genetic materials, from oocytes or embryos in the preimplantation stage is the primary step in PGD. For the past two decades these biopsies have been performed at three stages, the polar body, blastomere, and blastocyst, and the methodologies optimized to ensure the embryo’s viability. The most common approach involves biopsies at the cleavage stage. However, polar body and blastocyst biopsies are increasingly more often tested and applied. Approached for opening the zona pellucida involve next to the traditional mechanical and chemical means, novel approaches such as noncontact lasers. Their application may simplify and secure the procedure significantly. The most challenging question about PGD procedures remains at what stage biopsies should be taken. Much controversy has developed around this topic, highlighting the varying disadvantages and advantages of temporal biopsies. <ref name="PMID22723007"><pubmed>22723007</pubmed></ref><br />
<br />
{| class="wikitable"<br />
|- align="center" bgcolor="DDCEF2"<br />
|<br />
| Time of Biopsy<br />
| Advantages <br />
| Disadvantages<br />
|- bgcolor="FFFAFA"<br />
| Polar Body<br />
| Day 1<br />
| No harm to oocyte<br />
| Only maternal DNA is tested, often needs to be coupled with other biopsies<br />
|- bgcolor="FFFAFA"<br />
| Blastomere<br />
| Day 3<br />
| …<br />
| … <br />
|- bgcolor="FFFAFA"<br />
| Trophectoderm<br />
| Day 5 and 6 <br />
| Little harm, large amount of genetic material<br />
| Opening of blastocyst necessary, small time window for procedure<br />
|}<br />
<br />
<br />
[[File:Polar_Body,_Blastomere,_and_Trophectoderm_Biopsy.jpeg|thumb|Polar body (A), blastomere (B) and trophectoderm (C) biopsies<ref name="PMID25625041"><pubmed>25625041</pubmed></ref>.]]<br />
<br />
<br />
<br />
PMID 24305177<br />
===Polar Body Analysis===<br />
Day 1<br />
====Description====<br />
Polar body (PB) biopsy, which was introduced in 1990, offers a promising alternative to biopsies performed at the blastomere stage for PGD/S indications on legal and practical grounds. <br />
Description: Consequent embryo development does not necessitate the presence of the first and second PB and their removal may not be crucial. PB biopsy requires precise timing. Keeping track of the meiotic cell cycle is necessary to perform a successful biopsy and, therefore, PB biopsy usually is applied in combination with intracytoplasmic sperm injection (ICSI). During the maturation from the germinal vesicle stage to the metaphase-II stage the first PB is formed. A cytoplasmic bridge containing spindle remnants, that are still in contact with the cellular genetic material, links this PB to the oolemma for about 90 minutes after extrusion. It is possible to visualize these remnants by polarization microscopy and it is crucial to not perform the biopsy until the first PB is no longer firmly attached to the oolemma as this indicates an immature embryo.The oocyte tolerates mechanical zona dissection best during hours four until six after ICSI as the oolemma has stabilized by that time because of the cortical granule reaction. Over time the first PB degenerates stressing a temporal biopsy and its optimal extraction time window is four to 12 hours after ICSI. The second PB forms around two to four hours after ICSI. However, its optimal time window for biopsy is set to be eight to 16 hours after ICSI. This is due to the second PB being attached to the oolemma with spindle remnants until six hours after ICSI. Biopsy at this point may cause enucleation of the oocyte. In addition, studies have shown that the amplification efficiency of second PB’s DNA is worse if the PB is extracted prior to eight hours after ICSI. <br />
Thus, it is possible to perform sequential and simultaneous biopsies for the first and second PB. If performed, sequentially the first PB may be removed four to 12 hours and the second PB eight to 16 hours after ICSI. The optimal time window for a biopsy for both the first and second PB simultaneously is eight to 12 hours after ICSI. It is highly preferred to analyze both PBs due to potential aneuploidies in either PB and crossing overs during meiosis<ref name="PMID22723007"/>. <br />
====Procedure====<br />
Chemical opening achieved with for example acidic tyrode’s solution of the zona pellucida is not tolerated by the oocyte and may have detrimental effects on the embryo’s development. Therefore, the access to the perivitelline space of the oocyte is provided by mechanical zona dissection or by laser. Both techniques work well if performed by experienced embryologist. However, laser-assisted biopsy is less time consuming when compared to manual dissection. It is critical to consider the size of the introduced opening as it will remain permanent. If it is too large the blastomere may be lost during embryo development and if it is too small it may interfere with hatching of the embryo during blastocyst stage<ref name="PMID22723007"/><br />
<br />
[[File:Polar_Body_Biopsy.jpeg|thumb|The presence of a faint but clearly identifiable strand connecting PB2 to the <br />
oolemma. The biopsy was performed ∼9 h after ICSI<ref name="PMID21908464"><pubmed>21908464</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JTaQzszVr8o</html5media><br />
|-<br />
| Laser-assisted polar body biopsy<ref>RIUK, R. (2013, June 25) Polar Body Biopsy [Video file]. Retrieved from https://www.youtube.com/watch?v=JTaQzszVr8o</ref><br />
|}<br />
<br />
====Advantages & Disadvantages====<br />
PB biopsies can only investigate the maternal contributions to the embryo as they are of maternal origin. Thus, this procedure is appropriate for PGD solely for monogenetic diseases from the maternal side. Recessive diseases may be evaluated with PB biopsies on the basis that the embryo’s outcome will be determined by the paternal contribution. (...) It may still be applied for PGS as most aneuploidies either arise during meiosis or origin from the maternal genome. However, diagnosis error has been reported due to the lack of considering paternal contributions. <br />
Because PB biopsies are performed very early it is not yet known whether the oocyte will develop into a viable embryo. Thus, PBs are commonly frozen or fixed after biopsy and depending on the state of the embryo only chosen PBs will be tested. This is primarily an economic issue as many genetic testing procedures are very cost-intensive<ref name="PMID22723007"/>.<br />
<br />
[[File:Implantation_predictive_value_of_euploid_screening_results.jpeg|thumb|The sustained implantation predictive value (with 95 % confidence interval) of a euploid screening result obtained from the first polar body (PB1), PB1 and the second polar body (PB2), or a direct embryo biopsy for each stage of embryo transfer (cleavage-stage and blastocyst stage)<ref name="PMID25106935"><pubmed>25106935</pubmed></ref>.]]<br />
<br />
===Blastomere biopsy===<br />
Day 3 <br />
====Description====<br />
Blastomere biopsy has been the prevalent method for PGD and PGS in the last two decades. At least one, but up to two, blastomeres are biopsied on day three of the cleavage stage embryo. The right number of blastomeres removed is a controversial topic as two cells allow for more genetic material and more accurate results. However, removing two cells might be too invasive and damaging to the embryo. (Study)<ref name="PMID21748341"><pubmed>21748341</pubmed></ref><br />
====Procedure====<br />
Initially a hole was drilled into the zona pellucida using acid tyrodes and the blastomeres are removed via aspiration with a pipette<ref name="PMID21748341"/>.<br />
<br />
<br />
[[File:Aspiration_of_a_Blastomere.jpeg|thumb|Aspiration of a Blastomere into the biopsy pipette<ref name=" PMID24783200"><pubmed>24783200</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=TbridWVwipI</html5media><br />
|-<br />
| Laser-assisted blastomere biopsy<ref>Sukprasert, M. (2014, March 5) Day 3 Blastomere Biopsy 1 [Video file]. Retrieved from https://www.youtube.com/watch?v=TbridWVwipI</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
===Trophectoderm biopsy===<br />
Day 5 and 6<br />
====Description====<br />
The improvement of embryo culture media allowed the in vitro development of human embryos until the blastocyst stage and opened up the possibility to take blastocyst biopsies. During day three to day five the haploid maternal and paternal genomes work together for the first time to form the genome of the embryo. The maternal epigenetic control lessens significantly while preparing for implantation with precisely arranged events happening. The first event includes a rapid increase in the number of embryonic cells which are active in mitotic divisions and apoptosis of aberrant cells. This is followed by the formation of blastocoel (cavitation) which results from the flattening of cell located on the outside of the blastomere. Now the blastocyst will expand until the embryo hatches by rupturing the zona pellucida. The cells of the blastocyst will differentiate to form two distinct cell lineages, the outer trophectoderm and the inner cell mass<ref name="PMID22723007"/>.<br />
====Procedure====<br />
Trophectoderm biopsy is usually performed in Hepes buffered biopsy medium and opening approaches include needle cutting which has been replaced by lasers in past years. Different research groups report different timings of the opening to be the most successful. Some open the blastocyst on day three or four by creating a 25 µm which causes the trophectoderm to herniate through this hole and is, thus, accessible for biopsy. Others create this hole about four hours before biopsy which allows sufficient herniation of trophectoderm cells. It is also possible to open the blastocyst immediately before biopsy. This avoids an extra step and the inner cell mass usually is easy to locate. Blastocyst biopsies involve the removal of trophectoderm cells and the ideal time for the procedure is day five. Successful biopsies on day six have been performed, while little is known about the results of biopsies on day seven. However, since the window of implantation in humans is from day eight to ten after ovulation, day seven biopsies appear to be possible<ref name="PMID22723007"/>.<br />
-collapse of trophoblasts<br />
-possible: biopsy of hatched blastocyst, holding pipette careful mild suction force to hold embryo near ICM <br />
-Cryopreservation<br />
<br />
<br />
[[File:Microscopic images of human blastocysts for biopsy.jpeg|thumb|(A) Some trophectoderm cells in a blastocyst started to hatch and (B) the trophectoderm cells were biopsied with assisted laser cutting. Images in C–D show the blastocysts after vitrification and warming. Blastocysts had been cultured for 2–4 hrs after warming, showing good (ICM and trophectoderm cells) hatched (C) and hatching (D) blastocysts. The hatching blastocyst in (E) has good ICM but fair trophectoderm while the blastocyst in (F) has both fair ICM and trophectoderm. Arrows indicate ICMs and arrow heads indicate trophectoderm cells. Bar = 40 µm<ref name="PMID2190846"><pubmed>2190846</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JI_TQ8d8tNM</html5media><br />
|-<br />
| Laser-assisted blastocyst biopsy (at 00:50 min)<ref>Coco, R. (2014, April 30) Trophectoderm biopsy in a Hatching blastocyst protruding ICM [Video file]. Retrieved from https://www.youtube.com/watch?v=JI_TQ8d8tNM</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
Blastocyst biopsies are believed to be less damaging to the embryo and appear to be unrelated to implantation rates. In addition, this biopsy method allows for a larger extraction of cells for genetic testing. However, since they are performed late in in vitro development, the time window for genetic testing is relatively small. Fast and accurate genetic testing methods are needed to ensure a successful and safe result from this biopsy. Thus, blastocyst biopsies may gain more popularity in the future whn such methods have been developed or improved<ref name="PMID22723007"/>. <br />
<br />
<br />
==Genetic Techniques==<br />
<br />
===PCR===<br />
====Description====<br />
Polymerase chain reaction (PCR) amplifies DNA specific to genetic sequence of interest . PCR was developed by Kay Mullis in the 1980s, for which he was awarded the Nobel prize for chemistry in 1993. <ref> Pubmed Docs (2015) Polymerase Chain Reaction (PCR) Pubmen. Retrieved from [http://www.ncbi.nlm.nih.gov/probe/docs/techpcr/]</ref> This technique enables clinicians to monitor and diagnose diseases using minute samples such as embryonic cells, blood & tissue. <ref>Roche (2015) PCR: How We Copy DNA. Roche Molecular Systems Inc. retrieved From [http://molecular.roche.com/pcr/Pages/Process.aspx]</ref> PCR has many important applications like DNA fingerprinting, genetic mapping, detection of viruses and bacteria as well as being used to detect genetic disorders, as a part of PGD, in conjunction with IVF. It is used to detect molecular abnormalities such as single gene disorders like Tay Sach, Cycstic fibrosis, Duchenne Muscular Dystrophy, Thalassemia, Huntington disease, Spinal muscular atrophy and many more. Molecular and Genetic analysis require a significant amount of DNA, which we would not have without PCR. It revolutionized the study of DNA, replacing all previous recombinant DNA technology. <ref> Mullins, K., Francois, F.& Gibbs R.A. (1994 ) The Polymerase Chain Reaction. p3. Springer- Science +Business Media. Birkhauser, Boston<br />
Available at [https://books.google.com.au/books?hl=en&lr=&id=gjrTBwAAQBAJ&oi=fnd&pg=PR5&dq=kary+mullis+PCR&ots=mpzAyRh5ZY&sig=PQ4goNoKJ90tb3-MkPk62zrTGbw#v=onepage&q=kary%20mullis%20PCR&f=false] </ref> <br />
<br />
[[File:PCR.jpg|thumb|right|Polymerase chain reaction (PCR) amplifies DNA specific to genetic sequence of interest, enabling the monitoring and diagnose molecular abnormalities such as single gene disorders using minute samples such as embryonic cells, blood & tissue <ref>NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref>]]<br />
<br />
====Procedure====<br />
<br />
Sample are obtained from the the blastocyst, a polar body biopsy or the blastomeres stages of the embryo. <br />
Stage 1 Denaturing: separating the target strands of DNA <br />
The obtained sample is heated to roughly 90 degrees celcius, this heat causes breaks the relatively weak bonds between nucleotides that form DNA. the double stranded DNA to split into 2 single strands of DNA that are used as templates.<br />
Stage 2 Annealing: Binding the Primers to the target DNA sequence <br />
PCR will only copy the target sequence of DNA specified by specific PCR primer. These synthesized primers Oligonucleotides are small artificial pieces of DNA. <br />
TAQ polymerase enzyme synthesize 2 new strands of DNA duplicate to the single sample DNA stand template indicated by these primers. During this stage the reaction is cooled to a temperature between 40-60 degrees Celsius. <br />
Stage 3- Extension- making copies <br />
Each of these 2 copies are then used again as templates generating 2 further replications This cycle can occur as many 30 -40 times within a couple hours leading to billions of extra copies of the original DNA segment. The optimal temperature for the further replication is roughly 72 degrees Celsius. <br />
<br />
This process mediated by a thermocycler machine that is programmed to alter the temperature of the reaction every couple of minutes, perpetuating the cycle of DNA denaturing and synthesis. <br />
This process, generates exponential exact copy of the original template DNA sequence. <br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
!PCR cycles<br />
<br />
|{|<br />
|-<br />
| '''PCR Cycle'''<br />
| '''Target Copies'''<br />
|-<br />
| 1<br />
| 2<br />
|-<br />
| 2<br />
| 4<br />
|-<br />
| 3<br />
| 8<br />
|-<br />
| 4<br />
| 16<br />
|-"<br />
| 5 <br />
| 32<br />
|-<br />
| 6 <br />
| 64<br />
|-<br />
| 7 <br />
| 128<br />
|-<br />
| 8<br />
| 256<br />
|- <br />
| 9<br />
| 512 <br />
|-<br />
| 10<br />
| 1024<br />
|-<br />
| 15<br />
| 32,768<br />
|-<br />
| 20 <br />
| 1,048,578<br />
|-<br />
| 25<br />
| 33,554,432<br />
|-<br />
| 30 <br />
| 1,073,741,842<br />
|-<br />
|}<br />
<br />
<br />
<br />
{|class="wikitable" align="center"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="10" |'''Advantages'''<br />
|-bgcolor="FFFAFA"<br />
| fast and inexpensive way of copying a target sequence of DNA<br />
|-bgcolor="FFFAFA"<br />
| aids the diagnosis of single cell defects<br />
|-bgcolor="FFFAFA"<br />
| rapid generation of results within a couple hours<br />
|-bgcolor="FFFAFA"<br />
| can start from a single molecule of DNA, therefore is more sensitive <br />
|-bgcolor="FFFAFA"<br />
| has a flexible primer design enabling<br />
|-bgcolor="FFFAFA"<br />
| overcame previous issues associated with the limited availability of sites of end<br />
|-bgcolor="FFFAFA"<br />
| generates the DNA copies exponentially<br />
|-bgcolor="FFFAFA"<br />
| enables DNA amplification required for molecular and genetic analysis<br />
|-bgcolor="FFFAFA"<br />
|Valid diagnostic method in selecting unaffected embryos for embryo transfer <ref> Dreesen, J., Drusedaul, M., Smeets, H., Die-Smulders, C., Coonen, E., Dumoulin, J., Gielen, M., Evers, J., Herbergers, J. & Geradets, J. (2008) Validation of preimplantation genetic diagnosis by PCR analysis: genotype comparison of the blastomere and corresponding embryo, implications for clinical practice. Mol. Hum. Reprod. 14 (10):573-579.doi: 10.1093/molehr/gan052. Retrieved from [http://molehr.oxfordjournals.org/content/14/10/573.short] </ref> <ref><pubmed>20966460</pubmed></ref><br />
|-bgcolor="DDCEF2"<br />
| rowspan="5"|'''Disadvantages'''<br />
|-bgcolor="FFFAFA"<br />
| only during this exponential DNA replication phase can we determine the starting quantity sequence contained in the original sample ( template DNA strand)<br />
|-bgcolor="FFFAFA"<br />
| PCR reaction is limited by the presence of inhibitors present in the sample : reagent inhibitors <br />
|-bgcolor="FFFAFA"<br />
| self annealing due to the accumulation of the product -stopping exponential amplification for the target sequence and reach a plateau<br />
quantification of the end point of reaction of PCR products unreliable - therefore that is why we require real time quantitative RT-PCR necessary<br />
<ref> NIS (2015) Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref><br />
|}<br />
<br />
<br />
===Fluorescent In Situ Hybridisation (FISH)===<br />
<br />
<br />
====Description====<br />
Fluorescence in situ hybridization (FISH) the one of the most effective and rapid <ref name="PMID26338801"><pubmed>26338801</pubmed></ref> Preimplantation Genetic Diagnosis (PGD). This techniques used to locate a specific DNA sequences within a chromosome. FISH facilitates the clinical diagnosis of chromosomal abnormalities indicated by sequential duplications, deletions and rearrangements of chromosome, that are usually missed with microscopic analysis. This technique is especially relevant for female embryos with X-linked diseases,<ref name="PMID20809319"><pubmed>20809319</pubmed></ref> that have no other mutation specific tests [http://www.ncbi.nlm.nih.gov/pubmed/20809319] As part of PGD, samples are collected from various stages of the embyro,and they are able to conducted tests on the blastocyst, a polar body biopsy and the blastomeres <ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. FISH is 99% effective when used in conjunction with competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities<ref name="PMID26338801"/>.<br />
<br />
====Procedure==== <br />
<br />
Samples are collected from either the blastocyst, a polar body biopsy or the blastomeres stages of the embryo <ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
DNA strands are heated and denatured causing their the individual DNA strands to break apart<br />
Probes are single complimentary stands of DNA a that have been tagged with small chemical agents that glow brightly in the presence of a specific region on a chromosome. These specific probes then hybridize and join to their complementary DNA strand. <br />
The fluorescent tags enable the researchers to correctly identify the presence or lack thereof and location of the specific chromosomes that they are testing for. <ref name="PMID17876073"><pubmed>17876073</pubmed></ref><br />
Researcher analyse the results by identifying the number and the relative location of the fluorescent dots generated by the FISH images.<ref name="PMID17970921"><pubmed>17970921</pubmed></ref><br />
The probe will not fully hybridise if there has been a duplication or a deletion of the DNA - indicating chromosomal and sex chromosomal anomalies like trisomies and aneuploidies. <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref><br />
<br />
<br />
Different probes are used for different purposes: <ref>Unique, Rare Chromosome Disorder Support Group (2013) Fluorescence in situ hybridisation (FISH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/Other/FISH%20FTNW.pdf]</ref><br />
*'''Locus specific tags''' detect very small imbalances, and locate isolated small portions <br />
of genes within a chromosome<br />
*'''Alphoid/Centomeric Repeat probes''' are developed from the repetitive sequence located in the middle region of each chromosome, useful in determining the number of chromosomes , detecting rearrangement and when used in conjunction with locus probes to determine the absence of genetic material on a chromosome. <br />
*'''Paint Probes''' are collections of smaller probes with their own stains that bind to a different section on the chromosome - allowing the full chromosome too be labeled a unique colour, this "full colour map" can be used to know the spectral karyotype- full chromosomal mapping is useful in examining chromosomal abnormalities. <br />
<br />
[[File:Fluorescent In Situ Hybridisation (FISH).jpg|thumb|right|'''FISH''' We are able to tag Specific DNA sequences using Probes which have been tagged with fluorescent Labels.This technique enables the clinical diagnosis of chromosomal abnormalities, indicated by sequential duplication, deletions and rearrangements of chromosome <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref>]]<br />
<br />
{|class="wikitable" align="center"<br />
|-bgcolor="pink" <br />
| rowspan="8" |'''Advantages''' <br />
|-bgcolor="#FDE1F2" <br />
| FISH is 99% effective when used in conjunction with Competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities.<ref><pubmed>26338801</pubmed></ref><br />
|-bgcolor="#FDE1F2" <br />
| Rapid generation of results<br />
|-bgcolor="#FDE1F2" <br />
| Identifies very small translocations and aneuploidies that occur within chromosomes, that would usually be missed under microscopic analysis<br />
|-bgcolor="#FDE1F2" <br />
| Indicates whether the accessed chromosomes are normal <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|-bgcolor="#FDE1F2" <br />
| Tests for the most common chromosomal abnormalities - down syndrome chromosomes 13,16,18,21 and 22 <ref><pubmed>21749752</pubmed></ref><br />
|-bgcolor="#FDE1F2" <br />
| It may be used to compare the chromosomal gene arrangements in related species<br />
|-bgcolor="#FDE1F2" <br />
| can be used to identify and remove inheritable X-linked disease or sex chromasome anomalies such as Duchennes Muscular Dystrophy, hemophilia, ectodermal dysplasia <ref><pubmed>17876073</pubmed></ref><br />
|-bgcolor="#FEB745"<br />
| rowspan="5"|'''Disadvantages'''<br />
|-bgcolor="#FE1C5EA"<br />
| FISH destroys all cells tested <ref> O'Connor, C. (2008) Fluorescence in situ hybridization (FISH). Nature Education 1(1):171. retrieved from [http://www.nature.com/scitable/topicpage/fluorescence-in-situ-hybridization-fish-327] </ref><br />
|-bgcolor="#FE1C5EA"<br />
| It does not fully access all chromosomes (only ~ 12)<br />
|-bgcolor="#FE1C5EA"<br />
| Analysis of results is dependent upon the dot quality impacted by hybridisation efficiency or the camera sensitivity <ref><pubmed>17970921</pubmed></ref><br />
|-bgcolor="#FE1C5EA"<br />
| some studies indicate that using FISH on a day-3 embryo biopsy decreases the rate of live births <ref><pubmed>26168107</pubmed></ref><br />
|}<br />
<br />
===Array Comparative Genomic Hybridisation (aCGH)===<br />
====Description====<br />
<br />
aCGH also known as Microarray analysis efficiently scans the entire genome for chromosomal imbalances. CGH was initially developed to detect the number of changes in a solid tumor mass. It uses 2 genomes comparing the sample to the control, with each labeled in a different fluorescent dye<ref name="PMID1876176"><pubmed>1876176</pubmed></ref>. Earlier CGH techniques were limited by the resolution of the imaging <ref> Lichter, P., et al. Comparative genomic hybridization: Uses and limitations. Seminars in Hematology 37, 348–357 (2000)</ref> , these initial limitations were overcome by using Microarrays in conjunction with CGh to improve the resolution of the imaging, Array Comparative Genomic Hybridisation (aCGH). This method compares sample and control microarrayed slides containing small segments of DNA (probes). <ref> Lucito, R., et al. Representational oligonucleotide microarray analysis: A high-resolution method to detect genome copy number variation. Genome Research 13, 2291–2305 (2003) </ref> the Probes used will vary according from the small (25-85 base pairs) oligonucleotides manufactured to highlight different target sequences, to the very large genomic clones (80,000- 200,00 base pairs), and as these are significantly smaller than the traditional metaphase chromosomes used for CGH, generating a higher resolution of image. <ref name="PMID22467166"><pubmed>22467166</pubmed></ref>.aCGH is used as a diagnostic tool for prenatal detection f chromosomal abnormalities <ref name="PMID19012303"><pubmed>19012303</pubmed></ref>.<br />
<br />
<br />
====Procedure====<br />
<ref> Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432] </ref><br />
The sample is obtained (skin, blood or fetal cells) and DNA is obtained. <br />
As a part of PGD fetal cell samples are collected from; the fertilized egg polar bodies, the blastomere (day 3 embryo) or the blastocyst/tropoectoderm stage (day 5 embryo).<br />
Sample DNA is labeled with one fluorescent dye, and the control DNA is labeled with a different colored fluorescent dye. the control DNA is used as the base point of reference. <br />
heated and denatured single DNA strands then hybridize to their complementary single strand probes, which are then combined and applied to a microarray and the results are run through a computer program and a digital imaging system is used to quantify the results( fluorescent intensities of the labeled probes). <br />
<br />
[[File:aCGH.jpg|thumb|right|'''aCGH''' checks the entire genome for chromosomal imbalances, by comparing control and a sample slides contatining small segements of DNA sample microarrayed slides small segments of DNA. Illustrated by student z5020317 and adapted from <ref> NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation. retrieved from [http://www.phgfoundation.org/file/5237/]</ref> <ref>Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432]</ref>]]<br />
<br />
The fluorescent ratio and the hybridization signal at different locations on the genome of the control DNA are used to identify any variances present in the sample DNA. aCGH facilitates the clinical diagnosis of submicroscopic chromosomal duplication, deletion and rearrangements indicative of chromosomal disorders such as trisomies 1-22and specific sex linked disorders. <br />
Duplications in the DNA are displayed by the computer program as spikes/ peaks over an established threshold and deletions in DNA are displayed by the computer program as spikes/ toughs beneath this threshold <br />
<br />
{|class="wikitable" align="center"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="12" |'''Advantages''' <br />
|-bgcolor="FFFAFA"<br />
| Multiple applications: prenatal genetic diagnosis, cancer diagnosis, <ref name="PMID20193845"><pubmed>20193845</pubmed></ref> genetic screening for developmental delay (learning disabilities) <ref name="PMID17309648"><pubmed>17309648</pubmed></ref>. or congenital anomalies that are suspected to be genetic in origin <ref>NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation . retrieved from [http://www.phgfoundation.org/file/5237/]</ref><br />
|-bgcolor="FFFAFA"<br />
| trace represents all chromosomes present in the human genome chromosomes 1-22 and the X & Y chromosomes, and therefore is the most accurate method for testing whole embryo aneuploidy<br />
|-bgcolor="FFFAFA"<br />
| aCGH has been extensively tested, and Validated, and is now used world wide.<br />
|-bgcolor="FFFAFA"<br />
| Detects submicroscopic alterations<br />
|-bgcolor="FFFAFA"<br />
| Detects deletions and additions and rearrangements as well as amplification, of the WHOLE genome, simultaneously.<br />
|-bgcolor="FFFAFA"<br />
| Used as a diagnostic tool for prenatal detection of chromosomal abnormalities <ref name="PMID22034057"><pubmed>22034057</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Provides high resolution genomewide screening of segmental genomic copy number variations<br />
|-bgcolor="FFFAFA"<br />
| Very accurate when used in conjunction with FISH<br />
|-bgcolor="FFFAFA"<br />
| Alone is more reliable and in detecting chromosomal abnormalities, with a higher implantation success rate, than FISH <ref name="PMID20494259"><pubmed>20494259</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Allows an in depth research focus upon specific types of rearrangements within selected chromosomal regions, a recent particular area of interest is subtelomeric and pericentromeric rearrangements<br />
|-bgcolor="FFFAFA"<br />
| Reduces the risk of failed implantation and miscarriage, improving the chance of a healthy baby <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|-bgcolor="DDCEF2"<br />
| rowspan="9" |'''Disadvantages'''<br />
|-bgcolor="FFFAFA"<br />
| Translocations and inversions of DNA are not detected<br />
|-bgcolor="FFFAFA"<br />
| Limited ability diagnosing specific polyploidies such as triploidy <ref> Unique, Rare Chromosome Disorder Support Group (2013) Microarray-based Comparative Genomic Hybridiation (array CGH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/other/array%20cgh%20ftnw.pdf] </ref><br />
|-bgcolor="FFFAFA"<br />
| Will not detect mosaicism detection <20% (cultures where >1 of 5 cells are trisomy 12)<br />
|-bgcolor="FFFAFA"<br />
| Will not detect balanced chromosomal rearrangement<br />
|-bgcolor="FFFAFA"<br />
| Will not detect duplications or deletions <80kb<br />
|-bgcolor="FFFAFA"<br />
| Will not detect point mutations within genes <ref>Washington department of education (CGH- FAQ for physicians. Signature Genomic LAboratories, LLC. Retrieved from [https://depts.washington.edu/dbpeds/Lab%20Tests/SignatureCGH-physician_FAQ.pdf]</ref><br />
|-bgcolor="FFFAFA"<br />
| will not detect chromosomal position of genomic gains<br />
|-bgcolor="FFFAFA"<br />
| Will not detect loos of heterozygosity (LOH) or Absence of heterozygosity (AOH) <ref>WiCell Research Institute Inc. (2012) Comparative Genomic Hybridization Microarray. <br />
retrieved from [http://www.wicell.org/home/cytogenetic-services/cgh-microarray/array-comparative-genomic-hybridization-acgh.cmsx]</ref><br />
|}<br />
<br />
===Next Generation Sequencing===<br />
====Description====<br />
The development and advances within ART in the past 20 years, as well as the increasing popularity of IV, has lead to an influx of new technologies developed to screen embryos for chromosomal anomalies, which are covered by the umbrella term of Next generation Sequencing (NGS). NGS is a general term used to describe all of the new and emerging screening techniques currently being introduced and used as part of PGD for IVF . NGS screens for single gene disorders as well as conducting extensive and very comprehensive chromosome diagnosis by sequencing, counting, and accurately assembling millions of DNA reads, simultaneously. <ref name="PMID23499002"><pubmed>23499002</pubmed></ref> There is a movement for NGS to replace the other limited testing techniques and be used as the standard. <br />
====Procedure====<br />
Samples are collected from either blastomere or the blastocyst/tropoectoderm and processed for analysis by a computer system. <br />
The methodology of each process is unique to the technique being used. <br />
<br />
{|class="wikitable" align="center"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="14" |'''Advantages''' <br />
|-bgcolor="FFFAFA"<br />
| Cheaper<br />
|-bgcolor="FFFAFA"<br />
| Opens new diagnostic possibilities<br />
|-bgcolor="FFFAFA"<br />
| Accurately tests all 24 chromosomes<br />
|-bgcolor="FFFAFA"<br />
| Tests for the presence of monogenic diseases of known genetic background<br />
|-bgcolor="FFFAFA"<br />
| Reduces the number of biopsies required for diagnosis<br />
|-bgcolor="FFFAFA"<br />
| Higher detection rate of small translocations<br />
|-bgcolor="FFFAFA"<br />
| Highly accurate is testing for compound point mutations, chromosomal duplication, deletions and insertions <ref name="PMID23312231"><pubmed>23312231</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| It accurately detects chromosomal aneuploidy and unbalanced rearrangement <ref name="PMID25685330"><pubmed>25685330</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Higher detection rate of small translocations<br />
|-bgcolor="FFFAFA"<br />
| NGS single gene disorder screenings can conducted in conjunction with PCR comprehensive chromosomal screening<br />
|-bgcolor="FFFAFA"<br />
| Reduces human error <br />
|-bgcolor="FFFAFA"<br />
| Better detects the presence of mosaicism<br />
|-bgcolor="FFFAFA"<br />
| Work well in conjunction with CGH and aCGH as part of PGD, improving the chances of IVF. <ref> Morris, R. S. (2015 ) Next generation sequencing for PCG|PGS|CCS. IVF1 retrieved from [http://www.ivf1.com/next-generation-sequencing for-pgd] </ref><br />
|-bgcolor="DDCEF2"<br />
| rowspan "0" |'''Disadvantages''' <br />
|-bgcolor="FFFAFA"<br />
| There are limited information available to clinical applications of NGS <ref><pubmed>26100406</pubmed></ref><br />
|}<br />
<br />
==Diagnosis==<br />
There are a large amount of diseases that PGD can apply to, below are descriptions of the diseases that PGD are more commonly used for. Utilization of Diseased Cell Lines<br />
===Cystic Fibrosis===<br />
Cystic fibrosis is a single gene disorder. It is autosomal recessive and involves mutations in the cystic fibrosis transmembrane conductance regulator (CTFR) gene. The CTFR gene is normally responsible for the decrease in chloride and the transport of bicarbonate in epithelial cells thus playing a major physiological role. In PGD procedures, identification of the gene is assisted by microsatellite markers that have similar composition to the CTFR gene itself. Biopsy of two cells at the blastocyst stage is recommended if markers are not available. There are many variations of cystic fibrosis the most common being P.Phe508del <ref name="PMID26014425"><pubmed>26014425</pubmed></ref>.<br />
===Duchenne Muscular Dystrophy ===<br />
Duchenne Muscular Dystrophy is an X-linked recessive disease. It involves the Xp21 gene where majority of the mutations are chromosomal deletions with a smaller percentage resulting from duplications <ref name="PMID18359022"><pubmed>18359022</pubmed></ref>.<br />
<br />
===Autosomal Recessive MEckel-Gruber Syndrome===<br />
Autosomal recessive genetic defect caused by the TMEM67 gene. It results in cystic dysplasia of the kidneys with fibrotic change in the liber and occipital encephalocele. Other malformations could also be present in the central nervous system. In PGD whole genome amplification of single blastomeres are taken to identify the gene, this is also coupled with PCR techniques. Maternal plasma can also be extracted for PGS. <ref><pubmed>24039893</pubmed></ref> <br />
===β – Thalassemia=== <br />
β – Thalassemia is known as the most common type of autosomal recessive inherited disorder among haemoglobinopathies. It involves the adult β-globin gene and is associated with the absent or decreased expression of the gene. This is commonly caused by a single nucleotide change in the gene. PGD has been used successfully worldwide to identify the β-globin gene where its application is usually performed on a single blastomere or polar body <ref name="PMID19064120">19064120</pubmed></ref>.<br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
! Applicable diseases for PGD <ref>Genoma Group (2014). Retrieved September 18th, 2015, from http://www.preimplantationgeneticdiagnosis.it/genetic-diseases-diagnosed-by-pgd.htm </ref>, <ref>Genesis Genetics (2015). Retrieved September 18th, 2015, from http://genesisgenetics.org/pgd/what-we-test-for/</ref>, <ref>Human Fertilisation & Embryology Authority (2015). Retrieved Septembr 18th, 2015, from http://guide.hfea.gov.uk/pgd/</ref><br />
|-<br />
| '''Disease'''<br />
| '''Involved Genes'''<br />
|-<br />
| 5 Alpha Reductase Deficiency (5ARD)<br />
| SRD5A2 <br />
|-<br />
| Achondroplasia<br />
|FGFR3 <br />
|-<br />
| Acute Intermittent Porphyria <br />
| ALAD, ALAS2, CPOX, FECH, HMBS, PPOX, UROD, or UROS<br />
|-<br />
| Adrenoleukodystrophy (Adrenomyeloneuropathy)<br />
| ABCD1 <br />
|-<br />
| Agammaglobulinaemia (x-linked) <br />
|BTK <br />
|-<br />
| Agammaglobulinemia Bruton Tyrosine Kinase (BTK) <br />
|BTK <br />
|-<br />
| Aicardi Goutieres Syndrome 1 (AGS1) <br />
|TREX1, RNASEH2A, RNASEH2B, RNASEH2C, SAMHD1<br />
|-<br />
| Alagille Syndrome<br />
|JAG1 or NOTCH2<br />
|- <br />
| Alpers-Huttenlocher Syndrome <br />
|POLG <br />
|-<br />
| Alpha-1-antitrypsin deficiency <br />
|SERPINA1 <br />
|-<br />
| Alpha-Mannosidosis<br />
| MAN2B1 <br />
|-<br />
| Alpha Thalassemia <br />
|HBA1 or HBA2 <br />
|-<br />
| Alports Syndrome<br />
|COL4A3, COL4A4, COL4A5<br />
|-<br />
| Alzheimer's Disease - early onset (Type 3 and 4) <br />
|APP, PSEN1, or PSEN2<br />
|-<br />
| Amyotrophic Lateral Sclerosis 1 (ALS1) <br />
|C9orf72, SOD1, TARDBP, FUS, ANG, ALS2, SETX, VAPB <br />
|-<br />
| Argininosuccinic Aciduria <br />
| ASL<br />
|-<br />
| Arrhythmogenic Right Ventricular Cardiomyopathy/ Dysplasia (ARVC/D)<br />
| DSG2; DSP; PKP2<br />
|-<br />
| Ataxia Telangiectasia<br />
| ATM<br />
|-<br />
| Autosomal Recessive Meckel-Gruber Syndrome<br />
| TMEM67<br />
|-<br />
| Bardet-Biedl Syndrome (BBS)<br />
| BBS1; BBS10<br />
|-<br />
| Barth Syndrome<br />
| TAZ<br />
|-<br />
| Beta Thalassaemia<br />
| HBB<br />
|-<br />
| Birt-Hogg-Dubé Syndrome<br />
| FLCN<br />
|-<br />
| Breast Ovarian Cancer Familial Susceptibility (BRCA2)<br />
| BRCA1; BRCA2<br />
|-<br />
| Canavan Disease <br />
| ASPA<br />
|-<br />
| Carnitine-Acylcarnitine Translocase Deficiency <br />
| SLC25A20<br />
|-<br />
| Cerebral Arteriopathy with Subcortical Infarcts & Leukoencephalopathy (CADASIL)<br />
| NOTCH3<br />
|-<br />
| Cerebral Cavernous Malformation<br />
| CCM1<br />
|-<br />
| Charcot-Marie-Tooth Disease<br />
| GJB1; MPZ; NEFL; PMP22<br />
|-<br />
| CHARGE Syndrome<br />
| CHD7<br />
|-<br />
| Cherubism<br />
| SH3BP2<br />
|-<br />
| Choroideremia<br />
| CHM<br />
|-<br />
| Chronic Granulomatous Disease<br />
| CYBB; NCF1<br />
|-<br />
| Ciliary Dyskinesia<br />
| DNAH5<br />
|-<br />
| Citrullinemia<br />
| ASS1<br />
|-<br />
| Cleidocranial Dysplasia<br />
| RUNX2<br />
|-<br />
| Cockayne Syndrome<br />
| ERCC6<br />
|-<br />
| Congenital Adrenal Hyperplasia<br />
| CYP21A2<br />
|-<br />
| Congenital Cataracts<br />
| GJA8; VSX2<br />
|-<br />
| Congenital Diarrhea, Syndromic<br />
| SPINT2<br />
|-<br />
| Congenital Disorders of Glycosylation (CDG)<br />
| ALG1; ALG6; CDG1C; DOLK; PMM2<br />
|-<br />
| Cornelia de Lange Syndrome <br />
| NIPBL<br />
|-<br />
| Craniosynostosis<br />
| TWIST1<br />
|-<br />
| Crouzon Syndrome<br />
| FGFR2<br />
|-<br />
| Cysteinyl Leukotriene Receptor 1 Deficiency <br />
| CYSLTR1<br />
|-<br />
| Cystic Fibrosis<br />
| CFTR<br />
|-<br />
| Diamond –Blackfan Anemia <br />
| RPS19<br />
|-<br />
| Duchenne Muscular Dystrophy <br />
| DMD<br />
|-<br />
| Dyskeratosis congenita (Male embryos only)<br />
| DKC1<br />
|-<br />
| Ectodermal dysplasia (Hypohidrotic)<br />
| EDA; EDA1; GJB6; IKBKG<br />
|-<br />
| Familial Adenomatous polyposis coli (FAP)<br />
| APC<br />
|-<br />
| Familial Dysautonomia<br />
| IKBKAP<br />
|-<br />
| Fanconi Anemia <br />
| FANCA; FANCC; FANCD2; FANCF; FANCG; FANCJ<br />
|-<br />
| Fragile X Syndrome (FRAX)<br />
| FMR1<br />
|-<br />
| Galactosemia <br />
| GALT<br />
|-<br />
| Gangliosidosis<br />
| GLB1<br />
|-<br />
| Glanzmann Thrombasthenia <br />
| ITGA2B<br />
|-<br />
| Glutaric Acidemia (aciduria)<br />
| GCDH <br />
|-<br />
| Glycogen Storage Disease <br />
| G6PC; GAA; SLC37A4<br />
|-<br />
| Haemophilia A<br />
| F8<br />
|-<br />
| Haemophilia B<br />
| F9<br />
|-<br />
| Hereditary Nonpolyposis Colorectal Cancer: Lynch Syndrome<br />
| MLH1; MSH2; MSH6<br />
|-<br />
| Holt Oram Syndrome<br />
| TBX5<br />
|-<br />
| Huntington Disease<br />
| HD<br />
|-<br />
| Hydrocephalus<br />
| L1CAM<br />
|-<br />
| Ichthyosis <br />
| ABCA12; STS<br />
|-<br />
| Incontinentia Pigmenti (IP)<br />
| NEMO<br />
|-<br />
| Joubert Syndrome 5<br />
| INPP5E<br />
|-<br />
| Krabbe Disease<br />
| GALC<br />
|-<br />
| Leber Congenital Amaurosis (LCA)<br />
| CEP290; GUCY2D<br />
|-<br />
| Leigh Syndrome (Infantile Subacute Necrotising Encephalopathy)<br />
| LRPPRC<br />
|-<br />
| Lesch Nyan Syndrome<br />
| HPRT1<br />
|-<br />
| Leukocyte Adhesion Deficiency (Type I)<br />
| ITGB2<br />
|-<br />
| Li-Fraumeni Syndrome<br />
| TP53<br />
|-<br />
| Macular Dystrophy Retinal <br />
| VMD2<br />
|-<br />
| Maple Syrup Urine Disorder (MSUD)<br />
| BCKDHB<br />
|-<br />
| Marfan Syndrome <br />
| FBN1<br />
|-<br />
| Menkes Syndrome<br />
| ATP7A<br />
|-<br />
| Mitochondrial DNA Depletion Syndrom <br />
| POLG; RRM2B; SUCLA2; TK2<br />
|-<br />
| Mucolipidosis type II<br />
| GNPTAB<br />
|-<br />
| Multiple Endocrine Neoplasia<br />
| MEN1; MEN2A; MEN2B<br />
|-<br />
| Multiple Exostoses<br />
| EXT1; EXT2 <br />
|-<br />
| Myotubular myopathy<br />
| MTM1 <br />
|-<br />
| Nail-Patella Syndrome<br />
| LMX1B<br />
|-<br />
| Neurofibromatosis Type 1<br />
| NF1<br />
|-<br />
| Neurofibromatosis Type 2 <br />
| NF2<br />
|-<br />
| Noonan Syndrome<br />
| KRAS, PTPN11; SOS1<br />
|-<br />
| Norrie Disease<br />
| NDP<br />
|-<br />
| Ocular Albinism <br />
| GPR143<br />
|-<br />
| Oculocutaneous Albinism <br />
| OCA2; TYR <br />
|-<br />
| Oculodentaldigital Dysplasia<br />
| GJA1<br />
|-<br />
| Optic Atrophy<br />
| OPA1<br />
|-<br />
| Ornithine Transcarbamylase Deficiency <br />
| OTC<br />
|-<br />
| Osteogenesis imperfeca <br />
| COL1A1; COL1A2<br />
|-<br />
| Osteopetrosis <br />
| CLCN7; OSTM1; TCIRG1<br />
|-<br />
| Pachyonychia Congenita <br />
| KRT16; KRT6A<br />
|-<br />
| Pancreatitis, Hereditary<br />
| PRSS1 <br />
|-<br />
| Papillorenal syndrome <br />
| PAX2<br />
|-<br />
| Phenylketonuria <br />
| PAH <br />
|-<br />
| This table does not cover the complete list of diseases that PGD can be applied to.<br />
|}<br />
<br />
==Laws & Legal status==<br />
<br />
{| class="wikitable" <br />
|-bgcolor="DDCEF2"<br />
|'''Country'''<br />
|'''Legislation'''<br />
|-<br />
| Australia<br />
| PGD is currently used to detect serious genetic conditions to improve the outcome of Assisted Reproductive Technologies (ART). In very rare cases it may be used to select an embryo with compatible tissue for a sibling who has a life-threatening disease where other means of treatment is unavailable. This is with the conditions that the use of PGD will not affect the welfare and interests of the child to be born. The parents must also receive adequate counselling and have full understanding of the procedures of PGD. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"> National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art</ref><br />
The use of PGD for sex-selection is prohibited with the exception of reducing the risk of the transmission of serious sex-linked genetic conditions. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"/><br />
|-bgcolor="FFFAFA"<br />
| Brazil<br />
| The laws regarding PGD in Brazil are not strictly regulated. They are vague and there is limited information surround the activities of assisted reproduction in general in the country <ref name="PMID25493379"><pubmed>25493379</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| Czech Republic<br />
| The laws in the Czech Republic allow those with a “defined indication in order to exclude risk of serous genetically conditioned disease and defects with embryos before they are implanted into the cavity of the uterus”. Couples that undergo any assisted reproductive treatment including PGD have to be married. Sex-selection is illegal except in regards to serious sex-linked genetic diseases <ref name="PMID24777348"><pubmed>24777348</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| Greece<br />
| In Greece, ART is open to those up to the age of 50 with written consent. It can only be used if a medical necessity is present such as the susceptibility of serious hereditary diseases. Sex selection is banned apart from cases of sex-linked diseases and sexually transmitted diseases <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| India<br />
| In India there is a cultural preference for boys thus the Prenatal Diagnostic Techniques (Regulation and Prevention of Misuse) Act was introduced in 1994. This law limits the use of PGD for sex determination except in cases of specific congenital diseases. These laws however are not strictly enforced. <ref>World Health Organisation (2015) Gender and Genetics Retrieved on October 21st 2015 from:http://www.who.int/genomics/gender/en/index4.html</ref><br />
|-bgcolor="FFFAFA"<br />
| Portugal <br />
| ART is only available to those who are married or have a similar type of relationship for at least two years. The couples cannot be of the same sex and must be at least 18 years of age. Sex selection is illegal except in cases of sex-linked diseases. The use of PGD is illegal if the predictive value of genetic tests are very low <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| Spain<br />
| PGD can be applied to “serious hereditary diseases not amenable to postnatal curative treatment” and “detection of other abnormalities which may compromise the viability of the pre-embryo”. If PGD is to be used for any other purpose authorisation must be acquired <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| Sweden <br />
| The use of PGD is strictly regulated and couples must achieve authorisation of the National Board of Health and Welfare. It can only be used it can only be used if the child is at risk to inheriting a serious chromosomal or monogenetic disease. It cannot be used for selection of specific characteristics <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| United Kingdom<br />
| Those involved with carrying out the IVF treatment must have a license from the Human Fertilisation and Embryology Authority (HFEA). Only embryos that are approved by the HFEA can be implanted where the embryonic nuclear or mitochondrial DNA cannot be altered with the exception of preventing mitochondrial diseases <ref name="PMID24777348"/>. <br />
|}<br />
<br />
==Future/Current Research==<br />
===Noninvasive Preimplantation Genetic Testing without Embryo Biopsy===<br />
Different parameters of gametes, zygotes, embryos (“vacuoles in sperm heads, spindle position in mature oocytes, cleavage intervals of zygote, and embryo developmental dynamics”) may correlate with aneuploidy rates. This knowledge may be applied in potential noninvasive preimplantation diagnostic methods. Several methods have been proposed and are currently further researched<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Sperm Selection====<br />
Intracytoplasmic morphologically selected sperm injection (IMSI) is common procedure in IVF treatment to improve fertilization rates in patients with poor semen quality. In addition, studies have found that IMSI improves embryo development and that spermatozoa with large vacuoles in their heads correlate with increased aneuploidy rates and disturbed chromosomal structures. Thus, selecting spermatozoa based on morphological hallmarks may decrease aneuploidy rates in the fertilized embryos. As with polar body biopsies, however, this approach will solely be applicable if evidence for severe male detrimental contribution is given<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Blastocoel Fluid Extraction====<br />
In addition, a less invasive retrieval of material for diagnosis could include the extraction of the blastocoel fluid. The cavity of the blastocyst, lined by the trophectoderm, is filled with this blastocoel fluid, which contains metabolites of both trophectoderm and inner cell mass origin. The retrieval does not require a biopsy but merely a small opening to extract the fluid and, thus, causes less harm to the embryo. Multiple studies have applied this method<ref name="PMID22020776"><pubmed>22020776</pubmed></ref> <ref name="PMID23148560"><pubmed>23148560</pubmed></ref> and it may in the future become of clinical relevance.<br />
<br />
<br />
[[File:Aspiration_of_the_Blastocoel_Fluid.jpeg|thumb|Aspiration of the Blastocoel Fluid using a ICSI pipette<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.]]<br />
<br />
<br />
Next to metabolites, the blastocoel fluid can contain DNA. Studies have shown that genomic DNA is present in about 90% of the blastocoel fluid samples tested. Typically the fluid is removed with an ICSI pipette from a day five blastocyst through its mural trophectoderm until the blastocyst fully collapses around the embryo. Several concerns regarding this method in a clinical setting have been raised. The collected DNA may be contaminated by the culture media that contains DNA fractions. The DNA may also be least representative of the actual embryos genome as the DNA may originate from abnormal or degenerated cells. Even though labelled noninvasive, the blastocyst still undergoes manipulation to some degree which may affect its viability. Thus, more research is required until this method can evolve from research to clinical use<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
====Proteomics====<br />
The protein secretome of blastocysts may be representative of its chromosome constitution Recent studies have found biomarkers such as lipocalin-1, interleukin-10, tumor necrosis factor, stem cell factor, and chemokine ligand 13 to be differently secreted by aneuploid blastocyst than by euploid ones. The most significant biomarker appears to be interleukin-10. Paired with novel proteomic technologies and mass spectrometry this knowledge when extended may contribute to a new invasive preimplantation genetic diagnosis method<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Embryo Morphology====<br />
Using time lapse imaging the embryo’s morphology can be closely observed and potential aneuploidy characteristics detected. Such characteristics may include the time of division to five cells, the time between the division from three to four cells, and the duration of the division from one to two and subsequently to three. In addition, the morphological quality of ICM an TE has been positively associated with aneuploidy or euploidy prognosis<ref name="PMID26246880"><pubmed>26246880</pubmed></ref>. These may give rise to an embryo quality screening prior to implantation<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
==References==<br />
<br />
<references/><br />
<br />
<br />
{{StudentPage2015}}</div>Z5017878https://embryology.med.unsw.edu.au/embryology/index.php?title=2015_Group_Project_6&diff=2070332015 Group Project 62015-10-21T07:46:56Z<p>Z5017878: </p>
<hr />
<div>{{ANAT2341Project2015header}}<br />
<br />
<br />
=Preimplantation Genetic Diagnosis and Screening=<br />
==Introduction==<br />
Preimplantation genetic diagnosis (PGD) and screening (PGS) are reproductive options for couples with known family histories of genetic disease or couples undergoing IVF procedures due to infertility issues. PGD can diagnose many genetic disorders caused by known chromosomal abnormalities (number and/or structure) or single gene mutations, and, thus decrease the risk of termination of pregnancy or miscarriages and enable such couples to have an unaffected child<ref name="PMID24907939"><pubmed>24907939</pubmed></ref>. Through major improvements in PGD/S and general laboratory technology, the testing for abnormalities in fetuses has shifted from prenatal diagnosis during the first 2 trimesters <ref> Blackburn, S.L. (2003) '''Maternal, Fetal & Neonatal physiology: a Clinical perspective''' (2nd ed.). Seattle: Saudners </ref>, testing for overall fetal growth, complications of pregnancy, and birth defects<ref> Sadler T.W.(2012) '''Langman's Medical Embryology''' (12th ed.) Philadelphia: Lipincott, Wiliams & Wilkins, a Wolters Kluwer Business </ref>, to an embryonic focus especially in advancements in Artificial Reproductive Technologies (ART)<ref><pubmed>20638568</pubmed></ref>. In 1990 PGD for a recessive X-linked disease resulted in the first live birth<ref><pubmed>2330030</pubmed></ref> and has since been incorporated in clinical routine and applied for a variety of genetic diseases, such as sickle cell anemia, thalassemia, or cystic fibrosis<ref name="PMID24907939"/>.<br />
[[File:Preimplantation Genetic Diagnosis Procedure.jpeg|700px|thumb| Simplified steps for PGD<ref name="PMID24907939"/>]]<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=0e-79qKllqk</html5media><br />
|-<br />
| Preimplantation Genetic Diagnosis<ref>IVF Florida (2011, December 11) IVF Florida - South Florida Fertility Specialists - Pre-Implantation Genetic Diagnosis [Video file]. Retrieved from https://www.youtube.com/watch?v=0e-79qKllqk</ref><br />
|}<br />
<br />
==History==<br />
The advances in reproductive technology during the second half of the 20th century, led to PGD's first clinical application in 1990 <ref>Harper, J. (n.d.). The history of PGD. Lecture. UCL Centre for PG&D and CRGH.University College London</ref>.<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
|Year<br />
|<br />
|- bgcolor="FFFAFA"<br />
| '''1967''' <br />
|First PGD on rabbit blastocysts (Gardner& Edwards) <ref name="PMID6036172"><pubmed>6036172</pubmed></ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1986''' <br />
|First Cleavage Biopsy (Wilton & Trounson)<ref>Wilton, L. J., & Trounson, A. O. (1986). Viability of mouse embryos and blastomeres following biopsy of a single cell. In Proceedings of the 18th Annual Conference of the Australian Society for Reproductive Biology, Brisbane, Australia.</ref><br />
|- bgcolor="FFFAFA"<br />
|'''1987''' <br />
|First Blastocyst Biopsy (Muggleton-Harris, Monk, Rawlings, & Whittingham)<ref name="PMID3372699"><pubmed>3372699</pubmed></ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1988''' <br />
|First Polar Body Biopsy (Yury Verlinksy)<ref> Verlinsky, Y., Pergament, E., Andresen, P., Enriquez, G., & Strom, C. (1989). Genetic analysis of polar body DNA: A new approach to preimplantation genetic diagnosis. Am J Hum Genet, 45(4), A272.</ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1990''' <br />
|First Clinical PGD using PCR testing for X-linked (Handyside, Kontogianni, Hardy, & Winston)<ref name="PMID2330030"><pubmed>2330030</pubmed></ref> <br />
|} <br />
==Preimplantation Genetic Diagnosis==<br />
Preimplantation genetic diagnosis (PGD) is used to test the genetic makeup of embryos to detect single gene disorders, chromosomal abnormalities and mitochondrial disorders. It also has applications in gender selection for diseases with unequal gender distributions <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Some diseases commonly involved with PGD include cystic fibrosis, spinal muscular atrophy and beta – thalassaemia <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press.">Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press</ref> <ref name="PMID17823145"><pubmed>17823145</pubmed></ref>. It was first used in the United Kingdom in the 1980s of arenoleucodystrophy and primarily focusing on sex- linked disorders <ref name="PMID17823145"/><ref name="PMID23150080"><pubmed>23150080</pubmed></ref>. PGD is now capable of detecting single cell defects (molecular) and chromosomal disorders resulting from the inversion, translocation or deletion of chromosomes (cytogenic) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>,<ref name="PMID11325751"><pubmed>11325751</pubmed></ref>. PGD can be applied to the embryo at different stages. That is on polar bodies, blastomeres or blastocyst <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>.<br />
Depending on the type of genetic disorder, PGD utilises different methods of genetic testing. These include Fluorescence in situ hybridisation (FISH) which is used for sex – linked disorders and detects chromosomal rearrangements <ref name="PMID11325751"/><ref name="PMID17876073"><pubmed>17876073</pubmed></ref> and Embryo halotyping which allows the identification of chromosomes causing the inherited disorder through knowledge of the pattern of closely linked markers <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. Polymerase chain reaction (PCR) is also widely used to detect molecular abnormalities <ref name="PMID11325751"/>.<br />
PGD is tightly regulated and supported by large organisations namely The American Society for Reproductive Medicine, The European Society for Human Reproduction and Embryology (ESHRE), The European Society of Human Genetics and the Preimplantation Genetic Diagnosis International Society <ref name="PMID25500181><pubmed>25500181</pubmed></ref>.<br />
===Sex-linked disorders===<br />
The determination of a disease as gender specific usually correlates with the presence or absence of specific genes such as SRY on the Y chromosome. It is known that females have two X chromosomes and males have an X and a Y chromosome where abnormalities are more prevalent on the X chromosome. PGD can be used for sex selection where only male embryos are transferred to reduce the chance of inheriting X-linked disorders. However, this does not completely eradicate the problem as male embryos remain susceptible to inheriting an affected X chromosome. Sex determination is only used when the specific mutation is unknown and has yet to be discovered <ref name="PMID24866878"><pubmed>24866878</pubmed></ref>.<br />
===Single gene defects===<br />
Single gene defects can be dominant, recessive, autosomal or X-linked. They are commonly diagnosed using PCR and although the PCR available today is complex and capable of combatting a large range of disease the development of new protocols has been proven to be difficult due to the small DNA sample available <ref name="PMID26168107"><pubmed>26168107</pubmed></ref><br />
===Mitochondrial disorders===<br />
Mitochondrial disorders also known as oxidative phosphorylation disorders arise from mutations in the nuclear DNA or mitochondrial DNA <ref name="PMID26312584"><pubmed>26312584</pubmed></ref>. They pose as a problem because they are unrecognisable until the mutations in the cell reach a detrimental level <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Mitochondrial disorders cause miscarriages and stillbirths as well as death in children and young adults. The effects can either be contained in a single organ or more commonly involve multiple organ failure where organs with high energy demands such as the brain, liver muscle and heart and heavily influenced. They are usually occur spontaneously or result from inheritance from the mother. Since mitochondria are solely inherited from the mother oocyte donations have been used as a solution to combat mitochondrial disorders. Additionally, there has been an increasing use in PGD where embryos that stay under the given threshold of 18% gene-mutations are allowed to be transferred and result in normal development. New technology in the areas of nuclear gene transfer and genome editing are also being experimented with <ref name="PMID26312584"/>. <br />
===Chromosomal disorders===<br />
Chromosomal disorders can be reciprocal, Robertsonian translocations, inversions, deletions and insertions <ref name="PMID26168107"/>. . Data from ESHRE collected between 2010 and 2011 has shown that the most common chromosomal abnormality confronted in PGD are reciprocal chromosomal abnormalities <ref name"PMID26071418"><pubmed>26071418</pubmed></ref>. PGD has also been used successfully for Robertsonian translocations (RT), a type of structural translocation. Children who carry RT are phenotypically normal, however in their later years it is found that they will suffer from infertility and repeated miscarriages due to the high frequency of abnormal embryos <ref name="PMID22081077"><pubmed>22081077</pubmed></ref>. PCR and FISH are the two main techniques used for chromosomal disorders. To be able to conduct the examinations the cells are required to be at the metaphase stage <ref name="PMID26168107"/>. <br />
[[File:Reasons_for_PGD.jpg|600px|thumb|Reasons for PGD<ref name= "PMID24764761"><pubmed><24764761</pubmed></ref>]]<br />
==Preimplantation Genetic Screening==<br />
Prenatal Genetic Screening (PGS) involves an array of methods or ideas that aim to segregate embryos that have genetic flaws and those that are healthy <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. The occurrence of aneuploidy is high around the stages of early embryonic development and they are the most common cause if miscarriages and congenital birth defects <ref name= "PMID26085841"><pubmed>26085841</pubmed></ref>. They have little effect on the morphology of the embryo making them difficult to identify thus identification heavily relies on genetic testing <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. <br />
Genetic sampling is most commonly conducted using Microarray Comparative Genomic Hybridisation (aCGH) as well as FISH, Quantitative PCR and Single Nucleotide Polymorphism (SNP) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. These methods collectively aim to assess numeral and structural chromosomal errors <ref name= "PMID26085841"/>. Studies have also introduced Next- Generation Sequencing (NGS) <ref name= "PMID26085841"/> and Whole Genome Amplification used to screen imbalances in the complete 24-chromosomes <ref name="PMID25953353"><pubmed>25953353</pubmed></ref><br />
Statistics from ESHRE have shown that the most common indications for PGS is advanced age, followed by repeated implantation failure or recurrent miscarriage and male infertility <ref name="PMID26071418"><pubmed>26071418</pubmed></ref>.<br />
===Indications===<br />
A low percentage of structural abnormalities in chromosomes are responsible for the cause of miscarriages. Despite this, they are the most prevalent type of chromosomal abnormality accounted for in PGD <ref name="PMID20638568"/>. The presence of specific gene cycles, initiation of embryonic protein synthesis and evident physiological development are all indicative of a successful in vitro fertilisation procedure <ref name="PMID11576737"><pubmed>11576737</pubmed></ref>. To eliminate further errors from occurring during the PGD procedure it is recommended to undertake further prenatal testing such as amniocentesis in the later stages <ref name="PMID20638568"/>. <br />
====Advanced maternal age====<br />
Data provided by the ESHRE has shown that the mean age of women undergoing PGS is 39 years <ref name="PMID26071418"/>. Women of advanced age have been shown to have a lower rate of pregnancies reaching childbirth <ref name="PMID18583331"><pubmed>18583331</pubmed></ref>. The highlighted concern revolves around the increased occurrence of aneuploidy following maternal age. The optimal age range for the lowest aneuploidy incidence was found to be between 27 to 37 years of age (6%) then progressively higher in women aged up to 42 (33%) and most common in those 44 and above (53%) <ref name="PMID24355045"><pubmed>24355045</pubmed></ref>. <br />
====Recurrent pregnancy loss / IVF failure====<br />
Recurrent pregnancy loss is defined as three or more IVF failures after cumulative transfer of more than 10 good-quality embryos. These are primarily caused by two main factors, reduced endometrium receptivity or embryonic defects. Endometrium receptivity can be negatively influences by instances including uterine pathologies such as thin endometrium, altered expression of adhesive molecules and immunological factors. Additionally, embryonic defects may be due to genetic abnormalities, embryonic aneuploidy or zona hardening. Endometriosis and hydrosalpinx has been known to effect both the endometrium and embryo <ref name="PMID23260857"><pubmed>23260857</pubmed></ref>.<br />
====Human leukocyte antigen matching====<br />
First used in 2001, HLA matching is an option given to parents to save a child with haematological or immunological disease through conceiving another child who would potentially be able to donate cord blood or haematopoietic stem cells from the bone marrow for transplantation. The process namely PGD-HLA has shown to improve haematopoietic stem cell transplant (HSCT). PGD-HLA can only be performed when HSCT is not needed urgently due to the time needed to conceive and delivery the baby <ref name="PMID25500181"><pubmed>25500181</pubmed></ref>. It is most commonly applied to children suffering from relapsed leukaemia <ref name="PMID22524201"><pubmed>22524201</pubmed></ref>. In a case study PGD-HLA was proven to successfully cure 10 diseases including Fanconi anaemia, Diamond-Blackfan anaemia and beta thalassemia <ref name="PMID25066893><pubmed>25066893</pubmed></ref>.<br />
==Biopsy Methods==<br />
Biopsy, the removal of genetic materials, from oocytes or embryos in the preimplantation stage is the primary step in PGD. For the past two decades these biopsies have been performed at three stages, the polar body, blastomere, and blastocyst, and the methodologies optimized to ensure the embryo’s viability. The most common approach involves biopsies at the cleavage stage. However, polar body and blastocyst biopsies are increasingly more often tested and applied. Approached for opening the zona pellucida involve next to the traditional mechanical and chemical means, novel approaches such as noncontact lasers. Their application may simplify and secure the procedure significantly. The most challenging question about PGD procedures remains at what stage biopsies should be taken. Much controversy has developed around this topic, highlighting the varying disadvantages and advantages of temporal biopsies. <ref name="PMID22723007"><pubmed>22723007</pubmed></ref><br />
<br />
{| class="wikitable"<br />
|- align="center" bgcolor="DDCEF2"<br />
|<br />
| Time of Biopsy<br />
| Advantages <br />
| Disadvantages<br />
|- bgcolor="FFFAFA"<br />
| Polar Body<br />
| Day 1<br />
| No harm to oocyte<br />
| Only maternal DNA is tested, often needs to be coupled with other biopsies<br />
|- bgcolor="FFFAFA"<br />
| Blastomere<br />
| Day 3<br />
| …<br />
| … <br />
|- bgcolor="FFFAFA"<br />
| Trophectoderm<br />
| Day 5 and 6 <br />
| Little harm, large amount of genetic material<br />
| Opening of blastocyst necessary, small time window for procedure<br />
|}<br />
<br />
<br />
[[File:Polar_Body,_Blastomere,_and_Trophectoderm_Biopsy.jpeg|thumb|Polar body (A), blastomere (B) and trophectoderm (C) biopsies<ref name="PMID25625041"><pubmed>25625041</pubmed></ref>.]]<br />
<br />
<br />
<br />
PMID 24305177<br />
===Polar Body Analysis===<br />
Day 1<br />
====Description====<br />
Polar body (PB) biopsy, which was introduced in 1990, offers a promising alternative to biopsies performed at the blastomere stage for PGD/S indications on legal and practical grounds. <br />
Description: Consequent embryo development does not necessitate the presence of the first and second PB and their removal may not be crucial. PB biopsy requires precise timing. Keeping track of the meiotic cell cycle is necessary to perform a successful biopsy and, therefore, PB biopsy usually is applied in combination with intracytoplasmic sperm injection (ICSI). During the maturation from the germinal vesicle stage to the metaphase-II stage the first PB is formed. A cytoplasmic bridge containing spindle remnants, that are still in contact with the cellular genetic material, links this PB to the oolemma for about 90 minutes after extrusion. It is possible to visualize these remnants by polarization microscopy and it is crucial to not perform the biopsy until the first PB is no longer firmly attached to the oolemma as this indicates an immature embryo.The oocyte tolerates mechanical zona dissection best during hours four until six after ICSI as the oolemma has stabilized by that time because of the cortical granule reaction. Over time the first PB degenerates stressing a temporal biopsy and its optimal extraction time window is four to 12 hours after ICSI. The second PB forms around two to four hours after ICSI. However, its optimal time window for biopsy is set to be eight to 16 hours after ICSI. This is due to the second PB being attached to the oolemma with spindle remnants until six hours after ICSI. Biopsy at this point may cause enucleation of the oocyte. In addition, studies have shown that the amplification efficiency of second PB’s DNA is worse if the PB is extracted prior to eight hours after ICSI. <br />
Thus, it is possible to perform sequential and simultaneous biopsies for the first and second PB. If performed, sequentially the first PB may be removed four to 12 hours and the second PB eight to 16 hours after ICSI. The optimal time window for a biopsy for both the first and second PB simultaneously is eight to 12 hours after ICSI. It is highly preferred to analyze both PBs due to potential aneuploidies in either PB and crossing overs during meiosis<ref name="PMID22723007"/>. <br />
====Procedure====<br />
Chemical opening achieved with for example acidic tyrode’s solution of the zona pellucida is not tolerated by the oocyte and may have detrimental effects on the embryo’s development. Therefore, the access to the perivitelline space of the oocyte is provided by mechanical zona dissection or by laser. Both techniques work well if performed by experienced embryologist. However, laser-assisted biopsy is less time consuming when compared to manual dissection. It is critical to consider the size of the introduced opening as it will remain permanent. If it is too large the blastomere may be lost during embryo development and if it is too small it may interfere with hatching of the embryo during blastocyst stage<ref name="PMID22723007"/><br />
<br />
[[File:Polar_Body_Biopsy.jpeg|thumb|The presence of a faint but clearly identifiable strand connecting PB2 to the <br />
oolemma. The biopsy was performed ∼9 h after ICSI<ref name="PMID21908464"><pubmed>21908464</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JTaQzszVr8o</html5media><br />
|-<br />
| Laser-assisted polar body biopsy<ref>RIUK, R. (2013, June 25) Polar Body Biopsy [Video file]. Retrieved from https://www.youtube.com/watch?v=JTaQzszVr8o</ref><br />
|}<br />
<br />
====Advantages & Disadvantages====<br />
PB biopsies can only investigate the maternal contributions to the embryo as they are of maternal origin. Thus, this procedure is appropriate for PGD solely for monogenetic diseases from the maternal side. Recessive diseases may be evaluated with PB biopsies on the basis that the embryo’s outcome will be determined by the paternal contribution. (...) It may still be applied for PGS as most aneuploidies either arise during meiosis or origin from the maternal genome. However, diagnosis error has been reported due to the lack of considering paternal contributions. <br />
Because PB biopsies are performed very early it is not yet known whether the oocyte will develop into a viable embryo. Thus, PBs are commonly frozen or fixed after biopsy and depending on the state of the embryo only chosen PBs will be tested. This is primarily an economic issue as many genetic testing procedures are very cost-intensive<ref name="PMID22723007"/>.<br />
<br />
[[File:Implantation_predictive_value_of_euploid_screening_results.jpeg|thumb|The sustained implantation predictive value (with 95 % confidence interval) of a euploid screening result obtained from the first polar body (PB1), PB1 and the second polar body (PB2), or a direct embryo biopsy for each stage of embryo transfer (cleavage-stage and blastocyst stage)<ref name="PMID25106935"><pubmed>25106935</pubmed></ref>.]]<br />
<br />
===Blastomere biopsy===<br />
Day 3 <br />
====Description====<br />
Blastomere biopsy has been the prevalent method for PGD and PGS in the last two decades. At least one, but up to two, blastomeres are biopsied on day three of the cleavage stage embryo. The right number of blastomeres removed is a controversial topic as two cells allow for more genetic material and more accurate results. However, removing two cells might be too invasive and damaging to the embryo. (Study)<ref name="PMID21748341"><pubmed>21748341</pubmed></ref><br />
====Procedure====<br />
Initially a hole was drilled into the zona pellucida using acid tyrodes and the blastomeres are removed via aspiration with a pipette<ref name="PMID21748341"/>.<br />
<br />
<br />
[[File:Aspiration_of_a_Blastomere.jpeg|thumb|Aspiration of a Blastomere into the biopsy pipette<ref name=" PMID24783200"><pubmed>24783200</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=TbridWVwipI</html5media><br />
|-<br />
| Laser-assisted blastomere biopsy<ref>Sukprasert, M. (2014, March 5) Day 3 Blastomere Biopsy 1 [Video file]. Retrieved from https://www.youtube.com/watch?v=TbridWVwipI</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
===Trophectoderm biopsy===<br />
Day 5 and 6<br />
====Description====<br />
The improvement of embryo culture media allowed the in vitro development of human embryos until the blastocyst stage and opened up the possibility to take blastocyst biopsies. During day three to day five the haploid maternal and paternal genomes work together for the first time to form the genome of the embryo. The maternal epigenetic control lessens significantly while preparing for implantation with precisely arranged events happening. The first event includes a rapid increase in the number of embryonic cells which are active in mitotic divisions and apoptosis of aberrant cells. This is followed by the formation of blastocoel (cavitation) which results from the flattening of cell located on the outside of the blastomere. Now the blastocyst will expand until the embryo hatches by rupturing the zona pellucida. The cells of the blastocyst will differentiate to form two distinct cell lineages, the outer trophectoderm and the inner cell mass<ref name="PMID22723007"/>.<br />
====Procedure====<br />
Trophectoderm biopsy is usually performed in Hepes buffered biopsy medium and opening approaches include needle cutting which has been replaced by lasers in past years. Different research groups report different timings of the opening to be the most successful. Some open the blastocyst on day three or four by creating a 25 µm which causes the trophectoderm to herniate through this hole and is, thus, accessible for biopsy. Others create this hole about four hours before biopsy which allows sufficient herniation of trophectoderm cells. It is also possible to open the blastocyst immediately before biopsy. This avoids an extra step and the inner cell mass usually is easy to locate. Blastocyst biopsies involve the removal of trophectoderm cells and the ideal time for the procedure is day five. Successful biopsies on day six have been performed, while little is known about the results of biopsies on day seven. However, since the window of implantation in humans is from day eight to ten after ovulation, day seven biopsies appear to be possible<ref name="PMID22723007"/>.<br />
-collapse of trophoblasts<br />
-possible: biopsy of hatched blastocyst, holding pipette careful mild suction force to hold embryo near ICM <br />
-Cryopreservation<br />
<br />
<br />
[[File:Microscopic images of human blastocysts for biopsy.jpeg|thumb|(A) Some trophectoderm cells in a blastocyst started to hatch and (B) the trophectoderm cells were biopsied with assisted laser cutting. Images in C–D show the blastocysts after vitrification and warming. Blastocysts had been cultured for 2–4 hrs after warming, showing good (ICM and trophectoderm cells) hatched (C) and hatching (D) blastocysts. The hatching blastocyst in (E) has good ICM but fair trophectoderm while the blastocyst in (F) has both fair ICM and trophectoderm. Arrows indicate ICMs and arrow heads indicate trophectoderm cells. Bar = 40 µm<ref name="PMID2190846"><pubmed>2190846</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JI_TQ8d8tNM</html5media><br />
|-<br />
| Laser-assisted blastocyst biopsy (at 00:50 min)<ref>Coco, R. (2014, April 30) Trophectoderm biopsy in a Hatching blastocyst protruding ICM [Video file]. Retrieved from https://www.youtube.com/watch?v=JI_TQ8d8tNM</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
Blastocyst biopsies are believed to be less damaging to the embryo and appear to be unrelated to implantation rates. In addition, this biopsy method allows for a larger extraction of cells for genetic testing. However, since they are performed late in in vitro development, the time window for genetic testing is relatively small. Fast and accurate genetic testing methods are needed to ensure a successful and safe result from this biopsy. Thus, blastocyst biopsies may gain more popularity in the future whn such methods have been developed or improved<ref name="PMID22723007"/>. <br />
<br />
<br />
==Genetic Techniques==<br />
<br />
===PCR===<br />
====Description====<br />
Polymerase chain reaction (PCR) amplifies DNA specific to genetic sequence of interest . PCR was developed by Kay Mullis in the 1980s, for which he was awarded the Nobel prize for chemistry in 1993. <ref> Pubmed Docs (2015) Polymerase Chain Reaction (PCR) Pubmen. Retrieved from [http://www.ncbi.nlm.nih.gov/probe/docs/techpcr/]</ref> This technique enables clinicians to monitor and diagnose diseases using minute samples such as embryonic cells, blood & tissue. <ref>Roche (2015) PCR: How We Copy DNA. Roche Molecular Systems Inc. retrieved From [http://molecular.roche.com/pcr/Pages/Process.aspx]</ref> PCR has many important applications like DNA fingerprinting, genetic mapping, detection of viruses and bacteria as well as being used to detect genetic disorders, as a part of PGD, in conjunction with IVF. It is used to detect molecular abnormalities such as single gene disorders like Tay Sach, Cycstic fibrosis, Duchenne Muscular Dystrophy, Thalassemia, Huntington disease, Spinal muscular atrophy and many more. Molecular and Genetic analysis require a significant amount of DNA, which we would not have without PCR. It revolutionized the study of DNA, replacing all previous recombinant DNA technology. <ref> Mullins, K., Francois, F.& Gibbs R.A. (1994 ) The Polymerase Chain Reaction. p3. Springer- Science +Business Media. Birkhauser, Boston<br />
Available at [https://books.google.com.au/books?hl=en&lr=&id=gjrTBwAAQBAJ&oi=fnd&pg=PR5&dq=kary+mullis+PCR&ots=mpzAyRh5ZY&sig=PQ4goNoKJ90tb3-MkPk62zrTGbw#v=onepage&q=kary%20mullis%20PCR&f=false] </ref> <br />
<br />
[[File:PCR.jpg|thumb|right|Polymerase chain reaction (PCR) amplifies DNA specific to genetic sequence of interest, enabling the monitoring and diagnose molecular abnormalities such as single gene disorders using minute samples such as embryonic cells, blood & tissue <ref>NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref>]]<br />
<br />
====Procedure====<br />
<br />
Sample are obtained from the the blastocyst, a polar body biopsy or the blastomeres stages of the embryo. <br />
Stage 1 Denaturing: separating the target strands of DNA <br />
The obtained sample is heated to roughly 90 degrees celcius, this heat causes breaks the relatively weak bonds between nucleotides that form DNA. the double stranded DNA to split into 2 single strands of DNA that are used as templates.<br />
Stage 2 Annealing: Binding the Primers to the target DNA sequence <br />
PCR will only copy the target sequence of DNA specified by specific PCR primer. These synthesized primers Oligonucleotides are small artificial pieces of DNA. <br />
TAQ polymerase enzyme synthesize 2 new strands of DNA duplicate to the single sample DNA stand template indicated by these primers. During this stage the reaction is cooled to a temperature between 40-60 degrees Celsius. <br />
Stage 3- Extension- making copies <br />
Each of these 2 copies are then used again as templates generating 2 further replications This cycle can occur as many 30 -40 times within a couple hours leading to billions of extra copies of the original DNA segment. The optimal temperature for the further replication is roughly 72 degrees Celsius. <br />
<br />
This process mediated by a thermocycler machine that is programmed to alter the temperature of the reaction every couple of minutes, perpetuating the cycle of DNA denaturing and synthesis. <br />
This process, generates exponential exact copy of the original template DNA sequence. <br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
!PCR cycles<br />
<br />
|{|<br />
|-<br />
| '''PCR Cycle'''<br />
| '''Target Copies'''<br />
|-<br />
| 1<br />
| 2<br />
|-<br />
| 2<br />
| 4<br />
|-<br />
| 3<br />
| 8<br />
|-<br />
| 4<br />
| 16<br />
|-"<br />
| 5 <br />
| 32<br />
|-<br />
| 6 <br />
| 64<br />
|-<br />
| 7 <br />
| 128<br />
|-<br />
| 8<br />
| 256<br />
|- <br />
| 9<br />
| 512 <br />
|-<br />
| 10<br />
| 1024<br />
|-<br />
| 15<br />
| 32,768<br />
|-<br />
| 20 <br />
| 1,048,578<br />
|-<br />
| 25<br />
| 33,554,432<br />
|-<br />
| 30 <br />
| 1,073,741,842<br />
|-<br />
|}<br />
<br />
<br />
<br />
{|class="wikitable" align="center"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="10" |'''Advantages'''<br />
|-bgcolor="FFFAFA"<br />
| fast and inexpensive way of copying a target sequence of DNA<br />
|-bgcolor="FFFAFA"<br />
| aids the diagnosis of single cell defects<br />
|-bgcolor="FFFAFA"<br />
| rapid generation of results within a couple hours<br />
|-bgcolor="FFFAFA"<br />
| can start from a single molecule of DNA, therefore is more sensitive <br />
|-bgcolor="FFFAFA"<br />
| has a flexible primer design enabling<br />
|-bgcolor="FFFAFA"<br />
| overcame previous issues associated with the limited availability of sites of end<br />
|-bgcolor="FFFAFA"<br />
| generates the DNA copies exponentially<br />
|-bgcolor="FFFAFA"<br />
| enables DNA amplification required for molecular and genetic analysis<br />
|-bgcolor="FFFAFA"<br />
|Valid diagnostic method in selecting unaffected embryos for embryo transfer <ref> Dreesen, J., Drusedaul, M., Smeets, H., Die-Smulders, C., Coonen, E., Dumoulin, J., Gielen, M., Evers, J., Herbergers, J. & Geradets, J. (2008) Validation of preimplantation genetic diagnosis by PCR analysis: genotype comparison of the blastomere and corresponding embryo, implications for clinical practice. Mol. Hum. Reprod. 14 (10):573-579.doi: 10.1093/molehr/gan052. Retrieved from [http://molehr.oxfordjournals.org/content/14/10/573.short] </ref> <ref><pubmed>20966460</pubmed></ref><br />
|-bgcolor="DDCEF2"<br />
| rowspan="5"|'''Disadvantages'''<br />
|-bgcolor="FFFAFA"<br />
| only during this exponential DNA replication phase can we determine the starting quantity sequence contained in the original sample ( template DNA strand)<br />
|-bgcolor="FFFAFA"<br />
| PCR reaction is limited by the presence of inhibitors present in the sample : reagent inhibitors <br />
|-bgcolor="FFFAFA"<br />
| self annealing due to the accumulation of the product -stopping exponential amplification for the target sequence and reach a plateau<br />
quantification of the end point of reaction of PCR products unreliable - therefore that is why we require real time quantitative RT-PCR necessary<br />
<ref> NIS (2015) Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref><br />
|}<br />
<br />
<br />
===Fluorescent In Situ Hybridisation (FISH)===<br />
<br />
<br />
====Description====<br />
Fluorescence in situ hybridization (FISH) the one of the most effective and rapid <ref name="PMID26338801"><pubmed>26338801</pubmed></ref> Preimplantation Genetic Diagnosis (PGD). This techniques used to locate a specific DNA sequences within a chromosome. FISH facilitates the clinical diagnosis of chromosomal abnormalities indicated by sequential duplications, deletions and rearrangements of chromosome, that are usually missed with microscopic analysis. This technique is especially relevant for female embryos with X-linked diseases,<ref name="PMID20809319"><pubmed>20809319</pubmed></ref> that have no other mutation specific tests [http://www.ncbi.nlm.nih.gov/pubmed/20809319] As part of PGD, samples are collected from various stages of the embyro,and they are able to conducted tests on the blastocyst, a polar body biopsy and the blastomeres <ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. FISH is 99% effective when used in conjunction with competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities<ref name="PMID26338801"/>.<br />
<br />
====Procedure==== <br />
<br />
Samples are collected from either the blastocyst, a polar body biopsy or the blastomeres stages of the embryo <ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
DNA strands are heated and denatured causing their the individual DNA strands to break apart<br />
Probes are single complimentary stands of DNA a that have been tagged with small chemical agents that glow brightly in the presence of a specific region on a chromosome. These specific probes then hybridize and join to their complementary DNA strand. <br />
The fluorescent tags enable the researchers to correctly identify the presence or lack thereof and location of the specific chromosomes that they are testing for. <ref name="PMID17876073"><pubmed>17876073</pubmed></ref><br />
Researcher analyse the results by identifying the number and the relative location of the fluorescent dots generated by the FISH images.<ref name="PMID17970921"><pubmed>17970921</pubmed></ref><br />
The probe will not fully hybridise if there has been a duplication or a deletion of the DNA - indicating chromosomal and sex chromosomal anomalies like trisomies and aneuploidies. <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref><br />
<br />
<br />
Different probes are used for different purposes: <ref>Unique, Rare Chromosome Disorder Support Group (2013) Fluorescence in situ hybridisation (FISH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/Other/FISH%20FTNW.pdf]</ref><br />
*'''Locus specific tags''' detect very small imbalances, and locate isolated small portions <br />
of genes within a chromosome<br />
*'''Alphoid/Centomeric Repeat probes''' are developed from the repetitive sequence located in the middle region of each chromosome, useful in determining the number of chromosomes , detecting rearrangement and when used in conjunction with locus probes to determine the absence of genetic material on a chromosome. <br />
*'''Paint Probes''' are collections of smaller probes with their own stains that bind to a different section on the chromosome - allowing the full chromosome too be labeled a unique colour, this "full colour map" can be used to know the spectral karyotype- full chromosomal mapping is useful in examining chromosomal abnormalities. <br />
<br />
[[File:Fluorescent In Situ Hybridisation (FISH).jpg|thumb|right|'''FISH''' We are able to tag Specific DNA sequences using Probes which have been tagged with fluorescent Labels.This technique enables the clinical diagnosis of chromosomal abnormalities, indicated by sequential duplication, deletions and rearrangements of chromosome <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref>]]<br />
<br />
{|class="wikitable" align="center"<br />
|-bgcolor="pink" <br />
| rowspan="8" |'''Advantages''' <br />
|-bgcolor="#FDE1F2" <br />
| FISH is 99% effective when used in conjunction with Competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities.<ref><pubmed>26338801</pubmed></ref><br />
|-bgcolor="#FDE1F2" <br />
| Rapid generation of results<br />
|-bgcolor="#FDE1F2" <br />
| Identifies very small translocations and aneuploidies that occur within chromosomes, that would usually be missed under microscopic analysis<br />
|-bgcolor="#FDE1F2" <br />
| Indicates whether the accessed chromosomes are normal <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|-bgcolor="#FDE1F2" <br />
| Tests for the most common chromosomal abnormalities - down syndrome chromosomes 13,16,18,21 and 22 <ref><pubmed>21749752</pubmed></ref><br />
|-bgcolor="#FDE1F2" <br />
| It may be used to compare the chromosomal gene arrangements in related species<br />
|-bgcolor="#FDE1F2" <br />
| can be used to identify and remove inheritable X-linked disease or sex chromasome anomalies such as Duchennes Muscular Dystrophy, hemophilia, ectodermal dysplasia <ref><pubmed>17876073</pubmed></ref><br />
|-bgcolor="#FEB745"<br />
| rowspan="5"|'''Disadvantages'''<br />
|-bgcolor="#FE1C5EA"<br />
| FISH destroys all cells tested <ref> O'Connor, C. (2008) Fluorescence in situ hybridization (FISH). Nature Education 1(1):171. retrieved from [http://www.nature.com/scitable/topicpage/fluorescence-in-situ-hybridization-fish-327] </ref><br />
|-bgcolor="#FE1C5EA"<br />
| It does not fully access all chromosomes (only ~ 12)<br />
|-bgcolor="#FE1C5EA"<br />
| Analysis of results is dependent upon the dot quality impacted by hybridisation efficiency or the camera sensitivity <ref><pubmed>17970921</pubmed></ref><br />
|-bgcolor="#FE1C5EA"<br />
| some studies indicate that using FISH on a day-3 embryo biopsy decreases the rate of live births <ref><pubmed>26168107</pubmed></ref><br />
|}<br />
<br />
===Array Comparative Genomic Hybridisation (aCGH)===<br />
====Description====<br />
<br />
aCGH also known as Microarray analysis efficiently scans the entire genome for chromosomal imbalances. CGH was initially developed to detect the number of changes in a solid tumor mass. It uses 2 genomes comparing the sample to the control, with each labeled in a different fluorescent dye<ref name="PMID1876176"><pubmed>1876176</pubmed></ref>. Earlier CGH techniques were limited by the resolution of the imaging <ref> Lichter, P., et al. Comparative genomic hybridization: Uses and limitations. Seminars in Hematology 37, 348–357 (2000)</ref> , these initial limitations were overcome by using Microarrays in conjunction with CGh to improve the resolution of the imaging, Array Comparative Genomic Hybridisation (aCGH). This method compares sample and control microarrayed slides containing small segments of DNA (probes). <ref> Lucito, R., et al. Representational oligonucleotide microarray analysis: A high-resolution method to detect genome copy number variation. Genome Research 13, 2291–2305 (2003) </ref> the Probes used will vary according from the small (25-85 base pairs) oligonucleotides manufactured to highlight different target sequences, to the very large genomic clones (80,000- 200,00 base pairs), and as these are significantly smaller than the traditional metaphase chromosomes used for CGH, generating a higher resolution of image. <ref name="PMID22467166"><pubmed>22467166</pubmed></ref>.aCGH is used as a diagnostic tool for prenatal detection f chromosomal abnormalities <ref name="PMID19012303"><pubmed>19012303</pubmed></ref>.<br />
<br />
<br />
====Procedure====<br />
<ref> Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432] </ref><br />
The sample is obtained (skin, blood or fetal cells) and DNA is obtained. <br />
As a part of PGD fetal cell samples are collected from; the fertilized egg polar bodies, the blastomere (day 3 embryo) or the blastocyst/tropoectoderm stage (day 5 embryo).<br />
Sample DNA is labeled with one fluorescent dye, and the control DNA is labeled with a different colored fluorescent dye. the control DNA is used as the base point of reference. <br />
heated and denatured single DNA strands then hybridize to their complementary single strand probes, which are then combined and applied to a microarray and the results are run through a computer program and a digital imaging system is used to quantify the results( fluorescent intensities of the labeled probes). <br />
<br />
[[File:aCGH.jpg|thumb|right|'''aCGH''' checks the entire genome for chromosomal imbalances, by comparing control and a sample slides contatining small segements of DNA sample microarrayed slides small segments of DNA. Illustrated by student z5020317 and adapted from <ref> NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation. retrieved from [http://www.phgfoundation.org/file/5237/]</ref> <ref>Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432]</ref>]]<br />
<br />
The fluorescent ratio and the hybridization signal at different locations on the genome of the control DNA are used to identify any variances present in the sample DNA. aCGH facilitates the clinical diagnosis of submicroscopic chromosomal duplication, deletion and rearrangements indicative of chromosomal disorders such as trisomies 1-22and specific sex linked disorders. <br />
Duplications in the DNA are displayed by the computer program as spikes/ peaks over an established threshold and deletions in DNA are displayed by the computer program as spikes/ toughs beneath this threshold <br />
<br />
{|class="wikitable" align="center"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="12" |'''Advantages''' <br />
|-bgcolor="FFFAFA"<br />
| Multiple applications: prenatal genetic diagnosis, cancer diagnosis, <ref name="PMID20193845"><pubmed>20193845</pubmed></ref> genetic screening for developmental delay (learning disabilities) <ref name="PMID17309648"><pubmed>17309648</pubmed></ref>. or congenital anomalies that are suspected to be genetic in origin <ref>NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation . retrieved from [http://www.phgfoundation.org/file/5237/]</ref><br />
|-bgcolor="FFFAFA"<br />
| trace represents all chromosomes present in the human genome chromosomes 1-22 and the X & Y chromosomes, and therefore is the most accurate method for testing whole embryo aneuploidy<br />
|-bgcolor="FFFAFA"<br />
| aCGH has been extensively tested, and Validated, and is now used world wide.<br />
|-bgcolor="FFFAFA"<br />
| Detects submicroscopic alterations<br />
|-bgcolor="FFFAFA"<br />
| Detects deletions and additions and rearrangements as well as amplification, of the WHOLE genome, simultaneously.<br />
|-bgcolor="FFFAFA"<br />
| Used as a diagnostic tool for prenatal detection of chromosomal abnormalities <ref name="PMID22034057"><pubmed>22034057</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Provides high resolution genomewide screening of segmental genomic copy number variations<br />
|-bgcolor="FFFAFA"<br />
| Very accurate when used in conjunction with FISH<br />
|-bgcolor="FFFAFA"<br />
| Alone is more reliable and in detecting chromosomal abnormalities, with a higher implantation success rate, than FISH <ref name="PMID20494259"><pubmed>20494259</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Allows an in depth research focus upon specific types of rearrangements within selected chromosomal regions, a recent particular area of interest is subtelomeric and pericentromeric rearrangements<br />
|-bgcolor="FFFAFA"<br />
| Reduces the risk of failed implantation and miscarriage, improving the chance of a healthy baby <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|-bgcolor="DDCEF2"<br />
| rowspan="9" |'''Disadvantages'''<br />
|-bgcolor="FFFAFA"<br />
| Translocations and inversions of DNA are not detected<br />
|-bgcolor="FFFAFA"<br />
| Limited ability diagnosing specific polyploidies such as triploidy <ref> Unique, Rare Chromosome Disorder Support Group (2013) Microarray-based Comparative Genomic Hybridiation (array CGH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/other/array%20cgh%20ftnw.pdf] </ref><br />
|-bgcolor="FFFAFA"<br />
| Will not detect mosaicism detection <20% (cultures where >1 of 5 cells are trisomy 12)<br />
|-bgcolor="FFFAFA"<br />
| Will not detect balanced chromosomal rearrangement<br />
|-bgcolor="FFFAFA"<br />
| Will not detect duplications or deletions <80kb<br />
|-bgcolor="FFFAFA"<br />
| Will not detect point mutations within genes <ref>Washington department of education (CGH- FAQ for physicians. Signature Genomic LAboratories, LLC. Retrieved from [https://depts.washington.edu/dbpeds/Lab%20Tests/SignatureCGH-physician_FAQ.pdf]</ref><br />
|-bgcolor="FFFAFA"<br />
| will not detect chromosomal position of genomic gains<br />
|-bgcolor="FFFAFA"<br />
| Will not detect loos of heterozygosity (LOH) or Absence of heterozygosity (AOH) <ref>WiCell Research Institute Inc. (2012) Comparative Genomic Hybridization Microarray. <br />
retrieved from [http://www.wicell.org/home/cytogenetic-services/cgh-microarray/array-comparative-genomic-hybridization-acgh.cmsx]</ref><br />
|}<br />
<br />
===Next Generation Sequencing===<br />
====Description====<br />
The development and advances within ART in the past 20 years, as well as the increasing popularity of IV, has lead to an influx of new technologies developed to screen embryos for chromosomal anomalies, which are covered by the umbrella term of Next generation Sequencing (NGS). NGS is a general term used to describe all of the new and emerging screening techniques currently being introduced and used as part of PGD for IVF . NGS screens for single gene disorders as well as conducting extensive and very comprehensive chromosome diagnosis by sequencing, counting, and accurately assembling millions of DNA reads, simultaneously. <ref name="PMID23499002"><pubmed>23499002</pubmed></ref> There is a movement for NGS to replace the other limited testing techniques and be used as the standard. <br />
====Procedure====<br />
Samples are collected from either blastomere or the blastocyst/tropoectoderm and processed for analysis by a computer system. <br />
The methodology of each process is unique to the technique being used. <br />
<br />
{|class="wikitable" align="center"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="14" |'''Advantages''' <br />
|-bgcolor="FFFAFA"<br />
| Cheaper<br />
|-bgcolor="FFFAFA"<br />
| Opens new diagnostic possibilities<br />
|-bgcolor="FFFAFA"<br />
| Accurately tests all 24 chromosomes<br />
|-bgcolor="FFFAFA"<br />
| Tests for the presence of monogenic diseases of known genetic background<br />
|-bgcolor="FFFAFA"<br />
| Reduces the number of biopsies required for diagnosis<br />
|-bgcolor="FFFAFA"<br />
| Higher detection rate of small translocations<br />
|-bgcolor="FFFAFA"<br />
| Highly accurate is testing for compound point mutations, chromosomal duplication, deletions and insertions <ref name="23312231"><pubmed>23312231</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| It accurately detects chromosomal aneuploidy and unbalanced rearrangement <ref name="PMID25685330"><pubmed>25685330</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Higher detection rate of small translocations<br />
|-bgcolor="FFFAFA"<br />
| NGS single gene disorder screenings can conducted in conjunction with PCR comprehensive chromosomal screening<br />
|-bgcolor="FFFAFA"<br />
| Reduces human error <br />
|-bgcolor="FFFAFA"<br />
| Better detects the presence of mosaicism<br />
|-bgcolor="FFFAFA"<br />
| Work well in conjunction with CGH and aCGH as part of PGD, improving the chances of IVF. <ref> Morris, R. S. (2015 ) Next generation sequencing for PCG|PGS|CCS. IVF1 retrieved from [http://www.ivf1.com/next-generation-sequencing for-pgd] </ref><br />
|-bgcolor="DDCEF2"<br />
| '''Disadvantages''' <br />
|-bgcolor="FFFAFA"<br />
| There are limited information available to clinical applications of NGS <ref><pubmed>26100406</pubmed></ref><br />
|}<br />
<br />
==Diagnosis==<br />
There are a large amount of diseases that PGD can apply to, below are descriptions of the diseases that PGD are more commonly used for. Utilization of Diseased Cell Lines<br />
===Cystic Fibrosis===<br />
Cystic fibrosis is a single gene disorder. It is autosomal recessive and involves mutations in the cystic fibrosis transmembrane conductance regulator (CTFR) gene. The CTFR gene is normally responsible for the decrease in chloride and the transport of bicarbonate in epithelial cells thus playing a major physiological role. In PGD procedures, identification of the gene is assisted by microsatellite markers that have similar composition to the CTFR gene itself. Biopsy of two cells at the blastocyst stage is recommended if markers are not available. There are many variations of cystic fibrosis the most common being P.Phe508del <ref name="PMID26014425"><pubmed>26014425</pubmed></ref>.<br />
===Duchenne Muscular Dystrophy ===<br />
Duchenne Muscular Dystrophy is an X-linked recessive disease. It involves the Xp21 gene where majority of the mutations are chromosomal deletions with a smaller percentage resulting from duplications <ref name="PMID18359022"><pubmed>18359022</pubmed></ref>.<br />
<br />
===Autosomal Recessive MEckel-Gruber Syndrome===<br />
Autosomal recessive genetic defect caused by the TMEM67 gene. It results in cystic dysplasia of the kidneys with fibrotic change in the liber and occipital encephalocele. Other malformations could also be present in the central nervous system. In PGD whole genome amplification of single blastomeres are taken to identify the gene, this is also coupled with PCR techniques. Maternal plasma can also be extracted for PGS. <ref><pubmed>24039893</pubmed></ref> <br />
===β – Thalassemia=== <br />
β – Thalassemia is known as the most common type of autosomal recessive inherited disorder among haemoglobinopathies. It involves the adult β-globin gene and is associated with the absent or decreased expression of the gene. This is commonly caused by a single nucleotide change in the gene. PGD has been used successfully worldwide to identify the β-globin gene where its application is usually performed on a single blastomere or polar body <ref name="PMID19064120">19064120</pubmed></ref>.<br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
! Applicable diseases for PGD <ref>Genoma Group (2014). Retrieved September 18th, 2015, from http://www.preimplantationgeneticdiagnosis.it/genetic-diseases-diagnosed-by-pgd.htm </ref>, <ref>Genesis Genetics (2015). Retrieved September 18th, 2015, from http://genesisgenetics.org/pgd/what-we-test-for/</ref>, <ref>Human Fertilisation & Embryology Authority (2015). Retrieved Septembr 18th, 2015, from http://guide.hfea.gov.uk/pgd/</ref><br />
|-<br />
| '''Disease'''<br />
| '''Involved Genes'''<br />
|-<br />
| 5 Alpha Reductase Deficiency (5ARD)<br />
| SRD5A2 <br />
|-<br />
| Achondroplasia<br />
|FGFR3 <br />
|-<br />
| Acute Intermittent Porphyria <br />
| ALAD, ALAS2, CPOX, FECH, HMBS, PPOX, UROD, or UROS<br />
|-<br />
| Adrenoleukodystrophy (Adrenomyeloneuropathy)<br />
| ABCD1 <br />
|-<br />
| Agammaglobulinaemia (x-linked) <br />
|BTK <br />
|-<br />
| Agammaglobulinemia Bruton Tyrosine Kinase (BTK) <br />
|BTK <br />
|-<br />
| Aicardi Goutieres Syndrome 1 (AGS1) <br />
|TREX1, RNASEH2A, RNASEH2B, RNASEH2C, SAMHD1<br />
|-<br />
| Alagille Syndrome<br />
|JAG1 or NOTCH2<br />
|- <br />
| Alpers-Huttenlocher Syndrome <br />
|POLG <br />
|-<br />
| Alpha-1-antitrypsin deficiency <br />
|SERPINA1 <br />
|-<br />
| Alpha-Mannosidosis<br />
| MAN2B1 <br />
|-<br />
| Alpha Thalassemia <br />
|HBA1 or HBA2 <br />
|-<br />
| Alports Syndrome<br />
|COL4A3, COL4A4, COL4A5<br />
|-<br />
| Alzheimer's Disease - early onset (Type 3 and 4) <br />
|APP, PSEN1, or PSEN2<br />
|-<br />
| Amyotrophic Lateral Sclerosis 1 (ALS1) <br />
|C9orf72, SOD1, TARDBP, FUS, ANG, ALS2, SETX, VAPB <br />
|-<br />
| Argininosuccinic Aciduria <br />
| ASL<br />
|-<br />
| Arrhythmogenic Right Ventricular Cardiomyopathy/ Dysplasia (ARVC/D)<br />
| DSG2; DSP; PKP2<br />
|-<br />
| Ataxia Telangiectasia<br />
| ATM<br />
|-<br />
| Autosomal Recessive Meckel-Gruber Syndrome<br />
| TMEM67<br />
|-<br />
| Bardet-Biedl Syndrome (BBS)<br />
| BBS1; BBS10<br />
|-<br />
| Barth Syndrome<br />
| TAZ<br />
|-<br />
| Beta Thalassaemia<br />
| HBB<br />
|-<br />
| Birt-Hogg-Dubé Syndrome<br />
| FLCN<br />
|-<br />
| Breast Ovarian Cancer Familial Susceptibility (BRCA2)<br />
| BRCA1; BRCA2<br />
|-<br />
| Canavan Disease <br />
| ASPA<br />
|-<br />
| Carnitine-Acylcarnitine Translocase Deficiency <br />
| SLC25A20<br />
|-<br />
| Cerebral Arteriopathy with Subcortical Infarcts & Leukoencephalopathy (CADASIL)<br />
| NOTCH3<br />
|-<br />
| Cerebral Cavernous Malformation<br />
| CCM1<br />
|-<br />
| Charcot-Marie-Tooth Disease<br />
| GJB1; MPZ; NEFL; PMP22<br />
|-<br />
| CHARGE Syndrome<br />
| CHD7<br />
|-<br />
| Cherubism<br />
| SH3BP2<br />
|-<br />
| Choroideremia<br />
| CHM<br />
|-<br />
| Chronic Granulomatous Disease<br />
| CYBB; NCF1<br />
|-<br />
| Ciliary Dyskinesia<br />
| DNAH5<br />
|-<br />
| Citrullinemia<br />
| ASS1<br />
|-<br />
| Cleidocranial Dysplasia<br />
| RUNX2<br />
|-<br />
| Cockayne Syndrome<br />
| ERCC6<br />
|-<br />
| Congenital Adrenal Hyperplasia<br />
| CYP21A2<br />
|-<br />
| Congenital Cataracts<br />
| GJA8; VSX2<br />
|-<br />
| Congenital Diarrhea, Syndromic<br />
| SPINT2<br />
|-<br />
| Congenital Disorders of Glycosylation (CDG)<br />
| ALG1; ALG6; CDG1C; DOLK; PMM2<br />
|-<br />
| Cornelia de Lange Syndrome <br />
| NIPBL<br />
|-<br />
| Craniosynostosis<br />
| TWIST1<br />
|-<br />
| Crouzon Syndrome<br />
| FGFR2<br />
|-<br />
| Cysteinyl Leukotriene Receptor 1 Deficiency <br />
| CYSLTR1<br />
|-<br />
| Cystic Fibrosis<br />
| CFTR<br />
|-<br />
| Diamond –Blackfan Anemia <br />
| RPS19<br />
|-<br />
| Duchenne Muscular Dystrophy <br />
| DMD<br />
|-<br />
| Dyskeratosis congenita (Male embryos only)<br />
| DKC1<br />
|-<br />
| Ectodermal dysplasia (Hypohidrotic)<br />
| EDA; EDA1; GJB6; IKBKG<br />
|-<br />
| Familial Adenomatous polyposis coli (FAP)<br />
| APC<br />
|-<br />
| Familial Dysautonomia<br />
| IKBKAP<br />
|-<br />
| Fanconi Anemia <br />
| FANCA; FANCC; FANCD2; FANCF; FANCG; FANCJ<br />
|-<br />
| Fragile X Syndrome (FRAX)<br />
| FMR1<br />
|-<br />
| Galactosemia <br />
| GALT<br />
|-<br />
| Gangliosidosis<br />
| GLB1<br />
|-<br />
| Glanzmann Thrombasthenia <br />
| ITGA2B<br />
|-<br />
| Glutaric Acidemia (aciduria)<br />
| GCDH <br />
|-<br />
| Glycogen Storage Disease <br />
| G6PC; GAA; SLC37A4<br />
|-<br />
| Haemophilia A<br />
| F8<br />
|-<br />
| Haemophilia B<br />
| F9<br />
|-<br />
| Hereditary Nonpolyposis Colorectal Cancer: Lynch Syndrome<br />
| MLH1; MSH2; MSH6<br />
|-<br />
| Holt Oram Syndrome<br />
| TBX5<br />
|-<br />
| Huntington Disease<br />
| HD<br />
|-<br />
| Hydrocephalus<br />
| L1CAM<br />
|-<br />
| Ichthyosis <br />
| ABCA12; STS<br />
|-<br />
| Incontinentia Pigmenti (IP)<br />
| NEMO<br />
|-<br />
| Joubert Syndrome 5<br />
| INPP5E<br />
|-<br />
| Krabbe Disease<br />
| GALC<br />
|-<br />
| Leber Congenital Amaurosis (LCA)<br />
| CEP290; GUCY2D<br />
|-<br />
| Leigh Syndrome (Infantile Subacute Necrotising Encephalopathy)<br />
| LRPPRC<br />
|-<br />
| Lesch Nyan Syndrome<br />
| HPRT1<br />
|-<br />
| Leukocyte Adhesion Deficiency (Type I)<br />
| ITGB2<br />
|-<br />
| Li-Fraumeni Syndrome<br />
| TP53<br />
|-<br />
| Macular Dystrophy Retinal <br />
| VMD2<br />
|-<br />
| Maple Syrup Urine Disorder (MSUD)<br />
| BCKDHB<br />
|-<br />
| Marfan Syndrome <br />
| FBN1<br />
|-<br />
| Menkes Syndrome<br />
| ATP7A<br />
|-<br />
| Mitochondrial DNA Depletion Syndrom <br />
| POLG; RRM2B; SUCLA2; TK2<br />
|-<br />
| Mucolipidosis type II<br />
| GNPTAB<br />
|-<br />
| Multiple Endocrine Neoplasia<br />
| MEN1; MEN2A; MEN2B<br />
|-<br />
| Multiple Exostoses<br />
| EXT1; EXT2 <br />
|-<br />
| Myotubular myopathy<br />
| MTM1 <br />
|-<br />
| Nail-Patella Syndrome<br />
| LMX1B<br />
|-<br />
| Neurofibromatosis Type 1<br />
| NF1<br />
|-<br />
| Neurofibromatosis Type 2 <br />
| NF2<br />
|-<br />
| Noonan Syndrome<br />
| KRAS, PTPN11; SOS1<br />
|-<br />
| Norrie Disease<br />
| NDP<br />
|-<br />
| Ocular Albinism <br />
| GPR143<br />
|-<br />
| Oculocutaneous Albinism <br />
| OCA2; TYR <br />
|-<br />
| Oculodentaldigital Dysplasia<br />
| GJA1<br />
|-<br />
| Optic Atrophy<br />
| OPA1<br />
|-<br />
| Ornithine Transcarbamylase Deficiency <br />
| OTC<br />
|-<br />
| Osteogenesis imperfeca <br />
| COL1A1; COL1A2<br />
|-<br />
| Osteopetrosis <br />
| CLCN7; OSTM1; TCIRG1<br />
|-<br />
| Pachyonychia Congenita <br />
| KRT16; KRT6A<br />
|-<br />
| Pancreatitis, Hereditary<br />
| PRSS1 <br />
|-<br />
| Papillorenal syndrome <br />
| PAX2<br />
|-<br />
| Phenylketonuria <br />
| PAH <br />
|-<br />
| This table does not cover the complete list of diseases that PGD can be applied to.<br />
|}<br />
<br />
==Laws & Legal status==<br />
<br />
{| class="wikitable" <br />
|-bgcolor="DDCEF2"<br />
|'''Country'''<br />
|'''Legislation'''<br />
|-<br />
| Australia<br />
| PGD is currently used to detect serious genetic conditions to improve the outcome of Assisted Reproductive Technologies (ART). In very rare cases it may be used to select an embryo with compatible tissue for a sibling who has a life-threatening disease where other means of treatment is unavailable. This is with the conditions that the use of PGD will not affect the welfare and interests of the child to be born. The parents must also receive adequate counselling and have full understanding of the procedures of PGD. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"> National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art</ref><br />
The use of PGD for sex-selection is prohibited with the exception of reducing the risk of the transmission of serious sex-linked genetic conditions. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"/><br />
|-bgcolor="FFFAFA"<br />
| Brazil<br />
| The laws regarding PGD in Brazil are not strictly regulated. They are vague and there is limited information surround the activities of assisted reproduction in general in the country <ref name="PMID25493379"><pubmed>25493379</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| Czech Republic<br />
| The laws in the Czech Republic allow those with a “defined indication in order to exclude risk of serous genetically conditioned disease and defects with embryos before they are implanted into the cavity of the uterus”. Couples that undergo any assisted reproductive treatment including PGD have to be married. Sex-selection is illegal except in regards to serious sex-linked genetic diseases <ref name="PMID24777348"><pubmed>24777348</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| Greece<br />
| In Greece, ART is open to those up to the age of 50 with written consent. It can only be used if a medical necessity is present such as the susceptibility of serious hereditary diseases. Sex selection is banned apart from cases of sex-linked diseases and sexually transmitted diseases <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| India<br />
| In India there is a cultural preference for boys thus the Prenatal Diagnostic Techniques (Regulation and Prevention of Misuse) Act was introduced in 1994. This law limits the use of PGD for sex determination except in cases of specific congenital diseases. These laws however are not strictly enforced. <ref>World Health Organisation (2015) Gender and Genetics Retrieved on October 21st 2015 from:http://www.who.int/genomics/gender/en/index4.html</ref><br />
|-bgcolor="FFFAFA"<br />
| Portugal <br />
| ART is only available to those who are married or have a similar type of relationship for at least two years. The couples cannot be of the same sex and must be at least 18 years of age. Sex selection is illegal except in cases of sex-linked diseases. The use of PGD is illegal if the predictive value of genetic tests are very low <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| Spain<br />
| PGD can be applied to “serious hereditary diseases not amenable to postnatal curative treatment” and “detection of other abnormalities which may compromise the viability of the pre-embryo”. If PGD is to be used for any other purpose authorisation must be acquired <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| Sweden <br />
| The use of PGD is strictly regulated and couples must achieve authorisation of the National Board of Health and Welfare. It can only be used it can only be used if the child is at risk to inheriting a serious chromosomal or monogenetic disease. It cannot be used for selection of specific characteristics <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| United Kingdom<br />
| Those involved with carrying out the IVF treatment must have a license from the Human Fertilisation and Embryology Authority (HFEA). Only embryos that are approved by the HFEA can be implanted where the embryonic nuclear or mitochondrial DNA cannot be altered with the exception of preventing mitochondrial diseases <ref name="PMID24777348"/>. <br />
|}<br />
<br />
==Future/Current Research==<br />
===Noninvasive Preimplantation Genetic Testing without Embryo Biopsy===<br />
Different parameters of gametes, zygotes, embryos (“vacuoles in sperm heads, spindle position in mature oocytes, cleavage intervals of zygote, and embryo developmental dynamics”) may correlate with aneuploidy rates. This knowledge may be applied in potential noninvasive preimplantation diagnostic methods. Several methods have been proposed and are currently further researched<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Sperm Selection====<br />
Intracytoplasmic morphologically selected sperm injection (IMSI) is common procedure in IVF treatment to improve fertilization rates in patients with poor semen quality. In addition, studies have found that IMSI improves embryo development and that spermatozoa with large vacuoles in their heads correlate with increased aneuploidy rates and disturbed chromosomal structures. Thus, selecting spermatozoa based on morphological hallmarks may decrease aneuploidy rates in the fertilized embryos. As with polar body biopsies, however, this approach will solely be applicable if evidence for severe male detrimental contribution is given<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Blastocoel Fluid Extraction====<br />
In addition, a less invasive retrieval of material for diagnosis could include the extraction of the blastocoel fluid. The cavity of the blastocyst, lined by the trophectoderm, is filled with this blastocoel fluid, which contains metabolites of both trophectoderm and inner cell mass origin. The retrieval does not require a biopsy but merely a small opening to extract the fluid and, thus, causes less harm to the embryo. Multiple studies have applied this method<ref name="PMID22020776"><pubmed>22020776</pubmed></ref> <ref name="PMID23148560"><pubmed>23148560</pubmed></ref> and it may in the future become of clinical relevance.<br />
<br />
<br />
[[File:Aspiration_of_the_Blastocoel_Fluid.jpeg|thumb|Aspiration of the Blastocoel Fluid using a ICSI pipette<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.]]<br />
<br />
<br />
Next to metabolites, the blastocoel fluid can contain DNA. Studies have shown that genomic DNA is present in about 90% of the blastocoel fluid samples tested. Typically the fluid is removed with an ICSI pipette from a day five blastocyst through its mural trophectoderm until the blastocyst fully collapses around the embryo. Several concerns regarding this method in a clinical setting have been raised. The collected DNA may be contaminated by the culture media that contains DNA fractions. The DNA may also be least representative of the actual embryos genome as the DNA may originate from abnormal or degenerated cells. Even though labelled noninvasive, the blastocyst still undergoes manipulation to some degree which may affect its viability. Thus, more research is required until this method can evolve from research to clinical use<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
====Proteomics====<br />
The protein secretome of blastocysts may be representative of its chromosome constitution Recent studies have found biomarkers such as lipocalin-1, interleukin-10, tumor necrosis factor, stem cell factor, and chemokine ligand 13 to be differently secreted by aneuploid blastocyst than by euploid ones. The most significant biomarker appears to be interleukin-10. Paired with novel proteomic technologies and mass spectrometry this knowledge when extended may contribute to a new invasive preimplantation genetic diagnosis method<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Embryo Morphology====<br />
Using time lapse imaging the embryo’s morphology can be closely observed and potential aneuploidy characteristics detected. Such characteristics may include the time of division to five cells, the time between the division from three to four cells, and the duration of the division from one to two and subsequently to three. In addition, the morphological quality of ICM an TE has been positively associated with aneuploidy or euploidy prognosis<ref name="PMID26246880"><pubmed>26246880</pubmed></ref>. These may give rise to an embryo quality screening prior to implantation<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
==References==<br />
<br />
<references/><br />
<br />
<br />
{{StudentPage2015}}</div>Z5017878https://embryology.med.unsw.edu.au/embryology/index.php?title=2015_Group_Project_6&diff=2070272015 Group Project 62015-10-21T07:33:39Z<p>Z5017878: </p>
<hr />
<div>{{ANAT2341Project2015header}}<br />
<br />
<br />
=Preimplantation Genetic Diagnosis and Screening=<br />
==Introduction==<br />
Preimplantation genetic diagnosis (PGD) and screening (PGS) are reproductive options for couples with known family histories of genetic disease or couples undergoing IVF procedures due to infertility issues. PGD can diagnose many genetic disorders caused by known chromosomal abnormalities (number and/or structure) or single gene mutations, and, thus decrease the risk of termination of pregnancy or miscarriages and enable such couples to have an unaffected child<ref name="PMID24907939"><pubmed>24907939</pubmed></ref>. Through major improvements in PGD/S and general laboratory technology, the testing for abnormalities in fetuses has shifted from prenatal diagnosis during the first 2 trimesters <ref> Blackburn, S.L. (2003) '''Maternal, Fetal & Neonatal physiology: a Clinical perspective''' (2nd ed.). Seattle: Saudners </ref>, testing for overall fetal growth, complications of pregnancy, and birth defects<ref> Sadler T.W.(2012) '''Langman's Medical Embryology''' (12th ed.) Philadelphia: Lipincott, Wiliams & Wilkins, a Wolters Kluwer Business </ref>, to an embryonic focus especially in advancements in Artificial Reproductive Technologies (ART)<ref><pubmed>20638568</pubmed></ref>. In 1990 PGD for a recessive X-linked disease resulted in the first live birth<ref><pubmed>2330030</pubmed></ref> and has since been incorporated in clinical routine and applied for a variety of genetic diseases, such as sickle cell anemia, thalassemia, or cystic fibrosis<ref name="PMID24907939"/>.<br />
[[File:Preimplantation Genetic Diagnosis Procedure.jpeg|700px|thumb| Simplified steps for PGD<ref name="PMID24907939"/>]]<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=0e-79qKllqk</html5media><br />
|-<br />
| Preimplantation Genetic Diagnosis<ref>IVF Florida (2011, December 11) IVF Florida - South Florida Fertility Specialists - Pre-Implantation Genetic Diagnosis [Video file]. Retrieved from https://www.youtube.com/watch?v=0e-79qKllqk</ref><br />
|}<br />
<br />
==History==<br />
The advances in reproductive technology during the second half of the 20th century, led to PGD's first clinical application in 1990 <ref>Harper, J. (n.d.). The history of PGD. Lecture. UCL Centre for PG&D and CRGH.University College London</ref>.<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
|Year<br />
|<br />
|- bgcolor="FFFAFA"<br />
| '''1967''' <br />
|First PGD on rabbit blastocysts (Gardner& Edwards) <ref name="PMID6036172"><pubmed>6036172</pubmed></ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1986''' <br />
|First Cleavage Biopsy (Wilton & Trounson)<ref>Wilton, L. J., & Trounson, A. O. (1986). Viability of mouse embryos and blastomeres following biopsy of a single cell. In Proceedings of the 18th Annual Conference of the Australian Society for Reproductive Biology, Brisbane, Australia.</ref><br />
|- bgcolor="FFFAFA"<br />
|'''1987''' <br />
|First Blastocyst Biopsy (Muggleton-Harris, Monk, Rawlings, & Whittingham)<ref name="PMID3372699"><pubmed>3372699</pubmed></ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1988''' <br />
|First Polar Body Biopsy (Yury Verlinksy)<ref> Verlinsky, Y., Pergament, E., Andresen, P., Enriquez, G., & Strom, C. (1989). Genetic analysis of polar body DNA: A new approach to preimplantation genetic diagnosis. Am J Hum Genet, 45(4), A272.</ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1990''' <br />
|First Clinical PGD using PCR testing for X-linked (Handyside, Kontogianni, Hardy, & Winston)<ref name="PMID2330030"><pubmed>2330030</pubmed></ref> <br />
|} <br />
==Preimplantation Genetic Diagnosis==<br />
Preimplantation genetic diagnosis (PGD) is used to test the genetic makeup of embryos to detect single gene disorders, chromosomal abnormalities and mitochondrial disorders. It also has applications in gender selection for diseases with unequal gender distributions <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Some diseases commonly involved with PGD include cystic fibrosis, spinal muscular atrophy and beta – thalassaemia <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press.">Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press</ref> <ref name="PMID17823145"><pubmed>17823145</pubmed></ref>. It was first used in the United Kingdom in the 1980s of arenoleucodystrophy and primarily focusing on sex- linked disorders <ref name="PMID17823145"/><ref name="PMID23150080"><pubmed>23150080</pubmed></ref>. PGD is now capable of detecting single cell defects (molecular) and chromosomal disorders resulting from the inversion, translocation or deletion of chromosomes (cytogenic) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>,<ref name="PMID11325751"><pubmed>11325751</pubmed></ref>. PGD can be applied to the embryo at different stages. That is on polar bodies, blastomeres or blastocyst <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>.<br />
Depending on the type of genetic disorder, PGD utilises different methods of genetic testing. These include Fluorescence in situ hybridisation (FISH) which is used for sex – linked disorders and detects chromosomal rearrangements <ref name="PMID11325751"/><ref name="PMID17876073"><pubmed>17876073</pubmed></ref> and Embryo halotyping which allows the identification of chromosomes causing the inherited disorder through knowledge of the pattern of closely linked markers <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. Polymerase chain reaction (PCR) is also widely used to detect molecular abnormalities <ref name="PMID11325751"/>.<br />
PGD is tightly regulated and supported by large organisations namely The American Society for Reproductive Medicine, The European Society for Human Reproduction and Embryology (ESHRE), The European Society of Human Genetics and the Preimplantation Genetic Diagnosis International Society <ref name="PMID25500181><pubmed>25500181</pubmed></ref>.<br />
===Sex-linked disorders===<br />
The determination of a disease as gender specific usually correlates with the presence or absence of specific genes such as SRY on the Y chromosome. It is known that females have two X chromosomes and males have an X and a Y chromosome where abnormalities are more prevalent on the X chromosome. PGD can be used for sex selection where only male embryos are transferred to reduce the chance of inheriting X-linked disorders. However, this does not completely eradicate the problem as male embryos remain susceptible to inheriting an affected X chromosome. Sex determination is only used when the specific mutation is unknown and has yet to be discovered <ref name="PMID24866878"><pubmed>24866878</pubmed></ref>.<br />
===Single gene defects===<br />
Single gene defects can be dominant, recessive, autosomal or X-linked. They are commonly diagnosed using PCR and although the PCR available today is complex and capable of combatting a large range of disease the development of new protocols has been proven to be difficult due to the small DNA sample available <ref name="PMID26168107"><pubmed>26168107</pubmed></ref><br />
===Mitochondrial disorders===<br />
Mitochondrial disorders also known as oxidative phosphorylation disorders arise from mutations in the nuclear DNA or mitochondrial DNA <ref name="PMID26312584"><pubmed>26312584</pubmed></ref>. They pose as a problem because they are unrecognisable until the mutations in the cell reach a detrimental level <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Mitochondrial disorders cause miscarriages and stillbirths as well as death in children and young adults. The effects can either be contained in a single organ or more commonly involve multiple organ failure where organs with high energy demands such as the brain, liver muscle and heart and heavily influenced. They are usually occur spontaneously or result from inheritance from the mother. Since mitochondria are solely inherited from the mother oocyte donations have been used as a solution to combat mitochondrial disorders. Additionally, there has been an increasing use in PGD where embryos that stay under the given threshold of 18% gene-mutations are allowed to be transferred and result in normal development. New technology in the areas of nuclear gene transfer and genome editing are also being experimented with <ref name="PMID26312584"/>. <br />
===Chromosomal disorders===<br />
Chromosomal disorders can be reciprocal, Robertsonian translocations, inversions, deletions and insertions <ref name="PMID26168107"/>. . Data from ESHRE collected between 2010 and 2011 has shown that the most common chromosomal abnormality confronted in PGD are reciprocal chromosomal abnormalities <ref name"PMID26071418"><pubmed>26071418</pubmed></ref>. PGD has also been used successfully for Robertsonian translocations (RT), a type of structural translocation. Children who carry RT are phenotypically normal, however in their later years it is found that they will suffer from infertility and repeated miscarriages due to the high frequency of abnormal embryos <ref name="PMID22081077"><pubmed>22081077</pubmed></ref>. PCR and FISH are the two main techniques used for chromosomal disorders. To be able to conduct the examinations the cells are required to be at the metaphase stage <ref name="PMID26168107"/>. <br />
==Preimplantation Genetic Screening==<br />
Prenatal Genetic Screening (PGS) involves an array of methods or ideas that aim to segregate embryos that have genetic flaws and those that are healthy <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. The occurrence of aneuploidy is high around the stages of early embryonic development and they are the most common cause if miscarriages and congenital birth defects <ref name= "PMID26085841"><pubmed>26085841</pubmed></ref>. They have little effect on the morphology of the embryo making them difficult to identify thus identification heavily relies on genetic testing <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. <br />
Genetic sampling is most commonly conducted using Microarray Comparative Genomic Hybridisation (aCGH) as well as FISH, Quantitative PCR and Single Nucleotide Polymorphism (SNP) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. These methods collectively aim to assess numeral and structural chromosomal errors <ref name= "PMID26085841"/>. Studies have also introduced Next- Generation Sequencing (NGS) <ref name= "PMID26085841"/> and Whole Genome Amplification used to screen imbalances in the complete 24-chromosomes <ref name="PMID25953353"><pubmed>25953353</pubmed></ref><br />
Statistics from ESHRE have shown that the most common indications for PGS is advanced age, followed by repeated implantation failure or recurrent miscarriage and male infertility <ref name="PMID26071418"><pubmed>26071418</pubmed></ref>.<br />
====Indications====<br />
A low percentage of structural abnormalities in chromosomes are responsible for the cause of miscarriages. Despite this, they are the most prevalent type of chromosomal abnormality accounted for in PGD <ref name="PMID20638568"/>. The presence of specific gene cycles, initiation of embryonic protein synthesis and evident physiological development are all indicative of a successful in vitro fertilisation procedure <ref name="PMID11576737"><pubmed>11576737</pubmed></ref>. To eliminate further errors from occurring during the PGD procedure it is recommended to undertake further prenatal testing such as amniocentesis in the later stages <ref name="PMID20638568"/>. <br />
=====Advanced maternal age=====<br />
Data provided by the ESHRE has shown that the mean age of women undergoing PGS is 39 years <ref name="PMID26071418"/>. Women of advanced age have been shown to have a lower rate of pregnancies reaching childbirth <ref name="PMID18583331"><pubmed>18583331</pubmed></ref>. The highlighted concern revolves around the increased occurrence of aneuploidy following maternal age. The optimal age range for the lowest aneuploidy incidence was found to be between 27 to 37 years of age (6%) then progressively higher in women aged up to 42 (33%) and most common in those 44 and above (53%) <ref name="PMID24355045"><pubmed>24355045</pubmed></ref>. <br />
=====Recurrent pregnancy loss / IVF failure=====<br />
Recurrent pregnancy loss is defined as three or more IVF failures after cumulative transfer of more than 10 good-quality embryos. These are primarily caused by two main factors, reduced endometrium receptivity or embryonic defects. Endometrium receptivity can be negatively influences by instances including uterine pathologies such as thin endometrium, altered expression of adhesive molecules and immunological factors. Additionally, embryonic defects may be due to genetic abnormalities, embryonic aneuploidy or zona hardening. Endometriosis and hydrosalpinx has been known to effect both the endometrium and embryo <ref name="PMID23260857"><pubmed>23260857</pubmed></ref>.<br />
=====Human leukocyte antigen matching=====<br />
First used in 2001, HLA matching is an option given to parents to save a child with haematological or immunological disease through conceiving another child who would potentially be able to donate cord blood or haematopoietic stem cells from the bone marrow for transplantation. The process namely PGD-HLA has shown to improve haematopoietic stem cell transplant (HSCT). PGD-HLA can only be performed when HSCT is not needed urgently due to the time needed to conceive and delivery the baby <ref name="PMID25500181"><pubmed>25500181</pubmed></ref>. It is most commonly applied to children suffering from relapsed leukaemia <ref name="PMID22524201"><pubmed>22524201</pubmed></ref>. In a case study PGD-HLA was proven to successfully cure 10 diseases including Fanconi anaemia, Diamond-Blackfan anaemia and beta thalassemia <ref name="PMID25066893><pubmed>25066893</pubmed></ref>.<br />
==Biopsy Methods==<br />
Biopsy, the removal of genetic materials, from oocytes or embryos in the preimplantation stage is the primary step in PGD. For the past two decades these biopsies have been performed at three stages, the polar body, blastomere, and blastocyst, and the methodologies optimized to ensure the embryo’s viability. The most common approach involves biopsies at the cleavage stage. However, polar body and blastocyst biopsies are increasingly more often tested and applied. Approached for opening the zona pellucida involve next to the traditional mechanical and chemical means, novel approaches such as noncontact lasers. Their application may simplify and secure the procedure significantly. The most challenging question about PGD procedures remains at what stage biopsies should be taken. Much controversy has developed around this topic, highlighting the varying disadvantages and advantages of temporal biopsies. <ref name="PMID22723007"><pubmed>22723007</pubmed></ref><br />
<br />
{| class="wikitable"<br />
|- align="center" bgcolor="DDCEF2"<br />
|<br />
| Time of Biopsy<br />
| Advantages <br />
| Disadvantages<br />
|- bgcolor="FFFAFA"<br />
| Polar Body<br />
| Day 1<br />
| No harm to oocyte<br />
| Only maternal DNA is tested, often needs to be coupled with other biopsies<br />
|- bgcolor="FFFAFA"<br />
| Blastomere<br />
| Day 3<br />
| …<br />
| … <br />
|- bgcolor="FFFAFA"<br />
| Trophectoderm<br />
| Day 5 and 6 <br />
| Little harm, large amount of genetic material<br />
| Opening of blastocyst necessary, small time window for procedure<br />
|}<br />
<br />
<br />
[[File:Polar_Body,_Blastomere,_and_Trophectoderm_Biopsy.jpeg|thumb|Polar body (A), blastomere (B) and trophectoderm (C) biopsies<ref name="PMID25625041"><pubmed>25625041</pubmed></ref>.]]<br />
<br />
<br />
<br />
PMID 24305177<br />
===Polar Body Analysis===<br />
Day 1<br />
====Description====<br />
Polar body (PB) biopsy, which was introduced in 1990, offers a promising alternative to biopsies performed at the blastomere stage for PGD/S indications on legal and practical grounds. <br />
Description: Consequent embryo development does not necessitate the presence of the first and second PB and their removal may not be crucial. PB biopsy requires precise timing. Keeping track of the meiotic cell cycle is necessary to perform a successful biopsy and, therefore, PB biopsy usually is applied in combination with intracytoplasmic sperm injection (ICSI). During the maturation from the germinal vesicle stage to the metaphase-II stage the first PB is formed. A cytoplasmic bridge containing spindle remnants, that are still in contact with the cellular genetic material, links this PB to the oolemma for about 90 minutes after extrusion. It is possible to visualize these remnants by polarization microscopy and it is crucial to not perform the biopsy until the first PB is no longer firmly attached to the oolemma as this indicates an immature embryo.The oocyte tolerates mechanical zona dissection best during hours four until six after ICSI as the oolemma has stabilized by that time because of the cortical granule reaction. Over time the first PB degenerates stressing a temporal biopsy and its optimal extraction time window is four to 12 hours after ICSI. The second PB forms around two to four hours after ICSI. However, its optimal time window for biopsy is set to be eight to 16 hours after ICSI. This is due to the second PB being attached to the oolemma with spindle remnants until six hours after ICSI. Biopsy at this point may cause enucleation of the oocyte. In addition, studies have shown that the amplification efficiency of second PB’s DNA is worse if the PB is extracted prior to eight hours after ICSI. <br />
Thus, it is possible to perform sequential and simultaneous biopsies for the first and second PB. If performed, sequentially the first PB may be removed four to 12 hours and the second PB eight to 16 hours after ICSI. The optimal time window for a biopsy for both the first and second PB simultaneously is eight to 12 hours after ICSI. It is highly preferred to analyze both PBs due to potential aneuploidies in either PB and crossing overs during meiosis<ref name="PMID22723007"/>. <br />
====Procedure====<br />
Chemical opening achieved with for example acidic tyrode’s solution of the zona pellucida is not tolerated by the oocyte and may have detrimental effects on the embryo’s development. Therefore, the access to the perivitelline space of the oocyte is provided by mechanical zona dissection or by laser. Both techniques work well if performed by experienced embryologist. However, laser-assisted biopsy is less time consuming when compared to manual dissection. It is critical to consider the size of the introduced opening as it will remain permanent. If it is too large the blastomere may be lost during embryo development and if it is too small it may interfere with hatching of the embryo during blastocyst stage<ref name="PMID22723007"/><br />
<br />
[[File:Polar_Body_Biopsy.jpeg|thumb|The presence of a faint but clearly identifiable strand connecting PB2 to the <br />
oolemma. The biopsy was performed ∼9 h after ICSI<ref name="PMID21908464"><pubmed>21908464</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JTaQzszVr8o</html5media><br />
|-<br />
| Laser-assisted polar body biopsy<ref>RIUK, R. (2013, June 25) Polar Body Biopsy [Video file]. Retrieved from https://www.youtube.com/watch?v=JTaQzszVr8o</ref><br />
|}<br />
<br />
====Advantages & Disadvantages====<br />
PB biopsies can only investigate the maternal contributions to the embryo as they are of maternal origin. Thus, this procedure is appropriate for PGD solely for monogenetic diseases from the maternal side. Recessive diseases may be evaluated with PB biopsies on the basis that the embryo’s outcome will be determined by the paternal contribution. (...) It may still be applied for PGS as most aneuploidies either arise during meiosis or origin from the maternal genome. However, diagnosis error has been reported due to the lack of considering paternal contributions. <br />
Because PB biopsies are performed very early it is not yet known whether the oocyte will develop into a viable embryo. Thus, PBs are commonly frozen or fixed after biopsy and depending on the state of the embryo only chosen PBs will be tested. This is primarily an economic issue as many genetic testing procedures are very cost-intensive<ref name="PMID22723007"/>.<br />
<br />
[[File:Implantation_predictive_value_of_euploid_screening_results.jpeg|thumb|The sustained implantation predictive value (with 95 % confidence interval) of a euploid screening result obtained from the first polar body (PB1), PB1 and the second polar body (PB2), or a direct embryo biopsy for each stage of embryo transfer (cleavage-stage and blastocyst stage)<ref name="PMID25106935"><pubmed>25106935</pubmed></ref>.]]<br />
<br />
===Blastomere biopsy===<br />
Day 3 <br />
====Description====<br />
Blastomere biopsy has been the prevalent method for PGD and PGS in the last two decades. At least one, but up to two, blastomeres are biopsied on day three of the cleavage stage embryo. The right number of blastomeres removed is a controversial topic as two cells allow for more genetic material and more accurate results. However, removing two cells might be too invasive and damaging to the embryo. (Study)<ref name="PMID21748341"><pubmed>21748341</pubmed></ref><br />
====Procedure====<br />
Initially a hole was drilled into the zona pellucida using acid tyrodes and the blastomeres are removed via aspiration with a pipette<ref name="PMID21748341"/>.<br />
<br />
<br />
[[File:Aspiration_of_a_Blastomere.jpeg|thumb|Aspiration of a Blastomere into the biopsy pipette<ref name=" PMID24783200"><pubmed>24783200</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=TbridWVwipI</html5media><br />
|-<br />
| Laser-assisted blastomere biopsy<ref>Sukprasert, M. (2014, March 5) Day 3 Blastomere Biopsy 1 [Video file]. Retrieved from https://www.youtube.com/watch?v=TbridWVwipI</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
===Trophectoderm biopsy===<br />
Day 5 and 6<br />
====Description====<br />
The improvement of embryo culture media allowed the in vitro development of human embryos until the blastocyst stage and opened up the possibility to take blastocyst biopsies. During day three to day five the haploid maternal and paternal genomes work together for the first time to form the genome of the embryo. The maternal epigenetic control lessens significantly while preparing for implantation with precisely arranged events happening. The first event includes a rapid increase in the number of embryonic cells which are active in mitotic divisions and apoptosis of aberrant cells. This is followed by the formation of blastocoel (cavitation) which results from the flattening of cell located on the outside of the blastomere. Now the blastocyst will expand until the embryo hatches by rupturing the zona pellucida. The cells of the blastocyst will differentiate to form two distinct cell lineages, the outer trophectoderm and the inner cell mass<ref name="PMID22723007"/>.<br />
====Procedure====<br />
Trophectoderm biopsy is usually performed in Hepes buffered biopsy medium and opening approaches include needle cutting which has been replaced by lasers in past years. Different research groups report different timings of the opening to be the most successful. Some open the blastocyst on day three or four by creating a 25 µm which causes the trophectoderm to herniate through this hole and is, thus, accessible for biopsy. Others create this hole about four hours before biopsy which allows sufficient herniation of trophectoderm cells. It is also possible to open the blastocyst immediately before biopsy. This avoids an extra step and the inner cell mass usually is easy to locate. Blastocyst biopsies involve the removal of trophectoderm cells and the ideal time for the procedure is day five. Successful biopsies on day six have been performed, while little is known about the results of biopsies on day seven. However, since the window of implantation in humans is from day eight to ten after ovulation, day seven biopsies appear to be possible<ref name="PMID22723007"/>.<br />
-collapse of trophoblasts<br />
-possible: biopsy of hatched blastocyst, holding pipette careful mild suction force to hold embryo near ICM <br />
-Cryopreservation<br />
<br />
<br />
[[File:Microscopic images of human blastocysts for biopsy.jpeg|thumb|(A) Some trophectoderm cells in a blastocyst started to hatch and (B) the trophectoderm cells were biopsied with assisted laser cutting. Images in C–D show the blastocysts after vitrification and warming. Blastocysts had been cultured for 2–4 hrs after warming, showing good (ICM and trophectoderm cells) hatched (C) and hatching (D) blastocysts. The hatching blastocyst in (E) has good ICM but fair trophectoderm while the blastocyst in (F) has both fair ICM and trophectoderm. Arrows indicate ICMs and arrow heads indicate trophectoderm cells. Bar = 40 µm<ref name="PMID2190846"><pubmed>2190846</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JI_TQ8d8tNM</html5media><br />
|-<br />
| Laser-assisted blastocyst biopsy (at 00:50 min)<ref>Coco, R. (2014, April 30) Trophectoderm biopsy in a Hatching blastocyst protruding ICM [Video file]. Retrieved from https://www.youtube.com/watch?v=JI_TQ8d8tNM</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
Blastocyst biopsies are believed to be less damaging to the embryo and appear to be unrelated to implantation rates. In addition, this biopsy method allows for a larger extraction of cells for genetic testing. However, since they are performed late in in vitro development, the time window for genetic testing is relatively small. Fast and accurate genetic testing methods are needed to ensure a successful and safe result from this biopsy. Thus, blastocyst biopsies may gain more popularity in the future whn such methods have been developed or improved<ref name="PMID22723007"/>. <br />
<br />
<br />
==Genetic Techniques==<br />
<br />
===PCR===<br />
====Description====<br />
Polymerase chain reaction (PCR) amplifies DNA specific to genetic sequence of interest . PCR was developed by Kay Mullis in the 1980s, for which he was awarded the Nobel prize for chemistry in 1993. <ref> Pubmed Docs (2015) Polymerase Chain Reaction (PCR) Pubmen. Retrieved from [http://www.ncbi.nlm.nih.gov/probe/docs/techpcr/]</ref> This technique enables clinicians to monitor and diagnose diseases using minute samples such as embryonic cells, blood & tissue. <ref>Roche (2015) PCR: How We Copy DNA. Roche Molecular Systems Inc. retrieved From [http://molecular.roche.com/pcr/Pages/Process.aspx]</ref> PCR has many important applications like DNA fingerprinting, genetic mapping, detection of viruses and bacteria as well as being used to detect genetic disorders, as a part of PGD, in conjunction with IVF. It is used to detect molecular abnormalities such as single gene disorders like Tay Sach, Cycstic fibrosis, Duchenne Muscular Dystrophy, Thalassemia, Huntington disease, Spinal muscular atrophy and many more. Molecular and Genetic analysis require a significant amount of DNA, which we would not have without PCR. It revolutionized the study of DNA, replacing all previous recombinant DNA technology. <ref> Mullins, K., Francois, F.& Gibbs R.A. (1994 ) The Polymerase Chain Reaction. p3. Springer- Science +Business Media. Birkhauser, Boston<br />
Available at [https://books.google.com.au/books?hl=en&lr=&id=gjrTBwAAQBAJ&oi=fnd&pg=PR5&dq=kary+mullis+PCR&ots=mpzAyRh5ZY&sig=PQ4goNoKJ90tb3-MkPk62zrTGbw#v=onepage&q=kary%20mullis%20PCR&f=false] </ref> <br />
<br />
[[File:PCR.jpg|thumb|right|Polymerase chain reaction (PCR) amplifies DNA specific to genetic sequence of interest, enabling the monitoring and diagnose molecular abnormalities such as single gene disorders using minute samples such as embryonic cells, blood & tissue <ref>NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref>]]<br />
<br />
====Procedure====<br />
<br />
Sample are obtained from the the blastocyst, a polar body biopsy or the blastomeres stages of the embryo. <br />
Stage 1 Denaturing: separating the target strands of DNA <br />
The obtained sample is heated to roughly 90 degrees celcius, this heat causes breaks the relatively weak bonds between nucleotides that form DNA. the double stranded DNA to split into 2 single strands of DNA that are used as templates.<br />
Stage 2 Annealing: Binding the Primers to the target DNA sequence <br />
PCR will only copy the target sequence of DNA specified by specific PCR primer. These synthesized primers Oligonucleotides are small artificial pieces of DNA. <br />
TAQ polymerase enzyme synthesize 2 new strands of DNA duplicate to the single sample DNA stand template indicated by these primers. During this stage the reaction is cooled to a temperature between 40-60 degrees Celsius. <br />
Stage 3- Extension- making copies <br />
Each of these 2 copies are then used again as templates generating 2 further replications This cycle can occur as many 30 -40 times within a couple hours leading to billions of extra copies of the original DNA segment. The optimal temperature for the further replication is roughly 72 degrees Celsius. <br />
<br />
This process mediated by a thermocycler machine that is programmed to alter the temperature of the reaction every couple of minutes, perpetuating the cycle of DNA denaturing and synthesis. <br />
This process, generates exponential exact copy of the original template DNA sequence. <br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
!PCR cycles<br />
<br />
|{|<br />
|-<br />
| '''PCR Cycle'''<br />
| '''Target Copies'''<br />
|-<br />
| 1<br />
| 2<br />
|-<br />
| 2<br />
| 4<br />
|-<br />
| 3<br />
| 8<br />
|-<br />
| 4<br />
| 16<br />
|-"<br />
| 5 <br />
| 32<br />
|-<br />
| 6 <br />
| 64<br />
|-<br />
| 7 <br />
| 128<br />
|-<br />
| 8<br />
| 256<br />
|- <br />
| 9<br />
| 512 <br />
|-<br />
| 10<br />
| 1024<br />
|-<br />
| 15<br />
| 32,768<br />
|-<br />
| 20 <br />
| 1,048,578<br />
|-<br />
| 25<br />
| 33,554,432<br />
|-<br />
| 30 <br />
| 1,073,741,842<br />
|-<br />
|}<br />
<br />
<br />
<br />
{| class="wikitable" <br />
|-bgcolor="#9ACD32" <br />
| rowspan="10" |'''Advantages'''<br />
|-bgcolor="#F0FFF0"<br />
| fast and inexpensive way of copying a target sequence of DNA<br />
|-bgcolor="#F0FFF0"<br />
| aids the diagnosis of single cell defects<br />
|-bgcolor="#F0FFF0"<br />
| rapid generation of results within a couple hours<br />
|-bgcolor="#F0FFF0"<br />
| can start from a single molecule of DNA, therefore is more sensitive <br />
|-bgcolor="#F0FFF0"<br />
| has a flexible primer design enabling<br />
|-bgcolor="#F0FFF0"<br />
| overcame previous issues associated with the limited availability of sites of end<br />
|-bgcolor="#F0FFF0"<br />
| generates the DNA copies exponentially<br />
|-bgcolor="#F0FFF0"<br />
| enables DNA amplification required for molecular and genetic analysis<br />
|-bgcolor="#F0FFF0"<br />
|Valid diagnostic method in selecting unaffected embryos for embryo transfer <ref> Dreesen, J., Drusedaul, M., Smeets, H., Die-Smulders, C., Coonen, E., Dumoulin, J., Gielen, M., Evers, J., Herbergers, J. & Geradets, J. (2008) Validation of preimplantation genetic diagnosis by PCR analysis: genotype comparison of the blastomere and corresponding embryo, implications for clinical practice. Mol. Hum. Reprod. 14 (10):573-579.doi: 10.1093/molehr/gan052. Retrieved from [http://molehr.oxfordjournals.org/content/14/10/573.short] </ref> <ref><pubmed>20966460</pubmed></ref><br />
|-bgcolor="#9ACD32"<br />
| rowspan="5"|'''Disadvantages'''<br />
|-bgcolor="#F0FFF0"<br />
| only during this exponential DNA replication phase can we determine the starting quantity sequence contained in the original sample ( template DNA strand)<br />
|-bgcolor="#F0FFF0"<br />
| PCR reaction is limited by the presence of inhibitors present in the sample : reagent inhibitors <br />
|-bgcolor="#F0FFF0"<br />
| self annealing due to the accumulation of the product -stopping exponential amplification for the target sequence and reach a plateau<br />
quantification of the end point of reaction of PCR products unreliable - therefore that is why we require real time quantitative RT-PCR necessary<br />
<ref> NIS (2015) Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref><br />
|}<br />
<br />
<br />
===Fluorescent In Situ Hybridisation (FISH)===<br />
<br />
<br />
====Description====<br />
Fluorescence in situ hybridization (FISH) the one of the most effective and rapid <ref name="PMID26338801"><pubmed>26338801</pubmed></ref> Preimplantation Genetic Diagnosis (PGD). This techniques used to locate a specific DNA sequences within a chromosome. FISH facilitates the clinical diagnosis of chromosomal abnormalities indicated by sequential duplications, deletions and rearrangements of chromosome, that are usually missed with microscopic analysis. This technique is especially relevant for female embryos with X-linked diseases,<ref name="PMID20809319"><pubmed>20809319</pubmed></ref> that have no other mutation specific tests [http://www.ncbi.nlm.nih.gov/pubmed/20809319] As part of PGD, samples are collected from various stages of the embyro,and they are able to conducted tests on the blastocyst, a polar body biopsy and the blastomeres <ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. FISH is 99% effective when used in conjunction with competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities<ref name="PMID26338801"/>.<br />
<br />
====Procedure==== <br />
<br />
Samples are collected from either the blastocyst, a polar body biopsy or the blastomeres stages of the embryo <ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
DNA strands are heated and denatured causing their the individual DNA strands to break apart<br />
Probes are single complimentary stands of DNA a that have been tagged with small chemical agents that glow brightly in the presence of a specific region on a chromosome. These specific probes then hybridize and join to their complementary DNA strand. <br />
The fluorescent tags enable the researchers to correctly identify the presence or lack thereof and location of the specific chromosomes that they are testing for. <ref name="PMID17876073"><pubmed>17876073</pubmed></ref><br />
Researcher analyse the results by identifying the number and the relative location of the fluorescent dots generated by the FISH images.<ref name="PMID17970921"><pubmed>17970921</pubmed></ref><br />
The probe will not fully hybridise if there has been a duplication or a deletion of the DNA - indicating chromosomal and sex chromosomal anomalies like trisomies and aneuploidies. <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref><br />
<br />
<br />
Different probes are used for different purposes: <ref>Unique, Rare Chromosome Disorder Support Group (2013) Fluorescence in situ hybridisation (FISH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/Other/FISH%20FTNW.pdf]</ref><br />
*'''Locus specific tags''' detect very small imbalances, and locate isolated small portions <br />
of genes within a chromosome<br />
*'''Alphoid/Centomeric Repeat probes''' are developed from the repetitive sequence located in the middle region of each chromosome, useful in determining the number of chromosomes , detecting rearrangement and when used in conjunction with locus probes to determine the absence of genetic material on a chromosome. <br />
*'''Paint Probes''' are collections of smaller probes with their own stains that bind to a different section on the chromosome - allowing the full chromosome too be labeled a unique colour, this "full colour map" can be used to know the spectral karyotype- full chromosomal mapping is useful in examining chromosomal abnormalities. <br />
<br />
[[File:Fluorescent In Situ Hybridisation (FISH).jpg|thumb|right|'''FISH''' We are able to tag Specific DNA sequences using Probes which have been tagged with fluorescent Labels.This technique enables the clinical diagnosis of chromosomal abnormalities, indicated by sequential duplication, deletions and rearrangements of chromosome <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref>]]<br />
<br />
{|class="wikitable" align="center"<br />
|-bgcolor="pink" <br />
| rowspan="8" |'''Advantages''' <br />
|-bgcolor="#FDE1F2" <br />
| FISH is 99% effective when used in conjunction with Competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities.<ref><pubmed>26338801</pubmed></ref><br />
|-bgcolor="#FDE1F2" <br />
| Rapid generation of results<br />
|-bgcolor="#FDE1F2" <br />
| Identifies very small translocations and aneuploidies that occur within chromosomes, that would usually be missed under microscopic analysis<br />
|-bgcolor="#FDE1F2" <br />
| Indicates whether the accessed chromosomes are normal <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|-bgcolor="#FDE1F2" <br />
| Tests for the most common chromosomal abnormalities - down syndrome chromosomes 13,16,18,21 and 22 <ref><pubmed>21749752</pubmed></ref><br />
|-bgcolor="#FDE1F2" <br />
| It may be used to compare the chromosomal gene arrangements in related species<br />
|-bgcolor="#FDE1F2" <br />
| can be used to identify and remove inheritable X-linked disease or sex chromasome anomalies such as Duchennes Muscular Dystrophy, hemophilia, ectodermal dysplasia <ref><pubmed>17876073</pubmed></ref><br />
|-bgcolor="#FEB745"<br />
| rowspan="5"|'''Disadvantages'''<br />
|-bgcolor="#FE1C5EA"<br />
| FISH destroys all cells tested <ref> O'Connor, C. (2008) Fluorescence in situ hybridization (FISH). Nature Education 1(1):171. retrieved from [http://www.nature.com/scitable/topicpage/fluorescence-in-situ-hybridization-fish-327] </ref><br />
|-bgcolor="#FE1C5EA"<br />
| It does not fully access all chromosomes (only ~ 12)<br />
|-bgcolor="#FE1C5EA"<br />
| Analysis of results is dependent upon the dot quality impacted by hybridisation efficiency or the camera sensitivity <ref><pubmed>17970921</pubmed></ref><br />
|-bgcolor="#FE1C5EA"<br />
| some studies indicate that using FISH on a day-3 embryo biopsy decreases the rate of live births <ref><pubmed>26168107</pubmed></ref><br />
|}<br />
<br />
===Array Comparative Genomic Hybridisation (aCGH)===<br />
====Description====<br />
<br />
aCGH also known as Microarray analysis efficiently scans the entire genome for chromosomal imbalances. CGH was initially developed to detect the number of changes in a solid tumor mass. It uses 2 genomes comparing the sample to the control, with each labeled in a different fluorescent dye<ref name="PMID1876176"><pubmed>1876176</pubmed></ref>. Earlier CGH techniques were limited by the resolution of the imaging <ref> Lichter, P., et al. Comparative genomic hybridization: Uses and limitations. Seminars in Hematology 37, 348–357 (2000)</ref> , these initial limitations were overcome by using Microarrays in conjunction with CGh to improve the resolution of the imaging, Array Comparative Genomic Hybridisation (aCGH). This method compares sample and control microarrayed slides containing small segments of DNA (probes). <ref> Lucito, R., et al. Representational oligonucleotide microarray analysis: A high-resolution method to detect genome copy number variation. Genome Research 13, 2291–2305 (2003) </ref> the Probes used will vary according from the small (25-85 base pairs) oligonucleotides manufactured to highlight different target sequences, to the very large genomic clones (80,000- 200,00 base pairs), and as these are significantly smaller than the traditional metaphase chromosomes used for CGH, generating a higher resolution of image. <ref name="PMID22467166"><pubmed>22467166</pubmed></ref>.aCGH is used as a diagnostic tool for prenatal detection f chromosomal abnormalities <ref name="PMID19012303"><pubmed>19012303</pubmed></ref>.<br />
<br />
<br />
====Procedure====<br />
<ref> Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432] </ref><br />
The sample is obtained (skin, blood or fetal cells) and DNA is obtained. <br />
As a part of PGD fetal cell samples are collected from; the fertilized egg polar bodies, the blastomere (day 3 embryo) or the blastocyst/tropoectoderm stage (day 5 embryo).<br />
Sample DNA is labeled with one fluorescent dye, and the control DNA is labeled with a different colored fluorescent dye. the control DNA is used as the base point of reference. <br />
heated and denatured single DNA strands then hybridize to their complementary single strand probes, which are then combined and applied to a microarray and the results are run through a computer program and a digital imaging system is used to quantify the results( fluorescent intensities of the labeled probes). <br />
<br />
[[File:aCGH.jpg|thumb|right|'''aCGH''' checks the entire genome for chromosomal imbalances, by comparing control and a sample slides contatining small segements of DNA sample microarrayed slides small segments of DNA. Illustrated by student z5020317 and adapted from <ref> NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation. retrieved from [http://www.phgfoundation.org/file/5237/]</ref> <ref>Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432]</ref>]]<br />
<br />
<br />
<br />
The fluorescent ratio and the hybridization signal at different locations on the genome of the control DNA are used to identify any variances present in the sample DNA. aCGH facilitates the clinical diagnosis of submicroscopic chromosomal duplication, deletion and rearrangements indicative of chromosomal disorders such as trisomies 1-22and specific sex linked disorders. <br />
Duplications in the DNA are displayed by the computer program as spikes/ peaks over an established threshold and deletions in DNA are displayed by the computer program as spikes/ toughs beneath this threshold <br />
<br />
<br />
<br />
<br />
{|class="wikitable" align="center"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="12" |'''Advantages''' <br />
|-bgcolor="FFFAFA"<br />
| Multiple applications: prenatal genetic diagnosis, cancer diagnosis, <ref name="PMID20193845"><pubmed>20193845</pubmed></ref> genetic screening for developmental delay (learning disabilities) <ref name="PMID17309648"><pubmed>17309648</pubmed></ref>. or congenital anomalies that are suspected to be genetic in origin <ref>NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation . retrieved from [http://www.phgfoundation.org/file/5237/]</ref><br />
|-bgcolor="FFFAFA"<br />
| trace represents all chromosomes present in the human genome chromosomes 1-22 and the X & Y chromosomes, and therefore is the most accurate method for testing whole embryo aneuploidy<br />
|-bgcolor="FFFAFA"<br />
| aCGH has been extensively tested, and Validated, and is now used world wide.<br />
|-bgcolor="FFFAFA"<br />
| Detects submicroscopic alterations<br />
|-bgcolor="FFFAFA"<br />
| Detects deletions and additions and rearrangements as well as amplification, of the WHOLE genome, simultaneously.<br />
|-bgcolor="FFFAFA"<br />
| Used as a diagnostic tool for prenatal detection of chromosomal abnormalities <ref name="PMID22034057"><pubmed>22034057</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Provides high resolution genomewide screening of segmental genomic copy number variations<br />
|-bgcolor="FFFAFA"<br />
| Very accurate when used in conjunction with FISH<br />
|-bgcolor="FFFAFA"<br />
| Alone is more reliable and in detecting chromosomal abnormalities, with a higher implantation success rate, than FISH <ref name="PMID20494259"><pubmed>20494259</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Allows an in depth research focus upon specific types of rearrangements within selected chromosomal regions, a recent particular area of interest is subtelomeric and pericentromeric rearrangements<br />
|-bgcolor="FFFAFA"<br />
| Reduces the risk of failed implantation and miscarriage, improving the chance of a healthy baby <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|-bgcolor="DDCEF2"<br />
| rowspan="9" |'''Disadvantages'''<br />
|-bgcolor="FFFAFA"<br />
| Translocations and inversions of DNA are not detected<br />
|-bgcolor="FFFAFA"<br />
| Limited ability diagnosing specific polyploidies such as triploidy <ref> Unique, Rare Chromosome Disorder Support Group (2013) Microarray-based Comparative Genomic Hybridiation (array CGH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/other/array%20cgh%20ftnw.pdf] </ref><br />
|-bgcolor="FFFAFA"<br />
| Will not detect mosaicism detection <20% (cultures where >1 of 5 cells are trisomy 12)<br />
|-bgcolor="FFFAFA"<br />
| Will not detect balanced chromosomal rearrangement<br />
|-bgcolor="FFFAFA"<br />
| Will not detect duplications or deletions <80kb<br />
|-bgcolor="FFFAFA"<br />
| Will not detect point mutations within genes <ref>Washington department of education (CGH- FAQ for physicians. Signature Genomic LAboratories, LLC. Retrieved from [https://depts.washington.edu/dbpeds/Lab%20Tests/SignatureCGH-physician_FAQ.pdf]</ref><br />
|-bgcolor="FFFAFA"<br />
| will not detect chromosomal position of genomic gains<br />
|-bgcolor="FFFAFA"<br />
| Will not detect loos of heterozygosity (LOH) or Absence of heterozygosity (AOH) <ref>WiCell Research Institute Inc. (2012) Comparative Genomic Hybridization Microarray. <br />
retrieved from [http://www.wicell.org/home/cytogenetic-services/cgh-microarray/array-comparative-genomic-hybridization-acgh.cmsx]</ref><br />
|}<br />
<br />
<br />
<br />
===Next Generation Sequencing===<br />
====Description====<br />
The development and advances within ART in the past 20 years, as well as the increasing popularity of IV, has lead to an influx of new technologies developed to screen embryos for chromosomal anomalies, which are covered by the umbrella term of Next generation Sequencing (NGS). NGS is a general term used to describe all of the new and emerging screening techniques currently being introduced and used as part of PGD for IVF . NGS screens for single gene disorders as well as conducting extensive and very comprehensive chromosome diagnosis by sequencing, counting, and accurately assembling millions of DNA reads, simultaneously. <ref name="PMID23499002"><pubmed>23499002</pubmed></ref> There is a movement for NGS to replace the other limited testing techniques and be used as the standard. <br />
====Procedure====<br />
Samples are collected from either blastomere or the blastocyst/tropoectoderm and processed for analysis by a computer system. <br />
The methodology of each process is unique to the technique being used. <br />
<br />
<br />
<br />
{|class="wikitable" align="center"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="14" |'''Advantages''' <br />
|-bgcolor="FFFAFA"<br />
| Cheaper<br />
|-bgcolor="FFFAFA"<br />
| Opens new diagnostic possibilities<br />
|-bgcolor="FFFAFA"<br />
| Accurately tests all 24 chromosomes<br />
|-bgcolor="FFFAFA"<br />
| Tests for the presence of monogenic diseases of known genetic background<br />
|-bgcolor="FFFAFA"<br />
| Reduces the number of biopsies required for diagnosis<br />
|-bgcolor="FFFAFA"<br />
| Higher detection rate of small translocations<br />
|-bgcolor="FFFAFA"<br />
| Highly accurate is testing for compound point mutations, chromosomal duplication, deletions and insertions <ref name="23312231"><pubmed>23312231</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| It accurately detects chromosomal aneuploidy and unbalanced rearrangement <ref name="PMID25685330"><pubmed>25685330</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Higher detection rate of small translocations<br />
|-bgcolor="FFFAFA"<br />
| NGS single gene disorder screenings can conducted in conjunction with PCR comprehensive chromosomal screening<br />
|-bgcolor="FFFAFA"<br />
| Reduces human error <br />
|-bgcolor="FFFAFA"<br />
| Better detects the presence of mosaicism<br />
|-bgcolor="FFFAFA"<br />
| Work well in conjunction with CGH and aCGH as part of PGD, improving the chances of IVF. <ref> Morris, R. S. (2015 ) Next generation sequencing for PCG|PGS|CCS. IVF1 retrieved from [http://www.ivf1.com/next-generation-sequencing for-pgd] </ref><br />
|-bgcolor="DDCEF2"<br />
| rowspan="1" |'''Disadvantages''' <br />
|-bgcolor="FFFAFA"<br />
| There are limited information available to clinical applications of NGS <ref><pubmed>26100406</pubmed></ref><br />
|}<br />
<br />
<br />
<br />
<br />
<br />
<br />
==Diagnosis==<br />
There are a large amount of diseases that PGD can apply to, below are descriptions of the diseases that PGD are more commonly used for. Utilization of Diseased Cell Lines<br />
===Cystic Fibrosis===<br />
Cystic fibrosis is a single gene disorder. It is autosomal recessive and involves mutations in the cystic fibrosis transmembrane conductance regulator (CTFR) gene. The CTFR gene is normally responsible for the decrease in chloride and the transport of bicarbonate in epithelial cells thus playing a major physiological role. In PGD procedures, identification of the gene is assisted by microsatellite markers that have similar composition to the CTFR gene itself. Biopsy of two cells at the blastocyst stage is recommended if markers are not available. There are many variations of cystic fibrosis the most common being P.Phe508del <ref name="PMID26014425"><pubmed>26014425</pubmed></ref>.<br />
===Duchenne Muscular Dystrophy ===<br />
Duchenne Muscular Dystrophy is an X-linked recessive disease. It involves the Xp21 gene where majority of the mutations are chromosomal deletions with a smaller percentage resulting from duplications <ref name="PMID18359022"><pubmed>18359022</pubmed></ref>.<br />
<br />
===Autosomal Recessive MEckel-Gruber Syndrome===<br />
Autosomal recessive genetic defect caused by the TMEM67 gene. It results in cystic dysplasia of the kidneys with fibrotic change in the liber and occipital encephalocele. Other malformations could also be present in the central nervous system. In PGD whole genome amplification of single blastomeres are taken to identify the gene, this is also coupled with PCR techniques. Maternal plasma can also be extracted for PGS. <ref><pubmed>24039893</pubmed></ref> <br />
===β – Thalassemia=== <br />
β – Thalassemia is known as the most common type of autosomal recessive inherited disorder among haemoglobinopathies. It involves the adult β-globin gene and is associated with the absent or decreased expression of the gene. This is commonly caused by a single nucleotide change in the gene. PGD has been used successfully worldwide to identify the β-globin gene where its application is usually performed on a single blastomere or polar body <ref name="PMID19064120">19064120</pubmed></ref>.<br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
! Applicable diseases for PGD <ref>Genoma Group (2014). Retrieved September 18th, 2015, from http://www.preimplantationgeneticdiagnosis.it/genetic-diseases-diagnosed-by-pgd.htm </ref>, <ref>Genesis Genetics (2015). Retrieved September 18th, 2015, from http://genesisgenetics.org/pgd/what-we-test-for/</ref>, <ref>Human Fertilisation & Embryology Authority (2015). Retrieved Septembr 18th, 2015, from http://guide.hfea.gov.uk/pgd/</ref><br />
|-<br />
| '''Disease'''<br />
| '''Involved Genes'''<br />
|-<br />
| 5 Alpha Reductase Deficiency (5ARD)<br />
| SRD5A2 <br />
|-<br />
| Achondroplasia<br />
|FGFR3 <br />
|-<br />
| Acute Intermittent Porphyria <br />
| ALAD, ALAS2, CPOX, FECH, HMBS, PPOX, UROD, or UROS<br />
|-<br />
| Adrenoleukodystrophy (Adrenomyeloneuropathy)<br />
| ABCD1 <br />
|-<br />
| Agammaglobulinaemia (x-linked) <br />
|BTK <br />
|-<br />
| Agammaglobulinemia Bruton Tyrosine Kinase (BTK) <br />
|BTK <br />
|-<br />
| Aicardi Goutieres Syndrome 1 (AGS1) <br />
|TREX1, RNASEH2A, RNASEH2B, RNASEH2C, SAMHD1<br />
|-<br />
| Alagille Syndrome<br />
|JAG1 or NOTCH2<br />
|- <br />
| Alpers-Huttenlocher Syndrome <br />
|POLG <br />
|-<br />
| Alpha-1-antitrypsin deficiency <br />
|SERPINA1 <br />
|-<br />
| Alpha-Mannosidosis<br />
| MAN2B1 <br />
|-<br />
| Alpha Thalassemia <br />
|HBA1 or HBA2 <br />
|-<br />
| Alports Syndrome<br />
|COL4A3, COL4A4, COL4A5<br />
|-<br />
| Alzheimer's Disease - early onset (Type 3 and 4) <br />
|APP, PSEN1, or PSEN2<br />
|-<br />
| Amyotrophic Lateral Sclerosis 1 (ALS1) <br />
|C9orf72, SOD1, TARDBP, FUS, ANG, ALS2, SETX, VAPB <br />
|-<br />
| Argininosuccinic Aciduria <br />
| ASL<br />
|-<br />
| Arrhythmogenic Right Ventricular Cardiomyopathy/ Dysplasia (ARVC/D)<br />
| DSG2; DSP; PKP2<br />
|-<br />
| Ataxia Telangiectasia<br />
| ATM<br />
|-<br />
| Autosomal Recessive Meckel-Gruber Syndrome<br />
| TMEM67<br />
|-<br />
| Bardet-Biedl Syndrome (BBS)<br />
| BBS1; BBS10<br />
|-<br />
| Barth Syndrome<br />
| TAZ<br />
|-<br />
| Beta Thalassaemia<br />
| HBB<br />
|-<br />
| Birt-Hogg-Dubé Syndrome<br />
| FLCN<br />
|-<br />
| Breast Ovarian Cancer Familial Susceptibility (BRCA2)<br />
| BRCA1; BRCA2<br />
|-<br />
| Canavan Disease <br />
| ASPA<br />
|-<br />
| Carnitine-Acylcarnitine Translocase Deficiency <br />
| SLC25A20<br />
|-<br />
| Cerebral Arteriopathy with Subcortical Infarcts & Leukoencephalopathy (CADASIL)<br />
| NOTCH3<br />
|-<br />
| Cerebral Cavernous Malformation<br />
| CCM1<br />
|-<br />
| Charcot-Marie-Tooth Disease<br />
| GJB1; MPZ; NEFL; PMP22<br />
|-<br />
| CHARGE Syndrome<br />
| CHD7<br />
|-<br />
| Cherubism<br />
| SH3BP2<br />
|-<br />
| Choroideremia<br />
| CHM<br />
|-<br />
| Chronic Granulomatous Disease<br />
| CYBB; NCF1<br />
|-<br />
| Ciliary Dyskinesia<br />
| DNAH5<br />
|-<br />
| Citrullinemia<br />
| ASS1<br />
|-<br />
| Cleidocranial Dysplasia<br />
| RUNX2<br />
|-<br />
| Cockayne Syndrome<br />
| ERCC6<br />
|-<br />
| Congenital Adrenal Hyperplasia<br />
| CYP21A2<br />
|-<br />
| Congenital Cataracts<br />
| GJA8; VSX2<br />
|-<br />
| Congenital Diarrhea, Syndromic<br />
| SPINT2<br />
|-<br />
| Congenital Disorders of Glycosylation (CDG)<br />
| ALG1; ALG6; CDG1C; DOLK; PMM2<br />
|-<br />
| Cornelia de Lange Syndrome <br />
| NIPBL<br />
|-<br />
| Craniosynostosis<br />
| TWIST1<br />
|-<br />
| Crouzon Syndrome<br />
| FGFR2<br />
|-<br />
| Cysteinyl Leukotriene Receptor 1 Deficiency <br />
| CYSLTR1<br />
|-<br />
| Cystic Fibrosis<br />
| CFTR<br />
|-<br />
| Diamond –Blackfan Anemia <br />
| RPS19<br />
|-<br />
| Duchenne Muscular Dystrophy <br />
| DMD<br />
|-<br />
| Dyskeratosis congenita (Male embryos only)<br />
| DKC1<br />
|-<br />
| Ectodermal dysplasia (Hypohidrotic)<br />
| EDA; EDA1; GJB6; IKBKG<br />
|-<br />
| Familial Adenomatous polyposis coli (FAP)<br />
| APC<br />
|-<br />
| Familial Dysautonomia<br />
| IKBKAP<br />
|-<br />
| Fanconi Anemia <br />
| FANCA; FANCC; FANCD2; FANCF; FANCG; FANCJ<br />
|-<br />
| Fragile X Syndrome (FRAX)<br />
| FMR1<br />
|-<br />
| Galactosemia <br />
| GALT<br />
|-<br />
| Gangliosidosis<br />
| GLB1<br />
|-<br />
| Glanzmann Thrombasthenia <br />
| ITGA2B<br />
|-<br />
| Glutaric Acidemia (aciduria)<br />
| GCDH <br />
|-<br />
| Glycogen Storage Disease <br />
| G6PC; GAA; SLC37A4<br />
|-<br />
| Haemophilia A<br />
| F8<br />
|-<br />
| Haemophilia B<br />
| F9<br />
|-<br />
| Hereditary Nonpolyposis Colorectal Cancer: Lynch Syndrome<br />
| MLH1; MSH2; MSH6<br />
|-<br />
| Holt Oram Syndrome<br />
| TBX5<br />
|-<br />
| Huntington Disease<br />
| HD<br />
|-<br />
| Hydrocephalus<br />
| L1CAM<br />
|-<br />
| Ichthyosis <br />
| ABCA12; STS<br />
|-<br />
| Incontinentia Pigmenti (IP)<br />
| NEMO<br />
|-<br />
| Joubert Syndrome 5<br />
| INPP5E<br />
|-<br />
| Krabbe Disease<br />
| GALC<br />
|-<br />
| Leber Congenital Amaurosis (LCA)<br />
| CEP290; GUCY2D<br />
|-<br />
| Leigh Syndrome (Infantile Subacute Necrotising Encephalopathy)<br />
| LRPPRC<br />
|-<br />
| Lesch Nyan Syndrome<br />
| HPRT1<br />
|-<br />
| Leukocyte Adhesion Deficiency (Type I)<br />
| ITGB2<br />
|-<br />
| Li-Fraumeni Syndrome<br />
| TP53<br />
|-<br />
| Macular Dystrophy Retinal <br />
| VMD2<br />
|-<br />
| Maple Syrup Urine Disorder (MSUD)<br />
| BCKDHB<br />
|-<br />
| Marfan Syndrome <br />
| FBN1<br />
|-<br />
| Menkes Syndrome<br />
| ATP7A<br />
|-<br />
| Mitochondrial DNA Depletion Syndrom <br />
| POLG; RRM2B; SUCLA2; TK2<br />
|-<br />
| Mucolipidosis type II<br />
| GNPTAB<br />
|-<br />
| Multiple Endocrine Neoplasia<br />
| MEN1; MEN2A; MEN2B<br />
|-<br />
| Multiple Exostoses<br />
| EXT1; EXT2 <br />
|-<br />
| Myotubular myopathy<br />
| MTM1 <br />
|-<br />
| Nail-Patella Syndrome<br />
| LMX1B<br />
|-<br />
| Neurofibromatosis Type 1<br />
| NF1<br />
|-<br />
| Neurofibromatosis Type 2 <br />
| NF2<br />
|-<br />
| Noonan Syndrome<br />
| KRAS, PTPN11; SOS1<br />
|-<br />
| Norrie Disease<br />
| NDP<br />
|-<br />
| Ocular Albinism <br />
| GPR143<br />
|-<br />
| Oculocutaneous Albinism <br />
| OCA2; TYR <br />
|-<br />
| Oculodentaldigital Dysplasia<br />
| GJA1<br />
|-<br />
| Optic Atrophy<br />
| OPA1<br />
|-<br />
| Ornithine Transcarbamylase Deficiency <br />
| OTC<br />
|-<br />
| Osteogenesis imperfeca <br />
| COL1A1; COL1A2<br />
|-<br />
| Osteopetrosis <br />
| CLCN7; OSTM1; TCIRG1<br />
|-<br />
| Pachyonychia Congenita <br />
| KRT16; KRT6A<br />
|-<br />
| Pancreatitis, Hereditary<br />
| PRSS1 <br />
|-<br />
| Papillorenal syndrome <br />
| PAX2<br />
|-<br />
| Phenylketonuria <br />
| PAH <br />
|-<br />
| This table does not cover the complete list of diseases that PGD can be applied to.<br />
|}<br />
<br />
==Laws & Legal status==<br />
<br />
{| class="wikitable" <br />
|-bgcolor="DDCEF2"<br />
|'''Country'''<br />
|'''Legislation'''<br />
|-<br />
| Australia<br />
| PGD is currently used to detect serious genetic conditions to improve the outcome of Assisted Reproductive Technologies (ART). In very rare cases it may be used to select an embryo with compatible tissue for a sibling who has a life-threatening disease where other means of treatment is unavailable. This is with the conditions that the use of PGD will not affect the welfare and interests of the child to be born. The parents must also receive adequate counselling and have full understanding of the procedures of PGD. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"> National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art</ref><br />
The use of PGD for sex-selection is prohibited with the exception of reducing the risk of the transmission of serious sex-linked genetic conditions. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"/><br />
|-bgcolor="FFFAFA"<br />
| Brazil<br />
| The laws regarding PGD in Brazil are not strictly regulated. They are vague and there is limited information surround the activities of assisted reproduction in general in the country <ref name="PMID25493379"><pubmed>25493379</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| Czech Republic<br />
| The laws in the Czech Republic allow those with a “defined indication in order to exclude risk of serous genetically conditioned disease and defects with embryos before they are implanted into the cavity of the uterus”. Couples that undergo any assisted reproductive treatment including PGD have to be married. Sex-selection is illegal except in regards to serious sex-linked genetic diseases <ref name="PMID24777348"><pubmed>24777348</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| Greece<br />
| In Greece, ART is open to those up to the age of 50 with written consent. It can only be used if a medical necessity is present such as the susceptibility of serious hereditary diseases. Sex selection is banned apart from cases of sex-linked diseases and sexually transmitted diseases <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| India<br />
| In India there is a cultural preference for boys thus the Prenatal Diagnostic Techniques (Regulation and Prevention of Misuse) Act was introduced in 1994. This law limits the use of PGD for sex determination except in cases of specific congenital diseases. These laws however are not strictly enforced. <ref>World Health Organisation (2015) Gender and Genetics Retrieved on October 21st 2015 from:http://www.who.int/genomics/gender/en/index4.html</ref><br />
|-bgcolor="FFFAFA"<br />
| Portugal <br />
| ART is only available to those who are married or have a similar type of relationship for at least two years. The couples cannot be of the same sex and must be at least 18 years of age. Sex selection is illegal except in cases of sex-linked diseases. The use of PGD is illegal if the predictive value of genetic tests are very low <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| Spain<br />
| PGD can be applied to “serious hereditary diseases not amenable to postnatal curative treatment” and “detection of other abnormalities which may compromise the viability of the pre-embryo”. If PGD is to be used for any other purpose authorisation must be acquired <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| Sweden <br />
| The use of PGD is strictly regulated and couples must achieve authorisation of the National Board of Health and Welfare. It can only be used it can only be used if the child is at risk to inheriting a serious chromosomal or monogenetic disease. It cannot be used for selection of specific characteristics <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| United Kingdom<br />
| Those involved with carrying out the IVF treatment must have a license from the Human Fertilisation and Embryology Authority (HFEA). Only embryos that are approved by the HFEA can be implanted where the embryonic nuclear or mitochondrial DNA cannot be altered with the exception of preventing mitochondrial diseases <ref name="PMID24777348"/>. <br />
|}<br />
<br />
==Future/Current Research==<br />
===Noninvasive Preimplantation Genetic Testing without Embryo Biopsy===<br />
Different parameters of gametes, zygotes, embryos (“vacuoles in sperm heads, spindle position in mature oocytes, cleavage intervals of zygote, and embryo developmental dynamics”) may correlate with aneuploidy rates. This knowledge may be applied in potential noninvasive preimplantation diagnostic methods. Several methods have been proposed and are currently further researched<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Sperm Selection====<br />
Intracytoplasmic morphologically selected sperm injection (IMSI) is common procedure in IVF treatment to improve fertilization rates in patients with poor semen quality. In addition, studies have found that IMSI improves embryo development and that spermatozoa with large vacuoles in their heads correlate with increased aneuploidy rates and disturbed chromosomal structures. Thus, selecting spermatozoa based on morphological hallmarks may decrease aneuploidy rates in the fertilized embryos. As with polar body biopsies, however, this approach will solely be applicable if evidence for severe male detrimental contribution is given<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Blastocoel Fluid Extraction====<br />
In addition, a less invasive retrieval of material for diagnosis could include the extraction of the blastocoel fluid. The cavity of the blastocyst, lined by the trophectoderm, is filled with this blastocoel fluid, which contains metabolites of both trophectoderm and inner cell mass origin. The retrieval does not require a biopsy but merely a small opening to extract the fluid and, thus, causes less harm to the embryo. Multiple studies have applied this method<ref name="PMID22020776"><pubmed>22020776</pubmed></ref> <ref name="PMID23148560"><pubmed>23148560</pubmed></ref> and it may in the future become of clinical relevance.<br />
<br />
<br />
[[File:Aspiration_of_the_Blastocoel_Fluid.jpeg|thumb|Aspiration of the Blastocoel Fluid using a ICSI pipette<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.]]<br />
<br />
<br />
Next to metabolites, the blastocoel fluid can contain DNA. Studies have shown that genomic DNA is present in about 90% of the blastocoel fluid samples tested. Typically the fluid is removed with an ICSI pipette from a day five blastocyst through its mural trophectoderm until the blastocyst fully collapses around the embryo. Several concerns regarding this method in a clinical setting have been raised. The collected DNA may be contaminated by the culture media that contains DNA fractions. The DNA may also be least representative of the actual embryos genome as the DNA may originate from abnormal or degenerated cells. Even though labelled noninvasive, the blastocyst still undergoes manipulation to some degree which may affect its viability. Thus, more research is required until this method can evolve from research to clinical use<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
====Proteomics====<br />
The protein secretome of blastocysts may be representative of its chromosome constitution Recent studies have found biomarkers such as lipocalin-1, interleukin-10, tumor necrosis factor, stem cell factor, and chemokine ligand 13 to be differently secreted by aneuploid blastocyst than by euploid ones. The most significant biomarker appears to be interleukin-10. Paired with novel proteomic technologies and mass spectrometry this knowledge when extended may contribute to a new invasive preimplantation genetic diagnosis method<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Embryo Morphology====<br />
Using time lapse imaging the embryo’s morphology can be closely observed and potential aneuploidy characteristics detected. Such characteristics may include the time of division to five cells, the time between the division from three to four cells, and the duration of the division from one to two and subsequently to three. In addition, the morphological quality of ICM an TE has been positively associated with aneuploidy or euploidy prognosis<ref name="PMID26246880"><pubmed>26246880</pubmed></ref>. These may give rise to an embryo quality screening prior to implantation<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
==References==<br />
<br />
<references/><br />
<br />
<br />
{{StudentPage2015}}</div>Z5017878https://embryology.med.unsw.edu.au/embryology/index.php?title=2015_Group_Project_6&diff=2070252015 Group Project 62015-10-21T07:30:22Z<p>Z5017878: </p>
<hr />
<div>{{ANAT2341Project2015header}}<br />
<br />
<br />
=Preimplantation Genetic Diagnosis and Screening=<br />
==Introduction==<br />
Preimplantation genetic diagnosis (PGD) and screening (PGS) are reproductive options for couples with known family histories of genetic disease or couples undergoing IVF procedures due to infertility issues. PGD can diagnose many genetic disorders caused by known chromosomal abnormalities (number and/or structure) or single gene mutations, and, thus decrease the risk of termination of pregnancy or miscarriages and enable such couples to have an unaffected child<ref name="PMID24907939"><pubmed>24907939</pubmed></ref>. Through major improvements in PGD/S and general laboratory technology, the testing for abnormalities in fetuses has shifted from prenatal diagnosis during the first 2 trimesters <ref> Blackburn, S.L. (2003) '''Maternal, Fetal & Neonatal physiology: a Clinical perspective''' (2nd ed.). Seattle: Saudners </ref>, testing for overall fetal growth, complications of pregnancy, and birth defects<ref> Sadler T.W.(2012) '''Langman's Medical Embryology''' (12th ed.) Philadelphia: Lipincott, Wiliams & Wilkins, a Wolters Kluwer Business </ref>, to an embryonic focus especially in advancements in Artificial Reproductive Technologies (ART)<ref><pubmed>20638568</pubmed></ref>. In 1990 PGD for a recessive X-linked disease resulted in the first live birth<ref><pubmed>2330030</pubmed></ref> and has since been incorporated in clinical routine and applied for a variety of genetic diseases, such as sickle cell anemia, thalassemia, or cystic fibrosis<ref name="PMID24907939"/>.<br />
[[File:Preimplantation Genetic Diagnosis Procedure.jpeg|700px|thumb| Simplified steps for PGD<ref name="PMID24907939"/>]]<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=0e-79qKllqk</html5media><br />
|-<br />
| Preimplantation Genetic Diagnosis<ref>IVF Florida (2011, December 11) IVF Florida - South Florida Fertility Specialists - Pre-Implantation Genetic Diagnosis [Video file]. Retrieved from https://www.youtube.com/watch?v=0e-79qKllqk</ref><br />
|}<br />
<br />
==History==<br />
The advances in reproductive technology during the second half of the 20th century, led to PGD's first clinical application in 1990 <ref>Harper, J. (n.d.). The history of PGD. Lecture. UCL Centre for PG&D and CRGH.University College London</ref>.<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
|Year<br />
|<br />
|- bgcolor="FFFAFA"<br />
| '''1967''' <br />
|First PGD on rabbit blastocysts (Gardner& Edwards) <ref name="PMID6036172"><pubmed>6036172</pubmed></ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1986''' <br />
|First Cleavage Biopsy (Wilton & Trounson)<ref>Wilton, L. J., & Trounson, A. O. (1986). Viability of mouse embryos and blastomeres following biopsy of a single cell. In Proceedings of the 18th Annual Conference of the Australian Society for Reproductive Biology, Brisbane, Australia.</ref><br />
|- bgcolor="FFFAFA"<br />
|'''1987''' <br />
|First Blastocyst Biopsy (Muggleton-Harris, Monk, Rawlings, & Whittingham)<ref name="PMID3372699"><pubmed>3372699</pubmed></ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1988''' <br />
|First Polar Body Biopsy (Yury Verlinksy)<ref> Verlinsky, Y., Pergament, E., Andresen, P., Enriquez, G., & Strom, C. (1989). Genetic analysis of polar body DNA: A new approach to preimplantation genetic diagnosis. Am J Hum Genet, 45(4), A272.</ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1990''' <br />
|First Clinical PGD using PCR testing for X-linked (Handyside, Kontogianni, Hardy, & Winston)<ref name="PMID2330030"><pubmed>2330030</pubmed></ref> <br />
|} <br />
==Preimplantation Genetic Diagnosis==<br />
Preimplantation genetic diagnosis (PGD) is used to test the genetic makeup of embryos to detect single gene disorders, chromosomal abnormalities and mitochondrial disorders. It also has applications in gender selection for diseases with unequal gender distributions <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Some diseases commonly involved with PGD include cystic fibrosis, spinal muscular atrophy and beta – thalassaemia <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press.">Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press</ref> <ref name="PMID17823145"><pubmed>17823145</pubmed></ref>. It was first used in the United Kingdom in the 1980s of arenoleucodystrophy and primarily focusing on sex- linked disorders <ref name="PMID17823145"/><ref name="PMID23150080"><pubmed>23150080</pubmed></ref>. PGD is now capable of detecting single cell defects (molecular) and chromosomal disorders resulting from the inversion, translocation or deletion of chromosomes (cytogenic) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>,<ref name="PMID11325751"><pubmed>11325751</pubmed></ref>. PGD can be applied to the embryo at different stages. That is on polar bodies, blastomeres or blastocyst <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>.<br />
Depending on the type of genetic disorder, PGD utilises different methods of genetic testing. These include Fluorescence in situ hybridisation (FISH) which is used for sex – linked disorders and detects chromosomal rearrangements <ref name="PMID11325751"/><ref name="PMID17876073"><pubmed>17876073</pubmed></ref> and Embryo halotyping which allows the identification of chromosomes causing the inherited disorder through knowledge of the pattern of closely linked markers <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. Polymerase chain reaction (PCR) is also widely used to detect molecular abnormalities <ref name="PMID11325751"/>.<br />
PGD is tightly regulated and supported by large organisations namely The American Society for Reproductive Medicine, The European Society for Human Reproduction and Embryology (ESHRE), The European Society of Human Genetics and the Preimplantation Genetic Diagnosis International Society <ref name="PMID25500181><pubmed>25500181</pubmed></ref>.<br />
===Sex-linked disorders===<br />
The determination of a disease as gender specific usually correlates with the presence or absence of specific genes such as SRY on the Y chromosome. It is known that females have two X chromosomes and males have an X and a Y chromosome where abnormalities are more prevalent on the X chromosome. PGD can be used for sex selection where only male embryos are transferred to reduce the chance of inheriting X-linked disorders. However, this does not completely eradicate the problem as male embryos remain susceptible to inheriting an affected X chromosome. Sex determination is only used when the specific mutation is unknown and has yet to be discovered <ref name="PMID24866878"><pubmed>24866878</pubmed></ref>.<br />
===Single gene defects===<br />
Single gene defects can be dominant, recessive, autosomal or X-linked. They are commonly diagnosed using PCR and although the PCR available today is complex and capable of combatting a large range of disease the development of new protocols has been proven to be difficult due to the small DNA sample available <ref name="PMID26168107"><pubmed>26168107</pubmed></ref><br />
===Mitochondrial disorders===<br />
Mitochondrial disorders also known as oxidative phosphorylation disorders arise from mutations in the nuclear DNA or mitochondrial DNA <ref name="PMID26312584"><pubmed>26312584</pubmed></ref>. They pose as a problem because they are unrecognisable until the mutations in the cell reach a detrimental level <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Mitochondrial disorders cause miscarriages and stillbirths as well as death in children and young adults. The effects can either be contained in a single organ or more commonly involve multiple organ failure where organs with high energy demands such as the brain, liver muscle and heart and heavily influenced. They are usually occur spontaneously or result from inheritance from the mother. Since mitochondria are solely inherited from the mother oocyte donations have been used as a solution to combat mitochondrial disorders. Additionally, there has been an increasing use in PGD where embryos that stay under the given threshold of 18% gene-mutations are allowed to be transferred and result in normal development. New technology in the areas of nuclear gene transfer and genome editing are also being experimented with <ref name="PMID26312584"/>. <br />
===Chromosomal disorders===<br />
Chromosomal disorders can be reciprocal, Robertsonian translocations, inversions, deletions and insertions <ref name="PMID26168107"/>. . Data from ESHRE collected between 2010 and 2011 has shown that the most common chromosomal abnormality confronted in PGD are reciprocal chromosomal abnormalities <ref name"PMID26071418"><pubmed>26071418</pubmed></ref>. PGD has also been used successfully for Robertsonian translocations (RT), a type of structural translocation. Children who carry RT are phenotypically normal, however in their later years it is found that they will suffer from infertility and repeated miscarriages due to the high frequency of abnormal embryos <ref name="PMID22081077"><pubmed>22081077</pubmed></ref>. PCR and FISH are the two main techniques used for chromosomal disorders. To be able to conduct the examinations the cells are required to be at the metaphase stage <ref name="PMID26168107"/>. <br />
==Preimplantation Genetic Screening==<br />
Prenatal Genetic Screening (PGS) involves an array of methods or ideas that aim to segregate embryos that have genetic flaws and those that are healthy <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. The occurrence of aneuploidy is high around the stages of early embryonic development and they are the most common cause if miscarriages and congenital birth defects <ref name= "PMID26085841"><pubmed>26085841</pubmed></ref>. They have little effect on the morphology of the embryo making them difficult to identify thus identification heavily relies on genetic testing <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. <br />
Genetic sampling is most commonly conducted using Microarray Comparative Genomic Hybridisation (aCGH) as well as FISH, Quantitative PCR and Single Nucleotide Polymorphism (SNP) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. These methods collectively aim to assess numeral and structural chromosomal errors <ref name= "PMID26085841"/>. Studies have also introduced Next- Generation Sequencing (NGS) <ref name= "PMID26085841"/> and Whole Genome Amplification used to screen imbalances in the complete 24-chromosomes <ref name="PMID25953353"><pubmed>25953353</pubmed></ref><br />
Statistics from ESHRE have shown that the most common indications for PGS is advanced age, followed by repeated implantation failure or recurrent miscarriage and male infertility <ref name="PMID26071418"><pubmed>26071418</pubmed></ref>.<br />
====Indications====<br />
A low percentage of structural abnormalities in chromosomes are responsible for the cause of miscarriages. Despite this, they are the most prevalent type of chromosomal abnormality accounted for in PGD <ref name="PMID20638568"/>. The presence of specific gene cycles, initiation of embryonic protein synthesis and evident physiological development are all indicative of a successful in vitro fertilisation procedure <ref name="PMID11576737"><pubmed>11576737</pubmed></ref>. To eliminate further errors from occurring during the PGD procedure it is recommended to undertake further prenatal testing such as amniocentesis in the later stages <ref name="PMID20638568"/>. <br />
=====Advanced maternal age=====<br />
Data provided by the ESHRE has shown that the mean age of women undergoing PGS is 39 years <ref name="PMID26071418"/>. Women of advanced age have been shown to have a lower rate of pregnancies reaching childbirth <ref name="PMID18583331"><pubmed>18583331</pubmed></ref>. The highlighted concern revolves around the increased occurrence of aneuploidy following maternal age. The optimal age range for the lowest aneuploidy incidence was found to be between 27 to 37 years of age (6%) then progressively higher in women aged up to 42 (33%) and most common in those 44 and above (53%) <ref name="PMID24355045"><pubmed>24355045</pubmed></ref>. <br />
=====Recurrent pregnancy loss / IVF failure=====<br />
Recurrent pregnancy loss is defined as three or more IVF failures after cumulative transfer of more than 10 good-quality embryos. These are primarily caused by two main factors, reduced endometrium receptivity or embryonic defects. Endometrium receptivity can be negatively influences by instances including uterine pathologies such as thin endometrium, altered expression of adhesive molecules and immunological factors. Additionally, embryonic defects may be due to genetic abnormalities, embryonic aneuploidy or zona hardening. Endometriosis and hydrosalpinx has been known to effect both the endometrium and embryo <ref name="PMID23260857"><pubmed>23260857</pubmed></ref>.<br />
=====Human leukocyte antigen matching=====<br />
First used in 2001, HLA matching is an option given to parents to save a child with haematological or immunological disease through conceiving another child who would potentially be able to donate cord blood or haematopoietic stem cells from the bone marrow for transplantation. The process namely PGD-HLA has shown to improve haematopoietic stem cell transplant (HSCT). PGD-HLA can only be performed when HSCT is not needed urgently due to the time needed to conceive and delivery the baby <ref name="PMID25500181"><pubmed>25500181</pubmed></ref>. It is most commonly applied to children suffering from relapsed leukaemia <ref name="PMID22524201"><pubmed>22524201</pubmed></ref>. In a case study PGD-HLA was proven to successfully cure 10 diseases including Fanconi anaemia, Diamond-Blackfan anaemia and beta thalassemia <ref name="PMID25066893><pubmed>25066893</pubmed></ref>.<br />
==Biopsy Methods==<br />
Biopsy, the removal of genetic materials, from oocytes or embryos in the preimplantation stage is the primary step in PGD. For the past two decades these biopsies have been performed at three stages, the polar body, blastomere, and blastocyst, and the methodologies optimized to ensure the embryo’s viability. The most common approach involves biopsies at the cleavage stage. However, polar body and blastocyst biopsies are increasingly more often tested and applied. Approached for opening the zona pellucida involve next to the traditional mechanical and chemical means, novel approaches such as noncontact lasers. Their application may simplify and secure the procedure significantly. The most challenging question about PGD procedures remains at what stage biopsies should be taken. Much controversy has developed around this topic, highlighting the varying disadvantages and advantages of temporal biopsies. <ref name="PMID22723007"><pubmed>22723007</pubmed></ref><br />
<br />
{| class="wikitable"<br />
|- align="center" bgcolor="DDCEF2"<br />
|<br />
| Time of Biopsy<br />
| Advantages <br />
| Disadvantages<br />
|- bgcolor="FFFAFA"<br />
| Polar Body<br />
| Day 1<br />
| No harm to oocyte<br />
| Only maternal DNA is tested, often needs to be coupled with other biopsies<br />
|- bgcolor="FFFAFA"<br />
| Blastomere<br />
| Day 3<br />
| …<br />
| … <br />
|- bgcolor="FFFAFA"<br />
| Trophectoderm<br />
| Day 5 and 6 <br />
| Little harm, large amount of genetic material<br />
| Opening of blastocyst necessary, small time window for procedure<br />
|}<br />
<br />
<br />
[[File:Polar_Body,_Blastomere,_and_Trophectoderm_Biopsy.jpeg|thumb|Polar body (A), blastomere (B) and trophectoderm (C) biopsies<ref name="PMID25625041"><pubmed>25625041</pubmed></ref>.]]<br />
<br />
<br />
<br />
PMID 24305177<br />
===Polar Body Analysis===<br />
Day 1<br />
====Description====<br />
Polar body (PB) biopsy, which was introduced in 1990, offers a promising alternative to biopsies performed at the blastomere stage for PGD/S indications on legal and practical grounds. <br />
Description: Consequent embryo development does not necessitate the presence of the first and second PB and their removal may not be crucial. PB biopsy requires precise timing. Keeping track of the meiotic cell cycle is necessary to perform a successful biopsy and, therefore, PB biopsy usually is applied in combination with intracytoplasmic sperm injection (ICSI). During the maturation from the germinal vesicle stage to the metaphase-II stage the first PB is formed. A cytoplasmic bridge containing spindle remnants, that are still in contact with the cellular genetic material, links this PB to the oolemma for about 90 minutes after extrusion. It is possible to visualize these remnants by polarization microscopy and it is crucial to not perform the biopsy until the first PB is no longer firmly attached to the oolemma as this indicates an immature embryo.The oocyte tolerates mechanical zona dissection best during hours four until six after ICSI as the oolemma has stabilized by that time because of the cortical granule reaction. Over time the first PB degenerates stressing a temporal biopsy and its optimal extraction time window is four to 12 hours after ICSI. The second PB forms around two to four hours after ICSI. However, its optimal time window for biopsy is set to be eight to 16 hours after ICSI. This is due to the second PB being attached to the oolemma with spindle remnants until six hours after ICSI. Biopsy at this point may cause enucleation of the oocyte. In addition, studies have shown that the amplification efficiency of second PB’s DNA is worse if the PB is extracted prior to eight hours after ICSI. <br />
Thus, it is possible to perform sequential and simultaneous biopsies for the first and second PB. If performed, sequentially the first PB may be removed four to 12 hours and the second PB eight to 16 hours after ICSI. The optimal time window for a biopsy for both the first and second PB simultaneously is eight to 12 hours after ICSI. It is highly preferred to analyze both PBs due to potential aneuploidies in either PB and crossing overs during meiosis<ref name="PMID22723007"/>. <br />
====Procedure====<br />
Chemical opening achieved with for example acidic tyrode’s solution of the zona pellucida is not tolerated by the oocyte and may have detrimental effects on the embryo’s development. Therefore, the access to the perivitelline space of the oocyte is provided by mechanical zona dissection or by laser. Both techniques work well if performed by experienced embryologist. However, laser-assisted biopsy is less time consuming when compared to manual dissection. It is critical to consider the size of the introduced opening as it will remain permanent. If it is too large the blastomere may be lost during embryo development and if it is too small it may interfere with hatching of the embryo during blastocyst stage<ref name="PMID22723007"/><br />
<br />
[[File:Polar_Body_Biopsy.jpeg|thumb|The presence of a faint but clearly identifiable strand connecting PB2 to the <br />
oolemma. The biopsy was performed ∼9 h after ICSI<ref name="PMID21908464"><pubmed>21908464</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JTaQzszVr8o</html5media><br />
|-<br />
| Laser-assisted polar body biopsy<ref>RIUK, R. (2013, June 25) Polar Body Biopsy [Video file]. Retrieved from https://www.youtube.com/watch?v=JTaQzszVr8o</ref><br />
|}<br />
<br />
====Advantages & Disadvantages====<br />
PB biopsies can only investigate the maternal contributions to the embryo as they are of maternal origin. Thus, this procedure is appropriate for PGD solely for monogenetic diseases from the maternal side. Recessive diseases may be evaluated with PB biopsies on the basis that the embryo’s outcome will be determined by the paternal contribution. (...) It may still be applied for PGS as most aneuploidies either arise during meiosis or origin from the maternal genome. However, diagnosis error has been reported due to the lack of considering paternal contributions. <br />
Because PB biopsies are performed very early it is not yet known whether the oocyte will develop into a viable embryo. Thus, PBs are commonly frozen or fixed after biopsy and depending on the state of the embryo only chosen PBs will be tested. This is primarily an economic issue as many genetic testing procedures are very cost-intensive<ref name="PMID22723007"/>.<br />
<br />
[[File:Implantation_predictive_value_of_euploid_screening_results.jpeg|thumb|The sustained implantation predictive value (with 95 % confidence interval) of a euploid screening result obtained from the first polar body (PB1), PB1 and the second polar body (PB2), or a direct embryo biopsy for each stage of embryo transfer (cleavage-stage and blastocyst stage)<ref name="PMID25106935"><pubmed>25106935</pubmed></ref>.]]<br />
<br />
===Blastomere biopsy===<br />
Day 3 <br />
====Description====<br />
Blastomere biopsy has been the prevalent method for PGD and PGS in the last two decades. At least one, but up to two, blastomeres are biopsied on day three of the cleavage stage embryo. The right number of blastomeres removed is a controversial topic as two cells allow for more genetic material and more accurate results. However, removing two cells might be too invasive and damaging to the embryo. (Study)<ref name="PMID21748341"><pubmed>21748341</pubmed></ref><br />
====Procedure====<br />
Initially a hole was drilled into the zona pellucida using acid tyrodes and the blastomeres are removed via aspiration with a pipette<ref name="PMID21748341"/>.<br />
<br />
<br />
[[File:Aspiration_of_a_Blastomere.jpeg|thumb|Aspiration of a Blastomere into the biopsy pipette<ref name=" PMID24783200"><pubmed>24783200</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=TbridWVwipI</html5media><br />
|-<br />
| Laser-assisted blastomere biopsy<ref>Sukprasert, M. (2014, March 5) Day 3 Blastomere Biopsy 1 [Video file]. Retrieved from https://www.youtube.com/watch?v=TbridWVwipI</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
===Trophectoderm biopsy===<br />
Day 5 and 6<br />
====Description====<br />
The improvement of embryo culture media allowed the in vitro development of human embryos until the blastocyst stage and opened up the possibility to take blastocyst biopsies. During day three to day five the haploid maternal and paternal genomes work together for the first time to form the genome of the embryo. The maternal epigenetic control lessens significantly while preparing for implantation with precisely arranged events happening. The first event includes a rapid increase in the number of embryonic cells which are active in mitotic divisions and apoptosis of aberrant cells. This is followed by the formation of blastocoel (cavitation) which results from the flattening of cell located on the outside of the blastomere. Now the blastocyst will expand until the embryo hatches by rupturing the zona pellucida. The cells of the blastocyst will differentiate to form two distinct cell lineages, the outer trophectoderm and the inner cell mass<ref name="PMID22723007"/>.<br />
====Procedure====<br />
Trophectoderm biopsy is usually performed in Hepes buffered biopsy medium and opening approaches include needle cutting which has been replaced by lasers in past years. Different research groups report different timings of the opening to be the most successful. Some open the blastocyst on day three or four by creating a 25 µm which causes the trophectoderm to herniate through this hole and is, thus, accessible for biopsy. Others create this hole about four hours before biopsy which allows sufficient herniation of trophectoderm cells. It is also possible to open the blastocyst immediately before biopsy. This avoids an extra step and the inner cell mass usually is easy to locate. Blastocyst biopsies involve the removal of trophectoderm cells and the ideal time for the procedure is day five. Successful biopsies on day six have been performed, while little is known about the results of biopsies on day seven. However, since the window of implantation in humans is from day eight to ten after ovulation, day seven biopsies appear to be possible<ref name="PMID22723007"/>.<br />
-collapse of trophoblasts<br />
-possible: biopsy of hatched blastocyst, holding pipette careful mild suction force to hold embryo near ICM <br />
-Cryopreservation<br />
<br />
<br />
[[File:Microscopic images of human blastocysts for biopsy.jpeg|thumb|(A) Some trophectoderm cells in a blastocyst started to hatch and (B) the trophectoderm cells were biopsied with assisted laser cutting. Images in C–D show the blastocysts after vitrification and warming. Blastocysts had been cultured for 2–4 hrs after warming, showing good (ICM and trophectoderm cells) hatched (C) and hatching (D) blastocysts. The hatching blastocyst in (E) has good ICM but fair trophectoderm while the blastocyst in (F) has both fair ICM and trophectoderm. Arrows indicate ICMs and arrow heads indicate trophectoderm cells. Bar = 40 µm<ref name="PMID2190846"><pubmed>2190846</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JI_TQ8d8tNM</html5media><br />
|-<br />
| Laser-assisted blastocyst biopsy (at 00:50 min)<ref>Coco, R. (2014, April 30) Trophectoderm biopsy in a Hatching blastocyst protruding ICM [Video file]. Retrieved from https://www.youtube.com/watch?v=JI_TQ8d8tNM</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
Blastocyst biopsies are believed to be less damaging to the embryo and appear to be unrelated to implantation rates. In addition, this biopsy method allows for a larger extraction of cells for genetic testing. However, since they are performed late in in vitro development, the time window for genetic testing is relatively small. Fast and accurate genetic testing methods are needed to ensure a successful and safe result from this biopsy. Thus, blastocyst biopsies may gain more popularity in the future whn such methods have been developed or improved<ref name="PMID22723007"/>. <br />
<br />
<br />
==Genetic Techniques==<br />
<br />
===PCR===<br />
====Description====<br />
Polymerase chain reaction (PCR) amplifies DNA specific to genetic sequence of interest . PCR was developed by Kay Mullis in the 1980s, for which he was awarded the Nobel prize for chemistry in 1993. <ref> Pubmed Docs (2015) Polymerase Chain Reaction (PCR) Pubmen. Retrieved from [http://www.ncbi.nlm.nih.gov/probe/docs/techpcr/]</ref> This technique enables clinicians to monitor and diagnose diseases using minute samples such as embryonic cells, blood & tissue. <ref>Roche (2015) PCR: How We Copy DNA. Roche Molecular Systems Inc. retrieved From [http://molecular.roche.com/pcr/Pages/Process.aspx]</ref> PCR has many important applications like DNA fingerprinting, genetic mapping, detection of viruses and bacteria as well as being used to detect genetic disorders, as a part of PGD, in conjunction with IVF. It is used to detect molecular abnormalities such as single gene disorders like Tay Sach, Cycstic fibrosis, Duchenne Muscular Dystrophy, Thalassemia, Huntington disease, Spinal muscular atrophy and many more. Molecular and Genetic analysis require a significant amount of DNA, which we would not have without PCR. It revolutionized the study of DNA, replacing all previous recombinant DNA technology. <ref> Mullins, K., Francois, F.& Gibbs R.A. (1994 ) The Polymerase Chain Reaction. p3. Springer- Science +Business Media. Birkhauser, Boston<br />
Available at [https://books.google.com.au/books?hl=en&lr=&id=gjrTBwAAQBAJ&oi=fnd&pg=PR5&dq=kary+mullis+PCR&ots=mpzAyRh5ZY&sig=PQ4goNoKJ90tb3-MkPk62zrTGbw#v=onepage&q=kary%20mullis%20PCR&f=false] </ref> <br />
<br />
[[File:PCR.jpg|thumb|right|Polymerase chain reaction (PCR) amplifies DNA specific to genetic sequence of interest, enabling the monitoring and diagnose molecular abnormalities such as single gene disorders using minute samples such as embryonic cells, blood & tissue <ref>NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref>]]<br />
<br />
====Procedure====<br />
<br />
Sample are obtained from the the blastocyst, a polar body biopsy or the blastomeres stages of the embryo. <br />
Stage 1 Denaturing: separating the target strands of DNA <br />
The obtained sample is heated to roughly 90 degrees celcius, this heat causes breaks the relatively weak bonds between nucleotides that form DNA. the double stranded DNA to split into 2 single strands of DNA that are used as templates.<br />
Stage 2 Annealing: Binding the Primers to the target DNA sequence <br />
PCR will only copy the target sequence of DNA specified by specific PCR primer. These synthesized primers Oligonucleotides are small artificial pieces of DNA. <br />
TAQ polymerase enzyme synthesize 2 new strands of DNA duplicate to the single sample DNA stand template indicated by these primers. During this stage the reaction is cooled to a temperature between 40-60 degrees Celsius. <br />
Stage 3- Extension- making copies <br />
Each of these 2 copies are then used again as templates generating 2 further replications This cycle can occur as many 30 -40 times within a couple hours leading to billions of extra copies of the original DNA segment. The optimal temperature for the further replication is roughly 72 degrees Celsius. <br />
<br />
This process mediated by a thermocycler machine that is programmed to alter the temperature of the reaction every couple of minutes, perpetuating the cycle of DNA denaturing and synthesis. <br />
This process, generates exponential exact copy of the original template DNA sequence. <br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
!PCR cycles<br />
<br />
|{|<br />
|-<br />
| '''PCR Cycle'''<br />
| '''Target Copies'''<br />
|-<br />
| 1<br />
| 2<br />
|-<br />
| 2<br />
| 4<br />
|-<br />
| 3<br />
| 8<br />
|-<br />
| 4<br />
| 16<br />
|-"<br />
| 5 <br />
| 32<br />
|-<br />
| 6 <br />
| 64<br />
|-<br />
| 7 <br />
| 128<br />
|-<br />
| 8<br />
| 256<br />
|- <br />
| 9<br />
| 512 <br />
|-<br />
| 10<br />
| 1024<br />
|-<br />
| 15<br />
| 32,768<br />
|-<br />
| 20 <br />
| 1,048,578<br />
|-<br />
| 25<br />
| 33,554,432<br />
|-<br />
| 30 <br />
| 1,073,741,842<br />
|-<br />
|}<br />
<br />
<br />
<br />
{| class="wikitable" <br />
|-bgcolor="#9ACD32" <br />
| rowspan="10" |'''Advantages'''<br />
|-bgcolor="#F0FFF0"<br />
| fast and inexpensive way of copying a target sequence of DNA<br />
|-bgcolor="#F0FFF0"<br />
| aids the diagnosis of single cell defects<br />
|-bgcolor="#F0FFF0"<br />
| rapid generation of results within a couple hours<br />
|-bgcolor="#F0FFF0"<br />
| can start from a single molecule of DNA, therefore is more sensitive <br />
|-bgcolor="#F0FFF0"<br />
| has a flexible primer design enabling<br />
|-bgcolor="#F0FFF0"<br />
| overcame previous issues associated with the limited availability of sites of end<br />
|-bgcolor="#F0FFF0"<br />
| generates the DNA copies exponentially<br />
|-bgcolor="#F0FFF0"<br />
| enables DNA amplification required for molecular and genetic analysis<br />
|-bgcolor="#F0FFF0"<br />
|Valid diagnostic method in selecting unaffected embryos for embryo transfer <ref> Dreesen, J., Drusedaul, M., Smeets, H., Die-Smulders, C., Coonen, E., Dumoulin, J., Gielen, M., Evers, J., Herbergers, J. & Geradets, J. (2008) Validation of preimplantation genetic diagnosis by PCR analysis: genotype comparison of the blastomere and corresponding embryo, implications for clinical practice. Mol. Hum. Reprod. 14 (10):573-579.doi: 10.1093/molehr/gan052. Retrieved from [http://molehr.oxfordjournals.org/content/14/10/573.short] </ref> <ref><pubmed>20966460</pubmed></ref><br />
|-bgcolor="#9ACD32"<br />
| rowspan="5"|'''Disadvantages'''<br />
|-bgcolor="#F0FFF0"<br />
| only during this exponential DNA replication phase can we determine the starting quantity sequence contained in the original sample ( template DNA strand)<br />
|-bgcolor="#F0FFF0"<br />
| PCR reaction is limited by the presence of inhibitors present in the sample : reagent inhibitors <br />
|-bgcolor="#F0FFF0"<br />
| self annealing due to the accumulation of the product -stopping exponential amplification for the target sequence and reach a plateau<br />
quantification of the end point of reaction of PCR products unreliable - therefore that is why we require real time quantitative RT-PCR necessary<br />
<ref> NIS (2015) Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref><br />
|}<br />
<br />
<br />
===Fluorescent In Situ Hybridisation (FISH)===<br />
<br />
<br />
====Description====<br />
Fluorescence in situ hybridization (FISH) the one of the most effective and rapid <ref name="PMID26338801"><pubmed>26338801</pubmed></ref> Preimplantation Genetic Diagnosis (PGD). This techniques used to locate a specific DNA sequences within a chromosome. FISH facilitates the clinical diagnosis of chromosomal abnormalities indicated by sequential duplications, deletions and rearrangements of chromosome, that are usually missed with microscopic analysis. This technique is especially relevant for female embryos with X-linked diseases,<ref name="PMID20809319"><pubmed>20809319</pubmed></ref> that have no other mutation specific tests [http://www.ncbi.nlm.nih.gov/pubmed/20809319] As part of PGD, samples are collected from various stages of the embyro,and they are able to conducted tests on the blastocyst, a polar body biopsy and the blastomeres <ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. FISH is 99% effective when used in conjunction with competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities<ref name="PMID26338801"/>.<br />
<br />
====Procedure==== <br />
<br />
Samples are collected from either the blastocyst, a polar body biopsy or the blastomeres stages of the embryo <ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
DNA strands are heated and denatured causing their the individual DNA strands to break apart<br />
Probes are single complimentary stands of DNA a that have been tagged with small chemical agents that glow brightly in the presence of a specific region on a chromosome. These specific probes then hybridize and join to their complementary DNA strand. <br />
The fluorescent tags enable the researchers to correctly identify the presence or lack thereof and location of the specific chromosomes that they are testing for. <ref name="PMID17876073"><pubmed>17876073</pubmed></ref><br />
Researcher analyse the results by identifying the number and the relative location of the fluorescent dots generated by the FISH images.<ref name="PMID17970921"><pubmed>17970921</pubmed></ref><br />
The probe will not fully hybridise if there has been a duplication or a deletion of the DNA - indicating chromosomal and sex chromosomal anomalies like trisomies and aneuploidies. <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref><br />
<br />
<br />
Different probes are used for different purposes: <ref>Unique, Rare Chromosome Disorder Support Group (2013) Fluorescence in situ hybridisation (FISH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/Other/FISH%20FTNW.pdf]</ref><br />
*'''Locus specific tags''' detect very small imbalances, and locate isolated small portions <br />
of genes within a chromosome<br />
*'''Alphoid/Centomeric Repeat probes''' are developed from the repetitive sequence located in the middle region of each chromosome, useful in determining the number of chromosomes , detecting rearrangement and when used in conjunction with locus probes to determine the absence of genetic material on a chromosome. <br />
*'''Paint Probes''' are collections of smaller probes with their own stains that bind to a different section on the chromosome - allowing the full chromosome too be labeled a unique colour, this "full colour map" can be used to know the spectral karyotype- full chromosomal mapping is useful in examining chromosomal abnormalities. <br />
<br />
[[File:Fluorescent In Situ Hybridisation (FISH).jpg|thumb|right|'''FISH''' We are able to tag Specific DNA sequences using Probes which have been tagged with fluorescent Labels.This technique enables the clinical diagnosis of chromosomal abnormalities, indicated by sequential duplication, deletions and rearrangements of chromosome <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref>]]<br />
<br />
{|class="wikitable" align="center"<br />
|-bgcolor="pink" <br />
| rowspan="8" |'''Advantages''' <br />
|-bgcolor="#FDE1F2" <br />
| FISH is 99% effective when used in conjunction with Competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities.<ref><pubmed>26338801</pubmed></ref><br />
|-bgcolor="#FDE1F2" <br />
| Rapid generation of results<br />
|-bgcolor="#FDE1F2" <br />
| Identifies very small translocations and aneuploidies that occur within chromosomes, that would usually be missed under microscopic analysis<br />
|-bgcolor="#FDE1F2" <br />
| Indicates whether the accessed chromosomes are normal <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|-bgcolor="#FDE1F2" <br />
| Tests for the most common chromosomal abnormalities - down syndrome chromosomes 13,16,18,21 and 22 <ref><pubmed>21749752</pubmed></ref><br />
|-bgcolor="#FDE1F2" <br />
| It may be used to compare the chromosomal gene arrangements in related species<br />
|-bgcolor="#FDE1F2" <br />
| can be used to identify and remove inheritable X-linked disease or sex chromasome anomalies such as Duchennes Muscular Dystrophy, hemophilia, ectodermal dysplasia <ref><pubmed>17876073</pubmed></ref><br />
|-bgcolor="#FEB745"<br />
| rowspan="5"|'''Disadvantages'''<br />
|-bgcolor="#FE1C5EA"<br />
| FISH destroys all cells tested <ref> O'Connor, C. (2008) Fluorescence in situ hybridization (FISH). Nature Education 1(1):171. retrieved from [http://www.nature.com/scitable/topicpage/fluorescence-in-situ-hybridization-fish-327] </ref><br />
|-bgcolor="#FE1C5EA"<br />
| It does not fully access all chromosomes (only ~ 12)<br />
|-bgcolor="#FE1C5EA"<br />
| Analysis of results is dependent upon the dot quality impacted by hybridisation efficiency or the camera sensitivity <ref><pubmed>17970921</pubmed></ref><br />
|-bgcolor="#FE1C5EA"<br />
| some studies indicate that using FISH on a day-3 embryo biopsy decreases the rate of live births <ref><pubmed>26168107</pubmed></ref><br />
|}<br />
<br />
===Array Comparative Genomic Hybridisation (aCGH)===<br />
====Description====<br />
<br />
aCGH also known as Microarray analysis efficiently scans the entire genome for chromosomal imbalances. CGH was initially developed to detect the number of changes in a solid tumor mass. It uses 2 genomes comparing the sample to the control, with each labeled in a different fluorescent dye<ref name="PMID1876176"><pubmed>1876176</pubmed></ref>. Earlier CGH techniques were limited by the resolution of the imaging <ref> Lichter, P., et al. Comparative genomic hybridization: Uses and limitations. Seminars in Hematology 37, 348–357 (2000)</ref> , these initial limitations were overcome by using Microarrays in conjunction with CGh to improve the resolution of the imaging, Array Comparative Genomic Hybridisation (aCGH). This method compares sample and control microarrayed slides containing small segments of DNA (probes). <ref> Lucito, R., et al. Representational oligonucleotide microarray analysis: A high-resolution method to detect genome copy number variation. Genome Research 13, 2291–2305 (2003) </ref> the Probes used will vary according from the small (25-85 base pairs) oligonucleotides manufactured to highlight different target sequences, to the very large genomic clones (80,000- 200,00 base pairs), and as these are significantly smaller than the traditional metaphase chromosomes used for CGH, generating a higher resolution of image. <ref name="PMID22467166"><pubmed>22467166</pubmed></ref>.aCGH is used as a diagnostic tool for prenatal detection f chromosomal abnormalities <ref name="PMID19012303"><pubmed>19012303</pubmed></ref>.<br />
<br />
<br />
====Procedure====<br />
<ref> Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432] </ref><br />
The sample is obtained (skin, blood or fetal cells) and DNA is obtained. <br />
As a part of PGD fetal cell samples are collected from; the fertilized egg polar bodies, the blastomere (day 3 embryo) or the blastocyst/tropoectoderm stage (day 5 embryo).<br />
Sample DNA is labeled with one fluorescent dye, and the control DNA is labeled with a different colored fluorescent dye. the control DNA is used as the base point of reference. <br />
heated and denatured single DNA strands then hybridize to their complementary single strand probes, which are then combined and applied to a microarray and the results are run through a computer program and a digital imaging system is used to quantify the results( fluorescent intensities of the labeled probes). <br />
<br />
[[File:aCGH.jpg|thumb|right|'''aCGH''' checks the entire genome for chromosomal imbalances, by comparing control and a sample slides contatining small segements of DNA sample microarrayed slides small segments of DNA. Illustrated by student z5020317 and adapted from <ref> NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation. retrieved from [http://www.phgfoundation.org/file/5237/]</ref> <ref>Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432]</ref>]]<br />
<br />
<br />
<br />
The fluorescent ratio and the hybridization signal at different locations on the genome of the control DNA are used to identify any variances present in the sample DNA. aCGH facilitates the clinical diagnosis of submicroscopic chromosomal duplication, deletion and rearrangements indicative of chromosomal disorders such as trisomies 1-22and specific sex linked disorders. <br />
Duplications in the DNA are displayed by the computer program as spikes/ peaks over an established threshold and deletions in DNA are displayed by the computer program as spikes/ toughs beneath this threshold <br />
<br />
<br />
<br />
<br />
{|class="wikitable" align="center"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="12" |'''Advantages''' <br />
|-bgcolor="FFFAFA"<br />
| Multiple applications: prenatal genetic diagnosis, cancer diagnosis, <ref name="PMID20193845"><pubmed>20193845</pubmed></ref> genetic screening for developmental delay (learning disabilities) <ref name="PMID17309648"><pubmed>17309648</pubmed></ref>. or congenital anomalies that are suspected to be genetic in origin <ref>NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation . retrieved from [http://www.phgfoundation.org/file/5237/]</ref><br />
|-bgcolor="FFFAFA"<br />
| trace represents all chromosomes present in the human genome chromosomes 1-22 and the X & Y chromosomes, and therefore is the most accurate method for testing whole embryo aneuploidy<br />
|-bgcolor="FFFAFA"<br />
| aCGH has been extensively tested, and Validated, and is now used world wide.<br />
|-bgcolor="FFFAFA"<br />
| Detects submicroscopic alterations<br />
|-bgcolor="FFFAFA"<br />
| Detects deletions and additions and rearrangements as well as amplification, of the WHOLE genome, simultaneously.<br />
|-bgcolor="FFFAFA"<br />
| Used as a diagnostic tool for prenatal detection of chromosomal abnormalities <ref name="PMID22034057"><pubmed>22034057</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Provides high resolution genomewide screening of segmental genomic copy number variations<br />
|-bgcolor="FFFAFA"<br />
| Very accurate when used in conjunction with FISH<br />
|-bgcolor="FFFAFA"<br />
| Alone is more reliable and in detecting chromosomal abnormalities, with a higher implantation success rate, than FISH <ref name="PMID20494259"><pubmed>20494259</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Allows an in depth research focus upon specific types of rearrangements within selected chromosomal regions, a recent particular area of interest is subtelomeric and pericentromeric rearrangements<br />
|-bgcolor="FFFAFA"<br />
| Reduces the risk of failed implantation and miscarriage, improving the chance of a healthy baby <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|-bgcolor="DDCEF2"<br />
| rowspan="9" |'''Disadvantages'''<br />
|-bgcolor="FFFAFA"<br />
| Translocations and inversions of DNA are not detected<br />
|-bgcolor="FFFAFA"<br />
| Limited ability diagnosing specific polyploidies such as triploidy <ref> Unique, Rare Chromosome Disorder Support Group (2013) Microarray-based Comparative Genomic Hybridiation (array CGH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/other/array%20cgh%20ftnw.pdf] </ref><br />
|-bgcolor="FFFAFA"<br />
| Will not detect mosaicism detection <20% (cultures where >1 of 5 cells are trisomy 12)<br />
|-bgcolor="FFFAFA"<br />
| Will not detect balanced chromosomal rearrangement<br />
|-bgcolor="FFFAFA"<br />
| Will not detect duplications or deletions <80kb<br />
|-bgcolor="FFFAFA"<br />
| Will not detect point mutations within genes <ref>Washington department of education (CGH- FAQ for physicians. Signature Genomic LAboratories, LLC. Retrieved from [https://depts.washington.edu/dbpeds/Lab%20Tests/SignatureCGH-physician_FAQ.pdf]</ref><br />
|-bgcolor="FFFAFA"<br />
| will not detect chromosomal position of genomic gains<br />
|-bgcolor="FFFAFA"<br />
| Will not detect loos of heterozygosity (LOH) or Absence of heterozygosity (AOH) <ref>WiCell Research Institute Inc. (2012) Comparative Genomic Hybridization Microarray. <br />
retrieved from [http://www.wicell.org/home/cytogenetic-services/cgh-microarray/array-comparative-genomic-hybridization-acgh.cmsx]</ref><br />
|}<br />
<br />
<br />
<br />
===Next Generation Sequencing===<br />
====Description====<br />
The development and advances within ART in the past 20 years, as well as the increasing popularity of IV, has lead to an influx of new technologies developed to screen embryos for chromosomal anomalies, which are covered by the umbrella term of Next generation Sequencing (NGS). NGS is a general term used to describe all of the new and emerging screening techniques currently being introduced and used as part of PGD for IVF . NGS screens for single gene disorders as well as conducting extensive and very comprehensive chromosome diagnosis by sequencing, counting, and accurately assembling millions of DNA reads, simultaneously. <ref name="PMID23499002"><pubmed>23499002</pubmed></ref> There is a movement for NGS to replace the other limited testing techniques and be used as the standard. <br />
====Procedure====<br />
Samples are collected from either blastomere or the blastocyst/tropoectoderm and processed for analysis by a computer system. <br />
The methodology of each process is unique to the technique being used. <br />
<br />
<br />
<br />
{|class="wikitable" align="center"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="14" |'''Advantages''' <br />
|-bgcolor="FFFAFA"<br />
| Cheaper<br />
|-bgcolor="FFFAFA"<br />
| Opens new diagnostic possibilities<br />
|-bgcolor="FFFAFA"<br />
| Accurately tests all 24 chromosomes<br />
|-bgcolor="FFFAFA"<br />
| Tests for the presence of monogenic diseases of known genetic background<br />
|-bgcolor="FFFAFA"<br />
| Reduces the number of biopsies required for diagnosis<br />
|-bgcolor="FFFAFA"<br />
| Higher detection rate of small translocations<br />
|-bgcolor="FFFAFA"<br />
| Highly accurate is testing for compound point mutations, chromosomal duplication, deletions and insertions <ref name="23312231"><pubmed>23312231</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| It accurately detects chromosomal aneuploidy and unbalanced rearrangement <ref name="PMID25685330"><pubmed>25685330</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Higher detection rate of small translocations<br />
|-bgcolor="FFFAFA"<br />
| NGS single gene disorder screenings can conducted in conjunction with PCR comprehensive chromosomal screening<br />
|-bgcolor="FFFAFA"<br />
| Reduces human error <br />
|-bgcolor="FFFAFA"<br />
| Better detects the presence of mosaicism<br />
|-bgcolor="FFFAFA"<br />
| Work well in conjunction with CGH and aCGH as part of PGD, improving the chances of IVF. <ref> Morris, R. S. (2015 ) Next generation sequencing for PCG|PGS|CCS. IVF1 retrieved from [http://www.ivf1.com/next-generation-sequencing for-pgd] </ref><br />
| rowspan="1" |'''Disadvantages''' <br />
| There are limited information available to clinical applications of NGS <ref><pubmed>26100406</pubmed></ref><br />
|}<br />
<br />
<br />
<br />
<br />
<br />
<br />
==Diagnosis==<br />
There are a large amount of diseases that PGD can apply to, below are descriptions of the diseases that PGD are more commonly used for. Utilization of Diseased Cell Lines<br />
===Cystic Fibrosis===<br />
Cystic fibrosis is a single gene disorder. It is autosomal recessive and involves mutations in the cystic fibrosis transmembrane conductance regulator (CTFR) gene. The CTFR gene is normally responsible for the decrease in chloride and the transport of bicarbonate in epithelial cells thus playing a major physiological role. In PGD procedures, identification of the gene is assisted by microsatellite markers that have similar composition to the CTFR gene itself. Biopsy of two cells at the blastocyst stage is recommended if markers are not available. There are many variations of cystic fibrosis the most common being P.Phe508del <ref name="PMID26014425"><pubmed>26014425</pubmed></ref>.<br />
===Duchenne Muscular Dystrophy ===<br />
Duchenne Muscular Dystrophy is an X-linked recessive disease. It involves the Xp21 gene where majority of the mutations are chromosomal deletions with a smaller percentage resulting from duplications <ref name="PMID18359022"><pubmed>18359022</pubmed></ref>.<br />
<br />
===Autosomal Recessive MEckel-Gruber Syndrome===<br />
Autosomal recessive genetic defect caused by the TMEM67 gene. It results in cystic dysplasia of the kidneys with fibrotic change in the liber and occipital encephalocele. Other malformations could also be present in the central nervous system. In PGD whole genome amplification of single blastomeres are taken to identify the gene, this is also coupled with PCR techniques. Maternal plasma can also be extracted for PGS. <ref><pubmed>24039893</pubmed></ref> <br />
===β – Thalassemia=== <br />
β – Thalassemia is known as the most common type of autosomal recessive inherited disorder among haemoglobinopathies. It involves the adult β-globin gene and is associated with the absent or decreased expression of the gene. This is commonly caused by a single nucleotide change in the gene. PGD has been used successfully worldwide to identify the β-globin gene where its application is usually performed on a single blastomere or polar body <ref name="PMID19064120">19064120</pubmed></ref>.<br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
! Applicable diseases for PGD <ref>Genoma Group (2014). Retrieved September 18th, 2015, from http://www.preimplantationgeneticdiagnosis.it/genetic-diseases-diagnosed-by-pgd.htm </ref>, <ref>Genesis Genetics (2015). Retrieved September 18th, 2015, from http://genesisgenetics.org/pgd/what-we-test-for/</ref>, <ref>Human Fertilisation & Embryology Authority (2015). Retrieved Septembr 18th, 2015, from http://guide.hfea.gov.uk/pgd/</ref><br />
|-<br />
| '''Disease'''<br />
| '''Involved Genes'''<br />
|-<br />
| 5 Alpha Reductase Deficiency (5ARD)<br />
| SRD5A2 <br />
|-<br />
| Achondroplasia<br />
|FGFR3 <br />
|-<br />
| Acute Intermittent Porphyria <br />
| ALAD, ALAS2, CPOX, FECH, HMBS, PPOX, UROD, or UROS<br />
|-<br />
| Adrenoleukodystrophy (Adrenomyeloneuropathy)<br />
| ABCD1 <br />
|-<br />
| Agammaglobulinaemia (x-linked) <br />
|BTK <br />
|-<br />
| Agammaglobulinemia Bruton Tyrosine Kinase (BTK) <br />
|BTK <br />
|-<br />
| Aicardi Goutieres Syndrome 1 (AGS1) <br />
|TREX1, RNASEH2A, RNASEH2B, RNASEH2C, SAMHD1<br />
|-<br />
| Alagille Syndrome<br />
|JAG1 or NOTCH2<br />
|- <br />
| Alpers-Huttenlocher Syndrome <br />
|POLG <br />
|-<br />
| Alpha-1-antitrypsin deficiency <br />
|SERPINA1 <br />
|-<br />
| Alpha-Mannosidosis<br />
| MAN2B1 <br />
|-<br />
| Alpha Thalassemia <br />
|HBA1 or HBA2 <br />
|-<br />
| Alports Syndrome<br />
|COL4A3, COL4A4, COL4A5<br />
|-<br />
| Alzheimer's Disease - early onset (Type 3 and 4) <br />
|APP, PSEN1, or PSEN2<br />
|-<br />
| Amyotrophic Lateral Sclerosis 1 (ALS1) <br />
|C9orf72, SOD1, TARDBP, FUS, ANG, ALS2, SETX, VAPB <br />
|-<br />
| Argininosuccinic Aciduria <br />
| ASL<br />
|-<br />
| Arrhythmogenic Right Ventricular Cardiomyopathy/ Dysplasia (ARVC/D)<br />
| DSG2; DSP; PKP2<br />
|-<br />
| Ataxia Telangiectasia<br />
| ATM<br />
|-<br />
| Autosomal Recessive Meckel-Gruber Syndrome<br />
| TMEM67<br />
|-<br />
| Bardet-Biedl Syndrome (BBS)<br />
| BBS1; BBS10<br />
|-<br />
| Barth Syndrome<br />
| TAZ<br />
|-<br />
| Beta Thalassaemia<br />
| HBB<br />
|-<br />
| Birt-Hogg-Dubé Syndrome<br />
| FLCN<br />
|-<br />
| Breast Ovarian Cancer Familial Susceptibility (BRCA2)<br />
| BRCA1; BRCA2<br />
|-<br />
| Canavan Disease <br />
| ASPA<br />
|-<br />
| Carnitine-Acylcarnitine Translocase Deficiency <br />
| SLC25A20<br />
|-<br />
| Cerebral Arteriopathy with Subcortical Infarcts & Leukoencephalopathy (CADASIL)<br />
| NOTCH3<br />
|-<br />
| Cerebral Cavernous Malformation<br />
| CCM1<br />
|-<br />
| Charcot-Marie-Tooth Disease<br />
| GJB1; MPZ; NEFL; PMP22<br />
|-<br />
| CHARGE Syndrome<br />
| CHD7<br />
|-<br />
| Cherubism<br />
| SH3BP2<br />
|-<br />
| Choroideremia<br />
| CHM<br />
|-<br />
| Chronic Granulomatous Disease<br />
| CYBB; NCF1<br />
|-<br />
| Ciliary Dyskinesia<br />
| DNAH5<br />
|-<br />
| Citrullinemia<br />
| ASS1<br />
|-<br />
| Cleidocranial Dysplasia<br />
| RUNX2<br />
|-<br />
| Cockayne Syndrome<br />
| ERCC6<br />
|-<br />
| Congenital Adrenal Hyperplasia<br />
| CYP21A2<br />
|-<br />
| Congenital Cataracts<br />
| GJA8; VSX2<br />
|-<br />
| Congenital Diarrhea, Syndromic<br />
| SPINT2<br />
|-<br />
| Congenital Disorders of Glycosylation (CDG)<br />
| ALG1; ALG6; CDG1C; DOLK; PMM2<br />
|-<br />
| Cornelia de Lange Syndrome <br />
| NIPBL<br />
|-<br />
| Craniosynostosis<br />
| TWIST1<br />
|-<br />
| Crouzon Syndrome<br />
| FGFR2<br />
|-<br />
| Cysteinyl Leukotriene Receptor 1 Deficiency <br />
| CYSLTR1<br />
|-<br />
| Cystic Fibrosis<br />
| CFTR<br />
|-<br />
| Diamond –Blackfan Anemia <br />
| RPS19<br />
|-<br />
| Duchenne Muscular Dystrophy <br />
| DMD<br />
|-<br />
| Dyskeratosis congenita (Male embryos only)<br />
| DKC1<br />
|-<br />
| Ectodermal dysplasia (Hypohidrotic)<br />
| EDA; EDA1; GJB6; IKBKG<br />
|-<br />
| Familial Adenomatous polyposis coli (FAP)<br />
| APC<br />
|-<br />
| Familial Dysautonomia<br />
| IKBKAP<br />
|-<br />
| Fanconi Anemia <br />
| FANCA; FANCC; FANCD2; FANCF; FANCG; FANCJ<br />
|-<br />
| Fragile X Syndrome (FRAX)<br />
| FMR1<br />
|-<br />
| Galactosemia <br />
| GALT<br />
|-<br />
| Gangliosidosis<br />
| GLB1<br />
|-<br />
| Glanzmann Thrombasthenia <br />
| ITGA2B<br />
|-<br />
| Glutaric Acidemia (aciduria)<br />
| GCDH <br />
|-<br />
| Glycogen Storage Disease <br />
| G6PC; GAA; SLC37A4<br />
|-<br />
| Haemophilia A<br />
| F8<br />
|-<br />
| Haemophilia B<br />
| F9<br />
|-<br />
| Hereditary Nonpolyposis Colorectal Cancer: Lynch Syndrome<br />
| MLH1; MSH2; MSH6<br />
|-<br />
| Holt Oram Syndrome<br />
| TBX5<br />
|-<br />
| Huntington Disease<br />
| HD<br />
|-<br />
| Hydrocephalus<br />
| L1CAM<br />
|-<br />
| Ichthyosis <br />
| ABCA12; STS<br />
|-<br />
| Incontinentia Pigmenti (IP)<br />
| NEMO<br />
|-<br />
| Joubert Syndrome 5<br />
| INPP5E<br />
|-<br />
| Krabbe Disease<br />
| GALC<br />
|-<br />
| Leber Congenital Amaurosis (LCA)<br />
| CEP290; GUCY2D<br />
|-<br />
| Leigh Syndrome (Infantile Subacute Necrotising Encephalopathy)<br />
| LRPPRC<br />
|-<br />
| Lesch Nyan Syndrome<br />
| HPRT1<br />
|-<br />
| Leukocyte Adhesion Deficiency (Type I)<br />
| ITGB2<br />
|-<br />
| Li-Fraumeni Syndrome<br />
| TP53<br />
|-<br />
| Macular Dystrophy Retinal <br />
| VMD2<br />
|-<br />
| Maple Syrup Urine Disorder (MSUD)<br />
| BCKDHB<br />
|-<br />
| Marfan Syndrome <br />
| FBN1<br />
|-<br />
| Menkes Syndrome<br />
| ATP7A<br />
|-<br />
| Mitochondrial DNA Depletion Syndrom <br />
| POLG; RRM2B; SUCLA2; TK2<br />
|-<br />
| Mucolipidosis type II<br />
| GNPTAB<br />
|-<br />
| Multiple Endocrine Neoplasia<br />
| MEN1; MEN2A; MEN2B<br />
|-<br />
| Multiple Exostoses<br />
| EXT1; EXT2 <br />
|-<br />
| Myotubular myopathy<br />
| MTM1 <br />
|-<br />
| Nail-Patella Syndrome<br />
| LMX1B<br />
|-<br />
| Neurofibromatosis Type 1<br />
| NF1<br />
|-<br />
| Neurofibromatosis Type 2 <br />
| NF2<br />
|-<br />
| Noonan Syndrome<br />
| KRAS, PTPN11; SOS1<br />
|-<br />
| Norrie Disease<br />
| NDP<br />
|-<br />
| Ocular Albinism <br />
| GPR143<br />
|-<br />
| Oculocutaneous Albinism <br />
| OCA2; TYR <br />
|-<br />
| Oculodentaldigital Dysplasia<br />
| GJA1<br />
|-<br />
| Optic Atrophy<br />
| OPA1<br />
|-<br />
| Ornithine Transcarbamylase Deficiency <br />
| OTC<br />
|-<br />
| Osteogenesis imperfeca <br />
| COL1A1; COL1A2<br />
|-<br />
| Osteopetrosis <br />
| CLCN7; OSTM1; TCIRG1<br />
|-<br />
| Pachyonychia Congenita <br />
| KRT16; KRT6A<br />
|-<br />
| Pancreatitis, Hereditary<br />
| PRSS1 <br />
|-<br />
| Papillorenal syndrome <br />
| PAX2<br />
|-<br />
| Phenylketonuria <br />
| PAH <br />
|-<br />
| This table does not cover the complete list of diseases that PGD can be applied to.<br />
|}<br />
<br />
==Laws & Legal status==<br />
<br />
{| class="wikitable" <br />
|-bgcolor="DDCEF2"<br />
|'''Country'''<br />
|'''Legislation'''<br />
|-<br />
| Australia<br />
| PGD is currently used to detect serious genetic conditions to improve the outcome of Assisted Reproductive Technologies (ART). In very rare cases it may be used to select an embryo with compatible tissue for a sibling who has a life-threatening disease where other means of treatment is unavailable. This is with the conditions that the use of PGD will not affect the welfare and interests of the child to be born. The parents must also receive adequate counselling and have full understanding of the procedures of PGD. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"> National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art</ref><br />
The use of PGD for sex-selection is prohibited with the exception of reducing the risk of the transmission of serious sex-linked genetic conditions. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"/><br />
|-bgcolor="FFFAFA"<br />
| Brazil<br />
| The laws regarding PGD in Brazil are not strictly regulated. They are vague and there is limited information surround the activities of assisted reproduction in general in the country <ref name="PMID25493379"><pubmed>25493379</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| Czech Republic<br />
| The laws in the Czech Republic allow those with a “defined indication in order to exclude risk of serous genetically conditioned disease and defects with embryos before they are implanted into the cavity of the uterus”. Couples that undergo any assisted reproductive treatment including PGD have to be married. Sex-selection is illegal except in regards to serious sex-linked genetic diseases <ref name="PMID24777348"><pubmed>24777348</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| Greece<br />
| In Greece, ART is open to those up to the age of 50 with written consent. It can only be used if a medical necessity is present such as the susceptibility of serious hereditary diseases. Sex selection is banned apart from cases of sex-linked diseases and sexually transmitted diseases <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| India<br />
| In India there is a cultural preference for boys thus the Prenatal Diagnostic Techniques (Regulation and Prevention of Misuse) Act was introduced in 1994. This law limits the use of PGD for sex determination except in cases of specific congenital diseases. These laws however are not strictly enforced. <ref>World Health Organisation (2015) Gender and Genetics Retrieved on October 21st 2015 from:http://www.who.int/genomics/gender/en/index4.html</ref><br />
|-bgcolor="FFFAFA"<br />
| Portugal <br />
| ART is only available to those who are married or have a similar type of relationship for at least two years. The couples cannot be of the same sex and must be at least 18 years of age. Sex selection is illegal except in cases of sex-linked diseases. The use of PGD is illegal if the predictive value of genetic tests are very low <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| Spain<br />
| PGD can be applied to “serious hereditary diseases not amenable to postnatal curative treatment” and “detection of other abnormalities which may compromise the viability of the pre-embryo”. If PGD is to be used for any other purpose authorisation must be acquired <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| Sweden <br />
| The use of PGD is strictly regulated and couples must achieve authorisation of the National Board of Health and Welfare. It can only be used it can only be used if the child is at risk to inheriting a serious chromosomal or monogenetic disease. It cannot be used for selection of specific characteristics <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| United Kingdom<br />
| Those involved with carrying out the IVF treatment must have a license from the Human Fertilisation and Embryology Authority (HFEA). Only embryos that are approved by the HFEA can be implanted where the embryonic nuclear or mitochondrial DNA cannot be altered with the exception of preventing mitochondrial diseases <ref name="PMID24777348"/>. <br />
|}<br />
<br />
==Future/Current Research==<br />
===Noninvasive Preimplantation Genetic Testing without Embryo Biopsy===<br />
Different parameters of gametes, zygotes, embryos (“vacuoles in sperm heads, spindle position in mature oocytes, cleavage intervals of zygote, and embryo developmental dynamics”) may correlate with aneuploidy rates. This knowledge may be applied in potential noninvasive preimplantation diagnostic methods. Several methods have been proposed and are currently further researched<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Sperm Selection====<br />
Intracytoplasmic morphologically selected sperm injection (IMSI) is common procedure in IVF treatment to improve fertilization rates in patients with poor semen quality. In addition, studies have found that IMSI improves embryo development and that spermatozoa with large vacuoles in their heads correlate with increased aneuploidy rates and disturbed chromosomal structures. Thus, selecting spermatozoa based on morphological hallmarks may decrease aneuploidy rates in the fertilized embryos. As with polar body biopsies, however, this approach will solely be applicable if evidence for severe male detrimental contribution is given<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Blastocoel Fluid Extraction====<br />
In addition, a less invasive retrieval of material for diagnosis could include the extraction of the blastocoel fluid. The cavity of the blastocyst, lined by the trophectoderm, is filled with this blastocoel fluid, which contains metabolites of both trophectoderm and inner cell mass origin. The retrieval does not require a biopsy but merely a small opening to extract the fluid and, thus, causes less harm to the embryo. Multiple studies have applied this method<ref name="PMID22020776"><pubmed>22020776</pubmed></ref> <ref name="PMID23148560"><pubmed>23148560</pubmed></ref> and it may in the future become of clinical relevance.<br />
<br />
<br />
[[File:Aspiration_of_the_Blastocoel_Fluid.jpeg|thumb|Aspiration of the Blastocoel Fluid using a ICSI pipette<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.]]<br />
<br />
<br />
Next to metabolites, the blastocoel fluid can contain DNA. Studies have shown that genomic DNA is present in about 90% of the blastocoel fluid samples tested. Typically the fluid is removed with an ICSI pipette from a day five blastocyst through its mural trophectoderm until the blastocyst fully collapses around the embryo. Several concerns regarding this method in a clinical setting have been raised. The collected DNA may be contaminated by the culture media that contains DNA fractions. The DNA may also be least representative of the actual embryos genome as the DNA may originate from abnormal or degenerated cells. Even though labelled noninvasive, the blastocyst still undergoes manipulation to some degree which may affect its viability. Thus, more research is required until this method can evolve from research to clinical use<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
====Proteomics====<br />
The protein secretome of blastocysts may be representative of its chromosome constitution Recent studies have found biomarkers such as lipocalin-1, interleukin-10, tumor necrosis factor, stem cell factor, and chemokine ligand 13 to be differently secreted by aneuploid blastocyst than by euploid ones. The most significant biomarker appears to be interleukin-10. Paired with novel proteomic technologies and mass spectrometry this knowledge when extended may contribute to a new invasive preimplantation genetic diagnosis method<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Embryo Morphology====<br />
Using time lapse imaging the embryo’s morphology can be closely observed and potential aneuploidy characteristics detected. Such characteristics may include the time of division to five cells, the time between the division from three to four cells, and the duration of the division from one to two and subsequently to three. In addition, the morphological quality of ICM an TE has been positively associated with aneuploidy or euploidy prognosis<ref name="PMID26246880"><pubmed>26246880</pubmed></ref>. These may give rise to an embryo quality screening prior to implantation<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
==References==<br />
<br />
<references/><br />
<br />
<br />
{{StudentPage2015}}</div>Z5017878https://embryology.med.unsw.edu.au/embryology/index.php?title=2015_Group_Project_6&diff=2070192015 Group Project 62015-10-21T07:21:13Z<p>Z5017878: </p>
<hr />
<div>{{ANAT2341Project2015header}}<br />
<br />
<br />
=Preimplantation Genetic Diagnosis and Screening=<br />
==Introduction==<br />
Preimplantation genetic diagnosis (PGD) and screening (PGS) are reproductive options for couples with known family histories of genetic disease or couples undergoing IVF procedures due to infertility issues. PGD can diagnose many genetic disorders caused by known chromosomal abnormalities (number and/or structure) or single gene mutations, and, thus decrease the risk of termination of pregnancy or miscarriages and enable such couples to have an unaffected child<ref name="PMID24907939"><pubmed>24907939</pubmed></ref>. Through major improvements in PGD/S and general laboratory technology, the testing for abnormalities in fetuses has shifted from prenatal diagnosis during the first 2 trimesters <ref> Blackburn, S.L. (2003) '''Maternal, Fetal & Neonatal physiology: a Clinical perspective''' (2nd ed.). Seattle: Saudners </ref>, testing for overall fetal growth, complications of pregnancy, and birth defects<ref> Sadler T.W.(2012) '''Langman's Medical Embryology''' (12th ed.) Philadelphia: Lipincott, Wiliams & Wilkins, a Wolters Kluwer Business </ref>, to an embryonic focus especially in advancements in Artificial Reproductive Technologies (ART)<ref><pubmed>20638568</pubmed></ref>. In 1990 PGD for a recessive X-linked disease resulted in the first live birth<ref><pubmed>2330030</pubmed></ref> and has since been incorporated in clinical routine and applied for a variety of genetic diseases, such as sickle cell anemia, thalassemia, or cystic fibrosis<ref name="PMID24907939"/>.<br />
[[File:Preimplantation Genetic Diagnosis Procedure.jpeg|700px|thumb| Simplified steps for PGD<ref name="PMID24907939"/>]]<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=0e-79qKllqk</html5media><br />
|-<br />
| Preimplantation Genetic Diagnosis<ref>IVF Florida (2011, December 11) IVF Florida - South Florida Fertility Specialists - Pre-Implantation Genetic Diagnosis [Video file]. Retrieved from https://www.youtube.com/watch?v=0e-79qKllqk</ref><br />
|}<br />
<br />
==History==<br />
The advances in reproductive technology during the second half of the 20th century, led to PGD's first clinical application in 1990 <ref>Harper, J. (n.d.). The history of PGD. Lecture. UCL Centre for PG&D and CRGH.University College London</ref>.<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
|Year<br />
|<br />
|- bgcolor="FFFAFA"<br />
| '''1967''' <br />
|First PGD on rabbit blastocysts (Gardner& Edwards) <ref name="PMID6036172"><pubmed>6036172</pubmed></ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1986''' <br />
|First Cleavage Biopsy (Wilton & Trounson)<ref>Wilton, L. J., & Trounson, A. O. (1986). Viability of mouse embryos and blastomeres following biopsy of a single cell. In Proceedings of the 18th Annual Conference of the Australian Society for Reproductive Biology, Brisbane, Australia.</ref><br />
|- bgcolor="FFFAFA"<br />
|'''1987''' <br />
|First Blastocyst Biopsy (Muggleton-Harris, Monk, Rawlings, & Whittingham)<ref name="PMID3372699"><pubmed>3372699</pubmed></ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1988''' <br />
|First Polar Body Biopsy (Yury Verlinksy)<ref> Verlinsky, Y., Pergament, E., Andresen, P., Enriquez, G., & Strom, C. (1989). Genetic analysis of polar body DNA: A new approach to preimplantation genetic diagnosis. Am J Hum Genet, 45(4), A272.</ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1990''' <br />
|First Clinical PGD using PCR testing for X-linked (Handyside, Kontogianni, Hardy, & Winston)<ref name="PMID2330030"><pubmed>2330030</pubmed></ref> <br />
|} <br />
==Preimplantation Genetic Diagnosis==<br />
Preimplantation genetic diagnosis (PGD) is used to test the genetic makeup of embryos to detect single gene disorders, chromosomal abnormalities and mitochondrial disorders. It also has applications in gender selection for diseases with unequal gender distributions <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Some diseases commonly involved with PGD include cystic fibrosis, spinal muscular atrophy and beta – thalassaemia <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press.">Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press</ref> <ref name="PMID17823145"><pubmed>17823145</pubmed></ref>. It was first used in the United Kingdom in the 1980s of arenoleucodystrophy and primarily focusing on sex- linked disorders <ref name="PMID17823145"/><ref name="PMID23150080"><pubmed>23150080</pubmed></ref>. PGD is now capable of detecting single cell defects (molecular) and chromosomal disorders resulting from the inversion, translocation or deletion of chromosomes (cytogenic) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>,<ref name="PMID11325751"><pubmed>11325751</pubmed></ref>. PGD can be applied to the embryo at different stages. That is on polar bodies, blastomeres or blastocyst <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>.<br />
Depending on the type of genetic disorder, PGD utilises different methods of genetic testing. These include Fluorescence in situ hybridisation (FISH) which is used for sex – linked disorders and detects chromosomal rearrangements <ref name="PMID11325751"/><ref name="PMID17876073"><pubmed>17876073</pubmed></ref> and Embryo halotyping which allows the identification of chromosomes causing the inherited disorder through knowledge of the pattern of closely linked markers <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. Polymerase chain reaction (PCR) is also widely used to detect molecular abnormalities <ref name="PMID11325751"/>.<br />
PGD is tightly regulated and supported by large organisations namely The American Society for Reproductive Medicine, The European Society for Human Reproduction and Embryology (ESHRE), The European Society of Human Genetics and the Preimplantation Genetic Diagnosis International Society <ref name="PMID25500181><pubmed>25500181</pubmed></ref>.<br />
===Sex-linked disorders===<br />
The determination of a disease as gender specific usually correlates with the presence or absence of specific genes such as SRY on the Y chromosome. It is known that females have two X chromosomes and males have an X and a Y chromosome where abnormalities are more prevalent on the X chromosome. PGD can be used for sex selection where only male embryos are transferred to reduce the chance of inheriting X-linked disorders. However, this does not completely eradicate the problem as male embryos remain susceptible to inheriting an affected X chromosome. Sex determination is only used when the specific mutation is unknown and has yet to be discovered <ref name="PMID24866878"><pubmed>24866878</pubmed></ref>.<br />
===Single gene defects===<br />
Single gene defects can be dominant, recessive, autosomal or X-linked. They are commonly diagnosed using PCR and although the PCR available today is complex and capable of combatting a large range of disease the development of new protocols has been proven to be difficult due to the small DNA sample available <ref name="PMID26168107"><pubmed>26168107</pubmed></ref><br />
===Mitochondrial disorders===<br />
Mitochondrial disorders also known as oxidative phosphorylation disorders arise from mutations in the nuclear DNA or mitochondrial DNA <ref name="PMID26312584"><pubmed>26312584</pubmed></ref>. They pose as a problem because they are unrecognisable until the mutations in the cell reach a detrimental level <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Mitochondrial disorders cause miscarriages and stillbirths as well as death in children and young adults. The effects can either be contained in a single organ or more commonly involve multiple organ failure where organs with high energy demands such as the brain, liver muscle and heart and heavily influenced. They are usually occur spontaneously or result from inheritance from the mother. Since mitochondria are solely inherited from the mother oocyte donations have been used as a solution to combat mitochondrial disorders. Additionally, there has been an increasing use in PGD where embryos that stay under the given threshold of 18% gene-mutations are allowed to be transferred and result in normal development. New technology in the areas of nuclear gene transfer and genome editing are also being experimented with <ref name="PMID26312584"/>. <br />
===Chromosomal disorders===<br />
Chromosomal disorders can be reciprocal, Robertsonian translocations, inversions, deletions and insertions <ref name="PMID26168107"/>. . Data from ESHRE collected between 2010 and 2011 has shown that the most common chromosomal abnormality confronted in PGD are reciprocal chromosomal abnormalities <ref name"PMID26071418"><pubmed>26071418</pubmed></ref>. PGD has also been used successfully for Robertsonian translocations (RT), a type of structural translocation. Children who carry RT are phenotypically normal, however in their later years it is found that they will suffer from infertility and repeated miscarriages due to the high frequency of abnormal embryos <ref name="PMID22081077"><pubmed>22081077</pubmed></ref>. PCR and FISH are the two main techniques used for chromosomal disorders. To be able to conduct the examinations the cells are required to be at the metaphase stage <ref name="PMID26168107"/>. <br />
==Preimplantation Genetic Screening==<br />
Prenatal Genetic Screening (PGS) involves an array of methods or ideas that aim to segregate embryos that have genetic flaws and those that are healthy <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. The occurrence of aneuploidy is high around the stages of early embryonic development and they are the most common cause if miscarriages and congenital birth defects <ref name= "PMID26085841"><pubmed>26085841</pubmed></ref>. They have little effect on the morphology of the embryo making them difficult to identify thus identification heavily relies on genetic testing <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. <br />
Genetic sampling is most commonly conducted using Microarray Comparative Genomic Hybridisation (aCGH) as well as FISH, Quantitative PCR and Single Nucleotide Polymorphism (SNP) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. These methods collectively aim to assess numeral and structural chromosomal errors <ref name= "PMID26085841"/>. Studies have also introduced Next- Generation Sequencing (NGS) <ref name= "PMID26085841"/> and Whole Genome Amplification used to screen imbalances in the complete 24-chromosomes <ref name="PMID25953353"><pubmed>25953353</pubmed></ref><br />
Statistics from ESHRE have shown that the most common indications for PGS is advanced age, followed by repeated implantation failure or recurrent miscarriage and male infertility <ref name="PMID26071418"><pubmed>26071418</pubmed></ref>.<br />
====Indications====<br />
A low percentage of structural abnormalities in chromosomes are responsible for the cause of miscarriages. Despite this, they are the most prevalent type of chromosomal abnormality accounted for in PGD <ref name="PMID20638568"/>. The presence of specific gene cycles, initiation of embryonic protein synthesis and evident physiological development are all indicative of a successful in vitro fertilisation procedure <ref name="PMID11576737"><pubmed>11576737</pubmed></ref>. To eliminate further errors from occurring during the PGD procedure it is recommended to undertake further prenatal testing such as amniocentesis in the later stages <ref name="PMID20638568"/>. <br />
=====Advanced maternal age=====<br />
Data provided by the ESHRE has shown that the mean age of women undergoing PGS is 39 years <ref name="PMID26071418"/>. Women of advanced age have been shown to have a lower rate of pregnancies reaching childbirth <ref name="PMID18583331"><pubmed>18583331</pubmed></ref>. The highlighted concern revolves around the increased occurrence of aneuploidy following maternal age. The optimal age range for the lowest aneuploidy incidence was found to be between 27 to 37 years of age (6%) then progressively higher in women aged up to 42 (33%) and most common in those 44 and above (53%) <ref name="PMID24355045"><pubmed>24355045</pubmed></ref>. <br />
=====Recurrent pregnancy loss / IVF failure=====<br />
Recurrent pregnancy loss is defined as three or more IVF failures after cumulative transfer of more than 10 good-quality embryos. These are primarily caused by two main factors, reduced endometrium receptivity or embryonic defects. Endometrium receptivity can be negatively influences by instances including uterine pathologies such as thin endometrium, altered expression of adhesive molecules and immunological factors. Additionally, embryonic defects may be due to genetic abnormalities, embryonic aneuploidy or zona hardening. Endometriosis and hydrosalpinx has been known to effect both the endometrium and embryo <ref name="PMID23260857"><pubmed>23260857</pubmed></ref>.<br />
=====Human leukocyte antigen matching=====<br />
First used in 2001, HLA matching is an option given to parents to save a child with haematological or immunological disease through conceiving another child who would potentially be able to donate cord blood or haematopoietic stem cells from the bone marrow for transplantation. The process namely PGD-HLA has shown to improve haematopoietic stem cell transplant (HSCT). PGD-HLA can only be performed when HSCT is not needed urgently due to the time needed to conceive and delivery the baby <ref name="PMID25500181"><pubmed>25500181</pubmed></ref>. It is most commonly applied to children suffering from relapsed leukaemia <ref name="PMID22524201"><pubmed>22524201</pubmed></ref>. In a case study PGD-HLA was proven to successfully cure 10 diseases including Fanconi anaemia, Diamond-Blackfan anaemia and beta thalassemia <ref name="PMID25066893><pubmed>25066893</pubmed></ref>.<br />
==Biopsy Methods==<br />
Biopsy, the removal of genetic materials, from oocytes or embryos in the preimplantation stage is the primary step in PGD. For the past two decades these biopsies have been performed at three stages, the polar body, blastomere, and blastocyst, and the methodologies optimized to ensure the embryo’s viability. The most common approach involves biopsies at the cleavage stage. However, polar body and blastocyst biopsies are increasingly more often tested and applied. Approached for opening the zona pellucida involve next to the traditional mechanical and chemical means, novel approaches such as noncontact lasers. Their application may simplify and secure the procedure significantly. The most challenging question about PGD procedures remains at what stage biopsies should be taken. Much controversy has developed around this topic, highlighting the varying disadvantages and advantages of temporal biopsies. <ref name="PMID22723007"><pubmed>22723007</pubmed></ref><br />
<br />
{| class="wikitable"<br />
|- align="center" bgcolor="DDCEF2"<br />
|<br />
| Time of Biopsy<br />
| Advantages <br />
| Disadvantages<br />
|- bgcolor="FFFAFA"<br />
| Polar Body<br />
| Day 1<br />
| No harm to oocyte<br />
| Only maternal DNA is tested, often needs to be coupled with other biopsies<br />
|- bgcolor="FFFAFA"<br />
| Blastomere<br />
| Day 3<br />
| …<br />
| … <br />
|- bgcolor="FFFAFA"<br />
| Trophectoderm<br />
| Day 5 and 6 <br />
| Little harm, large amount of genetic material<br />
| Opening of blastocyst necessary, small time window for procedure<br />
|}<br />
<br />
<br />
[[File:Polar_Body,_Blastomere,_and_Trophectoderm_Biopsy.jpeg|thumb|Polar body (A), blastomere (B) and trophectoderm (C) biopsies<ref name="PMID25625041"><pubmed>25625041</pubmed></ref>.]]<br />
<br />
<br />
<br />
PMID 24305177<br />
===Polar Body Analysis===<br />
Day 1<br />
====Description====<br />
Polar body (PB) biopsy, which was introduced in 1990, offers a promising alternative to biopsies performed at the blastomere stage for PGD/S indications on legal and practical grounds. <br />
Description: Consequent embryo development does not necessitate the presence of the first and second PB and their removal may not be crucial. PB biopsy requires precise timing. Keeping track of the meiotic cell cycle is necessary to perform a successful biopsy and, therefore, PB biopsy usually is applied in combination with intracytoplasmic sperm injection (ICSI). During the maturation from the germinal vesicle stage to the metaphase-II stage the first PB is formed. A cytoplasmic bridge containing spindle remnants, that are still in contact with the cellular genetic material, links this PB to the oolemma for about 90 minutes after extrusion. It is possible to visualize these remnants by polarization microscopy and it is crucial to not perform the biopsy until the first PB is no longer firmly attached to the oolemma as this indicates an immature embryo.The oocyte tolerates mechanical zona dissection best during hours four until six after ICSI as the oolemma has stabilized by that time because of the cortical granule reaction. Over time the first PB degenerates stressing a temporal biopsy and its optimal extraction time window is four to 12 hours after ICSI. The second PB forms around two to four hours after ICSI. However, its optimal time window for biopsy is set to be eight to 16 hours after ICSI. This is due to the second PB being attached to the oolemma with spindle remnants until six hours after ICSI. Biopsy at this point may cause enucleation of the oocyte. In addition, studies have shown that the amplification efficiency of second PB’s DNA is worse if the PB is extracted prior to eight hours after ICSI. <br />
Thus, it is possible to perform sequential and simultaneous biopsies for the first and second PB. If performed, sequentially the first PB may be removed four to 12 hours and the second PB eight to 16 hours after ICSI. The optimal time window for a biopsy for both the first and second PB simultaneously is eight to 12 hours after ICSI. It is highly preferred to analyze both PBs due to potential aneuploidies in either PB and crossing overs during meiosis<ref name="PMID22723007"/>. <br />
====Procedure====<br />
Chemical opening achieved with for example acidic tyrode’s solution of the zona pellucida is not tolerated by the oocyte and may have detrimental effects on the embryo’s development. Therefore, the access to the perivitelline space of the oocyte is provided by mechanical zona dissection or by laser. Both techniques work well if performed by experienced embryologist. However, laser-assisted biopsy is less time consuming when compared to manual dissection. It is critical to consider the size of the introduced opening as it will remain permanent. If it is too large the blastomere may be lost during embryo development and if it is too small it may interfere with hatching of the embryo during blastocyst stage<ref name="PMID22723007"/><br />
<br />
[[File:Polar_Body_Biopsy.jpeg|thumb|The presence of a faint but clearly identifiable strand connecting PB2 to the <br />
oolemma. The biopsy was performed ∼9 h after ICSI<ref name="PMID21908464"><pubmed>21908464</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JTaQzszVr8o</html5media><br />
|-<br />
| Laser-assisted polar body biopsy<ref>RIUK, R. (2013, June 25) Polar Body Biopsy [Video file]. Retrieved from https://www.youtube.com/watch?v=JTaQzszVr8o</ref><br />
|}<br />
<br />
====Advantages & Disadvantages====<br />
PB biopsies can only investigate the maternal contributions to the embryo as they are of maternal origin. Thus, this procedure is appropriate for PGD solely for monogenetic diseases from the maternal side. Recessive diseases may be evaluated with PB biopsies on the basis that the embryo’s outcome will be determined by the paternal contribution. (...) It may still be applied for PGS as most aneuploidies either arise during meiosis or origin from the maternal genome. However, diagnosis error has been reported due to the lack of considering paternal contributions. <br />
Because PB biopsies are performed very early it is not yet known whether the oocyte will develop into a viable embryo. Thus, PBs are commonly frozen or fixed after biopsy and depending on the state of the embryo only chosen PBs will be tested. This is primarily an economic issue as many genetic testing procedures are very cost-intensive<ref name="PMID22723007"/>.<br />
<br />
[[File:Implantation_predictive_value_of_euploid_screening_results.jpeg|thumb|The sustained implantation predictive value (with 95 % confidence interval) of a euploid screening result obtained from the first polar body (PB1), PB1 and the second polar body (PB2), or a direct embryo biopsy for each stage of embryo transfer (cleavage-stage and blastocyst stage)<ref name="PMID25106935"><pubmed>25106935</pubmed></ref>.]]<br />
<br />
===Blastomere biopsy===<br />
Day 3 <br />
====Description====<br />
Blastomere biopsy has been the prevalent method for PGD and PGS in the last two decades. At least one, but up to two, blastomeres are biopsied on day three of the cleavage stage embryo. The right number of blastomeres removed is a controversial topic as two cells allow for more genetic material and more accurate results. However, removing two cells might be too invasive and damaging to the embryo. (Study)<ref name="PMID21748341"><pubmed>21748341</pubmed></ref><br />
====Procedure====<br />
Initially a hole was drilled into the zona pellucida using acid tyrodes and the blastomeres are removed via aspiration with a pipette<ref name="PMID21748341"/>.<br />
<br />
<br />
[[File:Aspiration_of_a_Blastomere.jpeg|thumb|Aspiration of a Blastomere into the biopsy pipette<ref name=" PMID24783200"><pubmed>24783200</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=TbridWVwipI</html5media><br />
|-<br />
| Laser-assisted blastomere biopsy<ref>Sukprasert, M. (2014, March 5) Day 3 Blastomere Biopsy 1 [Video file]. Retrieved from https://www.youtube.com/watch?v=TbridWVwipI</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
===Trophectoderm biopsy===<br />
Day 5 and 6<br />
====Description====<br />
The improvement of embryo culture media allowed the in vitro development of human embryos until the blastocyst stage and opened up the possibility to take blastocyst biopsies. During day three to day five the haploid maternal and paternal genomes work together for the first time to form the genome of the embryo. The maternal epigenetic control lessens significantly while preparing for implantation with precisely arranged events happening. The first event includes a rapid increase in the number of embryonic cells which are active in mitotic divisions and apoptosis of aberrant cells. This is followed by the formation of blastocoel (cavitation) which results from the flattening of cell located on the outside of the blastomere. Now the blastocyst will expand until the embryo hatches by rupturing the zona pellucida. The cells of the blastocyst will differentiate to form two distinct cell lineages, the outer trophectoderm and the inner cell mass<ref name="PMID22723007"/>.<br />
====Procedure====<br />
Trophectoderm biopsy is usually performed in Hepes buffered biopsy medium and opening approaches include needle cutting which has been replaced by lasers in past years. Different research groups report different timings of the opening to be the most successful. Some open the blastocyst on day three or four by creating a 25 µm which causes the trophectoderm to herniate through this hole and is, thus, accessible for biopsy. Others create this hole about four hours before biopsy which allows sufficient herniation of trophectoderm cells. It is also possible to open the blastocyst immediately before biopsy. This avoids an extra step and the inner cell mass usually is easy to locate. Blastocyst biopsies involve the removal of trophectoderm cells and the ideal time for the procedure is day five. Successful biopsies on day six have been performed, while little is known about the results of biopsies on day seven. However, since the window of implantation in humans is from day eight to ten after ovulation, day seven biopsies appear to be possible<ref name="PMID22723007"/>.<br />
-collapse of trophoblasts<br />
-possible: biopsy of hatched blastocyst, holding pipette careful mild suction force to hold embryo near ICM <br />
-Cryopreservation<br />
<br />
<br />
[[File:Microscopic images of human blastocysts for biopsy.jpeg|thumb|(A) Some trophectoderm cells in a blastocyst started to hatch and (B) the trophectoderm cells were biopsied with assisted laser cutting. Images in C–D show the blastocysts after vitrification and warming. Blastocysts had been cultured for 2–4 hrs after warming, showing good (ICM and trophectoderm cells) hatched (C) and hatching (D) blastocysts. The hatching blastocyst in (E) has good ICM but fair trophectoderm while the blastocyst in (F) has both fair ICM and trophectoderm. Arrows indicate ICMs and arrow heads indicate trophectoderm cells. Bar = 40 µm<ref name="PMID2190846"><pubmed>2190846</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JI_TQ8d8tNM</html5media><br />
|-<br />
| Laser-assisted blastocyst biopsy (at 00:50 min)<ref>Coco, R. (2014, April 30) Trophectoderm biopsy in a Hatching blastocyst protruding ICM [Video file]. Retrieved from https://www.youtube.com/watch?v=JI_TQ8d8tNM</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
Blastocyst biopsies are believed to be less damaging to the embryo and appear to be unrelated to implantation rates. In addition, this biopsy method allows for a larger extraction of cells for genetic testing. However, since they are performed late in in vitro development, the time window for genetic testing is relatively small. Fast and accurate genetic testing methods are needed to ensure a successful and safe result from this biopsy. Thus, blastocyst biopsies may gain more popularity in the future whn such methods have been developed or improved<ref name="PMID22723007"/>. <br />
<br />
<br />
==Genetic Techniques==<br />
<br />
===PCR===<br />
====Description====<br />
Polymerase chain reaction (PCR) amplifies DNA specific to genetic sequence of interest . PCR was developed by Kay Mullis in the 1980s, for which he was awarded the Nobel prize for chemistry in 1993. <ref> Pubmed Docs (2015) Polymerase Chain Reaction (PCR) Pubmen. Retrieved from [http://www.ncbi.nlm.nih.gov/probe/docs/techpcr/]</ref> This technique enables clinicians to monitor and diagnose diseases using minute samples such as embryonic cells, blood & tissue. <ref>Roche (2015) PCR: How We Copy DNA. Roche Molecular Systems Inc. retrieved From [http://molecular.roche.com/pcr/Pages/Process.aspx]</ref> PCR has many important applications like DNA fingerprinting, genetic mapping, detection of viruses and bacteria as well as being used to detect genetic disorders, as a part of PGD, in conjunction with IVF. It is used to detect molecular abnormalities such as single gene disorders like Tay Sach, Cycstic fibrosis, Duchenne Muscular Dystrophy, Thalassemia, Huntington disease, Spinal muscular atrophy and many more. Molecular and Genetic analysis require a significant amount of DNA, which we would not have without PCR. It revolutionized the study of DNA, replacing all previous recombinant DNA technology. <ref> Mullins, K., Francois, F.& Gibbs R.A. (1994 ) The Polymerase Chain Reaction. p3. Springer- Science +Business Media. Birkhauser, Boston<br />
Available at [https://books.google.com.au/books?hl=en&lr=&id=gjrTBwAAQBAJ&oi=fnd&pg=PR5&dq=kary+mullis+PCR&ots=mpzAyRh5ZY&sig=PQ4goNoKJ90tb3-MkPk62zrTGbw#v=onepage&q=kary%20mullis%20PCR&f=false] </ref> <br />
<br />
[[File:PCR.jpg|thumb|right|Polymerase chain reaction (PCR) amplifies DNA specific to genetic sequence of interest, enabling the monitoring and diagnose molecular abnormalities such as single gene disorders using minute samples such as embryonic cells, blood & tissue <ref>NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref>]]<br />
<br />
====Procedure====<br />
<br />
Sample are obtained from the the blastocyst, a polar body biopsy or the blastomeres stages of the embryo. <br />
Stage 1 Denaturing: separating the target strands of DNA <br />
The obtained sample is heated to roughly 90 degrees celcius, this heat causes breaks the relatively weak bonds between nucleotides that form DNA. the double stranded DNA to split into 2 single strands of DNA that are used as templates.<br />
Stage 2 Annealing: Binding the Primers to the target DNA sequence <br />
PCR will only copy the target sequence of DNA specified by specific PCR primer. These synthesized primers Oligonucleotides are small artificial pieces of DNA. <br />
TAQ polymerase enzyme synthesize 2 new strands of DNA duplicate to the single sample DNA stand template indicated by these primers. During this stage the reaction is cooled to a temperature between 40-60 degrees Celsius. <br />
Stage 3- Extension- making copies <br />
Each of these 2 copies are then used again as templates generating 2 further replications This cycle can occur as many 30 -40 times within a couple hours leading to billions of extra copies of the original DNA segment. The optimal temperature for the further replication is roughly 72 degrees Celsius. <br />
<br />
This process mediated by a thermocycler machine that is programmed to alter the temperature of the reaction every couple of minutes, perpetuating the cycle of DNA denaturing and synthesis. <br />
This process, generates exponential exact copy of the original template DNA sequence. <br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
!PCR cycles<br />
<br />
|{|<br />
|-<br />
| '''PCR Cycle'''<br />
| '''Target Copies'''<br />
|-<br />
| 1<br />
| 2<br />
|-<br />
| 2<br />
| 4<br />
|-<br />
| 3<br />
| 8<br />
|-<br />
| 4<br />
| 16<br />
|-"<br />
| 5 <br />
| 32<br />
|-<br />
| 6 <br />
| 64<br />
|-<br />
| 7 <br />
| 128<br />
|-<br />
| 8<br />
| 256<br />
|- <br />
| 9<br />
| 512 <br />
|-<br />
| 10<br />
| 1024<br />
|-<br />
| 15<br />
| 32,768<br />
|-<br />
| 20 <br />
| 1,048,578<br />
|-<br />
| 25<br />
| 33,554,432<br />
|-<br />
| 30 <br />
| 1,073,741,842<br />
|-<br />
|}<br />
<br />
<br />
<br />
{| class="wikitable" <br />
|-bgcolor="#9ACD32" <br />
| rowspan="10" |'''Advantages'''<br />
|-bgcolor="#F0FFF0"<br />
| fast and inexpensive way of copying a target sequence of DNA<br />
|-bgcolor="#F0FFF0"<br />
| aids the diagnosis of single cell defects<br />
|-bgcolor="#F0FFF0"<br />
| rapid generation of results within a couple hours<br />
|-bgcolor="#F0FFF0"<br />
| can start from a single molecule of DNA, therefore is more sensitive <br />
|-bgcolor="#F0FFF0"<br />
| has a flexible primer design enabling<br />
|-bgcolor="#F0FFF0"<br />
| overcame previous issues associated with the limited availability of sites of end<br />
|-bgcolor="#F0FFF0"<br />
| generates the DNA copies exponentially<br />
|-bgcolor="#F0FFF0"<br />
| enables DNA amplification required for molecular and genetic analysis<br />
|-bgcolor="#F0FFF0"<br />
|Valid diagnostic method in selecting unaffected embryos for embryo transfer <ref> Dreesen, J., Drusedaul, M., Smeets, H., Die-Smulders, C., Coonen, E., Dumoulin, J., Gielen, M., Evers, J., Herbergers, J. & Geradets, J. (2008) Validation of preimplantation genetic diagnosis by PCR analysis: genotype comparison of the blastomere and corresponding embryo, implications for clinical practice. Mol. Hum. Reprod. 14 (10):573-579.doi: 10.1093/molehr/gan052. Retrieved from [http://molehr.oxfordjournals.org/content/14/10/573.short] </ref> <ref><pubmed>20966460</pubmed></ref><br />
|-bgcolor="#9ACD32"<br />
| rowspan="5"|'''Disadvantages'''<br />
|-bgcolor="#F0FFF0"<br />
| only during this exponential DNA replication phase can we determine the starting quantity sequence contained in the original sample ( template DNA strand)<br />
|-bgcolor="#F0FFF0"<br />
| PCR reaction is limited by the presence of inhibitors present in the sample : reagent inhibitors <br />
|-bgcolor="#F0FFF0"<br />
| self annealing due to the accumulation of the product -stopping exponential amplification for the target sequence and reach a plateau<br />
quantification of the end point of reaction of PCR products unreliable - therefore that is why we require real time quantitative RT-PCR necessary<br />
<ref> NIS (2015) Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref><br />
|}<br />
<br />
<br />
===Fluorescent In Situ Hybridisation (FISH)===<br />
<br />
<br />
====Description====<br />
Fluorescence in situ hybridization (FISH) the one of the most effective and rapid <ref name="PMID26338801"><pubmed>26338801</pubmed></ref> Preimplantation Genetic Diagnosis (PGD). This techniques used to locate a specific DNA sequences within a chromosome. FISH facilitates the clinical diagnosis of chromosomal abnormalities indicated by sequential duplications, deletions and rearrangements of chromosome, that are usually missed with microscopic analysis. This technique is especially relevant for female embryos with X-linked diseases,<ref name="PMID20809319"><pubmed>20809319</pubmed></ref> that have no other mutation specific tests [http://www.ncbi.nlm.nih.gov/pubmed/20809319] As part of PGD, samples are collected from various stages of the embyro,and they are able to conducted tests on the blastocyst, a polar body biopsy and the blastomeres <ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. FISH is 99% effective when used in conjunction with competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities<ref name="PMID26338801"/>.<br />
<br />
====Procedure==== <br />
<br />
Samples are collected from either the blastocyst, a polar body biopsy or the blastomeres stages of the embryo <ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
DNA strands are heated and denatured causing their the individual DNA strands to break apart<br />
Probes are single complimentary stands of DNA a that have been tagged with small chemical agents that glow brightly in the presence of a specific region on a chromosome. These specific probes then hybridize and join to their complementary DNA strand. <br />
The fluorescent tags enable the researchers to correctly identify the presence or lack thereof and location of the specific chromosomes that they are testing for. <ref name="PMID17876073"><pubmed>17876073</pubmed></ref><br />
Researcher analyse the results by identifying the number and the relative location of the fluorescent dots generated by the FISH images.<ref name="PMID17970921"><pubmed>17970921</pubmed></ref><br />
The probe will not fully hybridise if there has been a duplication or a deletion of the DNA - indicating chromosomal and sex chromosomal anomalies like trisomies and aneuploidies. <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref><br />
<br />
<br />
Different probes are used for different purposes: <ref>Unique, Rare Chromosome Disorder Support Group (2013) Fluorescence in situ hybridisation (FISH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/Other/FISH%20FTNW.pdf]</ref><br />
*'''Locus specific tags''' detect very small imbalances, and locate isolated small portions <br />
of genes within a chromosome<br />
*'''Alphoid/Centomeric Repeat probes''' are developed from the repetitive sequence located in the middle region of each chromosome, useful in determining the number of chromosomes , detecting rearrangement and when used in conjunction with locus probes to determine the absence of genetic material on a chromosome. <br />
*'''Paint Probes''' are collections of smaller probes with their own stains that bind to a different section on the chromosome - allowing the full chromosome too be labeled a unique colour, this "full colour map" can be used to know the spectral karyotype- full chromosomal mapping is useful in examining chromosomal abnormalities. <br />
<br />
[[File:Fluorescent In Situ Hybridisation (FISH).jpg|thumb|right|'''FISH''' We are able to tag Specific DNA sequences using Probes which have been tagged with fluorescent Labels.This technique enables the clinical diagnosis of chromosomal abnormalities, indicated by sequential duplication, deletions and rearrangements of chromosome <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref>]]<br />
<br />
{|class="wikitable" align="center"<br />
|-bgcolor="pink" <br />
| rowspan="8" |'''Advantages''' <br />
|-bgcolor="#FDE1F2" <br />
| FISH is 99% effective when used in conjunction with Competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities.<ref><pubmed>26338801</pubmed></ref><br />
|-bgcolor="#FDE1F2" <br />
| Rapid generation of results<br />
|-bgcolor="#FDE1F2" <br />
| Identifies very small translocations and aneuploidies that occur within chromosomes, that would usually be missed under microscopic analysis<br />
|-bgcolor="#FDE1F2" <br />
| Indicates whether the accessed chromosomes are normal <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|-bgcolor="#FDE1F2" <br />
| Tests for the most common chromosomal abnormalities - down syndrome chromosomes 13,16,18,21 and 22 <ref><pubmed>21749752</pubmed></ref><br />
|-bgcolor="#FDE1F2" <br />
| It may be used to compare the chromosomal gene arrangements in related species<br />
|-bgcolor="#FDE1F2" <br />
| can be used to identify and remove inheritable X-linked disease or sex chromasome anomalies such as Duchennes Muscular Dystrophy, hemophilia, ectodermal dysplasia <ref><pubmed>17876073</pubmed></ref><br />
|-bgcolor="#FEB745"<br />
| rowspan="5"|'''Disadvantages'''<br />
|-bgcolor="#FE1C5EA"<br />
| FISH destroys all cells tested <ref> O'Connor, C. (2008) Fluorescence in situ hybridization (FISH). Nature Education 1(1):171. retrieved from [http://www.nature.com/scitable/topicpage/fluorescence-in-situ-hybridization-fish-327] </ref><br />
|-bgcolor="#FE1C5EA"<br />
| It does not fully access all chromosomes (only ~ 12)<br />
|-bgcolor="#FE1C5EA"<br />
| Analysis of results is dependent upon the dot quality impacted by hybridisation efficiency or the camera sensitivity <ref><pubmed>17970921</pubmed></ref><br />
|-bgcolor="#FE1C5EA"<br />
| some studies indicate that using FISH on a day-3 embryo biopsy decreases the rate of live births <ref><pubmed>26168107</pubmed></ref><br />
|}<br />
<br />
===Array Comparative Genomic Hybridisation (aCGH)===<br />
====Description====<br />
<br />
aCGH also known as Microarray analysis efficiently scans the entire genome for chromosomal imbalances. CGH was initially developed to detect the number of changes in a solid tumor mass. It uses 2 genomes comparing the sample to the control, with each labeled in a different fluorescent dye<ref name="PMID1876176"><pubmed>1876176</pubmed></ref>. Earlier CGH techniques were limited by the resolution of the imaging <ref> Lichter, P., et al. Comparative genomic hybridization: Uses and limitations. Seminars in Hematology 37, 348–357 (2000)</ref> , these initial limitations were overcome by using Microarrays in conjunction with CGh to improve the resolution of the imaging, Array Comparative Genomic Hybridisation (aCGH). This method compares sample and control microarrayed slides containing small segments of DNA (probes). <ref> Lucito, R., et al. Representational oligonucleotide microarray analysis: A high-resolution method to detect genome copy number variation. Genome Research 13, 2291–2305 (2003) </ref> the Probes used will vary according from the small (25-85 base pairs) oligonucleotides manufactured to highlight different target sequences, to the very large genomic clones (80,000- 200,00 base pairs), and as these are significantly smaller than the traditional metaphase chromosomes used for CGH, generating a higher resolution of image. <ref name="PMID22467166"><pubmed>22467166</pubmed></ref>.aCGH is used as a diagnostic tool for prenatal detection f chromosomal abnormalities <ref name="PMID19012303"><pubmed>19012303</pubmed></ref>.<br />
<br />
<br />
====Procedure====<br />
<ref> Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432] </ref><br />
The sample is obtained (skin, blood or fetal cells) and DNA is obtained. <br />
As a part of PGD fetal cell samples are collected from; the fertilized egg polar bodies, the blastomere (day 3 embryo) or the blastocyst/tropoectoderm stage (day 5 embryo).<br />
Sample DNA is labeled with one fluorescent dye, and the control DNA is labeled with a different colored fluorescent dye. the control DNA is used as the base point of reference. <br />
heated and denatured single DNA strands then hybridize to their complementary single strand probes, which are then combined and applied to a microarray and the results are run through a computer program and a digital imaging system is used to quantify the results( fluorescent intensities of the labeled probes). <br />
<br />
[[File:aCGH.jpg|thumb|right|'''aCGH''' checks the entire genome for chromosomal imbalances, by comparing control and a sample slides contatining small segements of DNA sample microarrayed slides small segments of DNA. Illustrated by student z5020317 and adapted from <ref> NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation. retrieved from [http://www.phgfoundation.org/file/5237/]</ref> <ref>Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432]</ref>]]<br />
<br />
<br />
<br />
The fluorescent ratio and the hybridization signal at different locations on the genome of the control DNA are used to identify any variances present in the sample DNA. aCGH facilitates the clinical diagnosis of submicroscopic chromosomal duplication, deletion and rearrangements indicative of chromosomal disorders such as trisomies 1-22and specific sex linked disorders. <br />
Duplications in the DNA are displayed by the computer program as spikes/ peaks over an established threshold and deletions in DNA are displayed by the computer program as spikes/ toughs beneath this threshold <br />
<br />
<br />
<br />
<br />
{|class="wikitable" align="center"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="12" |'''Advantages''' <br />
|-bgcolor="FFFAFA"<br />
| Multiple applications: prenatal genetic diagnosis, cancer diagnosis, <ref name="PMID20193845"><pubmed>20193845</pubmed></ref> genetic screening for developmental delay (learning disabilities) <ref name="PMID17309648"><pubmed>17309648</pubmed></ref>. or congenital anomalies that are suspected to be genetic in origin <ref>NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation . retrieved from [http://www.phgfoundation.org/file/5237/]</ref><br />
|-bgcolor="FFFAFA"<br />
| trace represents all chromosomes present in the human genome chromosomes 1-22 and the X & Y chromosomes, and therefore is the most accurate method for testing whole embryo aneuploidy<br />
|-bgcolor="FFFAFA"<br />
| aCGH has been extensively tested, and Validated, and is now used world wide.<br />
|-bgcolor="FFFAFA"<br />
| Detects submicroscopic alterations<br />
|-bgcolor="FFFAFA"<br />
| Detects deletions and additions and rearrangements as well as amplification, of the WHOLE genome, simultaneously.<br />
|-bgcolor="FFFAFA"<br />
| Used as a diagnostic tool for prenatal detection of chromosomal abnormalities <ref name="PMID22034057"><pubmed>22034057</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Provides high resolution genomewide screening of segmental genomic copy number variations<br />
|-bgcolor="FFFAFA"<br />
| Very accurate when used in conjunction with FISH<br />
|-bgcolor="FFFAFA"<br />
| Alone is more reliable and in detecting chromosomal abnormalities, with a higher implantation success rate, than FISH <ref name="PMID20494259"><pubmed>20494259</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Allows an in depth research focus upon specific types of rearrangements within selected chromosomal regions, a recent particular area of interest is subtelomeric and pericentromeric rearrangements<br />
|-bgcolor="FFFAFA"<br />
| Reduces the risk of failed implantation and miscarriage, improving the chance of a healthy baby <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|-bgcolor="DDCEF2"<br />
| rowspan="9" |'''Disadvantages'''<br />
|-bgcolor="FFFAFA"<br />
| Translocations and inversions of DNA are not detected<br />
|-bgcolor="FFFAFA"<br />
| Limited ability diagnosing specific polyploidies such as triploidy <ref> Unique, Rare Chromosome Disorder Support Group (2013) Microarray-based Comparative Genomic Hybridiation (array CGH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/other/array%20cgh%20ftnw.pdf] </ref><br />
|-bgcolor="FFFAFA"<br />
| Will not detect mosaicism detection <20% (cultures where >1 of 5 cells are trisomy 12)<br />
|-bgcolor="FFFAFA"<br />
| Will not detect balanced chromosomal rearrangement<br />
|-bgcolor="FFFAFA"<br />
| Will not detect duplications or deletions <80kb<br />
|-bgcolor="pink"|-bgcolor="FFFAFA"<br />
| Will not detect point mutations within genes <ref>Washington department of education (CGH- FAQ for physicians. Signature Genomic LAboratories, LLC. Retrieved from [https://depts.washington.edu/dbpeds/Lab%20Tests/SignatureCGH-physician_FAQ.pdf]</ref><br />
|-bgcolor="FFFAFA"<br />
| will not detect chromosomal position of genomic gains<br />
|-bgcolor="pink"<br />
| Will not detect loos of heterozygosity (LOH) or Absence of heterozygosity (AOH) <ref>WiCell Research Institute Inc. (2012) Comparative Genomic Hybridization Microarray. <br />
retrieved from [http://www.wicell.org/home/cytogenetic-services/cgh-microarray/array-comparative-genomic-hybridization-acgh.cmsx]</ref><br />
|}<br />
<br />
<br />
<br />
===Next Generation Sequencing===<br />
====Description====<br />
The development and advances within ART in the past 20 years, as well as the increasing popularity of IV, has lead to an influx of new technologies developed to screen embryos for chromosomal anomalies, which are covered by the umbrella term of Next generation Sequencing (NGS). NGS is a general term used to describe all of the new and emerging screening techniques currently being introduced and used as part of PGD for IVF . NGS screens for single gene disorders as well as conducting extensive and very comprehensive chromosome diagnosis by sequencing, counting, and accurately assembling millions of DNA reads, simultaneously. <ref name="PMID23499002"><pubmed>23499002</pubmed></ref> There is a movement for NGS to replace the other limited testing techniques and be used as the standard. <br />
====Procedure====<br />
Samples are collected from either blastomere or the blastocyst/tropoectoderm and processed for analysis by a computer system. <br />
The methodology of each process is unique to the technique being used. <br />
<br />
<br />
<br />
{|border="1" align="center"<br />
|-bgcolor="pink" <br />
| '''Advantages'''<br />
| '''Disadvantages'''<br />
|-bgcolor="FFFAFA"<br />
| cheaper<br />
| there are limited information available to clinical applications of NGS <ref><pubmed>26100406</pubmed></ref><br />
|bgcolor="FFFAFA"<br />
| opens new diagnostic possibilities<br />
|<br />
|-bgcolor="FFFAFA"<br />
| accurately tests all 24 chromosomes<br />
| <br />
|-bgcolor="FFFAFA"<br />
| tests for the presence of monogenic diseases of known genetic background<br />
| <br />
|-bgcolor="FFFAFA"<br />
| reduces the number of biopsies required for diagnosis<br />
| <br />
|-bgcolor="FFFAFA"<br />
| higher detection rate of small translocations<br />
| <br />
|-bgcolor="FFFAFA"<br />
| highly accurate is testing for compound point mutations, chromosomal duplication, deletions and insertions <ref name="23312231"><pubmed>23312231</pubmed></ref><br />
| <br />
|-bgcolor="pink"<br />
| it accurately detects chromosomal aneuploidy and unbalanced rearrangement <ref name="PMID25685330"><pubmed>25685330</pubmed></ref><br />
| <br />
|-bgcolor="white"<br />
| NGS single gene disorder screenings can conducted in conjunction with PCR comprehensive chromosomal screening<br />
|<br />
|-bgcolor="pink"<br />
| Reduces human error <br />
|<br />
|-bgcolor="white"<br />
| better detects the presence of mosaicism<br />
|<br />
|-bgcolor="pink"<br />
| work well in conjunction with CGH and aCGH as part of PGD, improving the chances of IVF. <ref> Morris, R. S. (2015 ) Next generation sequencing for PCG|PGS|CCS. IVF1 retrieved from [http://www.ivf1.com/next-generation-sequencing for-pgd] </ref><br />
|<br />
|}<br />
<br />
<br />
<br />
<br />
<br />
<br />
==Diagnosis==<br />
There are a large amount of diseases that PGD can apply to, below are descriptions of the diseases that PGD are more commonly used for. Utilization of Diseased Cell Lines<br />
===Cystic Fibrosis===<br />
Cystic fibrosis is a single gene disorder. It is autosomal recessive and involves mutations in the cystic fibrosis transmembrane conductance regulator (CTFR) gene. The CTFR gene is normally responsible for the decrease in chloride and the transport of bicarbonate in epithelial cells thus playing a major physiological role. In PGD procedures, identification of the gene is assisted by microsatellite markers that have similar composition to the CTFR gene itself. Biopsy of two cells at the blastocyst stage is recommended if markers are not available. There are many variations of cystic fibrosis the most common being P.Phe508del <ref name="PMID26014425"><pubmed>26014425</pubmed></ref>.<br />
===Duchenne Muscular Dystrophy ===<br />
Duchenne Muscular Dystrophy is an X-linked recessive disease. It involves the Xp21 gene where majority of the mutations are chromosomal deletions with a smaller percentage resulting from duplications <ref name="PMID18359022"><pubmed>18359022</pubmed></ref>.<br />
<br />
===Autosomal Recessive MEckel-Gruber Syndrome===<br />
Autosomal recessive genetic defect caused by the TMEM67 gene. It results in cystic dysplasia of the kidneys with fibrotic change in the liber and occipital encephalocele. Other malformations could also be present in the central nervous system. In PGD whole genome amplification of single blastomeres are taken to identify the gene, this is also coupled with PCR techniques. Maternal plasma can also be extracted for PGS. <ref><pubmed>24039893</pubmed></ref> <br />
===β – Thalassemia=== <br />
β – Thalassemia is known as the most common type of autosomal recessive inherited disorder among haemoglobinopathies. It involves the adult β-globin gene and is associated with the absent or decreased expression of the gene. This is commonly caused by a single nucleotide change in the gene. PGD has been used successfully worldwide to identify the β-globin gene where its application is usually performed on a single blastomere or polar body <ref name="PMID19064120">19064120</pubmed></ref>.<br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
! Applicable diseases for PGD <ref>Genoma Group (2014). Retrieved September 18th, 2015, from http://www.preimplantationgeneticdiagnosis.it/genetic-diseases-diagnosed-by-pgd.htm </ref>, <ref>Genesis Genetics (2015). Retrieved September 18th, 2015, from http://genesisgenetics.org/pgd/what-we-test-for/</ref>, <ref>Human Fertilisation & Embryology Authority (2015). Retrieved Septembr 18th, 2015, from http://guide.hfea.gov.uk/pgd/</ref><br />
|-<br />
| '''Disease'''<br />
| '''Involved Genes'''<br />
|-<br />
| 5 Alpha Reductase Deficiency (5ARD)<br />
| SRD5A2 <br />
|-<br />
| Achondroplasia<br />
|FGFR3 <br />
|-<br />
| Acute Intermittent Porphyria <br />
| ALAD, ALAS2, CPOX, FECH, HMBS, PPOX, UROD, or UROS<br />
|-<br />
| Adrenoleukodystrophy (Adrenomyeloneuropathy)<br />
| ABCD1 <br />
|-<br />
| Agammaglobulinaemia (x-linked) <br />
|BTK <br />
|-<br />
| Agammaglobulinemia Bruton Tyrosine Kinase (BTK) <br />
|BTK <br />
|-<br />
| Aicardi Goutieres Syndrome 1 (AGS1) <br />
|TREX1, RNASEH2A, RNASEH2B, RNASEH2C, SAMHD1<br />
|-<br />
| Alagille Syndrome<br />
|JAG1 or NOTCH2<br />
|- <br />
| Alpers-Huttenlocher Syndrome <br />
|POLG <br />
|-<br />
| Alpha-1-antitrypsin deficiency <br />
|SERPINA1 <br />
|-<br />
| Alpha-Mannosidosis<br />
| MAN2B1 <br />
|-<br />
| Alpha Thalassemia <br />
|HBA1 or HBA2 <br />
|-<br />
| Alports Syndrome<br />
|COL4A3, COL4A4, COL4A5<br />
|-<br />
| Alzheimer's Disease - early onset (Type 3 and 4) <br />
|APP, PSEN1, or PSEN2<br />
|-<br />
| Amyotrophic Lateral Sclerosis 1 (ALS1) <br />
|C9orf72, SOD1, TARDBP, FUS, ANG, ALS2, SETX, VAPB <br />
|-<br />
| Argininosuccinic Aciduria <br />
| ASL<br />
|-<br />
| Arrhythmogenic Right Ventricular Cardiomyopathy/ Dysplasia (ARVC/D)<br />
| DSG2; DSP; PKP2<br />
|-<br />
| Ataxia Telangiectasia<br />
| ATM<br />
|-<br />
| Autosomal Recessive Meckel-Gruber Syndrome<br />
| TMEM67<br />
|-<br />
| Bardet-Biedl Syndrome (BBS)<br />
| BBS1; BBS10<br />
|-<br />
| Barth Syndrome<br />
| TAZ<br />
|-<br />
| Beta Thalassaemia<br />
| HBB<br />
|-<br />
| Birt-Hogg-Dubé Syndrome<br />
| FLCN<br />
|-<br />
| Breast Ovarian Cancer Familial Susceptibility (BRCA2)<br />
| BRCA1; BRCA2<br />
|-<br />
| Canavan Disease <br />
| ASPA<br />
|-<br />
| Carnitine-Acylcarnitine Translocase Deficiency <br />
| SLC25A20<br />
|-<br />
| Cerebral Arteriopathy with Subcortical Infarcts & Leukoencephalopathy (CADASIL)<br />
| NOTCH3<br />
|-<br />
| Cerebral Cavernous Malformation<br />
| CCM1<br />
|-<br />
| Charcot-Marie-Tooth Disease<br />
| GJB1; MPZ; NEFL; PMP22<br />
|-<br />
| CHARGE Syndrome<br />
| CHD7<br />
|-<br />
| Cherubism<br />
| SH3BP2<br />
|-<br />
| Choroideremia<br />
| CHM<br />
|-<br />
| Chronic Granulomatous Disease<br />
| CYBB; NCF1<br />
|-<br />
| Ciliary Dyskinesia<br />
| DNAH5<br />
|-<br />
| Citrullinemia<br />
| ASS1<br />
|-<br />
| Cleidocranial Dysplasia<br />
| RUNX2<br />
|-<br />
| Cockayne Syndrome<br />
| ERCC6<br />
|-<br />
| Congenital Adrenal Hyperplasia<br />
| CYP21A2<br />
|-<br />
| Congenital Cataracts<br />
| GJA8; VSX2<br />
|-<br />
| Congenital Diarrhea, Syndromic<br />
| SPINT2<br />
|-<br />
| Congenital Disorders of Glycosylation (CDG)<br />
| ALG1; ALG6; CDG1C; DOLK; PMM2<br />
|-<br />
| Cornelia de Lange Syndrome <br />
| NIPBL<br />
|-<br />
| Craniosynostosis<br />
| TWIST1<br />
|-<br />
| Crouzon Syndrome<br />
| FGFR2<br />
|-<br />
| Cysteinyl Leukotriene Receptor 1 Deficiency <br />
| CYSLTR1<br />
|-<br />
| Cystic Fibrosis<br />
| CFTR<br />
|-<br />
| Diamond –Blackfan Anemia <br />
| RPS19<br />
|-<br />
| Duchenne Muscular Dystrophy <br />
| DMD<br />
|-<br />
| Dyskeratosis congenita (Male embryos only)<br />
| DKC1<br />
|-<br />
| Ectodermal dysplasia (Hypohidrotic)<br />
| EDA; EDA1; GJB6; IKBKG<br />
|-<br />
| Familial Adenomatous polyposis coli (FAP)<br />
| APC<br />
|-<br />
| Familial Dysautonomia<br />
| IKBKAP<br />
|-<br />
| Fanconi Anemia <br />
| FANCA; FANCC; FANCD2; FANCF; FANCG; FANCJ<br />
|-<br />
| Fragile X Syndrome (FRAX)<br />
| FMR1<br />
|-<br />
| Galactosemia <br />
| GALT<br />
|-<br />
| Gangliosidosis<br />
| GLB1<br />
|-<br />
| Glanzmann Thrombasthenia <br />
| ITGA2B<br />
|-<br />
| Glutaric Acidemia (aciduria)<br />
| GCDH <br />
|-<br />
| Glycogen Storage Disease <br />
| G6PC; GAA; SLC37A4<br />
|-<br />
| Haemophilia A<br />
| F8<br />
|-<br />
| Haemophilia B<br />
| F9<br />
|-<br />
| Hereditary Nonpolyposis Colorectal Cancer: Lynch Syndrome<br />
| MLH1; MSH2; MSH6<br />
|-<br />
| Holt Oram Syndrome<br />
| TBX5<br />
|-<br />
| Huntington Disease<br />
| HD<br />
|-<br />
| Hydrocephalus<br />
| L1CAM<br />
|-<br />
| Ichthyosis <br />
| ABCA12; STS<br />
|-<br />
| Incontinentia Pigmenti (IP)<br />
| NEMO<br />
|-<br />
| Joubert Syndrome 5<br />
| INPP5E<br />
|-<br />
| Krabbe Disease<br />
| GALC<br />
|-<br />
| Leber Congenital Amaurosis (LCA)<br />
| CEP290; GUCY2D<br />
|-<br />
| Leigh Syndrome (Infantile Subacute Necrotising Encephalopathy)<br />
| LRPPRC<br />
|-<br />
| Lesch Nyan Syndrome<br />
| HPRT1<br />
|-<br />
| Leukocyte Adhesion Deficiency (Type I)<br />
| ITGB2<br />
|-<br />
| Li-Fraumeni Syndrome<br />
| TP53<br />
|-<br />
| Macular Dystrophy Retinal <br />
| VMD2<br />
|-<br />
| Maple Syrup Urine Disorder (MSUD)<br />
| BCKDHB<br />
|-<br />
| Marfan Syndrome <br />
| FBN1<br />
|-<br />
| Menkes Syndrome<br />
| ATP7A<br />
|-<br />
| Mitochondrial DNA Depletion Syndrom <br />
| POLG; RRM2B; SUCLA2; TK2<br />
|-<br />
| Mucolipidosis type II<br />
| GNPTAB<br />
|-<br />
| Multiple Endocrine Neoplasia<br />
| MEN1; MEN2A; MEN2B<br />
|-<br />
| Multiple Exostoses<br />
| EXT1; EXT2 <br />
|-<br />
| Myotubular myopathy<br />
| MTM1 <br />
|-<br />
| Nail-Patella Syndrome<br />
| LMX1B<br />
|-<br />
| Neurofibromatosis Type 1<br />
| NF1<br />
|-<br />
| Neurofibromatosis Type 2 <br />
| NF2<br />
|-<br />
| Noonan Syndrome<br />
| KRAS, PTPN11; SOS1<br />
|-<br />
| Norrie Disease<br />
| NDP<br />
|-<br />
| Ocular Albinism <br />
| GPR143<br />
|-<br />
| Oculocutaneous Albinism <br />
| OCA2; TYR <br />
|-<br />
| Oculodentaldigital Dysplasia<br />
| GJA1<br />
|-<br />
| Optic Atrophy<br />
| OPA1<br />
|-<br />
| Ornithine Transcarbamylase Deficiency <br />
| OTC<br />
|-<br />
| Osteogenesis imperfeca <br />
| COL1A1; COL1A2<br />
|-<br />
| Osteopetrosis <br />
| CLCN7; OSTM1; TCIRG1<br />
|-<br />
| Pachyonychia Congenita <br />
| KRT16; KRT6A<br />
|-<br />
| Pancreatitis, Hereditary<br />
| PRSS1 <br />
|-<br />
| Papillorenal syndrome <br />
| PAX2<br />
|-<br />
| Phenylketonuria <br />
| PAH <br />
|-<br />
| This table does not cover the complete list of diseases that PGD can be applied to.<br />
|}<br />
<br />
==Laws & Legal status==<br />
<br />
{| class="wikitable" <br />
|-bgcolor="DDCEF2"<br />
|'''Country'''<br />
|'''Legislation'''<br />
|-<br />
| Australia<br />
| PGD is currently used to detect serious genetic conditions to improve the outcome of Assisted Reproductive Technologies (ART). In very rare cases it may be used to select an embryo with compatible tissue for a sibling who has a life-threatening disease where other means of treatment is unavailable. This is with the conditions that the use of PGD will not affect the welfare and interests of the child to be born. The parents must also receive adequate counselling and have full understanding of the procedures of PGD. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"> National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art</ref><br />
The use of PGD for sex-selection is prohibited with the exception of reducing the risk of the transmission of serious sex-linked genetic conditions. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"/><br />
|-bgcolor="FFFAFA"<br />
| Brazil<br />
| The laws regarding PGD in Brazil are not strictly regulated. They are vague and there is limited information surround the activities of assisted reproduction in general in the country <ref name="PMID25493379"><pubmed>25493379</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| Czech Republic<br />
| The laws in the Czech Republic allow those with a “defined indication in order to exclude risk of serous genetically conditioned disease and defects with embryos before they are implanted into the cavity of the uterus”. Couples that undergo any assisted reproductive treatment including PGD have to be married. Sex-selection is illegal except in regards to serious sex-linked genetic diseases <ref name="PMID24777348"><pubmed>24777348</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| Greece<br />
| In Greece, ART is open to those up to the age of 50 with written consent. It can only be used if a medical necessity is present such as the susceptibility of serious hereditary diseases. Sex selection is banned apart from cases of sex-linked diseases and sexually transmitted diseases <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| India<br />
| In India there is a cultural preference for boys thus the Prenatal Diagnostic Techniques (Regulation and Prevention of Misuse) Act was introduced in 1994. This law limits the use of PGD for sex determination except in cases of specific congenital diseases. These laws however are not strictly enforced. <ref>World Health Organisation (2015) Gender and Genetics Retrieved on October 21st 2015 from:http://www.who.int/genomics/gender/en/index4.html</ref><br />
|-bgcolor="FFFAFA"<br />
| Portugal <br />
| ART is only available to those who are married or have a similar type of relationship for at least two years. The couples cannot be of the same sex and must be at least 18 years of age. Sex selection is illegal except in cases of sex-linked diseases. The use of PGD is illegal if the predictive value of genetic tests are very low <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| Spain<br />
| PGD can be applied to “serious hereditary diseases not amenable to postnatal curative treatment” and “detection of other abnormalities which may compromise the viability of the pre-embryo”. If PGD is to be used for any other purpose authorisation must be acquired <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| Sweden <br />
| The use of PGD is strictly regulated and couples must achieve authorisation of the National Board of Health and Welfare. It can only be used it can only be used if the child is at risk to inheriting a serious chromosomal or monogenetic disease. It cannot be used for selection of specific characteristics <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| United Kingdom<br />
| Those involved with carrying out the IVF treatment must have a license from the Human Fertilisation and Embryology Authority (HFEA). Only embryos that are approved by the HFEA can be implanted where the embryonic nuclear or mitochondrial DNA cannot be altered with the exception of preventing mitochondrial diseases <ref name="PMID24777348"/>. <br />
|}<br />
<br />
==Future/Current Research==<br />
===Noninvasive Preimplantation Genetic Testing without Embryo Biopsy===<br />
Different parameters of gametes, zygotes, embryos (“vacuoles in sperm heads, spindle position in mature oocytes, cleavage intervals of zygote, and embryo developmental dynamics”) may correlate with aneuploidy rates. This knowledge may be applied in potential noninvasive preimplantation diagnostic methods. Several methods have been proposed and are currently further researched<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Sperm Selection====<br />
Intracytoplasmic morphologically selected sperm injection (IMSI) is common procedure in IVF treatment to improve fertilization rates in patients with poor semen quality. In addition, studies have found that IMSI improves embryo development and that spermatozoa with large vacuoles in their heads correlate with increased aneuploidy rates and disturbed chromosomal structures. Thus, selecting spermatozoa based on morphological hallmarks may decrease aneuploidy rates in the fertilized embryos. As with polar body biopsies, however, this approach will solely be applicable if evidence for severe male detrimental contribution is given<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Blastocoel Fluid Extraction====<br />
In addition, a less invasive retrieval of material for diagnosis could include the extraction of the blastocoel fluid. The cavity of the blastocyst, lined by the trophectoderm, is filled with this blastocoel fluid, which contains metabolites of both trophectoderm and inner cell mass origin. The retrieval does not require a biopsy but merely a small opening to extract the fluid and, thus, causes less harm to the embryo. Multiple studies have applied this method<ref name="PMID22020776"><pubmed>22020776</pubmed></ref> <ref name="PMID23148560"><pubmed>23148560</pubmed></ref> and it may in the future become of clinical relevance.<br />
<br />
<br />
[[File:Aspiration_of_the_Blastocoel_Fluid.jpeg|thumb|Aspiration of the Blastocoel Fluid using a ICSI pipette<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.]]<br />
<br />
<br />
Next to metabolites, the blastocoel fluid can contain DNA. Studies have shown that genomic DNA is present in about 90% of the blastocoel fluid samples tested. Typically the fluid is removed with an ICSI pipette from a day five blastocyst through its mural trophectoderm until the blastocyst fully collapses around the embryo. Several concerns regarding this method in a clinical setting have been raised. The collected DNA may be contaminated by the culture media that contains DNA fractions. The DNA may also be least representative of the actual embryos genome as the DNA may originate from abnormal or degenerated cells. Even though labelled noninvasive, the blastocyst still undergoes manipulation to some degree which may affect its viability. Thus, more research is required until this method can evolve from research to clinical use<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
====Proteomics====<br />
The protein secretome of blastocysts may be representative of its chromosome constitution Recent studies have found biomarkers such as lipocalin-1, interleukin-10, tumor necrosis factor, stem cell factor, and chemokine ligand 13 to be differently secreted by aneuploid blastocyst than by euploid ones. The most significant biomarker appears to be interleukin-10. Paired with novel proteomic technologies and mass spectrometry this knowledge when extended may contribute to a new invasive preimplantation genetic diagnosis method<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Embryo Morphology====<br />
Using time lapse imaging the embryo’s morphology can be closely observed and potential aneuploidy characteristics detected. Such characteristics may include the time of division to five cells, the time between the division from three to four cells, and the duration of the division from one to two and subsequently to three. In addition, the morphological quality of ICM an TE has been positively associated with aneuploidy or euploidy prognosis<ref name="PMID26246880"><pubmed>26246880</pubmed></ref>. These may give rise to an embryo quality screening prior to implantation<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
==References==<br />
<br />
<references/><br />
<br />
<br />
{{StudentPage2015}}</div>Z5017878https://embryology.med.unsw.edu.au/embryology/index.php?title=2015_Group_Project_6&diff=2070152015 Group Project 62015-10-21T07:18:42Z<p>Z5017878: </p>
<hr />
<div>{{ANAT2341Project2015header}}<br />
<br />
<br />
=Preimplantation Genetic Diagnosis and Screening=<br />
==Introduction==<br />
Preimplantation genetic diagnosis (PGD) and screening (PGS) are reproductive options for couples with known family histories of genetic disease or couples undergoing IVF procedures due to infertility issues. PGD can diagnose many genetic disorders caused by known chromosomal abnormalities (number and/or structure) or single gene mutations, and, thus decrease the risk of termination of pregnancy or miscarriages and enable such couples to have an unaffected child<ref name="PMID24907939"><pubmed>24907939</pubmed></ref>. Through major improvements in PGD/S and general laboratory technology, the testing for abnormalities in fetuses has shifted from prenatal diagnosis during the first 2 trimesters <ref> Blackburn, S.L. (2003) '''Maternal, Fetal & Neonatal physiology: a Clinical perspective''' (2nd ed.). Seattle: Saudners </ref>, testing for overall fetal growth, complications of pregnancy, and birth defects<ref> Sadler T.W.(2012) '''Langman's Medical Embryology''' (12th ed.) Philadelphia: Lipincott, Wiliams & Wilkins, a Wolters Kluwer Business </ref>, to an embryonic focus especially in advancements in Artificial Reproductive Technologies (ART)<ref><pubmed>20638568</pubmed></ref>. In 1990 PGD for a recessive X-linked disease resulted in the first live birth<ref><pubmed>2330030</pubmed></ref> and has since been incorporated in clinical routine and applied for a variety of genetic diseases, such as sickle cell anemia, thalassemia, or cystic fibrosis<ref name="PMID24907939"/>.<br />
[[File:Preimplantation Genetic Diagnosis Procedure.jpeg|700px|thumb| Simplified steps for PGD<ref name="PMID24907939"/>]]<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=0e-79qKllqk</html5media><br />
|-<br />
| Preimplantation Genetic Diagnosis<ref>IVF Florida (2011, December 11) IVF Florida - South Florida Fertility Specialists - Pre-Implantation Genetic Diagnosis [Video file]. Retrieved from https://www.youtube.com/watch?v=0e-79qKllqk</ref><br />
|}<br />
<br />
==History==<br />
The advances in reproductive technology during the second half of the 20th century, led to PGD's first clinical application in 1990 <ref>Harper, J. (n.d.). The history of PGD. Lecture. UCL Centre for PG&D and CRGH.University College London</ref>.<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
|Year<br />
|<br />
|- bgcolor="FFFAFA"<br />
| '''1967''' <br />
|First PGD on rabbit blastocysts (Gardner& Edwards) <ref name="PMID6036172"><pubmed>6036172</pubmed></ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1986''' <br />
|First Cleavage Biopsy (Wilton & Trounson)<ref>Wilton, L. J., & Trounson, A. O. (1986). Viability of mouse embryos and blastomeres following biopsy of a single cell. In Proceedings of the 18th Annual Conference of the Australian Society for Reproductive Biology, Brisbane, Australia.</ref><br />
|- bgcolor="FFFAFA"<br />
|'''1987''' <br />
|First Blastocyst Biopsy (Muggleton-Harris, Monk, Rawlings, & Whittingham)<ref name="PMID3372699"><pubmed>3372699</pubmed></ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1988''' <br />
|First Polar Body Biopsy (Yury Verlinksy)<ref> Verlinsky, Y., Pergament, E., Andresen, P., Enriquez, G., & Strom, C. (1989). Genetic analysis of polar body DNA: A new approach to preimplantation genetic diagnosis. Am J Hum Genet, 45(4), A272.</ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1990''' <br />
|First Clinical PGD using PCR testing for X-linked (Handyside, Kontogianni, Hardy, & Winston)<ref name="PMID2330030"><pubmed>2330030</pubmed></ref> <br />
|} <br />
==Preimplantation Genetic Diagnosis==<br />
Preimplantation genetic diagnosis (PGD) is used to test the genetic makeup of embryos to detect single gene disorders, chromosomal abnormalities and mitochondrial disorders. It also has applications in gender selection for diseases with unequal gender distributions <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Some diseases commonly involved with PGD include cystic fibrosis, spinal muscular atrophy and beta – thalassaemia <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press.">Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press</ref> <ref name="PMID17823145"><pubmed>17823145</pubmed></ref>. It was first used in the United Kingdom in the 1980s of arenoleucodystrophy and primarily focusing on sex- linked disorders <ref name="PMID17823145"/><ref name="PMID23150080"><pubmed>23150080</pubmed></ref>. PGD is now capable of detecting single cell defects (molecular) and chromosomal disorders resulting from the inversion, translocation or deletion of chromosomes (cytogenic) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>,<ref name="PMID11325751"><pubmed>11325751</pubmed></ref>. PGD can be applied to the embryo at different stages. That is on polar bodies, blastomeres or blastocyst <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>.<br />
Depending on the type of genetic disorder, PGD utilises different methods of genetic testing. These include Fluorescence in situ hybridisation (FISH) which is used for sex – linked disorders and detects chromosomal rearrangements <ref name="PMID11325751"/><ref name="PMID17876073"><pubmed>17876073</pubmed></ref> and Embryo halotyping which allows the identification of chromosomes causing the inherited disorder through knowledge of the pattern of closely linked markers <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. Polymerase chain reaction (PCR) is also widely used to detect molecular abnormalities <ref name="PMID11325751"/>.<br />
PGD is tightly regulated and supported by large organisations namely The American Society for Reproductive Medicine, The European Society for Human Reproduction and Embryology (ESHRE), The European Society of Human Genetics and the Preimplantation Genetic Diagnosis International Society <ref name="PMID25500181><pubmed>25500181</pubmed></ref>.<br />
===Sex-linked disorders===<br />
The determination of a disease as gender specific usually correlates with the presence or absence of specific genes such as SRY on the Y chromosome. It is known that females have two X chromosomes and males have an X and a Y chromosome where abnormalities are more prevalent on the X chromosome. PGD can be used for sex selection where only male embryos are transferred to reduce the chance of inheriting X-linked disorders. However, this does not completely eradicate the problem as male embryos remain susceptible to inheriting an affected X chromosome. Sex determination is only used when the specific mutation is unknown and has yet to be discovered <ref name="PMID24866878"><pubmed>24866878</pubmed></ref>.<br />
===Single gene defects===<br />
Single gene defects can be dominant, recessive, autosomal or X-linked. They are commonly diagnosed using PCR and although the PCR available today is complex and capable of combatting a large range of disease the development of new protocols has been proven to be difficult due to the small DNA sample available <ref name="PMID26168107"><pubmed>26168107</pubmed></ref><br />
===Mitochondrial disorders===<br />
Mitochondrial disorders also known as oxidative phosphorylation disorders arise from mutations in the nuclear DNA or mitochondrial DNA <ref name="PMID26312584"><pubmed>26312584</pubmed></ref>. They pose as a problem because they are unrecognisable until the mutations in the cell reach a detrimental level <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Mitochondrial disorders cause miscarriages and stillbirths as well as death in children and young adults. The effects can either be contained in a single organ or more commonly involve multiple organ failure where organs with high energy demands such as the brain, liver muscle and heart and heavily influenced. They are usually occur spontaneously or result from inheritance from the mother. Since mitochondria are solely inherited from the mother oocyte donations have been used as a solution to combat mitochondrial disorders. Additionally, there has been an increasing use in PGD where embryos that stay under the given threshold of 18% gene-mutations are allowed to be transferred and result in normal development. New technology in the areas of nuclear gene transfer and genome editing are also being experimented with <ref name="PMID26312584"/>. <br />
===Chromosomal disorders===<br />
Chromosomal disorders can be reciprocal, Robertsonian translocations, inversions, deletions and insertions <ref name="PMID26168107"/>. . Data from ESHRE collected between 2010 and 2011 has shown that the most common chromosomal abnormality confronted in PGD are reciprocal chromosomal abnormalities <ref name"PMID26071418"><pubmed>26071418</pubmed></ref>. PGD has also been used successfully for Robertsonian translocations (RT), a type of structural translocation. Children who carry RT are phenotypically normal, however in their later years it is found that they will suffer from infertility and repeated miscarriages due to the high frequency of abnormal embryos <ref name="PMID22081077"><pubmed>22081077</pubmed></ref>. PCR and FISH are the two main techniques used for chromosomal disorders. To be able to conduct the examinations the cells are required to be at the metaphase stage <ref name="PMID26168107"/>. <br />
==Preimplantation Genetic Screening==<br />
Prenatal Genetic Screening (PGS) involves an array of methods or ideas that aim to segregate embryos that have genetic flaws and those that are healthy <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. The occurrence of aneuploidy is high around the stages of early embryonic development and they are the most common cause if miscarriages and congenital birth defects <ref name= "PMID26085841"><pubmed>26085841</pubmed></ref>. They have little effect on the morphology of the embryo making them difficult to identify thus identification heavily relies on genetic testing <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. <br />
Genetic sampling is most commonly conducted using Microarray Comparative Genomic Hybridisation (aCGH) as well as FISH, Quantitative PCR and Single Nucleotide Polymorphism (SNP) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. These methods collectively aim to assess numeral and structural chromosomal errors <ref name= "PMID26085841"/>. Studies have also introduced Next- Generation Sequencing (NGS) <ref name= "PMID26085841"/> and Whole Genome Amplification used to screen imbalances in the complete 24-chromosomes <ref name="PMID25953353"><pubmed>25953353</pubmed></ref><br />
Statistics from ESHRE have shown that the most common indications for PGS is advanced age, followed by repeated implantation failure or recurrent miscarriage and male infertility <ref name="PMID26071418"><pubmed>26071418</pubmed></ref>.<br />
====Indications====<br />
A low percentage of structural abnormalities in chromosomes are responsible for the cause of miscarriages. Despite this, they are the most prevalent type of chromosomal abnormality accounted for in PGD <ref name="PMID20638568"/>. The presence of specific gene cycles, initiation of embryonic protein synthesis and evident physiological development are all indicative of a successful in vitro fertilisation procedure <ref name="PMID11576737"><pubmed>11576737</pubmed></ref>. To eliminate further errors from occurring during the PGD procedure it is recommended to undertake further prenatal testing such as amniocentesis in the later stages <ref name="PMID20638568"/>. <br />
=====Advanced maternal age=====<br />
Data provided by the ESHRE has shown that the mean age of women undergoing PGS is 39 years <ref name="PMID26071418"/>. Women of advanced age have been shown to have a lower rate of pregnancies reaching childbirth <ref name="PMID18583331"><pubmed>18583331</pubmed></ref>. The highlighted concern revolves around the increased occurrence of aneuploidy following maternal age. The optimal age range for the lowest aneuploidy incidence was found to be between 27 to 37 years of age (6%) then progressively higher in women aged up to 42 (33%) and most common in those 44 and above (53%) <ref name="PMID24355045"><pubmed>24355045</pubmed></ref>. <br />
=====Recurrent pregnancy loss / IVF failure=====<br />
Recurrent pregnancy loss is defined as three or more IVF failures after cumulative transfer of more than 10 good-quality embryos. These are primarily caused by two main factors, reduced endometrium receptivity or embryonic defects. Endometrium receptivity can be negatively influences by instances including uterine pathologies such as thin endometrium, altered expression of adhesive molecules and immunological factors. Additionally, embryonic defects may be due to genetic abnormalities, embryonic aneuploidy or zona hardening. Endometriosis and hydrosalpinx has been known to effect both the endometrium and embryo <ref name="PMID23260857"><pubmed>23260857</pubmed></ref>.<br />
=====Human leukocyte antigen matching=====<br />
First used in 2001, HLA matching is an option given to parents to save a child with haematological or immunological disease through conceiving another child who would potentially be able to donate cord blood or haematopoietic stem cells from the bone marrow for transplantation. The process namely PGD-HLA has shown to improve haematopoietic stem cell transplant (HSCT). PGD-HLA can only be performed when HSCT is not needed urgently due to the time needed to conceive and delivery the baby <ref name="PMID25500181"><pubmed>25500181</pubmed></ref>. It is most commonly applied to children suffering from relapsed leukaemia <ref name="PMID22524201"><pubmed>22524201</pubmed></ref>. In a case study PGD-HLA was proven to successfully cure 10 diseases including Fanconi anaemia, Diamond-Blackfan anaemia and beta thalassemia <ref name="PMID25066893><pubmed>25066893</pubmed></ref>.<br />
==Biopsy Methods==<br />
Biopsy, the removal of genetic materials, from oocytes or embryos in the preimplantation stage is the primary step in PGD. For the past two decades these biopsies have been performed at three stages, the polar body, blastomere, and blastocyst, and the methodologies optimized to ensure the embryo’s viability. The most common approach involves biopsies at the cleavage stage. However, polar body and blastocyst biopsies are increasingly more often tested and applied. Approached for opening the zona pellucida involve next to the traditional mechanical and chemical means, novel approaches such as noncontact lasers. Their application may simplify and secure the procedure significantly. The most challenging question about PGD procedures remains at what stage biopsies should be taken. Much controversy has developed around this topic, highlighting the varying disadvantages and advantages of temporal biopsies. <ref name="PMID22723007"><pubmed>22723007</pubmed></ref><br />
<br />
{| class="wikitable"<br />
|- align="center" bgcolor="DDCEF2"<br />
|<br />
| Time of Biopsy<br />
| Advantages <br />
| Disadvantages<br />
|- bgcolor="FFFAFA"<br />
| Polar Body<br />
| Day 1<br />
| No harm to oocyte<br />
| Only maternal DNA is tested, often needs to be coupled with other biopsies<br />
|- bgcolor="FFFAFA"<br />
| Blastomere<br />
| Day 3<br />
| …<br />
| … <br />
|- bgcolor="FFFAFA"<br />
| Trophectoderm<br />
| Day 5 and 6 <br />
| Little harm, large amount of genetic material<br />
| Opening of blastocyst necessary, small time window for procedure<br />
|}<br />
<br />
<br />
[[File:Polar_Body,_Blastomere,_and_Trophectoderm_Biopsy.jpeg|thumb|Polar body (A), blastomere (B) and trophectoderm (C) biopsies<ref name="PMID25625041"><pubmed>25625041</pubmed></ref>.]]<br />
<br />
<br />
<br />
PMID 24305177<br />
===Polar Body Analysis===<br />
Day 1<br />
====Description====<br />
Polar body (PB) biopsy, which was introduced in 1990, offers a promising alternative to biopsies performed at the blastomere stage for PGD/S indications on legal and practical grounds. <br />
Description: Consequent embryo development does not necessitate the presence of the first and second PB and their removal may not be crucial. PB biopsy requires precise timing. Keeping track of the meiotic cell cycle is necessary to perform a successful biopsy and, therefore, PB biopsy usually is applied in combination with intracytoplasmic sperm injection (ICSI). During the maturation from the germinal vesicle stage to the metaphase-II stage the first PB is formed. A cytoplasmic bridge containing spindle remnants, that are still in contact with the cellular genetic material, links this PB to the oolemma for about 90 minutes after extrusion. It is possible to visualize these remnants by polarization microscopy and it is crucial to not perform the biopsy until the first PB is no longer firmly attached to the oolemma as this indicates an immature embryo.The oocyte tolerates mechanical zona dissection best during hours four until six after ICSI as the oolemma has stabilized by that time because of the cortical granule reaction. Over time the first PB degenerates stressing a temporal biopsy and its optimal extraction time window is four to 12 hours after ICSI. The second PB forms around two to four hours after ICSI. However, its optimal time window for biopsy is set to be eight to 16 hours after ICSI. This is due to the second PB being attached to the oolemma with spindle remnants until six hours after ICSI. Biopsy at this point may cause enucleation of the oocyte. In addition, studies have shown that the amplification efficiency of second PB’s DNA is worse if the PB is extracted prior to eight hours after ICSI. <br />
Thus, it is possible to perform sequential and simultaneous biopsies for the first and second PB. If performed, sequentially the first PB may be removed four to 12 hours and the second PB eight to 16 hours after ICSI. The optimal time window for a biopsy for both the first and second PB simultaneously is eight to 12 hours after ICSI. It is highly preferred to analyze both PBs due to potential aneuploidies in either PB and crossing overs during meiosis<ref name="PMID22723007"/>. <br />
====Procedure====<br />
Chemical opening achieved with for example acidic tyrode’s solution of the zona pellucida is not tolerated by the oocyte and may have detrimental effects on the embryo’s development. Therefore, the access to the perivitelline space of the oocyte is provided by mechanical zona dissection or by laser. Both techniques work well if performed by experienced embryologist. However, laser-assisted biopsy is less time consuming when compared to manual dissection. It is critical to consider the size of the introduced opening as it will remain permanent. If it is too large the blastomere may be lost during embryo development and if it is too small it may interfere with hatching of the embryo during blastocyst stage<ref name="PMID22723007"/><br />
<br />
[[File:Polar_Body_Biopsy.jpeg|thumb|The presence of a faint but clearly identifiable strand connecting PB2 to the <br />
oolemma. The biopsy was performed ∼9 h after ICSI<ref name="PMID21908464"><pubmed>21908464</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JTaQzszVr8o</html5media><br />
|-<br />
| Laser-assisted polar body biopsy<ref>RIUK, R. (2013, June 25) Polar Body Biopsy [Video file]. Retrieved from https://www.youtube.com/watch?v=JTaQzszVr8o</ref><br />
|}<br />
<br />
====Advantages & Disadvantages====<br />
PB biopsies can only investigate the maternal contributions to the embryo as they are of maternal origin. Thus, this procedure is appropriate for PGD solely for monogenetic diseases from the maternal side. Recessive diseases may be evaluated with PB biopsies on the basis that the embryo’s outcome will be determined by the paternal contribution. (...) It may still be applied for PGS as most aneuploidies either arise during meiosis or origin from the maternal genome. However, diagnosis error has been reported due to the lack of considering paternal contributions. <br />
Because PB biopsies are performed very early it is not yet known whether the oocyte will develop into a viable embryo. Thus, PBs are commonly frozen or fixed after biopsy and depending on the state of the embryo only chosen PBs will be tested. This is primarily an economic issue as many genetic testing procedures are very cost-intensive<ref name="PMID22723007"/>.<br />
<br />
[[File:Implantation_predictive_value_of_euploid_screening_results.jpeg|thumb|The sustained implantation predictive value (with 95 % confidence interval) of a euploid screening result obtained from the first polar body (PB1), PB1 and the second polar body (PB2), or a direct embryo biopsy for each stage of embryo transfer (cleavage-stage and blastocyst stage)<ref name="PMID25106935"><pubmed>25106935</pubmed></ref>.]]<br />
<br />
===Blastomere biopsy===<br />
Day 3 <br />
====Description====<br />
Blastomere biopsy has been the prevalent method for PGD and PGS in the last two decades. At least one, but up to two, blastomeres are biopsied on day three of the cleavage stage embryo. The right number of blastomeres removed is a controversial topic as two cells allow for more genetic material and more accurate results. However, removing two cells might be too invasive and damaging to the embryo. (Study)<ref name="PMID21748341"><pubmed>21748341</pubmed></ref><br />
====Procedure====<br />
Initially a hole was drilled into the zona pellucida using acid tyrodes and the blastomeres are removed via aspiration with a pipette<ref name="PMID21748341"/>.<br />
<br />
<br />
[[File:Aspiration_of_a_Blastomere.jpeg|thumb|Aspiration of a Blastomere into the biopsy pipette<ref name=" PMID24783200"><pubmed>24783200</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=TbridWVwipI</html5media><br />
|-<br />
| Laser-assisted blastomere biopsy<ref>Sukprasert, M. (2014, March 5) Day 3 Blastomere Biopsy 1 [Video file]. Retrieved from https://www.youtube.com/watch?v=TbridWVwipI</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
===Trophectoderm biopsy===<br />
Day 5 and 6<br />
====Description====<br />
The improvement of embryo culture media allowed the in vitro development of human embryos until the blastocyst stage and opened up the possibility to take blastocyst biopsies. During day three to day five the haploid maternal and paternal genomes work together for the first time to form the genome of the embryo. The maternal epigenetic control lessens significantly while preparing for implantation with precisely arranged events happening. The first event includes a rapid increase in the number of embryonic cells which are active in mitotic divisions and apoptosis of aberrant cells. This is followed by the formation of blastocoel (cavitation) which results from the flattening of cell located on the outside of the blastomere. Now the blastocyst will expand until the embryo hatches by rupturing the zona pellucida. The cells of the blastocyst will differentiate to form two distinct cell lineages, the outer trophectoderm and the inner cell mass<ref name="PMID22723007"/>.<br />
====Procedure====<br />
Trophectoderm biopsy is usually performed in Hepes buffered biopsy medium and opening approaches include needle cutting which has been replaced by lasers in past years. Different research groups report different timings of the opening to be the most successful. Some open the blastocyst on day three or four by creating a 25 µm which causes the trophectoderm to herniate through this hole and is, thus, accessible for biopsy. Others create this hole about four hours before biopsy which allows sufficient herniation of trophectoderm cells. It is also possible to open the blastocyst immediately before biopsy. This avoids an extra step and the inner cell mass usually is easy to locate. Blastocyst biopsies involve the removal of trophectoderm cells and the ideal time for the procedure is day five. Successful biopsies on day six have been performed, while little is known about the results of biopsies on day seven. However, since the window of implantation in humans is from day eight to ten after ovulation, day seven biopsies appear to be possible<ref name="PMID22723007"/>.<br />
-collapse of trophoblasts<br />
-possible: biopsy of hatched blastocyst, holding pipette careful mild suction force to hold embryo near ICM <br />
-Cryopreservation<br />
<br />
<br />
[[File:Microscopic images of human blastocysts for biopsy.jpeg|thumb|(A) Some trophectoderm cells in a blastocyst started to hatch and (B) the trophectoderm cells were biopsied with assisted laser cutting. Images in C–D show the blastocysts after vitrification and warming. Blastocysts had been cultured for 2–4 hrs after warming, showing good (ICM and trophectoderm cells) hatched (C) and hatching (D) blastocysts. The hatching blastocyst in (E) has good ICM but fair trophectoderm while the blastocyst in (F) has both fair ICM and trophectoderm. Arrows indicate ICMs and arrow heads indicate trophectoderm cells. Bar = 40 µm<ref name="PMID2190846"><pubmed>2190846</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JI_TQ8d8tNM</html5media><br />
|-<br />
| Laser-assisted blastocyst biopsy (at 00:50 min)<ref>Coco, R. (2014, April 30) Trophectoderm biopsy in a Hatching blastocyst protruding ICM [Video file]. Retrieved from https://www.youtube.com/watch?v=JI_TQ8d8tNM</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
Blastocyst biopsies are believed to be less damaging to the embryo and appear to be unrelated to implantation rates. In addition, this biopsy method allows for a larger extraction of cells for genetic testing. However, since they are performed late in in vitro development, the time window for genetic testing is relatively small. Fast and accurate genetic testing methods are needed to ensure a successful and safe result from this biopsy. Thus, blastocyst biopsies may gain more popularity in the future whn such methods have been developed or improved<ref name="PMID22723007"/>. <br />
<br />
<br />
==Genetic Techniques==<br />
<br />
===PCR===<br />
====Description====<br />
Polymerase chain reaction (PCR) amplifies DNA specific to genetic sequence of interest . PCR was developed by Kay Mullis in the 1980s, for which he was awarded the Nobel prize for chemistry in 1993. <ref> Pubmed Docs (2015) Polymerase Chain Reaction (PCR) Pubmen. Retrieved from [http://www.ncbi.nlm.nih.gov/probe/docs/techpcr/]</ref> This technique enables clinicians to monitor and diagnose diseases using minute samples such as embryonic cells, blood & tissue. <ref>Roche (2015) PCR: How We Copy DNA. Roche Molecular Systems Inc. retrieved From [http://molecular.roche.com/pcr/Pages/Process.aspx]</ref> PCR has many important applications like DNA fingerprinting, genetic mapping, detection of viruses and bacteria as well as being used to detect genetic disorders, as a part of PGD, in conjunction with IVF. It is used to detect molecular abnormalities such as single gene disorders like Tay Sach, Cycstic fibrosis, Duchenne Muscular Dystrophy, Thalassemia, Huntington disease, Spinal muscular atrophy and many more. Molecular and Genetic analysis require a significant amount of DNA, which we would not have without PCR. It revolutionized the study of DNA, replacing all previous recombinant DNA technology. <ref> Mullins, K., Francois, F.& Gibbs R.A. (1994 ) The Polymerase Chain Reaction. p3. Springer- Science +Business Media. Birkhauser, Boston<br />
Available at [https://books.google.com.au/books?hl=en&lr=&id=gjrTBwAAQBAJ&oi=fnd&pg=PR5&dq=kary+mullis+PCR&ots=mpzAyRh5ZY&sig=PQ4goNoKJ90tb3-MkPk62zrTGbw#v=onepage&q=kary%20mullis%20PCR&f=false] </ref> <br />
<br />
[[File:PCR.jpg|thumb|right|Polymerase chain reaction (PCR) amplifies DNA specific to genetic sequence of interest, enabling the monitoring and diagnose molecular abnormalities such as single gene disorders using minute samples such as embryonic cells, blood & tissue <ref>NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref>]]<br />
<br />
====Procedure====<br />
<br />
Sample are obtained from the the blastocyst, a polar body biopsy or the blastomeres stages of the embryo. <br />
Stage 1 Denaturing: separating the target strands of DNA <br />
The obtained sample is heated to roughly 90 degrees celcius, this heat causes breaks the relatively weak bonds between nucleotides that form DNA. the double stranded DNA to split into 2 single strands of DNA that are used as templates.<br />
Stage 2 Annealing: Binding the Primers to the target DNA sequence <br />
PCR will only copy the target sequence of DNA specified by specific PCR primer. These synthesized primers Oligonucleotides are small artificial pieces of DNA. <br />
TAQ polymerase enzyme synthesize 2 new strands of DNA duplicate to the single sample DNA stand template indicated by these primers. During this stage the reaction is cooled to a temperature between 40-60 degrees Celsius. <br />
Stage 3- Extension- making copies <br />
Each of these 2 copies are then used again as templates generating 2 further replications This cycle can occur as many 30 -40 times within a couple hours leading to billions of extra copies of the original DNA segment. The optimal temperature for the further replication is roughly 72 degrees Celsius. <br />
<br />
This process mediated by a thermocycler machine that is programmed to alter the temperature of the reaction every couple of minutes, perpetuating the cycle of DNA denaturing and synthesis. <br />
This process, generates exponential exact copy of the original template DNA sequence. <br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
!PCR cycles<br />
<br />
|{|<br />
|-<br />
| '''PCR Cycle'''<br />
| '''Target Copies'''<br />
|-<br />
| 1<br />
| 2<br />
|-<br />
| 2<br />
| 4<br />
|-<br />
| 3<br />
| 8<br />
|-<br />
| 4<br />
| 16<br />
|-"<br />
| 5 <br />
| 32<br />
|-<br />
| 6 <br />
| 64<br />
|-<br />
| 7 <br />
| 128<br />
|-<br />
| 8<br />
| 256<br />
|- <br />
| 9<br />
| 512 <br />
|-<br />
| 10<br />
| 1024<br />
|-<br />
| 15<br />
| 32,768<br />
|-<br />
| 20 <br />
| 1,048,578<br />
|-<br />
| 25<br />
| 33,554,432<br />
|-<br />
| 30 <br />
| 1,073,741,842<br />
|-<br />
|}<br />
<br />
<br />
<br />
{| class="wikitable" <br />
|-bgcolor="#9ACD32" <br />
| rowspan="10" |'''Advantages'''<br />
|-bgcolor="#F0FFF0"<br />
| fast and inexpensive way of copying a target sequence of DNA<br />
|-bgcolor="#F0FFF0"<br />
| aids the diagnosis of single cell defects<br />
|-bgcolor="#F0FFF0"<br />
| rapid generation of results within a couple hours<br />
|-bgcolor="#F0FFF0"<br />
| can start from a single molecule of DNA, therefore is more sensitive <br />
|-bgcolor="#F0FFF0"<br />
| has a flexible primer design enabling<br />
|-bgcolor="#F0FFF0"<br />
| overcame previous issues associated with the limited availability of sites of end<br />
|-bgcolor="#F0FFF0"<br />
| generates the DNA copies exponentially<br />
|-bgcolor="#F0FFF0"<br />
| enables DNA amplification required for molecular and genetic analysis<br />
|-bgcolor="#F0FFF0"<br />
|Valid diagnostic method in selecting unaffected embryos for embryo transfer <ref> Dreesen, J., Drusedaul, M., Smeets, H., Die-Smulders, C., Coonen, E., Dumoulin, J., Gielen, M., Evers, J., Herbergers, J. & Geradets, J. (2008) Validation of preimplantation genetic diagnosis by PCR analysis: genotype comparison of the blastomere and corresponding embryo, implications for clinical practice. Mol. Hum. Reprod. 14 (10):573-579.doi: 10.1093/molehr/gan052. Retrieved from [http://molehr.oxfordjournals.org/content/14/10/573.short] </ref> <ref><pubmed>20966460</pubmed></ref><br />
|-bgcolor="#9ACD32"<br />
| rowspan="5"|'''Disadvantages'''<br />
|-bgcolor="#F0FFF0"<br />
| only during this exponential DNA replication phase can we determine the starting quantity sequence contained in the original sample ( template DNA strand)<br />
|-bgcolor="#F0FFF0"<br />
| PCR reaction is limited by the presence of inhibitors present in the sample : reagent inhibitors <br />
|-bgcolor="#F0FFF0"<br />
| self annealing due to the accumulation of the product -stopping exponential amplification for the target sequence and reach a plateau<br />
quantification of the end point of reaction of PCR products unreliable - therefore that is why we require real time quantitative RT-PCR necessary<br />
<ref> NIS (2015) Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref><br />
|}<br />
<br />
<br />
===Fluorescent In Situ Hybridisation (FISH)===<br />
<br />
<br />
====Description====<br />
Fluorescence in situ hybridization (FISH) the one of the most effective and rapid <ref name="PMID26338801"><pubmed>26338801</pubmed></ref> Preimplantation Genetic Diagnosis (PGD). This techniques used to locate a specific DNA sequences within a chromosome. FISH facilitates the clinical diagnosis of chromosomal abnormalities indicated by sequential duplications, deletions and rearrangements of chromosome, that are usually missed with microscopic analysis. This technique is especially relevant for female embryos with X-linked diseases,<ref name="PMID20809319"><pubmed>20809319</pubmed></ref> that have no other mutation specific tests [http://www.ncbi.nlm.nih.gov/pubmed/20809319] As part of PGD, samples are collected from various stages of the embyro,and they are able to conducted tests on the blastocyst, a polar body biopsy and the blastomeres <ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. FISH is 99% effective when used in conjunction with competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities<ref name="PMID26338801"/>.<br />
<br />
====Procedure==== <br />
<br />
Samples are collected from either the blastocyst, a polar body biopsy or the blastomeres stages of the embryo <ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
DNA strands are heated and denatured causing their the individual DNA strands to break apart<br />
Probes are single complimentary stands of DNA a that have been tagged with small chemical agents that glow brightly in the presence of a specific region on a chromosome. These specific probes then hybridize and join to their complementary DNA strand. <br />
The fluorescent tags enable the researchers to correctly identify the presence or lack thereof and location of the specific chromosomes that they are testing for. <ref name="PMID17876073"><pubmed>17876073</pubmed></ref><br />
Researcher analyse the results by identifying the number and the relative location of the fluorescent dots generated by the FISH images.<ref name="PMID17970921"><pubmed>17970921</pubmed></ref><br />
The probe will not fully hybridise if there has been a duplication or a deletion of the DNA - indicating chromosomal and sex chromosomal anomalies like trisomies and aneuploidies. <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref><br />
<br />
<br />
Different probes are used for different purposes: <ref>Unique, Rare Chromosome Disorder Support Group (2013) Fluorescence in situ hybridisation (FISH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/Other/FISH%20FTNW.pdf]</ref><br />
*'''Locus specific tags''' detect very small imbalances, and locate isolated small portions <br />
of genes within a chromosome<br />
*'''Alphoid/Centomeric Repeat probes''' are developed from the repetitive sequence located in the middle region of each chromosome, useful in determining the number of chromosomes , detecting rearrangement and when used in conjunction with locus probes to determine the absence of genetic material on a chromosome. <br />
*'''Paint Probes''' are collections of smaller probes with their own stains that bind to a different section on the chromosome - allowing the full chromosome too be labeled a unique colour, this "full colour map" can be used to know the spectral karyotype- full chromosomal mapping is useful in examining chromosomal abnormalities. <br />
<br />
[[File:Fluorescent In Situ Hybridisation (FISH).jpg|thumb|right|'''FISH''' We are able to tag Specific DNA sequences using Probes which have been tagged with fluorescent Labels.This technique enables the clinical diagnosis of chromosomal abnormalities, indicated by sequential duplication, deletions and rearrangements of chromosome <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref>]]<br />
<br />
{|class="wikitable" align="center"<br />
|-bgcolor="pink" <br />
| rowspan="8" |'''Advantages''' <br />
|-bgcolor="#FDE1F2" <br />
| FISH is 99% effective when used in conjunction with Competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities.<ref><pubmed>26338801</pubmed></ref><br />
|-bgcolor="#FDE1F2" <br />
| Rapid generation of results<br />
|-bgcolor="#FDE1F2" <br />
| Identifies very small translocations and aneuploidies that occur within chromosomes, that would usually be missed under microscopic analysis<br />
|-bgcolor="#FDE1F2" <br />
| Indicates whether the accessed chromosomes are normal <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|-bgcolor="#FDE1F2" <br />
| Tests for the most common chromosomal abnormalities - down syndrome chromosomes 13,16,18,21 and 22 <ref><pubmed>21749752</pubmed></ref><br />
|-bgcolor="#FDE1F2" <br />
| It may be used to compare the chromosomal gene arrangements in related species<br />
|-bgcolor="#FDE1F2" <br />
| can be used to identify and remove inheritable X-linked disease or sex chromasome anomalies such as Duchennes Muscular Dystrophy, hemophilia, ectodermal dysplasia <ref><pubmed>17876073</pubmed></ref><br />
|-bgcolor="#FEB745"<br />
| rowspan="5"|'''Disadvantages'''<br />
|-bgcolor="#FE1C5EA"<br />
| FISH destroys all cells tested <ref> O'Connor, C. (2008) Fluorescence in situ hybridization (FISH). Nature Education 1(1):171. retrieved from [http://www.nature.com/scitable/topicpage/fluorescence-in-situ-hybridization-fish-327] </ref><br />
|-bgcolor="#FE1C5EA"<br />
| It does not fully access all chromosomes (only ~ 12)<br />
|-bgcolor="#FE1C5EA"<br />
| Analysis of results is dependent upon the dot quality impacted by hybridisation efficiency or the camera sensitivity <ref><pubmed>17970921</pubmed></ref><br />
|-bgcolor="#FE1C5EA"<br />
| some studies indicate that using FISH on a day-3 embryo biopsy decreases the rate of live births <ref><pubmed>26168107</pubmed></ref><br />
|}<br />
<br />
===Array Comparative Genomic Hybridisation (aCGH)===<br />
====Description====<br />
<br />
aCGH also known as Microarray analysis efficiently scans the entire genome for chromosomal imbalances. CGH was initially developed to detect the number of changes in a solid tumor mass. It uses 2 genomes comparing the sample to the control, with each labeled in a different fluorescent dye<ref name="PMID1876176"><pubmed>1876176</pubmed></ref>. Earlier CGH techniques were limited by the resolution of the imaging <ref> Lichter, P., et al. Comparative genomic hybridization: Uses and limitations. Seminars in Hematology 37, 348–357 (2000)</ref> , these initial limitations were overcome by using Microarrays in conjunction with CGh to improve the resolution of the imaging, Array Comparative Genomic Hybridisation (aCGH). This method compares sample and control microarrayed slides containing small segments of DNA (probes). <ref> Lucito, R., et al. Representational oligonucleotide microarray analysis: A high-resolution method to detect genome copy number variation. Genome Research 13, 2291–2305 (2003) </ref> the Probes used will vary according from the small (25-85 base pairs) oligonucleotides manufactured to highlight different target sequences, to the very large genomic clones (80,000- 200,00 base pairs), and as these are significantly smaller than the traditional metaphase chromosomes used for CGH, generating a higher resolution of image. <ref name="PMID22467166"><pubmed>22467166</pubmed></ref>.aCGH is used as a diagnostic tool for prenatal detection f chromosomal abnormalities <ref name="PMID19012303"><pubmed>19012303</pubmed></ref>.<br />
<br />
<br />
====Procedure====<br />
<ref> Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432] </ref><br />
The sample is obtained (skin, blood or fetal cells) and DNA is obtained. <br />
As a part of PGD fetal cell samples are collected from; the fertilized egg polar bodies, the blastomere (day 3 embryo) or the blastocyst/tropoectoderm stage (day 5 embryo).<br />
Sample DNA is labeled with one fluorescent dye, and the control DNA is labeled with a different colored fluorescent dye. the control DNA is used as the base point of reference. <br />
heated and denatured single DNA strands then hybridize to their complementary single strand probes, which are then combined and applied to a microarray and the results are run through a computer program and a digital imaging system is used to quantify the results( fluorescent intensities of the labeled probes). <br />
<br />
[[File:aCGH.jpg|thumb|right|'''aCGH''' checks the entire genome for chromosomal imbalances, by comparing control and a sample slides contatining small segements of DNA sample microarrayed slides small segments of DNA. Illustrated by student z5020317 and adapted from <ref> NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation. retrieved from [http://www.phgfoundation.org/file/5237/]</ref> <ref>Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432]</ref>]]<br />
<br />
<br />
<br />
The fluorescent ratio and the hybridization signal at different locations on the genome of the control DNA are used to identify any variances present in the sample DNA. aCGH facilitates the clinical diagnosis of submicroscopic chromosomal duplication, deletion and rearrangements indicative of chromosomal disorders such as trisomies 1-22and specific sex linked disorders. <br />
Duplications in the DNA are displayed by the computer program as spikes/ peaks over an established threshold and deletions in DNA are displayed by the computer program as spikes/ toughs beneath this threshold <br />
<br />
<br />
<br />
<br />
{|class="wikitable" align="center"<br />
|-bgcolor="DDCEF2"<br />
| rowspan="11" |'''Advantages''' <br />
|-bgcolor="FFFAFA"<br />
| Multiple applications: prenatal genetic diagnosis, cancer diagnosis, <ref name="PMID20193845"><pubmed>20193845</pubmed></ref> genetic screening for developmental delay (learning disabilities) <ref name="PMID17309648"><pubmed>17309648</pubmed></ref>. or congenital anomalies that are suspected to be genetic in origin <ref>NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation . retrieved from [http://www.phgfoundation.org/file/5237/]</ref><br />
|-bgcolor="FFFAFA"<br />
| trace represents all chromosomes present in the human genome chromosomes 1-22 and the X & Y chromosomes, and therefore is the most accurate method for testing whole embryo aneuploidy<br />
|-bgcolor="FFFAFA"<br />
| aCGH has been extensively tested, and Validated, and is now used world wide.<br />
|-bgcolor="FFFAFA"<br />
| Detects submicroscopic alterations<br />
|-bgcolor="FFFAFA"<br />
| Detects deletions and additions and rearrangements as well as amplification, of the WHOLE genome, simultaneously.<br />
|-bgcolor="FFFAFA"<br />
| Used as a diagnostic tool for prenatal detection of chromosomal abnormalities <ref name="PMID22034057"><pubmed>22034057</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Provides high resolution genomewide screening of segmental genomic copy number variations<br />
|-bgcolor="FFFAFA"<br />
| Very accurate when used in conjunction with FISH<br />
|-bgcolor="FFFAFA"<br />
| Alone is more reliable and in detecting chromosomal abnormalities, with a higher implantation success rate, than FISH <ref name="PMID20494259"><pubmed>20494259</pubmed></ref><br />
|-bgcolor="FFFAFA"<br />
| Allows an in depth research focus upon specific types of rearrangements within selected chromosomal regions, a recent particular area of interest is subtelomeric and pericentromeric rearrangements<br />
|-bgcolor="FFFAFA"<br />
| Reduces the risk of failed implantation and miscarriage, improving the chance of a healthy baby <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|-bgcolor="DDCEF2"<br />
| rowspan="9" |'''Disadvantages'''<br />
|-bgcolor="FFFAFA"<br />
| Translocations and inversions of DNA are not detected<br />
|-bgcolor="FFFAFA"<br />
| Limited ability diagnosing specific polyploidies such as triploidy <ref> Unique, Rare Chromosome Disorder Support Group (2013) Microarray-based Comparative Genomic Hybridiation (array CGH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/other/array%20cgh%20ftnw.pdf] </ref><br />
|-bgcolor="FFFAFA"<br />
| Will not detect mosaicism detection <20% (cultures where >1 of 5 cells are trisomy 12)<br />
|-bgcolor="FFFAFA"<br />
| Will not detect balanced chromosomal rearrangement<br />
|-bgcolor="FFFAFA"<br />
| Will not detect duplications or deletions <80kb<br />
|-bgcolor="pink"|-bgcolor="FFFAFA"<br />
| Will not detect point mutations within genes <ref>Washington department of education (CGH- FAQ for physicians. Signature Genomic LAboratories, LLC. Retrieved from [https://depts.washington.edu/dbpeds/Lab%20Tests/SignatureCGH-physician_FAQ.pdf]</ref><br />
|-bgcolor="FFFAFA"<br />
| will not detect chromosomal position of genomic gains<br />
|-bgcolor="pink"<br />
| Will not detect loos of heterozygosity (LOH) or Absence of heterozygosity (AOH) <ref>WiCell Research Institute Inc. (2012) Comparative Genomic Hybridization Microarray. <br />
retrieved from [http://www.wicell.org/home/cytogenetic-services/cgh-microarray/array-comparative-genomic-hybridization-acgh.cmsx]</ref><br />
|}<br />
<br />
<br />
<br />
===Next Generation Sequencing===<br />
====Description====<br />
The development and advances within ART in the past 20 years, as well as the increasing popularity of IV, has lead to an influx of new technologies developed to screen embryos for chromosomal anomalies, which are covered by the umbrella term of Next generation Sequencing (NGS). NGS is a general term used to describe all of the new and emerging screening techniques currently being introduced and used as part of PGD for IVF . NGS screens for single gene disorders as well as conducting extensive and very comprehensive chromosome diagnosis by sequencing, counting, and accurately assembling millions of DNA reads, simultaneously. <ref name="PMID23499002"><pubmed>23499002</pubmed></ref> There is a movement for NGS to replace the other limited testing techniques and be used as the standard. <br />
====Procedure====<br />
Samples are collected from either blastomere or the blastocyst/tropoectoderm and processed for analysis by a computer system. <br />
The methodology of each process is unique to the technique being used. <br />
<br />
<br />
<br />
{|border="1" align="center"<br />
|-bgcolor="pink" <br />
| '''Advantages'''<br />
| '''Disadvantages'''<br />
|bgcolor="FFFAFA"<br />
| cheaper<br />
| there are limited information available to clinical applications of NGS <ref><pubmed>26100406</pubmed></ref><br />
|bgcolor="FFFAFA"<br />
| opens new diagnostic possibilities<br />
|<br />
|bgcolor="FFFAFA"<br />
| accurately tests all 24 chromosomes<br />
| <br />
|-bgcolor="FFFAFA"<br />
| tests for the presence of monogenic diseases of known genetic background<br />
| <br />
|-bgcolor="FFFAFA"<br />
| reduces the number of biopsies required for diagnosis<br />
| <br />
|-bgcolor="FFFAFA"<br />
| higher detection rate of small translocations<br />
| <br />
|-bgcolor="FFFAFA"<br />
| highly accurate is testing for compound point mutations, chromosomal duplication, deletions and insertions <ref name="23312231"><pubmed>23312231</pubmed></ref><br />
| <br />
|-bgcolor="pink"<br />
| it accurately detects chromosomal aneuploidy and unbalanced rearrangement <ref name="PMID25685330"><pubmed>25685330</pubmed></ref><br />
| <br />
|-bgcolor="white"<br />
| NGS single gene disorder screenings can conducted in conjunction with PCR comprehensive chromosomal screening<br />
|<br />
|-bgcolor="pink"<br />
| Reduces human error <br />
|<br />
|-bgcolor="white"<br />
| better detects the presence of mosaicism<br />
|<br />
|-bgcolor="pink"<br />
| work well in conjunction with CGH and aCGH as part of PGD, improving the chances of IVF. <ref> Morris, R. S. (2015 ) Next generation sequencing for PCG|PGS|CCS. IVF1 retrieved from [http://www.ivf1.com/next-generation-sequencing for-pgd] </ref><br />
|<br />
|}<br />
<br />
<br />
<br />
<br />
<br />
<br />
==Diagnosis==<br />
There are a large amount of diseases that PGD can apply to, below are descriptions of the diseases that PGD are more commonly used for. Utilization of Diseased Cell Lines<br />
===Cystic Fibrosis===<br />
Cystic fibrosis is a single gene disorder. It is autosomal recessive and involves mutations in the cystic fibrosis transmembrane conductance regulator (CTFR) gene. The CTFR gene is normally responsible for the decrease in chloride and the transport of bicarbonate in epithelial cells thus playing a major physiological role. In PGD procedures, identification of the gene is assisted by microsatellite markers that have similar composition to the CTFR gene itself. Biopsy of two cells at the blastocyst stage is recommended if markers are not available. There are many variations of cystic fibrosis the most common being P.Phe508del <ref name="PMID26014425"><pubmed>26014425</pubmed></ref>.<br />
===Duchenne Muscular Dystrophy ===<br />
Duchenne Muscular Dystrophy is an X-linked recessive disease. It involves the Xp21 gene where majority of the mutations are chromosomal deletions with a smaller percentage resulting from duplications <ref name="PMID18359022"><pubmed>18359022</pubmed></ref>.<br />
<br />
===Autosomal Recessive MEckel-Gruber Syndrome===<br />
Autosomal recessive genetic defect caused by the TMEM67 gene. It results in cystic dysplasia of the kidneys with fibrotic change in the liber and occipital encephalocele. Other malformations could also be present in the central nervous system. In PGD whole genome amplification of single blastomeres are taken to identify the gene, this is also coupled with PCR techniques. Maternal plasma can also be extracted for PGS. <ref><pubmed>24039893</pubmed></ref> <br />
===β – Thalassemia=== <br />
β – Thalassemia is known as the most common type of autosomal recessive inherited disorder among haemoglobinopathies. It involves the adult β-globin gene and is associated with the absent or decreased expression of the gene. This is commonly caused by a single nucleotide change in the gene. PGD has been used successfully worldwide to identify the β-globin gene where its application is usually performed on a single blastomere or polar body <ref name="PMID19064120">19064120</pubmed></ref>.<br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
! Applicable diseases for PGD <ref>Genoma Group (2014). Retrieved September 18th, 2015, from http://www.preimplantationgeneticdiagnosis.it/genetic-diseases-diagnosed-by-pgd.htm </ref>, <ref>Genesis Genetics (2015). Retrieved September 18th, 2015, from http://genesisgenetics.org/pgd/what-we-test-for/</ref>, <ref>Human Fertilisation & Embryology Authority (2015). Retrieved Septembr 18th, 2015, from http://guide.hfea.gov.uk/pgd/</ref><br />
|-<br />
| '''Disease'''<br />
| '''Involved Genes'''<br />
|-<br />
| 5 Alpha Reductase Deficiency (5ARD)<br />
| SRD5A2 <br />
|-<br />
| Achondroplasia<br />
|FGFR3 <br />
|-<br />
| Acute Intermittent Porphyria <br />
| ALAD, ALAS2, CPOX, FECH, HMBS, PPOX, UROD, or UROS<br />
|-<br />
| Adrenoleukodystrophy (Adrenomyeloneuropathy)<br />
| ABCD1 <br />
|-<br />
| Agammaglobulinaemia (x-linked) <br />
|BTK <br />
|-<br />
| Agammaglobulinemia Bruton Tyrosine Kinase (BTK) <br />
|BTK <br />
|-<br />
| Aicardi Goutieres Syndrome 1 (AGS1) <br />
|TREX1, RNASEH2A, RNASEH2B, RNASEH2C, SAMHD1<br />
|-<br />
| Alagille Syndrome<br />
|JAG1 or NOTCH2<br />
|- <br />
| Alpers-Huttenlocher Syndrome <br />
|POLG <br />
|-<br />
| Alpha-1-antitrypsin deficiency <br />
|SERPINA1 <br />
|-<br />
| Alpha-Mannosidosis<br />
| MAN2B1 <br />
|-<br />
| Alpha Thalassemia <br />
|HBA1 or HBA2 <br />
|-<br />
| Alports Syndrome<br />
|COL4A3, COL4A4, COL4A5<br />
|-<br />
| Alzheimer's Disease - early onset (Type 3 and 4) <br />
|APP, PSEN1, or PSEN2<br />
|-<br />
| Amyotrophic Lateral Sclerosis 1 (ALS1) <br />
|C9orf72, SOD1, TARDBP, FUS, ANG, ALS2, SETX, VAPB <br />
|-<br />
| Argininosuccinic Aciduria <br />
| ASL<br />
|-<br />
| Arrhythmogenic Right Ventricular Cardiomyopathy/ Dysplasia (ARVC/D)<br />
| DSG2; DSP; PKP2<br />
|-<br />
| Ataxia Telangiectasia<br />
| ATM<br />
|-<br />
| Autosomal Recessive Meckel-Gruber Syndrome<br />
| TMEM67<br />
|-<br />
| Bardet-Biedl Syndrome (BBS)<br />
| BBS1; BBS10<br />
|-<br />
| Barth Syndrome<br />
| TAZ<br />
|-<br />
| Beta Thalassaemia<br />
| HBB<br />
|-<br />
| Birt-Hogg-Dubé Syndrome<br />
| FLCN<br />
|-<br />
| Breast Ovarian Cancer Familial Susceptibility (BRCA2)<br />
| BRCA1; BRCA2<br />
|-<br />
| Canavan Disease <br />
| ASPA<br />
|-<br />
| Carnitine-Acylcarnitine Translocase Deficiency <br />
| SLC25A20<br />
|-<br />
| Cerebral Arteriopathy with Subcortical Infarcts & Leukoencephalopathy (CADASIL)<br />
| NOTCH3<br />
|-<br />
| Cerebral Cavernous Malformation<br />
| CCM1<br />
|-<br />
| Charcot-Marie-Tooth Disease<br />
| GJB1; MPZ; NEFL; PMP22<br />
|-<br />
| CHARGE Syndrome<br />
| CHD7<br />
|-<br />
| Cherubism<br />
| SH3BP2<br />
|-<br />
| Choroideremia<br />
| CHM<br />
|-<br />
| Chronic Granulomatous Disease<br />
| CYBB; NCF1<br />
|-<br />
| Ciliary Dyskinesia<br />
| DNAH5<br />
|-<br />
| Citrullinemia<br />
| ASS1<br />
|-<br />
| Cleidocranial Dysplasia<br />
| RUNX2<br />
|-<br />
| Cockayne Syndrome<br />
| ERCC6<br />
|-<br />
| Congenital Adrenal Hyperplasia<br />
| CYP21A2<br />
|-<br />
| Congenital Cataracts<br />
| GJA8; VSX2<br />
|-<br />
| Congenital Diarrhea, Syndromic<br />
| SPINT2<br />
|-<br />
| Congenital Disorders of Glycosylation (CDG)<br />
| ALG1; ALG6; CDG1C; DOLK; PMM2<br />
|-<br />
| Cornelia de Lange Syndrome <br />
| NIPBL<br />
|-<br />
| Craniosynostosis<br />
| TWIST1<br />
|-<br />
| Crouzon Syndrome<br />
| FGFR2<br />
|-<br />
| Cysteinyl Leukotriene Receptor 1 Deficiency <br />
| CYSLTR1<br />
|-<br />
| Cystic Fibrosis<br />
| CFTR<br />
|-<br />
| Diamond –Blackfan Anemia <br />
| RPS19<br />
|-<br />
| Duchenne Muscular Dystrophy <br />
| DMD<br />
|-<br />
| Dyskeratosis congenita (Male embryos only)<br />
| DKC1<br />
|-<br />
| Ectodermal dysplasia (Hypohidrotic)<br />
| EDA; EDA1; GJB6; IKBKG<br />
|-<br />
| Familial Adenomatous polyposis coli (FAP)<br />
| APC<br />
|-<br />
| Familial Dysautonomia<br />
| IKBKAP<br />
|-<br />
| Fanconi Anemia <br />
| FANCA; FANCC; FANCD2; FANCF; FANCG; FANCJ<br />
|-<br />
| Fragile X Syndrome (FRAX)<br />
| FMR1<br />
|-<br />
| Galactosemia <br />
| GALT<br />
|-<br />
| Gangliosidosis<br />
| GLB1<br />
|-<br />
| Glanzmann Thrombasthenia <br />
| ITGA2B<br />
|-<br />
| Glutaric Acidemia (aciduria)<br />
| GCDH <br />
|-<br />
| Glycogen Storage Disease <br />
| G6PC; GAA; SLC37A4<br />
|-<br />
| Haemophilia A<br />
| F8<br />
|-<br />
| Haemophilia B<br />
| F9<br />
|-<br />
| Hereditary Nonpolyposis Colorectal Cancer: Lynch Syndrome<br />
| MLH1; MSH2; MSH6<br />
|-<br />
| Holt Oram Syndrome<br />
| TBX5<br />
|-<br />
| Huntington Disease<br />
| HD<br />
|-<br />
| Hydrocephalus<br />
| L1CAM<br />
|-<br />
| Ichthyosis <br />
| ABCA12; STS<br />
|-<br />
| Incontinentia Pigmenti (IP)<br />
| NEMO<br />
|-<br />
| Joubert Syndrome 5<br />
| INPP5E<br />
|-<br />
| Krabbe Disease<br />
| GALC<br />
|-<br />
| Leber Congenital Amaurosis (LCA)<br />
| CEP290; GUCY2D<br />
|-<br />
| Leigh Syndrome (Infantile Subacute Necrotising Encephalopathy)<br />
| LRPPRC<br />
|-<br />
| Lesch Nyan Syndrome<br />
| HPRT1<br />
|-<br />
| Leukocyte Adhesion Deficiency (Type I)<br />
| ITGB2<br />
|-<br />
| Li-Fraumeni Syndrome<br />
| TP53<br />
|-<br />
| Macular Dystrophy Retinal <br />
| VMD2<br />
|-<br />
| Maple Syrup Urine Disorder (MSUD)<br />
| BCKDHB<br />
|-<br />
| Marfan Syndrome <br />
| FBN1<br />
|-<br />
| Menkes Syndrome<br />
| ATP7A<br />
|-<br />
| Mitochondrial DNA Depletion Syndrom <br />
| POLG; RRM2B; SUCLA2; TK2<br />
|-<br />
| Mucolipidosis type II<br />
| GNPTAB<br />
|-<br />
| Multiple Endocrine Neoplasia<br />
| MEN1; MEN2A; MEN2B<br />
|-<br />
| Multiple Exostoses<br />
| EXT1; EXT2 <br />
|-<br />
| Myotubular myopathy<br />
| MTM1 <br />
|-<br />
| Nail-Patella Syndrome<br />
| LMX1B<br />
|-<br />
| Neurofibromatosis Type 1<br />
| NF1<br />
|-<br />
| Neurofibromatosis Type 2 <br />
| NF2<br />
|-<br />
| Noonan Syndrome<br />
| KRAS, PTPN11; SOS1<br />
|-<br />
| Norrie Disease<br />
| NDP<br />
|-<br />
| Ocular Albinism <br />
| GPR143<br />
|-<br />
| Oculocutaneous Albinism <br />
| OCA2; TYR <br />
|-<br />
| Oculodentaldigital Dysplasia<br />
| GJA1<br />
|-<br />
| Optic Atrophy<br />
| OPA1<br />
|-<br />
| Ornithine Transcarbamylase Deficiency <br />
| OTC<br />
|-<br />
| Osteogenesis imperfeca <br />
| COL1A1; COL1A2<br />
|-<br />
| Osteopetrosis <br />
| CLCN7; OSTM1; TCIRG1<br />
|-<br />
| Pachyonychia Congenita <br />
| KRT16; KRT6A<br />
|-<br />
| Pancreatitis, Hereditary<br />
| PRSS1 <br />
|-<br />
| Papillorenal syndrome <br />
| PAX2<br />
|-<br />
| Phenylketonuria <br />
| PAH <br />
|-<br />
| This table does not cover the complete list of diseases that PGD can be applied to.<br />
|}<br />
<br />
==Laws & Legal status==<br />
<br />
{| class="wikitable" <br />
|-bgcolor="DDCEF2"<br />
|'''Country'''<br />
|'''Legislation'''<br />
|-<br />
| Australia<br />
| PGD is currently used to detect serious genetic conditions to improve the outcome of Assisted Reproductive Technologies (ART). In very rare cases it may be used to select an embryo with compatible tissue for a sibling who has a life-threatening disease where other means of treatment is unavailable. This is with the conditions that the use of PGD will not affect the welfare and interests of the child to be born. The parents must also receive adequate counselling and have full understanding of the procedures of PGD. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"> National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art</ref><br />
The use of PGD for sex-selection is prohibited with the exception of reducing the risk of the transmission of serious sex-linked genetic conditions. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"/><br />
|-bgcolor="FFFAFA"<br />
| Brazil<br />
| The laws regarding PGD in Brazil are not strictly regulated. They are vague and there is limited information surround the activities of assisted reproduction in general in the country <ref name="PMID25493379"><pubmed>25493379</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| Czech Republic<br />
| The laws in the Czech Republic allow those with a “defined indication in order to exclude risk of serous genetically conditioned disease and defects with embryos before they are implanted into the cavity of the uterus”. Couples that undergo any assisted reproductive treatment including PGD have to be married. Sex-selection is illegal except in regards to serious sex-linked genetic diseases <ref name="PMID24777348"><pubmed>24777348</pubmed></ref>.<br />
|-bgcolor="FFFAFA"<br />
| Greece<br />
| In Greece, ART is open to those up to the age of 50 with written consent. It can only be used if a medical necessity is present such as the susceptibility of serious hereditary diseases. Sex selection is banned apart from cases of sex-linked diseases and sexually transmitted diseases <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| India<br />
| In India there is a cultural preference for boys thus the Prenatal Diagnostic Techniques (Regulation and Prevention of Misuse) Act was introduced in 1994. This law limits the use of PGD for sex determination except in cases of specific congenital diseases. These laws however are not strictly enforced. <ref>World Health Organisation (2015) Gender and Genetics Retrieved on October 21st 2015 from:http://www.who.int/genomics/gender/en/index4.html</ref><br />
|-bgcolor="FFFAFA"<br />
| Portugal <br />
| ART is only available to those who are married or have a similar type of relationship for at least two years. The couples cannot be of the same sex and must be at least 18 years of age. Sex selection is illegal except in cases of sex-linked diseases. The use of PGD is illegal if the predictive value of genetic tests are very low <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| Spain<br />
| PGD can be applied to “serious hereditary diseases not amenable to postnatal curative treatment” and “detection of other abnormalities which may compromise the viability of the pre-embryo”. If PGD is to be used for any other purpose authorisation must be acquired <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| Sweden <br />
| The use of PGD is strictly regulated and couples must achieve authorisation of the National Board of Health and Welfare. It can only be used it can only be used if the child is at risk to inheriting a serious chromosomal or monogenetic disease. It cannot be used for selection of specific characteristics <ref name="PMID24777348"/>.<br />
|-bgcolor="FFFAFA"<br />
| United Kingdom<br />
| Those involved with carrying out the IVF treatment must have a license from the Human Fertilisation and Embryology Authority (HFEA). Only embryos that are approved by the HFEA can be implanted where the embryonic nuclear or mitochondrial DNA cannot be altered with the exception of preventing mitochondrial diseases <ref name="PMID24777348"/>. <br />
|}<br />
<br />
==Future/Current Research==<br />
===Noninvasive Preimplantation Genetic Testing without Embryo Biopsy===<br />
Different parameters of gametes, zygotes, embryos (“vacuoles in sperm heads, spindle position in mature oocytes, cleavage intervals of zygote, and embryo developmental dynamics”) may correlate with aneuploidy rates. This knowledge may be applied in potential noninvasive preimplantation diagnostic methods. Several methods have been proposed and are currently further researched<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Sperm Selection====<br />
Intracytoplasmic morphologically selected sperm injection (IMSI) is common procedure in IVF treatment to improve fertilization rates in patients with poor semen quality. In addition, studies have found that IMSI improves embryo development and that spermatozoa with large vacuoles in their heads correlate with increased aneuploidy rates and disturbed chromosomal structures. Thus, selecting spermatozoa based on morphological hallmarks may decrease aneuploidy rates in the fertilized embryos. As with polar body biopsies, however, this approach will solely be applicable if evidence for severe male detrimental contribution is given<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Blastocoel Fluid Extraction====<br />
In addition, a less invasive retrieval of material for diagnosis could include the extraction of the blastocoel fluid. The cavity of the blastocyst, lined by the trophectoderm, is filled with this blastocoel fluid, which contains metabolites of both trophectoderm and inner cell mass origin. The retrieval does not require a biopsy but merely a small opening to extract the fluid and, thus, causes less harm to the embryo. Multiple studies have applied this method<ref name="PMID22020776"><pubmed>22020776</pubmed></ref> <ref name="PMID23148560"><pubmed>23148560</pubmed></ref> and it may in the future become of clinical relevance.<br />
<br />
<br />
[[File:Aspiration_of_the_Blastocoel_Fluid.jpeg|thumb|Aspiration of the Blastocoel Fluid using a ICSI pipette<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.]]<br />
<br />
<br />
Next to metabolites, the blastocoel fluid can contain DNA. Studies have shown that genomic DNA is present in about 90% of the blastocoel fluid samples tested. Typically the fluid is removed with an ICSI pipette from a day five blastocyst through its mural trophectoderm until the blastocyst fully collapses around the embryo. Several concerns regarding this method in a clinical setting have been raised. The collected DNA may be contaminated by the culture media that contains DNA fractions. The DNA may also be least representative of the actual embryos genome as the DNA may originate from abnormal or degenerated cells. Even though labelled noninvasive, the blastocyst still undergoes manipulation to some degree which may affect its viability. Thus, more research is required until this method can evolve from research to clinical use<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
====Proteomics====<br />
The protein secretome of blastocysts may be representative of its chromosome constitution Recent studies have found biomarkers such as lipocalin-1, interleukin-10, tumor necrosis factor, stem cell factor, and chemokine ligand 13 to be differently secreted by aneuploid blastocyst than by euploid ones. The most significant biomarker appears to be interleukin-10. Paired with novel proteomic technologies and mass spectrometry this knowledge when extended may contribute to a new invasive preimplantation genetic diagnosis method<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Embryo Morphology====<br />
Using time lapse imaging the embryo’s morphology can be closely observed and potential aneuploidy characteristics detected. Such characteristics may include the time of division to five cells, the time between the division from three to four cells, and the duration of the division from one to two and subsequently to three. In addition, the morphological quality of ICM an TE has been positively associated with aneuploidy or euploidy prognosis<ref name="PMID26246880"><pubmed>26246880</pubmed></ref>. These may give rise to an embryo quality screening prior to implantation<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
==References==<br />
<br />
<references/><br />
<br />
<br />
{{StudentPage2015}}</div>Z5017878https://embryology.med.unsw.edu.au/embryology/index.php?title=2015_Group_Project_6&diff=2070132015 Group Project 62015-10-21T07:03:04Z<p>Z5017878: </p>
<hr />
<div>{{ANAT2341Project2015header}}<br />
<br />
<br />
=Preimplantation Genetic Diagnosis and Screening=<br />
==Introduction==<br />
Preimplantation genetic diagnosis (PGD) and screening (PGS) are reproductive options for couples with known family histories of genetic disease or couples undergoing IVF procedures due to infertility issues. PGD can diagnose many genetic disorders caused by known chromosomal abnormalities (number and/or structure) or single gene mutations, and, thus decrease the risk of termination of pregnancy or miscarriages and enable such couples to have an unaffected child<ref name="PMID24907939"><pubmed>24907939</pubmed></ref>. Through major improvements in PGD/S and general laboratory technology, the testing for abnormalities in fetuses has shifted from prenatal diagnosis during the first 2 trimesters <ref> Blackburn, S.L. (2003) '''Maternal, Fetal & Neonatal physiology: a Clinical perspective''' (2nd ed.). Seattle: Saudners </ref>, testing for overall fetal growth, complications of pregnancy, and birth defects<ref> Sadler T.W.(2012) '''Langman's Medical Embryology''' (12th ed.) Philadelphia: Lipincott, Wiliams & Wilkins, a Wolters Kluwer Business </ref>, to an embryonic focus especially in advancements in Artificial Reproductive Technologies (ART)<ref><pubmed>20638568</pubmed></ref>. In 1990 PGD for a recessive X-linked disease resulted in the first live birth<ref><pubmed>2330030</pubmed></ref> and has since been incorporated in clinical routine and applied for a variety of genetic diseases, such as sickle cell anemia, thalassemia, or cystic fibrosis<ref name="PMID24907939"/>.<br />
[[File:Preimplantation Genetic Diagnosis Procedure.jpeg|700px|thumb| Simplified steps for PGD<ref name="PMID24907939"/>]]<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=0e-79qKllqk</html5media><br />
|-<br />
| Preimplantation Genetic Diagnosis<ref>IVF Florida (2011, December 11) IVF Florida - South Florida Fertility Specialists - Pre-Implantation Genetic Diagnosis [Video file]. Retrieved from https://www.youtube.com/watch?v=0e-79qKllqk</ref><br />
|}<br />
<br />
==History==<br />
The advances in reproductive technology during the second half of the 20th century, led to PGD's first clinical application in 1990 <ref>Harper, J. (n.d.). The history of PGD. Lecture. UCL Centre for PG&D and CRGH.University College London</ref>.<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
|Year<br />
|<br />
|- bgcolor="FFFAFA"<br />
| '''1967''' <br />
|First PGD on rabbit blastocysts (Gardner& Edwards) <ref name="PMID6036172"><pubmed>6036172</pubmed></ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1986''' <br />
|First Cleavage Biopsy (Wilton & Trounson)<ref>Wilton, L. J., & Trounson, A. O. (1986). Viability of mouse embryos and blastomeres following biopsy of a single cell. In Proceedings of the 18th Annual Conference of the Australian Society for Reproductive Biology, Brisbane, Australia.</ref><br />
|- bgcolor="FFFAFA"<br />
|'''1987''' <br />
|First Blastocyst Biopsy (Muggleton-Harris, Monk, Rawlings, & Whittingham)<ref name="PMID3372699"><pubmed>3372699</pubmed></ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1988''' <br />
|First Polar Body Biopsy (Yury Verlinksy)<ref> Verlinsky, Y., Pergament, E., Andresen, P., Enriquez, G., & Strom, C. (1989). Genetic analysis of polar body DNA: A new approach to preimplantation genetic diagnosis. Am J Hum Genet, 45(4), A272.</ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1990''' <br />
|First Clinical PGD using PCR testing for X-linked (Handyside, Kontogianni, Hardy, & Winston)<ref name="PMID2330030"><pubmed>2330030</pubmed></ref> <br />
|} <br />
==Preimplantation Genetic Diagnosis==<br />
Preimplantation genetic diagnosis (PGD) is used to test the genetic makeup of embryos to detect single gene disorders, chromosomal abnormalities and mitochondrial disorders. It also has applications in gender selection for diseases with unequal gender distributions <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Some diseases commonly involved with PGD include cystic fibrosis, spinal muscular atrophy and beta – thalassaemia <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press.">Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press</ref> <ref name="PMID17823145"><pubmed>17823145</pubmed></ref>. It was first used in the United Kingdom in the 1980s of arenoleucodystrophy and primarily focusing on sex- linked disorders <ref name="PMID17823145"/><ref name="PMID23150080"><pubmed>23150080</pubmed></ref>. PGD is now capable of detecting single cell defects (molecular) and chromosomal disorders resulting from the inversion, translocation or deletion of chromosomes (cytogenic) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>,<ref name="PMID11325751"><pubmed>11325751</pubmed></ref>. PGD can be applied to the embryo at different stages. That is on polar bodies, blastomeres or blastocyst <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>.<br />
Depending on the type of genetic disorder, PGD utilises different methods of genetic testing. These include Fluorescence in situ hybridisation (FISH) which is used for sex – linked disorders and detects chromosomal rearrangements <ref name="PMID11325751"/><ref name="PMID17876073"><pubmed>17876073</pubmed></ref> and Embryo halotyping which allows the identification of chromosomes causing the inherited disorder through knowledge of the pattern of closely linked markers <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. Polymerase chain reaction (PCR) is also widely used to detect molecular abnormalities <ref name="PMID11325751"/>.<br />
PGD is tightly regulated and supported by large organisations namely The American Society for Reproductive Medicine, The European Society for Human Reproduction and Embryology (ESHRE), The European Society of Human Genetics and the Preimplantation Genetic Diagnosis International Society <ref name="PMID25500181><pubmed>25500181</pubmed></ref>.<br />
===Sex-linked disorders===<br />
The determination of a disease as gender specific usually correlates with the presence or absence of specific genes such as SRY on the Y chromosome. It is known that females have two X chromosomes and males have an X and a Y chromosome where abnormalities are more prevalent on the X chromosome. PGD can be used for sex selection where only male embryos are transferred to reduce the chance of inheriting X-linked disorders. However, this does not completely eradicate the problem as male embryos remain susceptible to inheriting an affected X chromosome. Sex determination is only used when the specific mutation is unknown and has yet to be discovered <ref name="PMID24866878"><pubmed>24866878</pubmed></ref>.<br />
===Single gene defects===<br />
Single gene defects can be dominant, recessive, autosomal or X-linked. They are commonly diagnosed using PCR and although the PCR available today is complex and capable of combatting a large range of disease the development of new protocols has been proven to be difficult due to the small DNA sample available <ref name="PMID26168107"><pubmed>26168107</pubmed></ref><br />
===Mitochondrial disorders===<br />
Mitochondrial disorders also known as oxidative phosphorylation disorders arise from mutations in the nuclear DNA or mitochondrial DNA <ref name="PMID26312584"><pubmed>26312584</pubmed></ref>. They pose as a problem because they are unrecognisable until the mutations in the cell reach a detrimental level <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Mitochondrial disorders cause miscarriages and stillbirths as well as death in children and young adults. The effects can either be contained in a single organ or more commonly involve multiple organ failure where organs with high energy demands such as the brain, liver muscle and heart and heavily influenced. They are usually occur spontaneously or result from inheritance from the mother. Since mitochondria are solely inherited from the mother oocyte donations have been used as a solution to combat mitochondrial disorders. Additionally, there has been an increasing use in PGD where embryos that stay under the given threshold of 18% gene-mutations are allowed to be transferred and result in normal development. New technology in the areas of nuclear gene transfer and genome editing are also being experimented with <ref name="PMID26312584"/>. <br />
===Chromosomal disorders===<br />
Chromosomal disorders can be reciprocal, Robertsonian translocations, inversions, deletions and insertions <ref name="PMID26168107"/>. . Data from ESHRE collected between 2010 and 2011 has shown that the most common chromosomal abnormality confronted in PGD are reciprocal chromosomal abnormalities <ref name"PMID26071418"><pubmed>26071418</pubmed></ref>. PGD has also been used successfully for Robertsonian translocations (RT), a type of structural translocation. Children who carry RT are phenotypically normal, however in their later years it is found that they will suffer from infertility and repeated miscarriages due to the high frequency of abnormal embryos <ref name="PMID22081077"><pubmed>22081077</pubmed></ref>. PCR and FISH are the two main techniques used for chromosomal disorders. To be able to conduct the examinations the cells are required to be at the metaphase stage <ref name="PMID26168107"/>. <br />
==Preimplantation Genetic Screening==<br />
Prenatal Genetic Screening (PGS) involves an array of methods or ideas that aim to segregate embryos that have genetic flaws and those that are healthy <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. The occurrence of aneuploidy is high around the stages of early embryonic development and they are the most common cause if miscarriages and congenital birth defects <ref name= "PMID26085841"><pubmed>26085841</pubmed></ref>. They have little effect on the morphology of the embryo making them difficult to identify thus identification heavily relies on genetic testing <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. <br />
Genetic sampling is most commonly conducted using Microarray Comparative Genomic Hybridisation (aCGH) as well as FISH, Quantitative PCR and Single Nucleotide Polymorphism (SNP) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. These methods collectively aim to assess numeral and structural chromosomal errors <ref name= "PMID26085841"/>. Studies have also introduced Next- Generation Sequencing (NGS) <ref name= "PMID26085841"/> and Whole Genome Amplification used to screen imbalances in the complete 24-chromosomes <ref name="PMID25953353"><pubmed>25953353</pubmed></ref><br />
Statistics from ESHRE have shown that the most common indications for PGS is advanced age, followed by repeated implantation failure or recurrent miscarriage and male infertility <ref name="PMID26071418"><pubmed>26071418</pubmed></ref>.<br />
====Indications====<br />
A low percentage of structural abnormalities in chromosomes are responsible for the cause of miscarriages. Despite this, they are the most prevalent type of chromosomal abnormality accounted for in PGD <ref name="PMID20638568"/>. The presence of specific gene cycles, initiation of embryonic protein synthesis and evident physiological development are all indicative of a successful in vitro fertilisation procedure <ref name="PMID11576737"><pubmed>11576737</pubmed></ref>. To eliminate further errors from occurring during the PGD procedure it is recommended to undertake further prenatal testing such as amniocentesis in the later stages <ref name="PMID20638568"/>. <br />
=====Advanced maternal age=====<br />
Data provided by the ESHRE has shown that the mean age of women undergoing PGS is 39 years <ref name="PMID26071418"/>. Women of advanced age have been shown to have a lower rate of pregnancies reaching childbirth <ref name="PMID18583331"><pubmed>18583331</pubmed></ref>. The highlighted concern revolves around the increased occurrence of aneuploidy following maternal age. The optimal age range for the lowest aneuploidy incidence was found to be between 27 to 37 years of age (6%) then progressively higher in women aged up to 42 (33%) and most common in those 44 and above (53%) <ref name="PMID24355045"><pubmed>24355045</pubmed></ref>. <br />
=====Recurrent pregnancy loss / IVF failure=====<br />
Recurrent pregnancy loss is defined as three or more IVF failures after cumulative transfer of more than 10 good-quality embryos. These are primarily caused by two main factors, reduced endometrium receptivity or embryonic defects. Endometrium receptivity can be negatively influences by instances including uterine pathologies such as thin endometrium, altered expression of adhesive molecules and immunological factors. Additionally, embryonic defects may be due to genetic abnormalities, embryonic aneuploidy or zona hardening. Endometriosis and hydrosalpinx has been known to effect both the endometrium and embryo <ref name="PMID23260857"><pubmed>23260857</pubmed></ref>.<br />
=====Human leukocyte antigen matching=====<br />
First used in 2001, HLA matching is an option given to parents to save a child with haematological or immunological disease through conceiving another child who would potentially be able to donate cord blood or haematopoietic stem cells from the bone marrow for transplantation. The process namely PGD-HLA has shown to improve haematopoietic stem cell transplant (HSCT). PGD-HLA can only be performed when HSCT is not needed urgently due to the time needed to conceive and delivery the baby <ref name="PMID25500181"><pubmed>25500181</pubmed></ref>. It is most commonly applied to children suffering from relapsed leukaemia <ref name="PMID22524201"><pubmed>22524201</pubmed></ref>. In a case study PGD-HLA was proven to successfully cure 10 diseases including Fanconi anaemia, Diamond-Blackfan anaemia and beta thalassemia <ref name="PMID25066893><pubmed>25066893</pubmed></ref>.<br />
==Biopsy Methods==<br />
Biopsy, the removal of genetic materials, from oocytes or embryos in the preimplantation stage is the primary step in PGD. For the past two decades these biopsies have been performed at three stages, the polar body, blastomere, and blastocyst, and the methodologies optimized to ensure the embryo’s viability. The most common approach involves biopsies at the cleavage stage. However, polar body and blastocyst biopsies are increasingly more often tested and applied. Approached for opening the zona pellucida involve next to the traditional mechanical and chemical means, novel approaches such as noncontact lasers. Their application may simplify and secure the procedure significantly. The most challenging question about PGD procedures remains at what stage biopsies should be taken. Much controversy has developed around this topic, highlighting the varying disadvantages and advantages of temporal biopsies. <ref name="PMID22723007"><pubmed>22723007</pubmed></ref><br />
<br />
{| class="wikitable"<br />
|- align="center" bgcolor="DDCEF2"<br />
|<br />
| Time of Biopsy<br />
| Advantages <br />
| Disadvantages<br />
|- bgcolor="FFFAFA"<br />
| Polar Body<br />
| Day 1<br />
| No harm to oocyte<br />
| Only maternal DNA is tested, often needs to be coupled with other biopsies<br />
|- bgcolor="FFFAFA"<br />
| Blastomere<br />
| Day 3<br />
| …<br />
| … <br />
|- bgcolor="FFFAFA"<br />
| Trophectoderm<br />
| Day 5 and 6 <br />
| Little harm, large amount of genetic material<br />
| Opening of blastocyst necessary, small time window for procedure<br />
|}<br />
<br />
<br />
[[File:Polar_Body,_Blastomere,_and_Trophectoderm_Biopsy.jpeg|thumb|Polar body (A), blastomere (B) and trophectoderm (C) biopsies<ref name="PMID25625041"><pubmed>25625041</pubmed></ref>.]]<br />
<br />
<br />
<br />
PMID 24305177<br />
===Polar Body Analysis===<br />
Day 1<br />
====Description====<br />
Polar body (PB) biopsy, which was introduced in 1990, offers a promising alternative to biopsies performed at the blastomere stage for PGD/S indications on legal and practical grounds. <br />
Description: Consequent embryo development does not necessitate the presence of the first and second PB and their removal may not be crucial. PB biopsy requires precise timing. Keeping track of the meiotic cell cycle is necessary to perform a successful biopsy and, therefore, PB biopsy usually is applied in combination with intracytoplasmic sperm injection (ICSI). During the maturation from the germinal vesicle stage to the metaphase-II stage the first PB is formed. A cytoplasmic bridge containing spindle remnants, that are still in contact with the cellular genetic material, links this PB to the oolemma for about 90 minutes after extrusion. It is possible to visualize these remnants by polarization microscopy and it is crucial to not perform the biopsy until the first PB is no longer firmly attached to the oolemma as this indicates an immature embryo.The oocyte tolerates mechanical zona dissection best during hours four until six after ICSI as the oolemma has stabilized by that time because of the cortical granule reaction. Over time the first PB degenerates stressing a temporal biopsy and its optimal extraction time window is four to 12 hours after ICSI. The second PB forms around two to four hours after ICSI. However, its optimal time window for biopsy is set to be eight to 16 hours after ICSI. This is due to the second PB being attached to the oolemma with spindle remnants until six hours after ICSI. Biopsy at this point may cause enucleation of the oocyte. In addition, studies have shown that the amplification efficiency of second PB’s DNA is worse if the PB is extracted prior to eight hours after ICSI. <br />
Thus, it is possible to perform sequential and simultaneous biopsies for the first and second PB. If performed, sequentially the first PB may be removed four to 12 hours and the second PB eight to 16 hours after ICSI. The optimal time window for a biopsy for both the first and second PB simultaneously is eight to 12 hours after ICSI. It is highly preferred to analyze both PBs due to potential aneuploidies in either PB and crossing overs during meiosis<ref name="PMID22723007"/>. <br />
====Procedure====<br />
Chemical opening achieved with for example acidic tyrode’s solution of the zona pellucida is not tolerated by the oocyte and may have detrimental effects on the embryo’s development. Therefore, the access to the perivitelline space of the oocyte is provided by mechanical zona dissection or by laser. Both techniques work well if performed by experienced embryologist. However, laser-assisted biopsy is less time consuming when compared to manual dissection. It is critical to consider the size of the introduced opening as it will remain permanent. If it is too large the blastomere may be lost during embryo development and if it is too small it may interfere with hatching of the embryo during blastocyst stage<ref name="PMID22723007"/><br />
<br />
[[File:Polar_Body_Biopsy.jpeg|thumb|The presence of a faint but clearly identifiable strand connecting PB2 to the <br />
oolemma. The biopsy was performed ∼9 h after ICSI<ref name="PMID21908464"><pubmed>21908464</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JTaQzszVr8o</html5media><br />
|-<br />
| Laser-assisted polar body biopsy<ref>RIUK, R. (2013, June 25) Polar Body Biopsy [Video file]. Retrieved from https://www.youtube.com/watch?v=JTaQzszVr8o</ref><br />
|}<br />
<br />
====Advantages & Disadvantages====<br />
PB biopsies can only investigate the maternal contributions to the embryo as they are of maternal origin. Thus, this procedure is appropriate for PGD solely for monogenetic diseases from the maternal side. Recessive diseases may be evaluated with PB biopsies on the basis that the embryo’s outcome will be determined by the paternal contribution. (...) It may still be applied for PGS as most aneuploidies either arise during meiosis or origin from the maternal genome. However, diagnosis error has been reported due to the lack of considering paternal contributions. <br />
Because PB biopsies are performed very early it is not yet known whether the oocyte will develop into a viable embryo. Thus, PBs are commonly frozen or fixed after biopsy and depending on the state of the embryo only chosen PBs will be tested. This is primarily an economic issue as many genetic testing procedures are very cost-intensive<ref name="PMID22723007"/>.<br />
<br />
[[File:Implantation_predictive_value_of_euploid_screening_results.jpeg|thumb|The sustained implantation predictive value (with 95 % confidence interval) of a euploid screening result obtained from the first polar body (PB1), PB1 and the second polar body (PB2), or a direct embryo biopsy for each stage of embryo transfer (cleavage-stage and blastocyst stage)<ref name="PMID25106935"><pubmed>25106935</pubmed></ref>.]]<br />
<br />
===Blastomere biopsy===<br />
Day 3 <br />
====Description====<br />
Blastomere biopsy has been the prevalent method for PGD and PGS in the last two decades. At least one, but up to two, blastomeres are biopsied on day three of the cleavage stage embryo. The right number of blastomeres removed is a controversial topic as two cells allow for more genetic material and more accurate results. However, removing two cells might be too invasive and damaging to the embryo. (Study)<ref name="PMID21748341"><pubmed>21748341</pubmed></ref><br />
====Procedure====<br />
Initially a hole was drilled into the zona pellucida using acid tyrodes and the blastomeres are removed via aspiration with a pipette<ref name="PMID21748341"/>.<br />
<br />
<br />
[[File:Aspiration_of_a_Blastomere.jpeg|thumb|Aspiration of a Blastomere into the biopsy pipette<ref name=" PMID24783200"><pubmed>24783200</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=TbridWVwipI</html5media><br />
|-<br />
| Laser-assisted blastomere biopsy<ref>Sukprasert, M. (2014, March 5) Day 3 Blastomere Biopsy 1 [Video file]. Retrieved from https://www.youtube.com/watch?v=TbridWVwipI</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
===Trophectoderm biopsy===<br />
Day 5 and 6<br />
====Description====<br />
The improvement of embryo culture media allowed the in vitro development of human embryos until the blastocyst stage and opened up the possibility to take blastocyst biopsies. During day three to day five the haploid maternal and paternal genomes work together for the first time to form the genome of the embryo. The maternal epigenetic control lessens significantly while preparing for implantation with precisely arranged events happening. The first event includes a rapid increase in the number of embryonic cells which are active in mitotic divisions and apoptosis of aberrant cells. This is followed by the formation of blastocoel (cavitation) which results from the flattening of cell located on the outside of the blastomere. Now the blastocyst will expand until the embryo hatches by rupturing the zona pellucida. The cells of the blastocyst will differentiate to form two distinct cell lineages, the outer trophectoderm and the inner cell mass<ref name="PMID22723007"/>.<br />
====Procedure====<br />
Trophectoderm biopsy is usually performed in Hepes buffered biopsy medium and opening approaches include needle cutting which has been replaced by lasers in past years. Different research groups report different timings of the opening to be the most successful. Some open the blastocyst on day three or four by creating a 25 µm which causes the trophectoderm to herniate through this hole and is, thus, accessible for biopsy. Others create this hole about four hours before biopsy which allows sufficient herniation of trophectoderm cells. It is also possible to open the blastocyst immediately before biopsy. This avoids an extra step and the inner cell mass usually is easy to locate. Blastocyst biopsies involve the removal of trophectoderm cells and the ideal time for the procedure is day five. Successful biopsies on day six have been performed, while little is known about the results of biopsies on day seven. However, since the window of implantation in humans is from day eight to ten after ovulation, day seven biopsies appear to be possible<ref name="PMID22723007"/>.<br />
-collapse of trophoblasts<br />
-possible: biopsy of hatched blastocyst, holding pipette careful mild suction force to hold embryo near ICM <br />
-Cryopreservation<br />
<br />
<br />
[[File:Microscopic images of human blastocysts for biopsy.jpeg|thumb|(A) Some trophectoderm cells in a blastocyst started to hatch and (B) the trophectoderm cells were biopsied with assisted laser cutting. Images in C–D show the blastocysts after vitrification and warming. Blastocysts had been cultured for 2–4 hrs after warming, showing good (ICM and trophectoderm cells) hatched (C) and hatching (D) blastocysts. The hatching blastocyst in (E) has good ICM but fair trophectoderm while the blastocyst in (F) has both fair ICM and trophectoderm. Arrows indicate ICMs and arrow heads indicate trophectoderm cells. Bar = 40 µm<ref name="PMID2190846"><pubmed>2190846</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JI_TQ8d8tNM</html5media><br />
|-<br />
| Laser-assisted blastocyst biopsy (at 00:50 min)<ref>Coco, R. (2014, April 30) Trophectoderm biopsy in a Hatching blastocyst protruding ICM [Video file]. Retrieved from https://www.youtube.com/watch?v=JI_TQ8d8tNM</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
Blastocyst biopsies are believed to be less damaging to the embryo and appear to be unrelated to implantation rates. In addition, this biopsy method allows for a larger extraction of cells for genetic testing. However, since they are performed late in in vitro development, the time window for genetic testing is relatively small. Fast and accurate genetic testing methods are needed to ensure a successful and safe result from this biopsy. Thus, blastocyst biopsies may gain more popularity in the future whn such methods have been developed or improved<ref name="PMID22723007"/>. <br />
<br />
<br />
==Genetic Techniques==<br />
<br />
===PCR===<br />
====Description====<br />
Polymerase chain reaction (PCR) amplifies DNA specific to genetic sequence of interest . PCR was developed by Kay Mullis in the 1980s, for which he was awarded the Nobel prize for chemistry in 1993. <ref> Pubmed Docs (2015) Polymerase Chain Reaction (PCR) Pubmen. Retrieved from [http://www.ncbi.nlm.nih.gov/probe/docs/techpcr/]</ref> This technique enables clinicians to monitor and diagnose diseases using minute samples such as embryonic cells, blood & tissue. <ref>Roche (2015) PCR: How We Copy DNA. Roche Molecular Systems Inc. retrieved From [http://molecular.roche.com/pcr/Pages/Process.aspx]</ref> PCR has many important applications like DNA fingerprinting, genetic mapping, detection of viruses and bacteria as well as being used to detect genetic disorders, as a part of PGD, in conjunction with IVF. It is used to detect molecular abnormalities such as single gene disorders like Tay Sach, Cycstic fibrosis, Duchenne Muscular Dystrophy, Thalassemia, Huntington disease, Spinal muscular atrophy and many more. Molecular and Genetic analysis require a significant amount of DNA, which we would not have without PCR. It revolutionized the study of DNA, replacing all previous recombinant DNA technology. <ref> Mullins, K., Francois, F.& Gibbs R.A. (1994 ) The Polymerase Chain Reaction. p3. Springer- Science +Business Media. Birkhauser, Boston<br />
Available at [https://books.google.com.au/books?hl=en&lr=&id=gjrTBwAAQBAJ&oi=fnd&pg=PR5&dq=kary+mullis+PCR&ots=mpzAyRh5ZY&sig=PQ4goNoKJ90tb3-MkPk62zrTGbw#v=onepage&q=kary%20mullis%20PCR&f=false] </ref> <br />
<br />
[[File:PCR.jpg|thumb|right|Polymerase chain reaction (PCR) amplifies DNA specific to genetic sequence of interest, enabling the monitoring and diagnose molecular abnormalities such as single gene disorders using minute samples such as embryonic cells, blood & tissue <ref>NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref>]]<br />
<br />
====Procedure====<br />
<br />
Sample are obtained from the the blastocyst, a polar body biopsy or the blastomeres stages of the embryo. <br />
Stage 1 Denaturing: separating the target strands of DNA <br />
The obtained sample is heated to roughly 90 degrees celcius, this heat causes breaks the relatively weak bonds between nucleotides that form DNA. the double stranded DNA to split into 2 single strands of DNA that are used as templates.<br />
Stage 2 Annealing: Binding the Primers to the target DNA sequence <br />
PCR will only copy the target sequence of DNA specified by specific PCR primer. These synthesized primers Oligonucleotides are small artificial pieces of DNA. <br />
TAQ polymerase enzyme synthesize 2 new strands of DNA duplicate to the single sample DNA stand template indicated by these primers. During this stage the reaction is cooled to a temperature between 40-60 degrees Celsius. <br />
Stage 3- Extension- making copies <br />
Each of these 2 copies are then used again as templates generating 2 further replications This cycle can occur as many 30 -40 times within a couple hours leading to billions of extra copies of the original DNA segment. The optimal temperature for the further replication is roughly 72 degrees Celsius. <br />
<br />
This process mediated by a thermocycler machine that is programmed to alter the temperature of the reaction every couple of minutes, perpetuating the cycle of DNA denaturing and synthesis. <br />
This process, generates exponential exact copy of the original template DNA sequence. <br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
!PCR cycles<br />
<br />
|{|<br />
|-<br />
| '''PCR Cycle'''<br />
| '''Target Copies'''<br />
|-<br />
| 1<br />
| 2<br />
|-<br />
| 2<br />
| 4<br />
|-<br />
| 3<br />
| 8<br />
|-<br />
| 4<br />
| 16<br />
|-"<br />
| 5 <br />
| 32<br />
|-<br />
| 6 <br />
| 64<br />
|-<br />
| 7 <br />
| 128<br />
|-<br />
| 8<br />
| 256<br />
|- <br />
| 9<br />
| 512 <br />
|-<br />
| 10<br />
| 1024<br />
|-<br />
| 15<br />
| 32,768<br />
|-<br />
| 20 <br />
| 1,048,578<br />
|-<br />
| 25<br />
| 33,554,432<br />
|-<br />
| 30 <br />
| 1,073,741,842<br />
|-<br />
|}<br />
<br />
<br />
<br />
{| class="wikitable" <br />
|-bgcolor="#9ACD32" <br />
| rowspan="10" |'''Advantages'''<br />
|-bgcolor="#F0FFF0"<br />
| fast and inexpensive way of copying a target sequence of DNA<br />
|-bgcolor="#F0FFF0"<br />
| aids the diagnosis of single cell defects<br />
|-bgcolor="#F0FFF0"<br />
| rapid generation of results within a couple hours<br />
|-bgcolor="#F0FFF0"<br />
| can start from a single molecule of DNA, therefore is more sensitive <br />
|-bgcolor="#F0FFF0"<br />
| has a flexible primer design enabling<br />
|-bgcolor="#F0FFF0"<br />
| overcame previous issues associated with the limited availability of sites of end<br />
|-bgcolor="#F0FFF0"<br />
| generates the DNA copies exponentially<br />
|-bgcolor="#F0FFF0"<br />
| enables DNA amplification required for molecular and genetic analysis<br />
|-bgcolor="#F0FFF0"<br />
|Valid diagnostic method in selecting unaffected embryos for embryo transfer <ref> Dreesen, J., Drusedaul, M., Smeets, H., Die-Smulders, C., Coonen, E., Dumoulin, J., Gielen, M., Evers, J., Herbergers, J. & Geradets, J. (2008) Validation of preimplantation genetic diagnosis by PCR analysis: genotype comparison of the blastomere and corresponding embryo, implications for clinical practice. Mol. Hum. Reprod. 14 (10):573-579.doi: 10.1093/molehr/gan052. Retrieved from [http://molehr.oxfordjournals.org/content/14/10/573.short] </ref> <ref><pubmed>20966460</pubmed></ref><br />
|-bgcolor="#9ACD32"<br />
| rowspan="5"|'''Disadvantages'''<br />
|-bgcolor="#F0FFF0"<br />
| only during this exponential DNA replication phase can we determine the starting quantity sequence contained in the original sample ( template DNA strand)<br />
|-bgcolor="#F0FFF0"<br />
| PCR reaction is limited by the presence of inhibitors present in the sample : reagent inhibitors <br />
|-bgcolor="#F0FFF0"<br />
| self annealing due to the accumulation of the product -stopping exponential amplification for the target sequence and reach a plateau<br />
quantification of the end point of reaction of PCR products unreliable - therefore that is why we require real time quantitative RT-PCR necessary<br />
<ref> NIS (2015) Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref><br />
|}<br />
<br />
<br />
===Fluorescent In Situ Hybridisation (FISH)===<br />
<br />
<br />
====Description====<br />
Fluorescence in situ hybridization (FISH) the one of the most effective and rapid <ref name="PMID26338801"><pubmed>26338801</pubmed></ref> Preimplantation Genetic Diagnosis (PGD). This techniques used to locate a specific DNA sequences within a chromosome. FISH facilitates the clinical diagnosis of chromosomal abnormalities indicated by sequential duplications, deletions and rearrangements of chromosome, that are usually missed with microscopic analysis. This technique is especially relevant for female embryos with X-linked diseases,<ref name="PMID20809319"><pubmed>20809319</pubmed></ref> that have no other mutation specific tests [http://www.ncbi.nlm.nih.gov/pubmed/20809319] As part of PGD, samples are collected from various stages of the embyro,and they are able to conducted tests on the blastocyst, a polar body biopsy and the blastomeres <ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. FISH is 99% effective when used in conjunction with competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities<ref name="PMID26338801"/>.<br />
<br />
====Procedure==== <br />
<br />
Samples are collected from either the blastocyst, a polar body biopsy or the blastomeres stages of the embryo <ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
DNA strands are heated and denatured causing their the individual DNA strands to break apart<br />
Probes are single complimentary stands of DNA a that have been tagged with small chemical agents that glow brightly in the presence of a specific region on a chromosome. These specific probes then hybridize and join to their complementary DNA strand. <br />
The fluorescent tags enable the researchers to correctly identify the presence or lack thereof and location of the specific chromosomes that they are testing for. <ref name="PMID17876073"><pubmed>17876073</pubmed></ref><br />
Researcher analyse the results by identifying the number and the relative location of the fluorescent dots generated by the FISH images.<ref name="PMID17970921"><pubmed>17970921</pubmed></ref><br />
The probe will not fully hybridise if there has been a duplication or a deletion of the DNA - indicating chromosomal and sex chromosomal anomalies like trisomies and aneuploidies. <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref><br />
<br />
<br />
Different probes are used for different purposes: <ref>Unique, Rare Chromosome Disorder Support Group (2013) Fluorescence in situ hybridisation (FISH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/Other/FISH%20FTNW.pdf]</ref><br />
*'''Locus specific tags''' detect very small imbalances, and locate isolated small portions <br />
of genes within a chromosome<br />
*'''Alphoid/Centomeric Repeat probes''' are developed from the repetitive sequence located in the middle region of each chromosome, useful in determining the number of chromosomes , detecting rearrangement and when used in conjunction with locus probes to determine the absence of genetic material on a chromosome. <br />
*'''Paint Probes''' are collections of smaller probes with their own stains that bind to a different section on the chromosome - allowing the full chromosome too be labeled a unique colour, this "full colour map" can be used to know the spectral karyotype- full chromosomal mapping is useful in examining chromosomal abnormalities. <br />
<br />
[[File:Fluorescent In Situ Hybridisation (FISH).jpg|thumb|right|'''FISH''' We are able to tag Specific DNA sequences using Probes which have been tagged with fluorescent Labels.This technique enables the clinical diagnosis of chromosomal abnormalities, indicated by sequential duplication, deletions and rearrangements of chromosome <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref>]]<br />
<br />
{|class="wikitable" align="center"<br />
|-bgcolor="pink" <br />
| rowspan="8" |'''Advantages''' <br />
|-bgcolor="#FDE1F2" <br />
| FISH is 99% effective when used in conjunction with Competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities.<ref><pubmed>26338801</pubmed></ref><br />
|-bgcolor="#FDE1F2" <br />
| Rapid generation of results<br />
|-bgcolor="#FDE1F2" <br />
| Identifies very small translocations and aneuploidies that occur within chromosomes, that would usually be missed under microscopic analysis<br />
|-bgcolor="#FDE1F2" <br />
| Indicates whether the accessed chromosomes are normal <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|-bgcolor="#FDE1F2" <br />
| Tests for the most common chromosomal abnormalities - down syndrome chromosomes 13,16,18,21 and 22 <ref><pubmed>21749752</pubmed></ref><br />
|-bgcolor="#FDE1F2" <br />
| It may be used to compare the chromosomal gene arrangements in related species<br />
|-bgcolor="#FDE1F2" <br />
| can be used to identify and remove inheritable X-linked disease or sex chromasome anomalies such as Duchennes Muscular Dystrophy, hemophilia, ectodermal dysplasia <ref><pubmed>17876073</pubmed></ref><br />
|-bgcolor="#FEB745"<br />
| rowspan="5"|'''Disadvantages'''<br />
|-bgcolor="#FE1C5EA"<br />
| FISH destroys all cells tested <ref> O'Connor, C. (2008) Fluorescence in situ hybridization (FISH). Nature Education 1(1):171. retrieved from [http://www.nature.com/scitable/topicpage/fluorescence-in-situ-hybridization-fish-327] </ref><br />
|-bgcolor="#FE1C5EA"<br />
| It does not fully access all chromosomes (only ~ 12)<br />
|-bgcolor="#FE1C5EA"<br />
| Analysis of results is dependent upon the dot quality impacted by hybridisation efficiency or the camera sensitivity <ref><pubmed>17970921</pubmed></ref><br />
|-bgcolor="#FE1C5EA"<br />
| some studies indicate that using FISH on a day-3 embryo biopsy decreases the rate of live births <ref><pubmed>26168107</pubmed></ref><br />
|}<br />
<br />
===Array Comparative Genomic Hybridisation (aCGH)===<br />
====Description====<br />
<br />
aCGH also known as Microarray analysis efficiently scans the entire genome for chromosomal imbalances. CGH was initially developed to detect the number of changes in a solid tumor mass. It uses 2 genomes comparing the sample to the control, with each labeled in a different fluorescent dye<ref name="PMID1876176"><pubmed>1876176</pubmed></ref>. Earlier CGH techniques were limited by the resolution of the imaging <ref> Lichter, P., et al. Comparative genomic hybridization: Uses and limitations. Seminars in Hematology 37, 348–357 (2000)</ref> , these initial limitations were overcome by using Microarrays in conjunction with CGh to improve the resolution of the imaging, Array Comparative Genomic Hybridisation (aCGH). This method compares sample and control microarrayed slides containing small segments of DNA (probes). <ref> Lucito, R., et al. Representational oligonucleotide microarray analysis: A high-resolution method to detect genome copy number variation. Genome Research 13, 2291–2305 (2003) </ref> the Probes used will vary according from the small (25-85 base pairs) oligonucleotides manufactured to highlight different target sequences, to the very large genomic clones (80,000- 200,00 base pairs), and as these are significantly smaller than the traditional metaphase chromosomes used for CGH, generating a higher resolution of image. <ref name="PMID22467166"><pubmed>22467166</pubmed></ref>.aCGH is used as a diagnostic tool for prenatal detection f chromosomal abnormalities <ref name="PMID19012303"><pubmed>19012303</pubmed></ref>.<br />
<br />
<br />
====Procedure====<br />
<ref> Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432] </ref><br />
The sample is obtained (skin, blood or fetal cells) and DNA is obtained. <br />
As a part of PGD fetal cell samples are collected from; the fertilized egg polar bodies, the blastomere (day 3 embryo) or the blastocyst/tropoectoderm stage (day 5 embryo).<br />
Sample DNA is labeled with one fluorescent dye, and the control DNA is labeled with a different colored fluorescent dye. the control DNA is used as the base point of reference. <br />
heated and denatured single DNA strands then hybridize to their complementary single strand probes, which are then combined and applied to a microarray and the results are run through a computer program and a digital imaging system is used to quantify the results( fluorescent intensities of the labeled probes). <br />
<br />
[[File:aCGH.jpg|thumb|right|'''aCGH''' checks the entire genome for chromosomal imbalances, by comparing control and a sample slides contatining small segements of DNA sample microarrayed slides small segments of DNA. Illustrated by student z5020317 and adapted from <ref> NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation. retrieved from [http://www.phgfoundation.org/file/5237/]</ref> <ref>Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432]</ref>]]<br />
<br />
<br />
<br />
The fluorescent ratio and the hybridization signal at different locations on the genome of the control DNA are used to identify any variances present in the sample DNA. aCGH facilitates the clinical diagnosis of submicroscopic chromosomal duplication, deletion and rearrangements indicative of chromosomal disorders such as trisomies 1-22and specific sex linked disorders. <br />
Duplications in the DNA are displayed by the computer program as spikes/ peaks over an established threshold and deletions in DNA are displayed by the computer program as spikes/ toughs beneath this threshold <br />
<br />
<br />
<br />
<br />
{|border="1" align="center"<br />
|-bgcolor="pink" <br />
| '''Advantages''' <br />
| '''Disadvantages'''<br />
|-<br />
| multiple applications: prenatal genetic diagnosis, cancer diagnosis, <ref name="PMID20193845"><pubmed>20193845</pubmed></ref> genetic screening for developmental delay (learning disabilities) <ref name="PMID17309648"><pubmed>17309648</pubmed></ref>. or congenital anomalies that are suspected to be genetic in origin <ref>NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation . retrieved from [http://www.phgfoundation.org/file/5237/]</ref><br />
| translocations and inversions of DNA are not detected<br />
|-bgcolor="pink"<br />
| trace represents all chromosomes present in the human genome chromosomes 1-22 and the X & Y chromosomes, and therefore is the most accurate method for testing whole embryo aneuploidy<br />
| limited ability diagnosing specific polyploidies such as triploidy <ref> Unique, Rare Chromosome Disorder Support Group (2013) Microarray-based Comparative Genomic Hybridiation (array CGH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/other/array%20cgh%20ftnw.pdf] </ref><br />
|-<br />
| aCGH has been extensively tested, and Validated, and is now used world wide.<br />
| will not detect mosaicism detection <20% (cultures where >1 of 5 cells are trisomy 12)<br />
|-bgcolor="pink"<br />
| detects deletions and additions and rearrangements as well as amplification, of the WHOLE genome, simultaneously.<br />
| will not detect balanced chromosomal rearrangement<br />
|-<br />
| detects submicroscopic alterations<br />
| will not detect duplications or deletions <80kb<br />
|-bgcolor="pink"<br />
| used as a diagnostic tool for prenatal detection of chromosomal abnormalities <ref name="PMID22034057"><pubmed>22034057</pubmed></ref><br />
| will not detect point mutations within genes <ref>Washington department of education (CGH- FAQ for physicians. Signature Genomic LAboratories, LLC. Retrieved from [https://depts.washington.edu/dbpeds/Lab%20Tests/SignatureCGH-physician_FAQ.pdf]</ref><br />
|-<br />
| provides high resolution genomewide screening of segmental genomic copy number variations<br />
| will not detect chromosomal position of genomic gains<br />
|-bgcolor="pink"<br />
| very accurate when used in conjunction with FISH<br />
| will not detect loos of heterozygosity (LOH) or Absence of heterozygosity (AOH) <ref>WiCell Research Institute Inc. (2012) Comparative Genomic Hybridization Microarray. <br />
retrieved from [http://www.wicell.org/home/cytogenetic-services/cgh-microarray/array-comparative-genomic-hybridization-acgh.cmsx]</ref><br />
|-<br />
|Alone is more reliable and in detecting chromosomal abnormalities, with a higher implantation success rate, than FISH <ref name="PMID20494259"><pubmed>20494259</pubmed></ref><br />
|<br />
|-bgcolor="pink"<br />
|Allows an in depth research focus upon specific types of rearrangements within selected chromosomal regions, a recent particular area of interest is subtelomeric and pericentromeric rearrangements<br />
|<br />
|-<br />
|reduces the risk of failed implantation and miscarriage, improving the chance of a healthy baby <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|<br />
|}<br />
<br />
<br />
<br />
===Next Generation Sequencing===<br />
====Description====<br />
The development and advances within ART in the past 20 years, as well as the increasing popularity of IV, has lead to an influx of new technologies developed to screen embryos for chromosomal anomalies, which are covered by the umbrella term of Next generation Sequencing (NGS). NGS is a general term used to describe all of the new and emerging screening techniques currently being introduced and used as part of PGD for IVF . NGS screens for single gene disorders as well as conducting extensive and very comprehensive chromosome diagnosis by sequencing, counting, and accurately assembling millions of DNA reads, simultaneously. <ref name="PMID23499002"><pubmed>23499002</pubmed></ref> There is a movement for NGS to replace the other limited testing techniques and be used as the standard. <br />
====Procedure====<br />
Samples are collected from either blastomere or the blastocyst/tropoectoderm and processed for analysis by a computer system. <br />
The methodology of each process is unique to the technique being used. <br />
<br />
<br />
<br />
{|border="1" align="center"<br />
|-bgcolor="pink" <br />
| '''Advantages'''<br />
| '''Disadvantages'''<br />
|-bgcolor="white"<br />
| cheaper<br />
| there are limited information available to clinical applications of NGS <ref><pubmed>26100406</pubmed></ref><br />
|-bgcolor="pink"<br />
| opens new diagnostic possibilities<br />
|<br />
|-bgcolor="white"<br />
| accurately tests all 24 chromosomes<br />
| <br />
|-bgcolor="pink"<br />
| tests for the presence of monogenic diseases of known genetic background<br />
| <br />
|-bgcolor="white"<br />
| reduces the number of biopsies required for diagnosis<br />
| <br />
|-bgcolor="pink"<br />
| higher detection rate of small translocations<br />
| <br />
|-bgcolor="white"<br />
| highly accurate is testing for compound point mutations, chromosomal duplication, deletions and insertions <ref name="23312231"><pubmed>23312231</pubmed></ref><br />
| <br />
|-bgcolor="pink"<br />
| it accurately detects chromosomal aneuploidy and unbalanced rearrangement <ref name="PMID25685330"><pubmed>25685330</pubmed></ref><br />
| <br />
|-bgcolor="white"<br />
| NGS single gene disorder screenings can conducted in conjunction with PCR comprehensive chromosomal screening<br />
|<br />
|-bgcolor="pink"<br />
| Reduces human error <br />
|<br />
|-bgcolor="white"<br />
| better detects the presence of mosaicism<br />
|<br />
|-bgcolor="pink"<br />
| work well in conjunction with CGH and aCGH as part of PGD, improving the chances of IVF. <ref> Morris, R. S. (2015 ) Next generation sequencing for PCG|PGS|CCS. IVF1 retrieved from [http://www.ivf1.com/next-generation-sequencing for-pgd] </ref><br />
|<br />
|}<br />
<br />
<br />
<br />
<br />
<br />
<br />
==Diagnosis==<br />
There are a large amount of diseases that PGD can apply to, below are descriptions of the diseases that PGD are more commonly used for. Utilization of Diseased Cell Lines<br />
===Cystic Fibrosis===<br />
Cystic fibrosis is a single gene disorder. It is autosomal recessive and involves mutations in the cystic fibrosis transmembrane conductance regulator (CTFR) gene. The CTFR gene is normally responsible for the decrease in chloride and the transport of bicarbonate in epithelial cells thus playing a major physiological role. In PGD procedures, identification of the gene is assisted by microsatellite markers that have similar composition to the CTFR gene itself. Biopsy of two cells at the blastocyst stage is recommended if markers are not available. There are many variations of cystic fibrosis the most common being P.Phe508del <ref name="PMID26014425"><pubmed>26014425</pubmed></ref>.<br />
===Duchenne Muscular Dystrophy ===<br />
Duchenne Muscular Dystrophy is an X-linked recessive disease. It involves the Xp21 gene where majority of the mutations are chromosomal deletions with a smaller percentage resulting from duplications <ref name="PMID18359022"><pubmed>18359022</pubmed></ref>.<br />
<br />
===Autosomal Recessive MEckel-Gruber Syndrome===<br />
Autosomal recessive genetic defect caused by the TMEM67 gene. It results in cystic dysplasia of the kidneys with fibrotic change in the liber and occipital encephalocele. Other malformations could also be present in the central nervous system. In PGD whole genome amplification of single blastomeres are taken to identify the gene, this is also coupled with PCR techniques. Maternal plasma can also be extracted for PGS. <ref><pubmed>24039893</pubmed></ref> <br />
===β – Thalassemia=== <br />
β – Thalassemia is known as the most common type of autosomal recessive inherited disorder among haemoglobinopathies. It involves the adult β-globin gene and is associated with the absent or decreased expression of the gene. This is commonly caused by a single nucleotide change in the gene. PGD has been used successfully worldwide to identify the β-globin gene where its application is usually performed on a single blastomere or polar body <ref name="PMID19064120">19064120</pubmed></ref>.<br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
! Applicable diseases for PGD <ref>Genoma Group (2014). Retrieved September 18th, 2015, from http://www.preimplantationgeneticdiagnosis.it/genetic-diseases-diagnosed-by-pgd.htm </ref>, <ref>Genesis Genetics (2015). Retrieved September 18th, 2015, from http://genesisgenetics.org/pgd/what-we-test-for/</ref>, <ref>Human Fertilisation & Embryology Authority (2015). Retrieved Septembr 18th, 2015, from http://guide.hfea.gov.uk/pgd/</ref><br />
|-<br />
| '''Disease'''<br />
| '''Involved Genes'''<br />
|-<br />
| 5 Alpha Reductase Deficiency (5ARD)<br />
| SRD5A2 <br />
|-<br />
| Achondroplasia<br />
|FGFR3 <br />
|-<br />
| Acute Intermittent Porphyria <br />
| ALAD, ALAS2, CPOX, FECH, HMBS, PPOX, UROD, or UROS<br />
|-<br />
| Adrenoleukodystrophy (Adrenomyeloneuropathy)<br />
| ABCD1 <br />
|-<br />
| Agammaglobulinaemia (x-linked) <br />
|BTK <br />
|-<br />
| Agammaglobulinemia Bruton Tyrosine Kinase (BTK) <br />
|BTK <br />
|-<br />
| Aicardi Goutieres Syndrome 1 (AGS1) <br />
|TREX1, RNASEH2A, RNASEH2B, RNASEH2C, SAMHD1<br />
|-<br />
| Alagille Syndrome<br />
|JAG1 or NOTCH2<br />
|- <br />
| Alpers-Huttenlocher Syndrome <br />
|POLG <br />
|-<br />
| Alpha-1-antitrypsin deficiency <br />
|SERPINA1 <br />
|-<br />
| Alpha-Mannosidosis<br />
| MAN2B1 <br />
|-<br />
| Alpha Thalassemia <br />
|HBA1 or HBA2 <br />
|-<br />
| Alports Syndrome<br />
|COL4A3, COL4A4, COL4A5<br />
|-<br />
| Alzheimer's Disease - early onset (Type 3 and 4) <br />
|APP, PSEN1, or PSEN2<br />
|-<br />
| Amyotrophic Lateral Sclerosis 1 (ALS1) <br />
|C9orf72, SOD1, TARDBP, FUS, ANG, ALS2, SETX, VAPB <br />
|-<br />
| Argininosuccinic Aciduria <br />
| ASL<br />
|-<br />
| Arrhythmogenic Right Ventricular Cardiomyopathy/ Dysplasia (ARVC/D)<br />
| DSG2; DSP; PKP2<br />
|-<br />
| Ataxia Telangiectasia<br />
| ATM<br />
|-<br />
| Autosomal Recessive Meckel-Gruber Syndrome<br />
| TMEM67<br />
|-<br />
| Bardet-Biedl Syndrome (BBS)<br />
| BBS1; BBS10<br />
|-<br />
| Barth Syndrome<br />
| TAZ<br />
|-<br />
| Beta Thalassaemia<br />
| HBB<br />
|-<br />
| Birt-Hogg-Dubé Syndrome<br />
| FLCN<br />
|-<br />
| Breast Ovarian Cancer Familial Susceptibility (BRCA2)<br />
| BRCA1; BRCA2<br />
|-<br />
| Canavan Disease <br />
| ASPA<br />
|-<br />
| Carnitine-Acylcarnitine Translocase Deficiency <br />
| SLC25A20<br />
|-<br />
| Cerebral Arteriopathy with Subcortical Infarcts & Leukoencephalopathy (CADASIL)<br />
| NOTCH3<br />
|-<br />
| Cerebral Cavernous Malformation<br />
| CCM1<br />
|-<br />
| Charcot-Marie-Tooth Disease<br />
| GJB1; MPZ; NEFL; PMP22<br />
|-<br />
| CHARGE Syndrome<br />
| CHD7<br />
|-<br />
| Cherubism<br />
| SH3BP2<br />
|-<br />
| Choroideremia<br />
| CHM<br />
|-<br />
| Chronic Granulomatous Disease<br />
| CYBB; NCF1<br />
|-<br />
| Ciliary Dyskinesia<br />
| DNAH5<br />
|-<br />
| Citrullinemia<br />
| ASS1<br />
|-<br />
| Cleidocranial Dysplasia<br />
| RUNX2<br />
|-<br />
| Cockayne Syndrome<br />
| ERCC6<br />
|-<br />
| Congenital Adrenal Hyperplasia<br />
| CYP21A2<br />
|-<br />
| Congenital Cataracts<br />
| GJA8; VSX2<br />
|-<br />
| Congenital Diarrhea, Syndromic<br />
| SPINT2<br />
|-<br />
| Congenital Disorders of Glycosylation (CDG)<br />
| ALG1; ALG6; CDG1C; DOLK; PMM2<br />
|-<br />
| Cornelia de Lange Syndrome <br />
| NIPBL<br />
|-<br />
| Craniosynostosis<br />
| TWIST1<br />
|-<br />
| Crouzon Syndrome<br />
| FGFR2<br />
|-<br />
| Cysteinyl Leukotriene Receptor 1 Deficiency <br />
| CYSLTR1<br />
|-<br />
| Cystic Fibrosis<br />
| CFTR<br />
|-<br />
| Diamond –Blackfan Anemia <br />
| RPS19<br />
|-<br />
| Duchenne Muscular Dystrophy <br />
| DMD<br />
|-<br />
| Dyskeratosis congenita (Male embryos only)<br />
| DKC1<br />
|-<br />
| Ectodermal dysplasia (Hypohidrotic)<br />
| EDA; EDA1; GJB6; IKBKG<br />
|-<br />
| Familial Adenomatous polyposis coli (FAP)<br />
| APC<br />
|-<br />
| Familial Dysautonomia<br />
| IKBKAP<br />
|-<br />
| Fanconi Anemia <br />
| FANCA; FANCC; FANCD2; FANCF; FANCG; FANCJ<br />
|-<br />
| Fragile X Syndrome (FRAX)<br />
| FMR1<br />
|-<br />
| Galactosemia <br />
| GALT<br />
|-<br />
| Gangliosidosis<br />
| GLB1<br />
|-<br />
| Glanzmann Thrombasthenia <br />
| ITGA2B<br />
|-<br />
| Glutaric Acidemia (aciduria)<br />
| GCDH <br />
|-<br />
| Glycogen Storage Disease <br />
| G6PC; GAA; SLC37A4<br />
|-<br />
| Haemophilia A<br />
| F8<br />
|-<br />
| Haemophilia B<br />
| F9<br />
|-<br />
| Hereditary Nonpolyposis Colorectal Cancer: Lynch Syndrome<br />
| MLH1; MSH2; MSH6<br />
|-<br />
| Holt Oram Syndrome<br />
| TBX5<br />
|-<br />
| Huntington Disease<br />
| HD<br />
|-<br />
| Hydrocephalus<br />
| L1CAM<br />
|-<br />
| Ichthyosis <br />
| ABCA12; STS<br />
|-<br />
| Incontinentia Pigmenti (IP)<br />
| NEMO<br />
|-<br />
| Joubert Syndrome 5<br />
| INPP5E<br />
|-<br />
| Krabbe Disease<br />
| GALC<br />
|-<br />
| Leber Congenital Amaurosis (LCA)<br />
| CEP290; GUCY2D<br />
|-<br />
| Leigh Syndrome (Infantile Subacute Necrotising Encephalopathy)<br />
| LRPPRC<br />
|-<br />
| Lesch Nyan Syndrome<br />
| HPRT1<br />
|-<br />
| Leukocyte Adhesion Deficiency (Type I)<br />
| ITGB2<br />
|-<br />
| Li-Fraumeni Syndrome<br />
| TP53<br />
|-<br />
| Macular Dystrophy Retinal <br />
| VMD2<br />
|-<br />
| Maple Syrup Urine Disorder (MSUD)<br />
| BCKDHB<br />
|-<br />
| Marfan Syndrome <br />
| FBN1<br />
|-<br />
| Menkes Syndrome<br />
| ATP7A<br />
|-<br />
| Mitochondrial DNA Depletion Syndrom <br />
| POLG; RRM2B; SUCLA2; TK2<br />
|-<br />
| Mucolipidosis type II<br />
| GNPTAB<br />
|-<br />
| Multiple Endocrine Neoplasia<br />
| MEN1; MEN2A; MEN2B<br />
|-<br />
| Multiple Exostoses<br />
| EXT1; EXT2 <br />
|-<br />
| Myotubular myopathy<br />
| MTM1 <br />
|-<br />
| Nail-Patella Syndrome<br />
| LMX1B<br />
|-<br />
| Neurofibromatosis Type 1<br />
| NF1<br />
|-<br />
| Neurofibromatosis Type 2 <br />
| NF2<br />
|-<br />
| Noonan Syndrome<br />
| KRAS, PTPN11; SOS1<br />
|-<br />
| Norrie Disease<br />
| NDP<br />
|-<br />
| Ocular Albinism <br />
| GPR143<br />
|-<br />
| Oculocutaneous Albinism <br />
| OCA2; TYR <br />
|-<br />
| Oculodentaldigital Dysplasia<br />
| GJA1<br />
|-<br />
| Optic Atrophy<br />
| OPA1<br />
|-<br />
| Ornithine Transcarbamylase Deficiency <br />
| OTC<br />
|-<br />
| Osteogenesis imperfeca <br />
| COL1A1; COL1A2<br />
|-<br />
| Osteopetrosis <br />
| CLCN7; OSTM1; TCIRG1<br />
|-<br />
| Pachyonychia Congenita <br />
| KRT16; KRT6A<br />
|-<br />
| Pancreatitis, Hereditary<br />
| PRSS1 <br />
|-<br />
| Papillorenal syndrome <br />
| PAX2<br />
|-<br />
| Phenylketonuria <br />
| PAH <br />
|-<br />
| This table does not cover the complete list of diseases that PGD can be applied to.<br />
|}<br />
<br />
==Laws & Legal status==<br />
<br />
{| class="wikitable" <br />
|-<br />
| Australia<br />
| PGD is currently used to detect serious genetic conditions to improve the outcome of Assisted Reproductive Technologies (ART). In very rare cases it may be used to select an embryo with compatible tissue for a sibling who has a life-threatening disease where other means of treatment is unavailable. This is with the conditions that the use of PGD will not affect the welfare and interests of the child to be born. The parents must also receive adequate counselling and have full understanding of the procedures of PGD. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"> National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art</ref><br />
The use of PGD for sex-selection is prohibited with the exception of reducing the risk of the transmission of serious sex-linked genetic conditions. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"/><br />
|-<br />
| Brazil<br />
| The laws regarding PGD in Brazil are not strictly regulated. They are vague and there is limited information surround the activities of assisted reproduction in general in the country <ref name="PMID25493379"><pubmed>25493379</pubmed></ref>.<br />
|-<br />
| Czech Republic<br />
| The laws in the Czech Republic allow those with a “defined indication in order to exclude risk of serous genetically conditioned disease and defects with embryos before they are implanted into the cavity of the uterus”. Couples that undergo any assisted reproductive treatment including PGD have to be married. Sex-selection is illegal except in regards to serious sex-linked genetic diseases <ref name="PMID24777348"><pubmed>24777348</pubmed></ref>.<br />
|-<br />
| Greece<br />
| In Greece, ART is open to those up to the age of 50 with written consent. It can only be used if a medical necessity is present such as the susceptibility of serious hereditary diseases. Sex selection is banned apart from cases of sex-linked diseases and sexually transmitted diseases <ref name="PMID24777348"/>.<br />
|-<br />
| India<br />
| In India there is a cultural preference for boys thus the Prenatal Diagnostic Techniques (Regulation and Prevention of Misuse) Act was introduced in 1994. This law limits the use of PGD for sex determination except in cases of specific congenital diseases. These laws however are not strictly enforced. <ref>World Health Organisation (2015) Gender and Genetics Retrieved on October 21st 2015 from:http://www.who.int/genomics/gender/en/index4.html</ref><br />
|-<br />
| Portugal <br />
| ART is only available to those who are married or have a similar type of relationship for at least two years. The couples cannot be of the same sex and must be at least 18 years of age. Sex selection is illegal except in cases of sex-linked diseases. The use of PGD is illegal if the predictive value of genetic tests are very low <ref name="PMID24777348"/>.<br />
|-<br />
| Spain<br />
| PGD can be applied to “serious hereditary diseases not amenable to postnatal curative treatment” and “detection of other abnormalities which may compromise the viability of the pre-embryo”. If PGD is to be used for any other purpose authorisation must be acquired <ref name="PMID24777348"/>.<br />
|-<br />
| Sweden <br />
| The use of PGD is strictly regulated and couples must achieve authorisation of the National Board of Health and Welfare. It can only be used it can only be used if the child is at risk to inheriting a serious chromosomal or monogenetic disease. It cannot be used for selection of specific characteristics <ref name="PMID24777348"/>.<br />
|-<br />
| United Kingdom<br />
| Those involved with carrying out the IVF treatment must have a license from the Human Fertilisation and Embryology Authority (HFEA). Only embryos that are approved by the HFEA can be implanted where the embryonic nuclear or mitochondrial DNA cannot be altered with the exception of preventing mitochondrial diseases <ref name="PMID24777348"/>. <br />
|}<br />
<br />
==Future/Current Research==<br />
===Noninvasive Preimplantation Genetic Testing without Embryo Biopsy===<br />
Different parameters of gametes, zygotes, embryos (“vacuoles in sperm heads, spindle position in mature oocytes, cleavage intervals of zygote, and embryo developmental dynamics”) may correlate with aneuploidy rates. This knowledge may be applied in potential noninvasive preimplantation diagnostic methods. Several methods have been proposed and are currently further researched<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Sperm Selection====<br />
Intracytoplasmic morphologically selected sperm injection (IMSI) is common procedure in IVF treatment to improve fertilization rates in patients with poor semen quality. In addition, studies have found that IMSI improves embryo development and that spermatozoa with large vacuoles in their heads correlate with increased aneuploidy rates and disturbed chromosomal structures. Thus, selecting spermatozoa based on morphological hallmarks may decrease aneuploidy rates in the fertilized embryos. As with polar body biopsies, however, this approach will solely be applicable if evidence for severe male detrimental contribution is given<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Blastocoel Fluid Extraction====<br />
In addition, a less invasive retrieval of material for diagnosis could include the extraction of the blastocoel fluid. The cavity of the blastocyst, lined by the trophectoderm, is filled with this blastocoel fluid, which contains metabolites of both trophectoderm and inner cell mass origin. The retrieval does not require a biopsy but merely a small opening to extract the fluid and, thus, causes less harm to the embryo. Multiple studies have applied this method<ref name="PMID22020776"><pubmed>22020776</pubmed></ref> <ref name="PMID23148560"><pubmed>23148560</pubmed></ref> and it may in the future become of clinical relevance.<br />
<br />
<br />
[[File:Aspiration_of_the_Blastocoel_Fluid.jpeg|thumb|Aspiration of the Blastocoel Fluid using a ICSI pipette<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.]]<br />
<br />
<br />
Next to metabolites, the blastocoel fluid can contain DNA. Studies have shown that genomic DNA is present in about 90% of the blastocoel fluid samples tested. Typically the fluid is removed with an ICSI pipette from a day five blastocyst through its mural trophectoderm until the blastocyst fully collapses around the embryo. Several concerns regarding this method in a clinical setting have been raised. The collected DNA may be contaminated by the culture media that contains DNA fractions. The DNA may also be least representative of the actual embryos genome as the DNA may originate from abnormal or degenerated cells. Even though labelled noninvasive, the blastocyst still undergoes manipulation to some degree which may affect its viability. Thus, more research is required until this method can evolve from research to clinical use<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
====Proteomics====<br />
The protein secretome of blastocysts may be representative of its chromosome constitution Recent studies have found biomarkers such as lipocalin-1, interleukin-10, tumor necrosis factor, stem cell factor, and chemokine ligand 13 to be differently secreted by aneuploid blastocyst than by euploid ones. The most significant biomarker appears to be interleukin-10. Paired with novel proteomic technologies and mass spectrometry this knowledge when extended may contribute to a new invasive preimplantation genetic diagnosis method<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Embryo Morphology====<br />
Using time lapse imaging the embryo’s morphology can be closely observed and potential aneuploidy characteristics detected. Such characteristics may include the time of division to five cells, the time between the division from three to four cells, and the duration of the division from one to two and subsequently to three. In addition, the morphological quality of ICM an TE has been positively associated with aneuploidy or euploidy prognosis<ref name="PMID26246880"><pubmed>26246880</pubmed></ref>. These may give rise to an embryo quality screening prior to implantation<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
==References==<br />
<br />
<references/><br />
<br />
<br />
{{StudentPage2015}}</div>Z5017878https://embryology.med.unsw.edu.au/embryology/index.php?title=2015_Group_Project_6&diff=2070112015 Group Project 62015-10-21T06:58:02Z<p>Z5017878: </p>
<hr />
<div>{{ANAT2341Project2015header}}<br />
<br />
<br />
=Preimplantation Genetic Diagnosis and Screening=<br />
==Introduction==<br />
Preimplantation genetic diagnosis (PGD) and screening (PGS) are reproductive options for couples with known family histories of genetic disease or couples undergoing IVF procedures due to infertility issues. PGD can diagnose many genetic disorders caused by known chromosomal abnormalities (number and/or structure) or single gene mutations, and, thus decrease the risk of termination of pregnancy or miscarriages and enable such couples to have an unaffected child<ref name="PMID24907939"><pubmed>24907939</pubmed></ref>. Through major improvements in PGD/S and general laboratory technology, the testing for abnormalities in fetuses has shifted from prenatal diagnosis during the first 2 trimesters <ref> Blackburn, S.L. (2003) '''Maternal, Fetal & Neonatal physiology: a Clinical perspective''' (2nd ed.). Seattle: Saudners </ref>, testing for overall fetal growth, complications of pregnancy, and birth defects<ref> Sadler T.W.(2012) '''Langman's Medical Embryology''' (12th ed.) Philadelphia: Lipincott, Wiliams & Wilkins, a Wolters Kluwer Business </ref>, to an embryonic focus especially in advancements in Artificial Reproductive Technologies (ART)<ref><pubmed>20638568</pubmed></ref>. In 1990 PGD for a recessive X-linked disease resulted in the first live birth<ref><pubmed>2330030</pubmed></ref> and has since been incorporated in clinical routine and applied for a variety of genetic diseases, such as sickle cell anemia, thalassemia, or cystic fibrosis<ref name="PMID24907939"/>.<br />
[[File:Preimplantation Genetic Diagnosis Procedure.jpeg|700px|thumb| Simplified steps for PGD<ref name="PMID24907939"/>]]<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=0e-79qKllqk</html5media><br />
|-<br />
| Preimplantation Genetic Diagnosis<ref>IVF Florida (2011, December 11) IVF Florida - South Florida Fertility Specialists - Pre-Implantation Genetic Diagnosis [Video file]. Retrieved from https://www.youtube.com/watch?v=0e-79qKllqk</ref><br />
|}<br />
<br />
==History==<br />
The advances in reproductive technology during the second half of the 20th century, led to PGD's first clinical application in 1990 <ref>Harper, J. (n.d.). The history of PGD. Lecture. UCL Centre for PG&D and CRGH.University College London</ref>.<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
|Year<br />
|<br />
|- bgcolor="FFFAFA"<br />
| '''1967''' <br />
|First PGD on rabbit blastocysts (Gardner& Edwards) <ref name="PMID6036172"><pubmed>6036172</pubmed></ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1986''' <br />
|First Cleavage Biopsy (Wilton & Trounson)<ref>Wilton, L. J., & Trounson, A. O. (1986). Viability of mouse embryos and blastomeres following biopsy of a single cell. In Proceedings of the 18th Annual Conference of the Australian Society for Reproductive Biology, Brisbane, Australia.</ref><br />
|- bgcolor="FFFAFA"<br />
|'''1987''' <br />
|First Blastocyst Biopsy (Muggleton-Harris, Monk, Rawlings, & Whittingham)<ref name="PMID3372699"><pubmed>3372699</pubmed></ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1988''' <br />
|First Polar Body Biopsy (Yury Verlinksy)<ref> Verlinsky, Y., Pergament, E., Andresen, P., Enriquez, G., & Strom, C. (1989). Genetic analysis of polar body DNA: A new approach to preimplantation genetic diagnosis. Am J Hum Genet, 45(4), A272.</ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1990''' <br />
|First Clinical PGD using PCR testing for X-linked (Handyside, Kontogianni, Hardy, & Winston)<ref name="PMID2330030"><pubmed>2330030</pubmed></ref> <br />
|} <br />
==Preimplantation Genetic Diagnosis==<br />
Preimplantation genetic diagnosis (PGD) is used to test the genetic makeup of embryos to detect single gene disorders, chromosomal abnormalities and mitochondrial disorders. It also has applications in gender selection for diseases with unequal gender distributions <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Some diseases commonly involved with PGD include cystic fibrosis, spinal muscular atrophy and beta – thalassaemia <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press.">Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press</ref> <ref name="PMID17823145"><pubmed>17823145</pubmed></ref>. It was first used in the United Kingdom in the 1980s of arenoleucodystrophy and primarily focusing on sex- linked disorders <ref name="PMID17823145"/><ref name="PMID23150080"><pubmed>23150080</pubmed></ref>. PGD is now capable of detecting single cell defects (molecular) and chromosomal disorders resulting from the inversion, translocation or deletion of chromosomes (cytogenic) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>,<ref name="PMID11325751"><pubmed>11325751</pubmed></ref>. PGD can be applied to the embryo at different stages. That is on polar bodies, blastomeres or blastocyst <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>.<br />
Depending on the type of genetic disorder, PGD utilises different methods of genetic testing. These include Fluorescence in situ hybridisation (FISH) which is used for sex – linked disorders and detects chromosomal rearrangements <ref name="PMID11325751"/><ref name="PMID17876073"><pubmed>17876073</pubmed></ref> and Embryo halotyping which allows the identification of chromosomes causing the inherited disorder through knowledge of the pattern of closely linked markers <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. Polymerase chain reaction (PCR) is also widely used to detect molecular abnormalities <ref name="PMID11325751"/>.<br />
PGD is tightly regulated and supported by large organisations namely The American Society for Reproductive Medicine, The European Society for Human Reproduction and Embryology (ESHRE), The European Society of Human Genetics and the Preimplantation Genetic Diagnosis International Society <ref name="PMID25500181><pubmed>25500181</pubmed></ref>.<br />
===Sex-linked disorders===<br />
The determination of a disease as gender specific usually correlates with the presence or absence of specific genes such as SRY on the Y chromosome. It is known that females have two X chromosomes and males have an X and a Y chromosome where abnormalities are more prevalent on the X chromosome. PGD can be used for sex selection where only male embryos are transferred to reduce the chance of inheriting X-linked disorders. However, this does not completely eradicate the problem as male embryos remain susceptible to inheriting an affected X chromosome. Sex determination is only used when the specific mutation is unknown and has yet to be discovered <ref name="PMID24866878"><pubmed>24866878</pubmed></ref>.<br />
===Single gene defects===<br />
Single gene defects can be dominant, recessive, autosomal or X-linked. They are commonly diagnosed using PCR and although the PCR available today is complex and capable of combatting a large range of disease the development of new protocols has been proven to be difficult due to the small DNA sample available <ref name="PMID26168107"><pubmed>26168107</pubmed></ref><br />
===Mitochondrial disorders===<br />
Mitochondrial disorders also known as oxidative phosphorylation disorders arise from mutations in the nuclear DNA or mitochondrial DNA <ref name="PMID26312584"><pubmed>26312584</pubmed></ref>. They pose as a problem because they are unrecognisable until the mutations in the cell reach a detrimental level <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Mitochondrial disorders cause miscarriages and stillbirths as well as death in children and young adults. The effects can either be contained in a single organ or more commonly involve multiple organ failure where organs with high energy demands such as the brain, liver muscle and heart and heavily influenced. They are usually occur spontaneously or result from inheritance from the mother. Since mitochondria are solely inherited from the mother oocyte donations have been used as a solution to combat mitochondrial disorders. Additionally, there has been an increasing use in PGD where embryos that stay under the given threshold of 18% gene-mutations are allowed to be transferred and result in normal development. New technology in the areas of nuclear gene transfer and genome editing are also being experimented with <ref name="PMID26312584"/>. <br />
===Chromosomal disorders===<br />
Chromosomal disorders can be reciprocal, Robertsonian translocations, inversions, deletions and insertions <ref name="PMID26168107"/>. . Data from ESHRE collected between 2010 and 2011 has shown that the most common chromosomal abnormality confronted in PGD are reciprocal chromosomal abnormalities <ref name"PMID26071418"><pubmed>26071418</pubmed></ref>. PGD has also been used successfully for Robertsonian translocations (RT), a type of structural translocation. Children who carry RT are phenotypically normal, however in their later years it is found that they will suffer from infertility and repeated miscarriages due to the high frequency of abnormal embryos <ref name="PMID22081077"><pubmed>22081077</pubmed></ref>. PCR and FISH are the two main techniques used for chromosomal disorders. To be able to conduct the examinations the cells are required to be at the metaphase stage <ref name="PMID26168107"/>. <br />
==Preimplantation Genetic Screening==<br />
Prenatal Genetic Screening (PGS) involves an array of methods or ideas that aim to segregate embryos that have genetic flaws and those that are healthy <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. The occurrence of aneuploidy is high around the stages of early embryonic development and they are the most common cause if miscarriages and congenital birth defects <ref name= "PMID26085841"><pubmed>26085841</pubmed></ref>. They have little effect on the morphology of the embryo making them difficult to identify thus identification heavily relies on genetic testing <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. <br />
Genetic sampling is most commonly conducted using Microarray Comparative Genomic Hybridisation (aCGH) as well as FISH, Quantitative PCR and Single Nucleotide Polymorphism (SNP) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. These methods collectively aim to assess numeral and structural chromosomal errors <ref name= "PMID26085841"/>. Studies have also introduced Next- Generation Sequencing (NGS) <ref name= "PMID26085841"/> and Whole Genome Amplification used to screen imbalances in the complete 24-chromosomes <ref name="PMID25953353"><pubmed>25953353</pubmed></ref><br />
Statistics from ESHRE have shown that the most common indications for PGS is advanced age, followed by repeated implantation failure or recurrent miscarriage and male infertility <ref name="PMID26071418"><pubmed>26071418</pubmed></ref>.<br />
====Indications====<br />
A low percentage of structural abnormalities in chromosomes are responsible for the cause of miscarriages. Despite this, they are the most prevalent type of chromosomal abnormality accounted for in PGD <ref name="PMID20638568"/>. The presence of specific gene cycles, initiation of embryonic protein synthesis and evident physiological development are all indicative of a successful in vitro fertilisation procedure <ref name="PMID11576737"><pubmed>11576737</pubmed></ref>. To eliminate further errors from occurring during the PGD procedure it is recommended to undertake further prenatal testing such as amniocentesis in the later stages <ref name="PMID20638568"/>. <br />
=====Advanced maternal age=====<br />
Data provided by the ESHRE has shown that the mean age of women undergoing PGS is 39 years <ref name="PMID26071418"/>. Women of advanced age have been shown to have a lower rate of pregnancies reaching childbirth <ref name="PMID18583331"><pubmed>18583331</pubmed></ref>. The highlighted concern revolves around the increased occurrence of aneuploidy following maternal age. The optimal age range for the lowest aneuploidy incidence was found to be between 27 to 37 years of age (6%) then progressively higher in women aged up to 42 (33%) and most common in those 44 and above (53%) <ref name="PMID24355045"><pubmed>24355045</pubmed></ref>. <br />
=====Recurrent pregnancy loss / IVF failure=====<br />
Recurrent pregnancy loss is defined as three or more IVF failures after cumulative transfer of more than 10 good-quality embryos. These are primarily caused by two main factors, reduced endometrium receptivity or embryonic defects. Endometrium receptivity can be negatively influences by instances including uterine pathologies such as thin endometrium, altered expression of adhesive molecules and immunological factors. Additionally, embryonic defects may be due to genetic abnormalities, embryonic aneuploidy or zona hardening. Endometriosis and hydrosalpinx has been known to effect both the endometrium and embryo <ref name="PMID23260857"><pubmed>23260857</pubmed></ref>.<br />
=====Human leukocyte antigen matching=====<br />
First used in 2001, HLA matching is an option given to parents to save a child with haematological or immunological disease through conceiving another child who would potentially be able to donate cord blood or haematopoietic stem cells from the bone marrow for transplantation. The process namely PGD-HLA has shown to improve haematopoietic stem cell transplant (HSCT). PGD-HLA can only be performed when HSCT is not needed urgently due to the time needed to conceive and delivery the baby <ref name="PMID25500181"><pubmed>25500181</pubmed></ref>. It is most commonly applied to children suffering from relapsed leukaemia <ref name="PMID22524201"><pubmed>22524201</pubmed></ref>. In a case study PGD-HLA was proven to successfully cure 10 diseases including Fanconi anaemia, Diamond-Blackfan anaemia and beta thalassemia <ref name="PMID25066893><pubmed>25066893</pubmed></ref>.<br />
==Biopsy Methods==<br />
Biopsy, the removal of genetic materials, from oocytes or embryos in the preimplantation stage is the primary step in PGD. For the past two decades these biopsies have been performed at three stages, the polar body, blastomere, and blastocyst, and the methodologies optimized to ensure the embryo’s viability. The most common approach involves biopsies at the cleavage stage. However, polar body and blastocyst biopsies are increasingly more often tested and applied. Approached for opening the zona pellucida involve next to the traditional mechanical and chemical means, novel approaches such as noncontact lasers. Their application may simplify and secure the procedure significantly. The most challenging question about PGD procedures remains at what stage biopsies should be taken. Much controversy has developed around this topic, highlighting the varying disadvantages and advantages of temporal biopsies. <ref name="PMID22723007"><pubmed>22723007</pubmed></ref><br />
<br />
{| class="wikitable"<br />
|- align="center" bgcolor="DDCEF2"<br />
|<br />
| Time of Biopsy<br />
| Advantages <br />
| Disadvantages<br />
|- bgcolor="FFFAFA"<br />
| Polar Body<br />
| Day 1<br />
| No harm to oocyte<br />
| Only maternal DNA is tested, often needs to be coupled with other biopsies<br />
|- bgcolor="FFFAFA"<br />
| Blastomere<br />
| Day 3<br />
| …<br />
| … <br />
|- bgcolor="FFFAFA"<br />
| Trophectoderm<br />
| Day 5 and 6 <br />
| Little harm, large amount of genetic material<br />
| Opening of blastocyst necessary, small time window for procedure<br />
|}<br />
<br />
<br />
[[File:Polar_Body,_Blastomere,_and_Trophectoderm_Biopsy.jpeg|thumb|Polar body (A), blastomere (B) and trophectoderm (C) biopsies<ref name="PMID25625041"><pubmed>25625041</pubmed></ref>.]]<br />
<br />
<br />
<br />
PMID 24305177<br />
===Polar Body Analysis===<br />
Day 1<br />
====Description====<br />
Polar body (PB) biopsy, which was introduced in 1990, offers a promising alternative to biopsies performed at the blastomere stage for PGD/S indications on legal and practical grounds. <br />
Description: Consequent embryo development does not necessitate the presence of the first and second PB and their removal may not be crucial. PB biopsy requires precise timing. Keeping track of the meiotic cell cycle is necessary to perform a successful biopsy and, therefore, PB biopsy usually is applied in combination with intracytoplasmic sperm injection (ICSI). During the maturation from the germinal vesicle stage to the metaphase-II stage the first PB is formed. A cytoplasmic bridge containing spindle remnants, that are still in contact with the cellular genetic material, links this PB to the oolemma for about 90 minutes after extrusion. It is possible to visualize these remnants by polarization microscopy and it is crucial to not perform the biopsy until the first PB is no longer firmly attached to the oolemma as this indicates an immature embryo.The oocyte tolerates mechanical zona dissection best during hours four until six after ICSI as the oolemma has stabilized by that time because of the cortical granule reaction. Over time the first PB degenerates stressing a temporal biopsy and its optimal extraction time window is four to 12 hours after ICSI. The second PB forms around two to four hours after ICSI. However, its optimal time window for biopsy is set to be eight to 16 hours after ICSI. This is due to the second PB being attached to the oolemma with spindle remnants until six hours after ICSI. Biopsy at this point may cause enucleation of the oocyte. In addition, studies have shown that the amplification efficiency of second PB’s DNA is worse if the PB is extracted prior to eight hours after ICSI. <br />
Thus, it is possible to perform sequential and simultaneous biopsies for the first and second PB. If performed, sequentially the first PB may be removed four to 12 hours and the second PB eight to 16 hours after ICSI. The optimal time window for a biopsy for both the first and second PB simultaneously is eight to 12 hours after ICSI. It is highly preferred to analyze both PBs due to potential aneuploidies in either PB and crossing overs during meiosis<ref name="PMID22723007"/>. <br />
====Procedure====<br />
Chemical opening achieved with for example acidic tyrode’s solution of the zona pellucida is not tolerated by the oocyte and may have detrimental effects on the embryo’s development. Therefore, the access to the perivitelline space of the oocyte is provided by mechanical zona dissection or by laser. Both techniques work well if performed by experienced embryologist. However, laser-assisted biopsy is less time consuming when compared to manual dissection. It is critical to consider the size of the introduced opening as it will remain permanent. If it is too large the blastomere may be lost during embryo development and if it is too small it may interfere with hatching of the embryo during blastocyst stage<ref name="PMID22723007"/><br />
<br />
[[File:Polar_Body_Biopsy.jpeg|thumb|The presence of a faint but clearly identifiable strand connecting PB2 to the <br />
oolemma. The biopsy was performed ∼9 h after ICSI<ref name="PMID21908464"><pubmed>21908464</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JTaQzszVr8o</html5media><br />
|-<br />
| Laser-assisted polar body biopsy<ref>RIUK, R. (2013, June 25) Polar Body Biopsy [Video file]. Retrieved from https://www.youtube.com/watch?v=JTaQzszVr8o</ref><br />
|}<br />
<br />
====Advantages & Disadvantages====<br />
PB biopsies can only investigate the maternal contributions to the embryo as they are of maternal origin. Thus, this procedure is appropriate for PGD solely for monogenetic diseases from the maternal side. Recessive diseases may be evaluated with PB biopsies on the basis that the embryo’s outcome will be determined by the paternal contribution. (...) It may still be applied for PGS as most aneuploidies either arise during meiosis or origin from the maternal genome. However, diagnosis error has been reported due to the lack of considering paternal contributions. <br />
Because PB biopsies are performed very early it is not yet known whether the oocyte will develop into a viable embryo. Thus, PBs are commonly frozen or fixed after biopsy and depending on the state of the embryo only chosen PBs will be tested. This is primarily an economic issue as many genetic testing procedures are very cost-intensive<ref name="PMID22723007"/>.<br />
<br />
[[File:Implantation_predictive_value_of_euploid_screening_results.jpeg|thumb|The sustained implantation predictive value (with 95 % confidence interval) of a euploid screening result obtained from the first polar body (PB1), PB1 and the second polar body (PB2), or a direct embryo biopsy for each stage of embryo transfer (cleavage-stage and blastocyst stage)<ref name="PMID25106935"><pubmed>25106935</pubmed></ref>.]]<br />
<br />
===Blastomere biopsy===<br />
Day 3 <br />
====Description====<br />
Blastomere biopsy has been the prevalent method for PGD and PGS in the last two decades. At least one, but up to two, blastomeres are biopsied on day three of the cleavage stage embryo. The right number of blastomeres removed is a controversial topic as two cells allow for more genetic material and more accurate results. However, removing two cells might be too invasive and damaging to the embryo. (Study)<ref name="PMID21748341"><pubmed>21748341</pubmed></ref><br />
====Procedure====<br />
Initially a hole was drilled into the zona pellucida using acid tyrodes and the blastomeres are removed via aspiration with a pipette<ref name="PMID21748341"/>.<br />
<br />
<br />
[[File:Aspiration_of_a_Blastomere.jpeg|thumb|Aspiration of a Blastomere into the biopsy pipette<ref name=" PMID24783200"><pubmed>24783200</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=TbridWVwipI</html5media><br />
|-<br />
| Laser-assisted blastomere biopsy<ref>Sukprasert, M. (2014, March 5) Day 3 Blastomere Biopsy 1 [Video file]. Retrieved from https://www.youtube.com/watch?v=TbridWVwipI</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
===Trophectoderm biopsy===<br />
Day 5 and 6<br />
====Description====<br />
The improvement of embryo culture media allowed the in vitro development of human embryos until the blastocyst stage and opened up the possibility to take blastocyst biopsies. During day three to day five the haploid maternal and paternal genomes work together for the first time to form the genome of the embryo. The maternal epigenetic control lessens significantly while preparing for implantation with precisely arranged events happening. The first event includes a rapid increase in the number of embryonic cells which are active in mitotic divisions and apoptosis of aberrant cells. This is followed by the formation of blastocoel (cavitation) which results from the flattening of cell located on the outside of the blastomere. Now the blastocyst will expand until the embryo hatches by rupturing the zona pellucida. The cells of the blastocyst will differentiate to form two distinct cell lineages, the outer trophectoderm and the inner cell mass<ref name="PMID22723007"/>.<br />
====Procedure====<br />
Trophectoderm biopsy is usually performed in Hepes buffered biopsy medium and opening approaches include needle cutting which has been replaced by lasers in past years. Different research groups report different timings of the opening to be the most successful. Some open the blastocyst on day three or four by creating a 25 µm which causes the trophectoderm to herniate through this hole and is, thus, accessible for biopsy. Others create this hole about four hours before biopsy which allows sufficient herniation of trophectoderm cells. It is also possible to open the blastocyst immediately before biopsy. This avoids an extra step and the inner cell mass usually is easy to locate. Blastocyst biopsies involve the removal of trophectoderm cells and the ideal time for the procedure is day five. Successful biopsies on day six have been performed, while little is known about the results of biopsies on day seven. However, since the window of implantation in humans is from day eight to ten after ovulation, day seven biopsies appear to be possible<ref name="PMID22723007"/>.<br />
-collapse of trophoblasts<br />
-possible: biopsy of hatched blastocyst, holding pipette careful mild suction force to hold embryo near ICM <br />
-Cryopreservation<br />
<br />
<br />
[[File:Microscopic images of human blastocysts for biopsy.jpeg|thumb|(A) Some trophectoderm cells in a blastocyst started to hatch and (B) the trophectoderm cells were biopsied with assisted laser cutting. Images in C–D show the blastocysts after vitrification and warming. Blastocysts had been cultured for 2–4 hrs after warming, showing good (ICM and trophectoderm cells) hatched (C) and hatching (D) blastocysts. The hatching blastocyst in (E) has good ICM but fair trophectoderm while the blastocyst in (F) has both fair ICM and trophectoderm. Arrows indicate ICMs and arrow heads indicate trophectoderm cells. Bar = 40 µm<ref name="PMID2190846"><pubmed>2190846</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JI_TQ8d8tNM</html5media><br />
|-<br />
| Laser-assisted blastocyst biopsy (at 00:50 min)<ref>Coco, R. (2014, April 30) Trophectoderm biopsy in a Hatching blastocyst protruding ICM [Video file]. Retrieved from https://www.youtube.com/watch?v=JI_TQ8d8tNM</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
Blastocyst biopsies are believed to be less damaging to the embryo and appear to be unrelated to implantation rates. In addition, this biopsy method allows for a larger extraction of cells for genetic testing. However, since they are performed late in in vitro development, the time window for genetic testing is relatively small. Fast and accurate genetic testing methods are needed to ensure a successful and safe result from this biopsy. Thus, blastocyst biopsies may gain more popularity in the future whn such methods have been developed or improved<ref name="PMID22723007"/>. <br />
<br />
<br />
==Genetic Techniques==<br />
<br />
===PCR===<br />
====Description====<br />
Polymerase chain reaction (PCR) amplifies DNA specific to genetic sequence of interest . PCR was developed by Kay Mullis in the 1980s, for which he was awarded the Nobel prize for chemistry in 1993. <ref> Pubmed Docs (2015) Polymerase Chain Reaction (PCR) Pubmen. Retrieved from [http://www.ncbi.nlm.nih.gov/probe/docs/techpcr/]</ref> This technique enables clinicians to monitor and diagnose diseases using minute samples such as embryonic cells, blood & tissue. <ref>Roche (2015) PCR: How We Copy DNA. Roche Molecular Systems Inc. retrieved From [http://molecular.roche.com/pcr/Pages/Process.aspx]</ref> PCR has many important applications like DNA fingerprinting, genetic mapping, detection of viruses and bacteria as well as being used to detect genetic disorders, as a part of PGD, in conjunction with IVF. It is used to detect molecular abnormalities such as single gene disorders like Tay Sach, Cycstic fibrosis, Duchenne Muscular Dystrophy, Thalassemia, Huntington disease, Spinal muscular atrophy and many more. Molecular and Genetic analysis require a significant amount of DNA, which we would not have without PCR. It revolutionized the study of DNA, replacing all previous recombinant DNA technology. <ref> Mullins, K., Francois, F.& Gibbs R.A. (1994 ) The Polymerase Chain Reaction. p3. Springer- Science +Business Media. Birkhauser, Boston<br />
Available at [https://books.google.com.au/books?hl=en&lr=&id=gjrTBwAAQBAJ&oi=fnd&pg=PR5&dq=kary+mullis+PCR&ots=mpzAyRh5ZY&sig=PQ4goNoKJ90tb3-MkPk62zrTGbw#v=onepage&q=kary%20mullis%20PCR&f=false] </ref> <br />
<br />
[[File:PCR.jpg|thumb|right|Polymerase chain reaction (PCR) amplifies DNA specific to genetic sequence of interest, enabling the monitoring and diagnose molecular abnormalities such as single gene disorders using minute samples such as embryonic cells, blood & tissue <ref>NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref>]]<br />
<br />
====Procedure====<br />
<br />
Sample are obtained from the the blastocyst, a polar body biopsy or the blastomeres stages of the embryo. <br />
Stage 1 Denaturing: separating the target strands of DNA <br />
The obtained sample is heated to roughly 90 degrees celcius, this heat causes breaks the relatively weak bonds between nucleotides that form DNA. the double stranded DNA to split into 2 single strands of DNA that are used as templates.<br />
Stage 2 Annealing: Binding the Primers to the target DNA sequence <br />
PCR will only copy the target sequence of DNA specified by specific PCR primer. These synthesized primers Oligonucleotides are small artificial pieces of DNA. <br />
TAQ polymerase enzyme synthesize 2 new strands of DNA duplicate to the single sample DNA stand template indicated by these primers. During this stage the reaction is cooled to a temperature between 40-60 degrees Celsius. <br />
Stage 3- Extension- making copies <br />
Each of these 2 copies are then used again as templates generating 2 further replications This cycle can occur as many 30 -40 times within a couple hours leading to billions of extra copies of the original DNA segment. The optimal temperature for the further replication is roughly 72 degrees Celsius. <br />
<br />
This process mediated by a thermocycler machine that is programmed to alter the temperature of the reaction every couple of minutes, perpetuating the cycle of DNA denaturing and synthesis. <br />
This process, generates exponential exact copy of the original template DNA sequence. <br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
!PCR cycles<br />
<br />
|{|<br />
|-<br />
| '''PCR Cycle'''<br />
| '''Target Copies'''<br />
|-<br />
| 1<br />
| 2<br />
|-<br />
| 2<br />
| 4<br />
|-<br />
| 3<br />
| 8<br />
|-<br />
| 4<br />
| 16<br />
|-"<br />
| 5 <br />
| 32<br />
|-<br />
| 6 <br />
| 64<br />
|-<br />
| 7 <br />
| 128<br />
|-<br />
| 8<br />
| 256<br />
|- <br />
| 9<br />
| 512 <br />
|-<br />
| 10<br />
| 1024<br />
|-<br />
| 15<br />
| 32,768<br />
|-<br />
| 20 <br />
| 1,048,578<br />
|-<br />
| 25<br />
| 33,554,432<br />
|-<br />
| 30 <br />
| 1,073,741,842<br />
|-<br />
|}<br />
<br />
<br />
<br />
{| class="wikitable" <br />
|-bgcolor="#9ACD32" <br />
| rowspan="10" |'''Advantages'''<br />
|-bgcolor="#F0FFF0"<br />
| fast and inexpensive way of copying a target sequence of DNA<br />
|-bgcolor="#F0FFF0"<br />
| aids the diagnosis of single cell defects<br />
|-bgcolor="#F0FFF0"<br />
| rapid generation of results within a couple hours<br />
|-bgcolor="#F0FFF0"<br />
| can start from a single molecule of DNA, therefore is more sensitive <br />
|-bgcolor="#F0FFF0"<br />
| has a flexible primer design enabling<br />
|-bgcolor="#F0FFF0"<br />
| overcame previous issues associated with the limited availability of sites of end<br />
|-bgcolor="#F0FFF0"<br />
| generates the DNA copies exponentially<br />
|-bgcolor="#F0FFF0"<br />
| enables DNA amplification required for molecular and genetic analysis<br />
|-bgcolor="#F0FFF0"<br />
|Valid diagnostic method in selecting unaffected embryos for embryo transfer <ref> Dreesen, J., Drusedaul, M., Smeets, H., Die-Smulders, C., Coonen, E., Dumoulin, J., Gielen, M., Evers, J., Herbergers, J. & Geradets, J. (2008) Validation of preimplantation genetic diagnosis by PCR analysis: genotype comparison of the blastomere and corresponding embryo, implications for clinical practice. Mol. Hum. Reprod. 14 (10):573-579.doi: 10.1093/molehr/gan052. Retrieved from [http://molehr.oxfordjournals.org/content/14/10/573.short] </ref> <ref><pubmed>20966460</pubmed></ref><br />
|-bgcolor="#9ACD32"<br />
| rowspan="5"|'''Disadvantages'''<br />
|-bgcolor="#F0FFF0"<br />
| only during this exponential DNA replication phase can we determine the starting quantity sequence contained in the original sample ( template DNA strand)<br />
|-bgcolor="#F0FFF0"<br />
| PCR reaction is limited by the presence of inhibitors present in the sample : reagent inhibitors <br />
|-bgcolor="#F0FFF0"<br />
| self annealing due to the accumulation of the product -stopping exponential amplification for the target sequence and reach a plateau<br />
quantification of the end point of reaction of PCR products unreliable - therefore that is why we require real time quantitative RT-PCR necessary<br />
<ref> NIS (2015) Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref><br />
|}<br />
<br />
<br />
===Fluorescent In Situ Hybridisation (FISH)===<br />
<br />
<br />
====Description====<br />
Fluorescence in situ hybridization (FISH) the one of the most effective and rapid <ref name="PMID26338801"><pubmed>26338801</pubmed></ref> Preimplantation Genetic Diagnosis (PGD). This techniques used to locate a specific DNA sequences within a chromosome. FISH facilitates the clinical diagnosis of chromosomal abnormalities indicated by sequential duplications, deletions and rearrangements of chromosome, that are usually missed with microscopic analysis. This technique is especially relevant for female embryos with X-linked diseases,<ref name="PMID20809319"><pubmed>20809319</pubmed></ref> that have no other mutation specific tests [http://www.ncbi.nlm.nih.gov/pubmed/20809319] As part of PGD, samples are collected from various stages of the embyro,and they are able to conducted tests on the blastocyst, a polar body biopsy and the blastomeres <ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. FISH is 99% effective when used in conjunction with competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities<ref name="PMID26338801"/>.<br />
<br />
====Procedure==== <br />
<br />
Samples are collected from either the blastocyst, a polar body biopsy or the blastomeres stages of the embryo <ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
DNA strands are heated and denatured causing their the individual DNA strands to break apart<br />
Probes are single complimentary stands of DNA a that have been tagged with small chemical agents that glow brightly in the presence of a specific region on a chromosome. These specific probes then hybridize and join to their complementary DNA strand. <br />
The fluorescent tags enable the researchers to correctly identify the presence or lack thereof and location of the specific chromosomes that they are testing for. <ref name="PMID17876073"><pubmed>17876073</pubmed></ref><br />
Researcher analyse the results by identifying the number and the relative location of the fluorescent dots generated by the FISH images.<ref name="PMID17970921"><pubmed>17970921</pubmed></ref><br />
The probe will not fully hybridise if there has been a duplication or a deletion of the DNA - indicating chromosomal and sex chromosomal anomalies like trisomies and aneuploidies. <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref><br />
<br />
<br />
Different probes are used for different purposes: <ref>Unique, Rare Chromosome Disorder Support Group (2013) Fluorescence in situ hybridisation (FISH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/Other/FISH%20FTNW.pdf]</ref><br />
*'''Locus specific tags''' detect very small imbalances, and locate isolated small portions <br />
of genes within a chromosome<br />
*'''Alphoid/Centomeric Repeat probes''' are developed from the repetitive sequence located in the middle region of each chromosome, useful in determining the number of chromosomes , detecting rearrangement and when used in conjunction with locus probes to determine the absence of genetic material on a chromosome. <br />
*'''Paint Probes''' are collections of smaller probes with their own stains that bind to a different section on the chromosome - allowing the full chromosome too be labeled a unique colour, this "full colour map" can be used to know the spectral karyotype- full chromosomal mapping is useful in examining chromosomal abnormalities. <br />
<br />
[[File:Fluorescent In Situ Hybridisation (FISH).jpg|thumb|right|'''FISH''' We are able to tag Specific DNA sequences using Probes which have been tagged with fluorescent Labels.This technique enables the clinical diagnosis of chromosomal abnormalities, indicated by sequential duplication, deletions and rearrangements of chromosome <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref>]]<br />
<br />
{|class="wikitable" align="center"<br />
|-bgcolor="pink" <br />
| rowspan="8" |'''Advantages''' <br />
|-bgcolor="#FDE1F2" <br />
| FISH is 99% effective when used in conjunction with Competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities.<ref><pubmed>26338801</pubmed></ref><br />
|-bgcolor="#FDE1F2" <br />
| Rapid generation of results<br />
|-bgcolor="#FDE1F2" <br />
| Identifies very small translocations and aneuploidies that occur within chromosomes, that would usually be missed under microscopic analysis<br />
|-bgcolor="#FDE1F2" <br />
| Indicates whether the accessed chromosomes are normal <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|-bgcolor="#FDE1F2" <br />
| Tests for the most common chromosomal abnormalities - down syndrome chromosomes 13,16,18,21 and 22 <ref><pubmed>21749752</pubmed></ref><br />
|-bgcolor="#FDE1F2" <br />
| It may be used to compare the chromosomal gene arrangements in related species<br />
|-bgcolor="#FDE1F2" <br />
| can be used to identify and remove inheritable X-linked disease or sex chromasome anomalies such as Duchennes Muscular Dystrophy, hemophilia, ectodermal dysplasia <ref><pubmed>17876073</pubmed></ref><br />
|-bgcolor="#FEB745"<br />
| rowspan="5"|'''Disadvantages'''<br />
|-bgcolor="#FE1C5EA"<br />
| FISH destroys all cells tested <ref> O'Connor, C. (2008) Fluorescence in situ hybridization (FISH). Nature Education 1(1):171. retrieved from [http://www.nature.com/scitable/topicpage/fluorescence-in-situ-hybridization-fish-327] </ref><br />
|-bgcolor="#FE1C5EA"<br />
| It does not fully access all chromosomes (only ~ 12)<br />
|-bgcolor="#FE1C5EA"<br />
| Analysis of results is dependent upon the dot quality impacted by hybridisation efficiency or the camera sensitivity <ref><pubmed>17970921</pubmed></ref><br />
|-bgcolor="#FE1C5EA"<br />
| some studies indicate that using FISH on a day-3 embryo biopsy decreases the rate of live births <ref><pubmed>26168107</pubmed></ref><br />
|}<br />
<br />
===Array Comparative Genomic Hybridisation (aCGH)===<br />
====Description====<br />
<br />
aCGH also known as Microarray analysis efficiently scans the entire genome for chromosomal imbalances. CGH was initially developed to detect the number of changes in a solid tumor mass. It uses 2 genomes comparing the sample to the control, with each labeled in a different fluorescent dye<ref name="PMID1876176"><pubmed>1876176</pubmed></ref>. Earlier CGH techniques were limited by the resolution of the imaging <ref> Lichter, P., et al. Comparative genomic hybridization: Uses and limitations. Seminars in Hematology 37, 348–357 (2000)</ref> , these initial limitations were overcome by using Microarrays in conjunction with CGh to improve the resolution of the imaging, Array Comparative Genomic Hybridisation (aCGH). This method compares sample and control microarrayed slides containing small segments of DNA (probes). <ref> Lucito, R., et al. Representational oligonucleotide microarray analysis: A high-resolution method to detect genome copy number variation. Genome Research 13, 2291–2305 (2003) </ref> the Probes used will vary according from the small (25-85 base pairs) oligonucleotides manufactured to highlight different target sequences, to the very large genomic clones (80,000- 200,00 base pairs), and as these are significantly smaller than the traditional metaphase chromosomes used for CGH, generating a higher resolution of image. <ref name="PMID22467166"><pubmed>22467166</pubmed></ref>.aCGH is used as a diagnostic tool for prenatal detection f chromosomal abnormalities <ref name="PMID19012303"><pubmed>19012303</pubmed></ref>.<br />
<br />
<br />
====Procedure====<br />
<ref> Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432] </ref><br />
The sample is obtained (skin, blood or fetal cells) and DNA is obtained. <br />
As a part of PGD fetal cell samples are collected from; the fertilized egg polar bodies, the blastomere (day 3 embryo) or the blastocyst/tropoectoderm stage (day 5 embryo).<br />
Sample DNA is labeled with one fluorescent dye, and the control DNA is labeled with a different colored fluorescent dye. the control DNA is used as the base point of reference. <br />
heated and denatured single DNA strands then hybridize to their complementary single strand probes, which are then combined and applied to a microarray and the results are run through a computer program and a digital imaging system is used to quantify the results( fluorescent intensities of the labeled probes). <br />
<br />
[[File:aCGH.jpg|thumb|right|'''aCGH''' checks the entire genome for chromosomal imbalances, by comparing control and a sample slides contatining small segements of DNA sample microarrayed slides small segments of DNA. Illustrated by student z5020317 and adapted from <ref> NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation. retrieved from [http://www.phgfoundation.org/file/5237/]</ref> <ref>Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432]</ref>]]<br />
<br />
<br />
<br />
The fluorescent ratio and the hybridization signal at different locations on the genome of the control DNA are used to identify any variances present in the sample DNA. aCGH facilitates the clinical diagnosis of submicroscopic chromosomal duplication, deletion and rearrangements indicative of chromosomal disorders such as trisomies 1-22and specific sex linked disorders. <br />
Duplications in the DNA are displayed by the computer program as spikes/ peaks over an established threshold and deletions in DNA are displayed by the computer program as spikes/ toughs beneath this threshold <br />
<br />
<br />
<br />
<br />
{|border="1" align="center"<br />
|-bgcolor="pink" <br />
| '''Advantages''' <br />
| '''Disadvantages'''<br />
|-<br />
| multiple applications: prenatal genetic diagnosis, cancer diagnosis, <ref name="PMID20193845"><pubmed>20193845</pubmed></ref> genetic screening for developmental delay (learning disabilities) <ref name="PMID17309648"><pubmed>17309648</pubmed></ref>. or congenital anomalies that are suspected to be genetic in origin <ref>NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation . retrieved from [http://www.phgfoundation.org/file/5237/]</ref><br />
| translocations and inversions of DNA are not detected<br />
|-bgcolor="pink"<br />
| trace represents all chromosomes present in the human genome chromosomes 1-22 and the X & Y chromosomes, and therefore is the most accurate method for testing whole embryo aneuploidy<br />
| limited ability diagnosing specific polyploidies such as triploidy <ref> Unique, Rare Chromosome Disorder Support Group (2013) Microarray-based Comparative Genomic Hybridiation (array CGH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/other/array%20cgh%20ftnw.pdf] </ref><br />
|-<br />
| aCGH has been extensively tested, and Validated, and is now used world wide.<br />
| will not detect mosaicism detection <20% (cultures where >1 of 5 cells are trisomy 12)<br />
|-bgcolor="pink"<br />
| detects deletions and additions and rearrangements as well as amplification, of the WHOLE genome, simultaneously.<br />
| will not detect balanced chromosomal rearrangement<br />
|-<br />
| detects submicroscopic alterations<br />
| will not detect duplications or deletions <80kb<br />
|-bgcolor="pink"<br />
| used as a diagnostic tool for prenatal detection of chromosomal abnormalities <ref name="PMID22034057"><pubmed>22034057</pubmed></ref><br />
| will not detect point mutations within genes <ref>Washington department of education (CGH- FAQ for physicians. Signature Genomic LAboratories, LLC. Retrieved from [https://depts.washington.edu/dbpeds/Lab%20Tests/SignatureCGH-physician_FAQ.pdf]</ref><br />
|-<br />
| provides high resolution genomewide screening of segmental genomic copy number variations<br />
| will not detect chromosomal position of genomic gains<br />
|-bgcolor="pink"<br />
| very accurate when used in conjunction with FISH<br />
| will not detect loos of heterozygosity (LOH) or Absence of heterozygosity (AOH) <ref>WiCell Research Institute Inc. (2012) Comparative Genomic Hybridization Microarray. <br />
retrieved from [http://www.wicell.org/home/cytogenetic-services/cgh-microarray/array-comparative-genomic-hybridization-acgh.cmsx]</ref><br />
|-<br />
|Alone is more reliable and in detecting chromosomal abnormalities, with a higher implantation success rate, than FISH <ref name="PMID20494259"><pubmed>20494259</pubmed></ref><br />
|<br />
|-bgcolor="pink"<br />
|Allows an in depth research focus upon specific types of rearrangements within selected chromosomal regions, a recent particular area of interest is subtelomeric and pericentromeric rearrangements<br />
|<br />
|-<br />
|reduces the risk of failed implantation and miscarriage, improving the chance of a healthy baby <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|<br />
|}<br />
<br />
<br />
<br />
===Next Generation Sequencing===<br />
====Description====<br />
The development and advances within ART in the past 20 years, as well as the increasing popularity of IV, has lead to an influx of new technologies developed to screen embryos for chromosomal anomalies, which are covered by the umbrella term of Next generation Sequencing (NGS). NGS is a general term used to describe all of the new and emerging screening techniques currently being introduced and used as part of PGD for IVF . NGS screens for single gene disorders as well as conducting extensive and very comprehensive chromosome diagnosis by sequencing, counting, and accurately assembling millions of DNA reads, simultaneously. <ref name="PMID23499002"><pubmed>23499002</pubmed></ref> There is a movement for NGS to replace the other limited testing techniques and be used as the standard. <br />
====Procedure====<br />
Samples are collected from either blastomere or the blastocyst/tropoectoderm and processed for analysis by a computer system. <br />
The methodology of each process is unique to the technique being used. <br />
<br />
<br />
<br />
{|border="1" align="center"<br />
|-bgcolor="pink" <br />
| '''Advantages'''<br />
| '''Disadvantages'''<br />
|-bgcolor="white"<br />
| cheaper<br />
| there are limited information available to clinical applications of NGS <ref><pubmed>26100406</pubmed></ref><br />
|-bgcolor="pink"<br />
| opens new diagnostic possibilities<br />
|<br />
|-bgcolor="white"<br />
| accurately tests all 24 chromosomes<br />
| <br />
|-bgcolor="pink"<br />
| tests for the presence of monogenic diseases of known genetic background<br />
| <br />
|-bgcolor="white"<br />
| reduces the number of biopsies required for diagnosis<br />
| <br />
|-bgcolor="pink"<br />
| higher detection rate of small translocations<br />
| <br />
|-bgcolor="white"<br />
| highly accurate is testing for compound point mutations, chromosomal duplication, deletions and insertions <ref name="23312231"><pubmed>23312231</pubmed></ref><br />
| <br />
|-bgcolor="pink"<br />
| it accurately detects chromosomal aneuploidy and unbalanced rearrangement <ref name="PMID25685330"><pubmed>25685330</pubmed></ref><br />
| <br />
|-bgcolor="white"<br />
| NGS single gene disorder screenings can conducted in conjunction with PCR comprehensive chromosomal screening<br />
|<br />
|-bgcolor="pink"<br />
| Reduces human error <br />
|<br />
|-bgcolor="white"<br />
| better detects the presence of mosaicism<br />
|<br />
|-bgcolor="pink"<br />
| work well in conjunction with CGH and aCGH as part of PGD, improving the chances of IVF. <ref> Morris, R. S. (2015 ) Next generation sequencing for PCG|PGS|CCS. IVF1 retrieved from [http://www.ivf1.com/next-generation-sequencing for-pgd] </ref><br />
|<br />
|}<br />
<br />
<br />
<br />
<br />
<br />
<br />
==Diagnosis==<br />
There are a large amount of diseases that PGD can apply to, below are descriptions of the diseases that PGD are more commonly used for. Utilization of Diseased Cell Lines<br />
===Cystic Fibrosis===<br />
Cystic fibrosis is a single gene disorder. It is autosomal recessive and involves mutations in the cystic fibrosis transmembrane conductance regulator (CTFR) gene. The CTFR gene is normally responsible for the decrease in chloride and the transport of bicarbonate in epithelial cells thus playing a major physiological role. In PGD procedures, identification of the gene is assisted by microsatellite markers that have similar composition to the CTFR gene itself. Biopsy of two cells at the blastocyst stage is recommended if markers are not available. There are many variations of cystic fibrosis the most common being P.Phe508del <ref name="PMID26014425"><pubmed>26014425</pubmed></ref>.<br />
===Duchenne Muscular Dystrophy ===<br />
Duchenne Muscular Dystrophy is an X-linked recessive disease. It involves the Xp21 gene where majority of the mutations are chromosomal deletions with a smaller percentage resulting from duplications <ref name="PMID18359022"><pubmed>18359022</pubmed></ref>.<br />
<br />
===Autosomal Recessive MEckel-Gruber Syndrome===<br />
Autosomal recessive genetic defect caused by the TMEM67 gene. It results in cystic dysplasia of the kidneys with fibrotic change in the liber and occipital encephalocele. Other malformations could also be present in the central nervous system. In PGD whole genome amplification of single blastomeres are taken to identify the gene, this is also coupled with PCR techniques. Maternal plasma can also be extracted for PGS. <ref><pubmed>24039893</pubmed></ref> <br />
===β – Thalassemia=== <br />
β – Thalassemia is known as the most common type of autosomal recessive inherited disorder among haemoglobinopathies. It involves the adult β-globin gene and is associated with the absent or decreased expression of the gene. This is commonly caused by a single nucleotide change in the gene. PGD has been used successfully worldwide to identify the β-globin gene where its application is usually performed on a single blastomere or polar body <ref name="PMID19064120">19064120</pubmed></ref>.<br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
! Applicable diseases for PGD <ref>Genoma Group (2014). Retrieved September 18th, 2015, from http://www.preimplantationgeneticdiagnosis.it/genetic-diseases-diagnosed-by-pgd.htm </ref>, <ref>Genesis Genetics (2015). Retrieved September 18th, 2015, from http://genesisgenetics.org/pgd/what-we-test-for/</ref>, <ref>Human Fertilisation & Embryology Authority (2015). Retrieved Septembr 18th, 2015, from http://guide.hfea.gov.uk/pgd/</ref><br />
|-<br />
| '''Disease'''<br />
| '''Involved Genes'''<br />
|-<br />
| 5 Alpha Reductase Deficiency (5ARD)<br />
| SRD5A2 <br />
|-<br />
| Achondroplasia<br />
|FGFR3 <br />
|-<br />
| Acute Intermittent Porphyria <br />
| ALAD, ALAS2, CPOX, FECH, HMBS, PPOX, UROD, or UROS<br />
|-<br />
| Adrenoleukodystrophy (Adrenomyeloneuropathy)<br />
| ABCD1 <br />
|-<br />
| Agammaglobulinaemia (x-linked) <br />
|BTK <br />
|-<br />
| Agammaglobulinemia Bruton Tyrosine Kinase (BTK) <br />
|BTK <br />
|-<br />
| Aicardi Goutieres Syndrome 1 (AGS1) <br />
|TREX1, RNASEH2A, RNASEH2B, RNASEH2C, SAMHD1<br />
|-<br />
| Alagille Syndrome<br />
|JAG1 or NOTCH2<br />
|- <br />
| Alpers-Huttenlocher Syndrome <br />
|POLG <br />
|-<br />
| Alpha-1-antitrypsin deficiency <br />
|SERPINA1 <br />
|-<br />
| Alpha-Mannosidosis<br />
| MAN2B1 <br />
|-<br />
| Alpha Thalassemia <br />
|HBA1 or HBA2 <br />
|-<br />
| Alports Syndrome<br />
|COL4A3, COL4A4, COL4A5<br />
|-<br />
| Alzheimer's Disease - early onset (Type 3 and 4) <br />
|APP, PSEN1, or PSEN2<br />
|-<br />
| Amyotrophic Lateral Sclerosis 1 (ALS1) <br />
|C9orf72, SOD1, TARDBP, FUS, ANG, ALS2, SETX, VAPB <br />
|-<br />
| Argininosuccinic Aciduria <br />
| ASL<br />
|-<br />
| Arrhythmogenic Right Ventricular Cardiomyopathy/ Dysplasia (ARVC/D)<br />
| DSG2; DSP; PKP2<br />
|-<br />
| Ataxia Telangiectasia<br />
| ATM<br />
|-<br />
| Autosomal Recessive Meckel-Gruber Syndrome<br />
| TMEM67<br />
|-<br />
| Bardet-Biedl Syndrome (BBS)<br />
| BBS1; BBS10<br />
|-<br />
| Barth Syndrome<br />
| TAZ<br />
|-<br />
| Beta Thalassaemia<br />
| HBB<br />
|-<br />
| Birt-Hogg-Dubé Syndrome<br />
| FLCN<br />
|-<br />
| Breast Ovarian Cancer Familial Susceptibility (BRCA2)<br />
| BRCA1; BRCA2<br />
|-<br />
| Canavan Disease <br />
| ASPA<br />
|-<br />
| Carnitine-Acylcarnitine Translocase Deficiency <br />
| SLC25A20<br />
|-<br />
| Cerebral Arteriopathy with Subcortical Infarcts & Leukoencephalopathy (CADASIL)<br />
| NOTCH3<br />
|-<br />
| Cerebral Cavernous Malformation<br />
| CCM1<br />
|-<br />
| Charcot-Marie-Tooth Disease<br />
| GJB1; MPZ; NEFL; PMP22<br />
|-<br />
| CHARGE Syndrome<br />
| CHD7<br />
|-<br />
| Cherubism<br />
| SH3BP2<br />
|-<br />
| Choroideremia<br />
| CHM<br />
|-<br />
| Chronic Granulomatous Disease<br />
| CYBB; NCF1<br />
|-<br />
| Ciliary Dyskinesia<br />
| DNAH5<br />
|-<br />
| Citrullinemia<br />
| ASS1<br />
|-<br />
| Cleidocranial Dysplasia<br />
| RUNX2<br />
|-<br />
| Cockayne Syndrome<br />
| ERCC6<br />
|-<br />
| Congenital Adrenal Hyperplasia<br />
| CYP21A2<br />
|-<br />
| Congenital Cataracts<br />
| GJA8; VSX2<br />
|-<br />
| Congenital Diarrhea, Syndromic<br />
| SPINT2<br />
|-<br />
| Congenital Disorders of Glycosylation (CDG)<br />
| ALG1; ALG6; CDG1C; DOLK; PMM2<br />
|-<br />
| Cornelia de Lange Syndrome <br />
| NIPBL<br />
|-<br />
| Craniosynostosis<br />
| TWIST1<br />
|-<br />
| Crouzon Syndrome<br />
| FGFR2<br />
|-<br />
| Cysteinyl Leukotriene Receptor 1 Deficiency <br />
| CYSLTR1<br />
|-<br />
| Cystic Fibrosis<br />
| CFTR<br />
|-<br />
| Diamond –Blackfan Anemia <br />
| RPS19<br />
|-<br />
| Duchenne Muscular Dystrophy <br />
| DMD<br />
|-<br />
| Dyskeratosis congenita (Male embryos only)<br />
| DKC1<br />
|-<br />
| Ectodermal dysplasia (Hypohidrotic)<br />
| EDA; EDA1; GJB6; IKBKG<br />
|-<br />
| Familial Adenomatous polyposis coli (FAP)<br />
| APC<br />
|-<br />
| Familial Dysautonomia<br />
| IKBKAP<br />
|-<br />
| Fanconi Anemia <br />
| FANCA; FANCC; FANCD2; FANCF; FANCG; FANCJ<br />
|-<br />
| Fragile X Syndrome (FRAX)<br />
| FMR1<br />
|-<br />
| Galactosemia <br />
| GALT<br />
|-<br />
| Gangliosidosis<br />
| GLB1<br />
|-<br />
| Glanzmann Thrombasthenia <br />
| ITGA2B<br />
|-<br />
| Glutaric Acidemia (aciduria)<br />
| GCDH <br />
|-<br />
| Glycogen Storage Disease <br />
| G6PC; GAA; SLC37A4<br />
|-<br />
| Haemophilia A<br />
| F8<br />
|-<br />
| Haemophilia B<br />
| F9<br />
|-<br />
| Hereditary Nonpolyposis Colorectal Cancer: Lynch Syndrome<br />
| MLH1; MSH2; MSH6<br />
|-<br />
| Holt Oram Syndrome<br />
| TBX5<br />
|-<br />
| Huntington Disease<br />
| HD<br />
|-<br />
| Hydrocephalus<br />
| L1CAM<br />
|-<br />
| Ichthyosis <br />
| ABCA12; STS<br />
|-<br />
| Incontinentia Pigmenti (IP)<br />
| NEMO<br />
|-<br />
| Joubert Syndrome 5<br />
| INPP5E<br />
|-<br />
| Krabbe Disease<br />
| GALC<br />
|-<br />
| Leber Congenital Amaurosis (LCA)<br />
| CEP290; GUCY2D<br />
|-<br />
| Leigh Syndrome (Infantile Subacute Necrotising Encephalopathy)<br />
| LRPPRC<br />
|-<br />
| Lesch Nyan Syndrome<br />
| HPRT1<br />
|-<br />
| Leukocyte Adhesion Deficiency (Type I)<br />
| ITGB2<br />
|-<br />
| Li-Fraumeni Syndrome<br />
| TP53<br />
|-<br />
| Macular Dystrophy Retinal <br />
| VMD2<br />
|-<br />
| Maple Syrup Urine Disorder (MSUD)<br />
| BCKDHB<br />
|-<br />
| Marfan Syndrome <br />
| FBN1<br />
|-<br />
| Menkes Syndrome<br />
| ATP7A<br />
|-<br />
| Mitochondrial DNA Depletion Syndrom <br />
| POLG; RRM2B; SUCLA2; TK2<br />
|-<br />
| Mucolipidosis type II<br />
| GNPTAB<br />
|-<br />
| Multiple Endocrine Neoplasia<br />
| MEN1; MEN2A; MEN2B<br />
|-<br />
| Multiple Exostoses<br />
| EXT1; EXT2 <br />
|-<br />
| Myotubular myopathy<br />
| MTM1 <br />
|-<br />
| Nail-Patella Syndrome<br />
| LMX1B<br />
|-<br />
| Neurofibromatosis Type 1<br />
| NF1<br />
|-<br />
| Neurofibromatosis Type 2 <br />
| NF2<br />
|-<br />
| Noonan Syndrome<br />
| KRAS, PTPN11; SOS1<br />
|-<br />
| Norrie Disease<br />
| NDP<br />
|-<br />
| Ocular Albinism <br />
| GPR143<br />
|-<br />
| Oculocutaneous Albinism <br />
| OCA2; TYR <br />
|-<br />
| Oculodentaldigital Dysplasia<br />
| GJA1<br />
|-<br />
| Optic Atrophy<br />
| OPA1<br />
|-<br />
| Ornithine Transcarbamylase Deficiency <br />
| OTC<br />
|-<br />
| Osteogenesis imperfeca <br />
| COL1A1; COL1A2<br />
|-<br />
| Osteopetrosis <br />
| CLCN7; OSTM1; TCIRG1<br />
|-<br />
| Pachyonychia Congenita <br />
| KRT16; KRT6A<br />
|-<br />
| Pancreatitis, Hereditary<br />
| PRSS1 <br />
|-<br />
| Papillorenal syndrome <br />
| PAX2<br />
|-<br />
| Phenylketonuria <br />
| PAH <br />
|-<br />
| This table does not cover the complete list of diseases that PGD can be applied to.<br />
|}<br />
<br />
==Laws & Legal status==<br />
<br />
{ class="wikitable" <br />
|-<br />
| Australia<br />
| PGD is currently used to detect serious genetic conditions to improve the outcome of Assisted Reproductive Technologies (ART). In very rare cases it may be used to select an embryo with compatible tissue for a sibling who has a life-threatening disease where other means of treatment is unavailable. This is with the conditions that the use of PGD will not affect the welfare and interests of the child to be born. The parents must also receive adequate counselling and have full understanding of the procedures of PGD. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"> National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art</ref><br />
The use of PGD for sex-selection is prohibited with the exception of reducing the risk of the transmission of serious sex-linked genetic conditions. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"/><br />
|-<br />
| Brazil<br />
| The laws regarding PGD in Brazil are not strictly regulated. They are vague and there is limited information surround the activities of assisted reproduction in general in the country <ref name="PMID25493379"><pubmed>25493379</pubmed></ref>.<br />
|-<br />
| Czech Republic<br />
| The laws in the Czech Republic allow those with a “defined indication in order to exclude risk of serous genetically conditioned disease and defects with embryos before they are implanted into the cavity of the uterus”. Couples that undergo any assisted reproductive treatment including PGD have to be married. Sex-selection is illegal except in regards to serious sex-linked genetic diseases <ref name="PMID24777348"><pubmed>24777348</pubmed></ref>.<br />
|-<br />
| Greece<br />
| In Greece, ART is open to those up to the age of 50 with written consent. It can only be used if a medical necessity is present such as the susceptibility of serious hereditary diseases. Sex selection is banned apart from cases of sex-linked diseases and sexually transmitted diseases <ref name="PMID24777348"/>.<br />
|-<br />
| India<br />
| In India there is a cultural preference for boys thus the Prenatal Diagnostic Techniques (Regulation and Prevention of Misuse) Act was introduced in 1994. This law limits the use of PGD for sex determination except in cases of specific congenital diseases. These laws however are not strictly enforced. <ref>World Health Organisation (2015) Gender and Genetics Retrieved on October 21st 2015 from:http://www.who.int/genomics/gender/en/index4.html</ref><br />
|-<br />
| Portugal <br />
| ART is only available to those who are married or have a similar type of relationship for at least two years. The couples cannot be of the same sex and must be at least 18 years of age. Sex selection is illegal except in cases of sex-linked diseases. The use of PGD is illegal if the predictive value of genetic tests are very low <ref name="PMID24777348"/>.<br />
|-<br />
| Spain<br />
| PGD can be applied to “serious hereditary diseases not amenable to postnatal curative treatment” and “detection of other abnormalities which may compromise the viability of the pre-embryo”. If PGD is to be used for any other purpose authorisation must be acquired <ref name="PMID24777348"/>.<br />
|-<br />
| Sweden <br />
| The use of PGD is strictly regulated and couples must achieve authorisation of the National Board of Health and Welfare. It can only be used it can only be used if the child is at risk to inheriting a serious chromosomal or monogenetic disease. It cannot be used for selection of specific characteristics <ref name="PMID24777348"/>.<br />
|-<br />
| United Kingdom<br />
| Those involved with carrying out the IVF treatment must have a license from the Human Fertilisation and Embryology Authority (HFEA). Only embryos that are approved by the HFEA can be implanted where the embryonic nuclear or mitochondrial DNA cannot be altered with the exception of preventing mitochondrial diseases <ref name="PMID24777348"/>. <br />
|}<br />
<br />
==Future/Current Research==<br />
===Noninvasive Preimplantation Genetic Testing without Embryo Biopsy===<br />
Different parameters of gametes, zygotes, embryos (“vacuoles in sperm heads, spindle position in mature oocytes, cleavage intervals of zygote, and embryo developmental dynamics”) may correlate with aneuploidy rates. This knowledge may be applied in potential noninvasive preimplantation diagnostic methods. Several methods have been proposed and are currently further researched<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Sperm Selection====<br />
Intracytoplasmic morphologically selected sperm injection (IMSI) is common procedure in IVF treatment to improve fertilization rates in patients with poor semen quality. In addition, studies have found that IMSI improves embryo development and that spermatozoa with large vacuoles in their heads correlate with increased aneuploidy rates and disturbed chromosomal structures. Thus, selecting spermatozoa based on morphological hallmarks may decrease aneuploidy rates in the fertilized embryos. As with polar body biopsies, however, this approach will solely be applicable if evidence for severe male detrimental contribution is given<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Blastocoel Fluid Extraction====<br />
In addition, a less invasive retrieval of material for diagnosis could include the extraction of the blastocoel fluid. The cavity of the blastocyst, lined by the trophectoderm, is filled with this blastocoel fluid, which contains metabolites of both trophectoderm and inner cell mass origin. The retrieval does not require a biopsy but merely a small opening to extract the fluid and, thus, causes less harm to the embryo. Multiple studies have applied this method<ref name="PMID22020776"><pubmed>22020776</pubmed></ref> <ref name="PMID23148560"><pubmed>23148560</pubmed></ref> and it may in the future become of clinical relevance.<br />
<br />
<br />
[[File:Aspiration_of_the_Blastocoel_Fluid.jpeg|thumb|Aspiration of the Blastocoel Fluid using a ICSI pipette<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.]]<br />
<br />
<br />
Next to metabolites, the blastocoel fluid can contain DNA. Studies have shown that genomic DNA is present in about 90% of the blastocoel fluid samples tested. Typically the fluid is removed with an ICSI pipette from a day five blastocyst through its mural trophectoderm until the blastocyst fully collapses around the embryo. Several concerns regarding this method in a clinical setting have been raised. The collected DNA may be contaminated by the culture media that contains DNA fractions. The DNA may also be least representative of the actual embryos genome as the DNA may originate from abnormal or degenerated cells. Even though labelled noninvasive, the blastocyst still undergoes manipulation to some degree which may affect its viability. Thus, more research is required until this method can evolve from research to clinical use<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
====Proteomics====<br />
The protein secretome of blastocysts may be representative of its chromosome constitution Recent studies have found biomarkers such as lipocalin-1, interleukin-10, tumor necrosis factor, stem cell factor, and chemokine ligand 13 to be differently secreted by aneuploid blastocyst than by euploid ones. The most significant biomarker appears to be interleukin-10. Paired with novel proteomic technologies and mass spectrometry this knowledge when extended may contribute to a new invasive preimplantation genetic diagnosis method<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Embryo Morphology====<br />
Using time lapse imaging the embryo’s morphology can be closely observed and potential aneuploidy characteristics detected. Such characteristics may include the time of division to five cells, the time between the division from three to four cells, and the duration of the division from one to two and subsequently to three. In addition, the morphological quality of ICM an TE has been positively associated with aneuploidy or euploidy prognosis<ref name="PMID26246880"><pubmed>26246880</pubmed></ref>. These may give rise to an embryo quality screening prior to implantation<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
==References==<br />
<br />
<references/><br />
<br />
<br />
{{StudentPage2015}}</div>Z5017878https://embryology.med.unsw.edu.au/embryology/index.php?title=2015_Group_Project_6&diff=2070072015 Group Project 62015-10-21T06:54:38Z<p>Z5017878: </p>
<hr />
<div>{{ANAT2341Project2015header}}<br />
<br />
<br />
=Preimplantation Genetic Diagnosis and Screening=<br />
==Introduction==<br />
Preimplantation genetic diagnosis (PGD) and screening (PGS) are reproductive options for couples with known family histories of genetic disease or couples undergoing IVF procedures due to infertility issues. PGD can diagnose many genetic disorders caused by known chromosomal abnormalities (number and/or structure) or single gene mutations, and, thus decrease the risk of termination of pregnancy or miscarriages and enable such couples to have an unaffected child<ref name="PMID24907939"><pubmed>24907939</pubmed></ref>. Through major improvements in PGD/S and general laboratory technology, the testing for abnormalities in fetuses has shifted from prenatal diagnosis during the first 2 trimesters <ref> Blackburn, S.L. (2003) '''Maternal, Fetal & Neonatal physiology: a Clinical perspective''' (2nd ed.). Seattle: Saudners </ref>, testing for overall fetal growth, complications of pregnancy, and birth defects<ref> Sadler T.W.(2012) '''Langman's Medical Embryology''' (12th ed.) Philadelphia: Lipincott, Wiliams & Wilkins, a Wolters Kluwer Business </ref>, to an embryonic focus especially in advancements in Artificial Reproductive Technologies (ART)<ref><pubmed>20638568</pubmed></ref>. In 1990 PGD for a recessive X-linked disease resulted in the first live birth<ref><pubmed>2330030</pubmed></ref> and has since been incorporated in clinical routine and applied for a variety of genetic diseases, such as sickle cell anemia, thalassemia, or cystic fibrosis<ref name="PMID24907939"/>.<br />
[[File:Preimplantation Genetic Diagnosis Procedure.jpeg|700px|thumb|centre| Simplified steps for PGD<ref name="PMID24907939"/>]]<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=0e-79qKllqk</html5media><br />
|-<br />
| Preimplantation Genetic Diagnosis<ref>IVF Florida (2011, December 11) IVF Florida - South Florida Fertility Specialists - Pre-Implantation Genetic Diagnosis [Video file]. Retrieved from https://www.youtube.com/watch?v=0e-79qKllqk</ref><br />
|}<br />
<br />
==History==<br />
The advances in reproductive technology during the second half of the 20th century, led to PGD's first clinical application in 1990 <ref>Harper, J. (n.d.). The history of PGD. Lecture. UCL Centre for PG&D and CRGH.University College London</ref>.<br />
{|class="wikitable"<br />
|-bgcolor="DDCEF2"<br />
|Year<br />
|<br />
|- bgcolor="FFFAFA"<br />
| '''1967''' <br />
|First PGD on rabbit blastocysts (Gardner& Edwards) <ref name="PMID6036172"><pubmed>6036172</pubmed></ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1986''' <br />
|First Cleavage Biopsy (Wilton & Trounson)<ref>Wilton, L. J., & Trounson, A. O. (1986). Viability of mouse embryos and blastomeres following biopsy of a single cell. In Proceedings of the 18th Annual Conference of the Australian Society for Reproductive Biology, Brisbane, Australia.</ref><br />
|- bgcolor="FFFAFA"<br />
|'''1987''' <br />
|First Blastocyst Biopsy (Muggleton-Harris, Monk, Rawlings, & Whittingham)<ref name="PMID3372699"><pubmed>3372699</pubmed></ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1988''' <br />
|First Polar Body Biopsy (Yury Verlinksy)<ref> Verlinsky, Y., Pergament, E., Andresen, P., Enriquez, G., & Strom, C. (1989). Genetic analysis of polar body DNA: A new approach to preimplantation genetic diagnosis. Am J Hum Genet, 45(4), A272.</ref> <br />
|- bgcolor="FFFAFA"<br />
|'''1990''' <br />
|First Clinical PGD using PCR testing for X-linked (Handyside, Kontogianni, Hardy, & Winston)<ref name="PMID2330030"><pubmed>2330030</pubmed></ref> <br />
|} <br />
==Preimplantation Genetic Diagnosis==<br />
Preimplantation genetic diagnosis (PGD) is used to test the genetic makeup of embryos to detect single gene disorders, chromosomal abnormalities and mitochondrial disorders. It also has applications in gender selection for diseases with unequal gender distributions <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Some diseases commonly involved with PGD include cystic fibrosis, spinal muscular atrophy and beta – thalassaemia <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press.">Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press</ref> <ref name="PMID17823145"><pubmed>17823145</pubmed></ref>. It was first used in the United Kingdom in the 1980s of arenoleucodystrophy and primarily focusing on sex- linked disorders <ref name="PMID17823145"/><ref name="PMID23150080"><pubmed>23150080</pubmed></ref>. PGD is now capable of detecting single cell defects (molecular) and chromosomal disorders resulting from the inversion, translocation or deletion of chromosomes (cytogenic) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>,<ref name="PMID11325751"><pubmed>11325751</pubmed></ref>. PGD can be applied to the embryo at different stages. That is on polar bodies, blastomeres or blastocyst <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>.<br />
Depending on the type of genetic disorder, PGD utilises different methods of genetic testing. These include Fluorescence in situ hybridisation (FISH) which is used for sex – linked disorders and detects chromosomal rearrangements <ref name="PMID11325751"/><ref name="PMID17876073"><pubmed>17876073</pubmed></ref> and Embryo halotyping which allows the identification of chromosomes causing the inherited disorder through knowledge of the pattern of closely linked markers <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. Polymerase chain reaction (PCR) is also widely used to detect molecular abnormalities <ref name="PMID11325751"/>.<br />
PGD is tightly regulated and supported by large organisations namely The American Society for Reproductive Medicine, The European Society for Human Reproduction and Embryology (ESHRE), The European Society of Human Genetics and the Preimplantation Genetic Diagnosis International Society <ref name="PMID25500181><pubmed>25500181</pubmed></ref>.<br />
===Sex-linked disorders===<br />
The determination of a disease as gender specific usually correlates with the presence or absence of specific genes such as SRY on the Y chromosome. It is known that females have two X chromosomes and males have an X and a Y chromosome where abnormalities are more prevalent on the X chromosome. PGD can be used for sex selection where only male embryos are transferred to reduce the chance of inheriting X-linked disorders. However, this does not completely eradicate the problem as male embryos remain susceptible to inheriting an affected X chromosome. Sex determination is only used when the specific mutation is unknown and has yet to be discovered <ref name="PMID24866878"><pubmed>24866878</pubmed></ref>.<br />
===Single gene defects===<br />
Single gene defects can be dominant, recessive, autosomal or X-linked. They are commonly diagnosed using PCR and although the PCR available today is complex and capable of combatting a large range of disease the development of new protocols has been proven to be difficult due to the small DNA sample available <ref name="PMID26168107"><pubmed>26168107</pubmed></ref><br />
===Mitochondrial disorders===<br />
Mitochondrial disorders also known as oxidative phosphorylation disorders arise from mutations in the nuclear DNA or mitochondrial DNA <ref name="PMID26312584"><pubmed>26312584</pubmed></ref>. They pose as a problem because they are unrecognisable until the mutations in the cell reach a detrimental level <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Mitochondrial disorders cause miscarriages and stillbirths as well as death in children and young adults. The effects can either be contained in a single organ or more commonly involve multiple organ failure where organs with high energy demands such as the brain, liver muscle and heart and heavily influenced. They are usually occur spontaneously or result from inheritance from the mother. Since mitochondria are solely inherited from the mother oocyte donations have been used as a solution to combat mitochondrial disorders. Additionally, there has been an increasing use in PGD where embryos that stay under the given threshold of 18% gene-mutations are allowed to be transferred and result in normal development. New technology in the areas of nuclear gene transfer and genome editing are also being experimented with <ref name="PMID26312584"/>. <br />
===Chromosomal disorders===<br />
Chromosomal disorders can be reciprocal, Robertsonian translocations, inversions, deletions and insertions <ref name="PMID26168107"/>. . Data from ESHRE collected between 2010 and 2011 has shown that the most common chromosomal abnormality confronted in PGD are reciprocal chromosomal abnormalities <ref name"PMID26071418"><pubmed>26071418</pubmed></ref>. PGD has also been used successfully for Robertsonian translocations (RT), a type of structural translocation. Children who carry RT are phenotypically normal, however in their later years it is found that they will suffer from infertility and repeated miscarriages due to the high frequency of abnormal embryos <ref name="PMID22081077"><pubmed>22081077</pubmed></ref>. PCR and FISH are the two main techniques used for chromosomal disorders. To be able to conduct the examinations the cells are required to be at the metaphase stage <ref name="PMID26168107"/>. <br />
==Preimplantation Genetic Screening==<br />
Prenatal Genetic Screening (PGS) involves an array of methods or ideas that aim to segregate embryos that have genetic flaws and those that are healthy <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. The occurrence of aneuploidy is high around the stages of early embryonic development and they are the most common cause if miscarriages and congenital birth defects <ref name= "PMID26085841"><pubmed>26085841</pubmed></ref>. They have little effect on the morphology of the embryo making them difficult to identify thus identification heavily relies on genetic testing <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. <br />
Genetic sampling is most commonly conducted using Microarray Comparative Genomic Hybridisation (aCGH) as well as FISH, Quantitative PCR and Single Nucleotide Polymorphism (SNP) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. These methods collectively aim to assess numeral and structural chromosomal errors <ref name= "PMID26085841"/>. Studies have also introduced Next- Generation Sequencing (NGS) <ref name= "PMID26085841"/> and Whole Genome Amplification used to screen imbalances in the complete 24-chromosomes <ref name="PMID25953353"><pubmed>25953353</pubmed></ref><br />
Statistics from ESHRE have shown that the most common indications for PGS is advanced age, followed by repeated implantation failure or recurrent miscarriage and male infertility <ref name="PMID26071418"><pubmed>26071418</pubmed></ref>.<br />
====Indications====<br />
A low percentage of structural abnormalities in chromosomes are responsible for the cause of miscarriages. Despite this, they are the most prevalent type of chromosomal abnormality accounted for in PGD <ref name="PMID20638568"/>. The presence of specific gene cycles, initiation of embryonic protein synthesis and evident physiological development are all indicative of a successful in vitro fertilisation procedure <ref name="PMID11576737"><pubmed>11576737</pubmed></ref>. To eliminate further errors from occurring during the PGD procedure it is recommended to undertake further prenatal testing such as amniocentesis in the later stages <ref name="PMID20638568"/>. <br />
=====Advanced maternal age=====<br />
Data provided by the ESHRE has shown that the mean age of women undergoing PGS is 39 years <ref name="PMID26071418"/>. Women of advanced age have been shown to have a lower rate of pregnancies reaching childbirth <ref name="PMID18583331"><pubmed>18583331</pubmed></ref>. The highlighted concern revolves around the increased occurrence of aneuploidy following maternal age. The optimal age range for the lowest aneuploidy incidence was found to be between 27 to 37 years of age (6%) then progressively higher in women aged up to 42 (33%) and most common in those 44 and above (53%) <ref name="PMID24355045"><pubmed>24355045</pubmed></ref>. <br />
=====Recurrent pregnancy loss / IVF failure=====<br />
Recurrent pregnancy loss is defined as three or more IVF failures after cumulative transfer of more than 10 good-quality embryos. These are primarily caused by two main factors, reduced endometrium receptivity or embryonic defects. Endometrium receptivity can be negatively influences by instances including uterine pathologies such as thin endometrium, altered expression of adhesive molecules and immunological factors. Additionally, embryonic defects may be due to genetic abnormalities, embryonic aneuploidy or zona hardening. Endometriosis and hydrosalpinx has been known to effect both the endometrium and embryo <ref name="PMID23260857"><pubmed>23260857</pubmed></ref>.<br />
=====Human leukocyte antigen matching=====<br />
First used in 2001, HLA matching is an option given to parents to save a child with haematological or immunological disease through conceiving another child who would potentially be able to donate cord blood or haematopoietic stem cells from the bone marrow for transplantation. The process namely PGD-HLA has shown to improve haematopoietic stem cell transplant (HSCT). PGD-HLA can only be performed when HSCT is not needed urgently due to the time needed to conceive and delivery the baby <ref name="PMID25500181"><pubmed>25500181</pubmed></ref>. It is most commonly applied to children suffering from relapsed leukaemia <ref name="PMID22524201"><pubmed>22524201</pubmed></ref>. In a case study PGD-HLA was proven to successfully cure 10 diseases including Fanconi anaemia, Diamond-Blackfan anaemia and beta thalassemia <ref name="PMID25066893><pubmed>25066893</pubmed></ref>.<br />
==Biopsy Methods==<br />
Biopsy, the removal of genetic materials, from oocytes or embryos in the preimplantation stage is the primary step in PGD. For the past two decades these biopsies have been performed at three stages, the polar body, blastomere, and blastocyst, and the methodologies optimized to ensure the embryo’s viability. The most common approach involves biopsies at the cleavage stage. However, polar body and blastocyst biopsies are increasingly more often tested and applied. Approached for opening the zona pellucida involve next to the traditional mechanical and chemical means, novel approaches such as noncontact lasers. Their application may simplify and secure the procedure significantly. The most challenging question about PGD procedures remains at what stage biopsies should be taken. Much controversy has developed around this topic, highlighting the varying disadvantages and advantages of temporal biopsies. <ref name="PMID22723007"><pubmed>22723007</pubmed></ref><br />
<br />
{| class="wikitable"<br />
|- align="center" bgcolor="DDCEF2"<br />
|<br />
| Time of Biopsy<br />
| Advantages <br />
| Disadvantages<br />
|- bgcolor="FFFAFA"<br />
| Polar Body<br />
| Day 1<br />
| No harm to oocyte<br />
| Only maternal DNA is tested, often needs to be coupled with other biopsies<br />
|- bgcolor="FFFAFA"<br />
| Blastomere<br />
| Day 3<br />
| …<br />
| … <br />
|- bgcolor="FFFAFA"<br />
| Trophectoderm<br />
| Day 5 and 6 <br />
| Little harm, large amount of genetic material<br />
| Opening of blastocyst necessary, small time window for procedure<br />
|}<br />
<br />
<br />
[[File:Polar_Body,_Blastomere,_and_Trophectoderm_Biopsy.jpeg|thumb|Polar body (A), blastomere (B) and trophectoderm (C) biopsies<ref name="PMID25625041"><pubmed>25625041</pubmed></ref>.]]<br />
<br />
<br />
<br />
PMID 24305177<br />
===Polar Body Analysis===<br />
Day 1<br />
====Description====<br />
Polar body (PB) biopsy, which was introduced in 1990, offers a promising alternative to biopsies performed at the blastomere stage for PGD/S indications on legal and practical grounds. <br />
Description: Consequent embryo development does not necessitate the presence of the first and second PB and their removal may not be crucial. PB biopsy requires precise timing. Keeping track of the meiotic cell cycle is necessary to perform a successful biopsy and, therefore, PB biopsy usually is applied in combination with intracytoplasmic sperm injection (ICSI). During the maturation from the germinal vesicle stage to the metaphase-II stage the first PB is formed. A cytoplasmic bridge containing spindle remnants, that are still in contact with the cellular genetic material, links this PB to the oolemma for about 90 minutes after extrusion. It is possible to visualize these remnants by polarization microscopy and it is crucial to not perform the biopsy until the first PB is no longer firmly attached to the oolemma as this indicates an immature embryo.The oocyte tolerates mechanical zona dissection best during hours four until six after ICSI as the oolemma has stabilized by that time because of the cortical granule reaction. Over time the first PB degenerates stressing a temporal biopsy and its optimal extraction time window is four to 12 hours after ICSI. The second PB forms around two to four hours after ICSI. However, its optimal time window for biopsy is set to be eight to 16 hours after ICSI. This is due to the second PB being attached to the oolemma with spindle remnants until six hours after ICSI. Biopsy at this point may cause enucleation of the oocyte. In addition, studies have shown that the amplification efficiency of second PB’s DNA is worse if the PB is extracted prior to eight hours after ICSI. <br />
Thus, it is possible to perform sequential and simultaneous biopsies for the first and second PB. If performed, sequentially the first PB may be removed four to 12 hours and the second PB eight to 16 hours after ICSI. The optimal time window for a biopsy for both the first and second PB simultaneously is eight to 12 hours after ICSI. It is highly preferred to analyze both PBs due to potential aneuploidies in either PB and crossing overs during meiosis<ref name="PMID22723007"/>. <br />
====Procedure====<br />
Chemical opening achieved with for example acidic tyrode’s solution of the zona pellucida is not tolerated by the oocyte and may have detrimental effects on the embryo’s development. Therefore, the access to the perivitelline space of the oocyte is provided by mechanical zona dissection or by laser. Both techniques work well if performed by experienced embryologist. However, laser-assisted biopsy is less time consuming when compared to manual dissection. It is critical to consider the size of the introduced opening as it will remain permanent. If it is too large the blastomere may be lost during embryo development and if it is too small it may interfere with hatching of the embryo during blastocyst stage<ref name="PMID22723007"/><br />
<br />
[[File:Polar_Body_Biopsy.jpeg|thumb|The presence of a faint but clearly identifiable strand connecting PB2 to the <br />
oolemma. The biopsy was performed ∼9 h after ICSI<ref name="PMID21908464"><pubmed>21908464</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JTaQzszVr8o</html5media><br />
|-<br />
| Laser-assisted polar body biopsy<ref>RIUK, R. (2013, June 25) Polar Body Biopsy [Video file]. Retrieved from https://www.youtube.com/watch?v=JTaQzszVr8o</ref><br />
|}<br />
<br />
====Advantages & Disadvantages====<br />
PB biopsies can only investigate the maternal contributions to the embryo as they are of maternal origin. Thus, this procedure is appropriate for PGD solely for monogenetic diseases from the maternal side. Recessive diseases may be evaluated with PB biopsies on the basis that the embryo’s outcome will be determined by the paternal contribution. (...) It may still be applied for PGS as most aneuploidies either arise during meiosis or origin from the maternal genome. However, diagnosis error has been reported due to the lack of considering paternal contributions. <br />
Because PB biopsies are performed very early it is not yet known whether the oocyte will develop into a viable embryo. Thus, PBs are commonly frozen or fixed after biopsy and depending on the state of the embryo only chosen PBs will be tested. This is primarily an economic issue as many genetic testing procedures are very cost-intensive<ref name="PMID22723007"/>.<br />
<br />
[[File:Implantation_predictive_value_of_euploid_screening_results.jpeg|thumb|The sustained implantation predictive value (with 95 % confidence interval) of a euploid screening result obtained from the first polar body (PB1), PB1 and the second polar body (PB2), or a direct embryo biopsy for each stage of embryo transfer (cleavage-stage and blastocyst stage)<ref name="PMID25106935"><pubmed>25106935</pubmed></ref>.]]<br />
<br />
===Blastomere biopsy===<br />
Day 3 <br />
====Description====<br />
Blastomere biopsy has been the prevalent method for PGD and PGS in the last two decades. At least one, but up to two, blastomeres are biopsied on day three of the cleavage stage embryo. The right number of blastomeres removed is a controversial topic as two cells allow for more genetic material and more accurate results. However, removing two cells might be too invasive and damaging to the embryo. (Study)<ref name="PMID21748341"><pubmed>21748341</pubmed></ref><br />
====Procedure====<br />
Initially a hole was drilled into the zona pellucida using acid tyrodes and the blastomeres are removed via aspiration with a pipette<ref name="PMID21748341"/>.<br />
<br />
<br />
[[File:Aspiration_of_a_Blastomere.jpeg|thumb|Aspiration of a Blastomere into the biopsy pipette<ref name=" PMID24783200"><pubmed>24783200</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=TbridWVwipI</html5media><br />
|-<br />
| Laser-assisted blastomere biopsy<ref>Sukprasert, M. (2014, March 5) Day 3 Blastomere Biopsy 1 [Video file]. Retrieved from https://www.youtube.com/watch?v=TbridWVwipI</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
===Trophectoderm biopsy===<br />
Day 5 and 6<br />
====Description====<br />
The improvement of embryo culture media allowed the in vitro development of human embryos until the blastocyst stage and opened up the possibility to take blastocyst biopsies. During day three to day five the haploid maternal and paternal genomes work together for the first time to form the genome of the embryo. The maternal epigenetic control lessens significantly while preparing for implantation with precisely arranged events happening. The first event includes a rapid increase in the number of embryonic cells which are active in mitotic divisions and apoptosis of aberrant cells. This is followed by the formation of blastocoel (cavitation) which results from the flattening of cell located on the outside of the blastomere. Now the blastocyst will expand until the embryo hatches by rupturing the zona pellucida. The cells of the blastocyst will differentiate to form two distinct cell lineages, the outer trophectoderm and the inner cell mass<ref name="PMID22723007"/>.<br />
====Procedure====<br />
Trophectoderm biopsy is usually performed in Hepes buffered biopsy medium and opening approaches include needle cutting which has been replaced by lasers in past years. Different research groups report different timings of the opening to be the most successful. Some open the blastocyst on day three or four by creating a 25 µm which causes the trophectoderm to herniate through this hole and is, thus, accessible for biopsy. Others create this hole about four hours before biopsy which allows sufficient herniation of trophectoderm cells. It is also possible to open the blastocyst immediately before biopsy. This avoids an extra step and the inner cell mass usually is easy to locate. Blastocyst biopsies involve the removal of trophectoderm cells and the ideal time for the procedure is day five. Successful biopsies on day six have been performed, while little is known about the results of biopsies on day seven. However, since the window of implantation in humans is from day eight to ten after ovulation, day seven biopsies appear to be possible<ref name="PMID22723007"/>.<br />
-collapse of trophoblasts<br />
-possible: biopsy of hatched blastocyst, holding pipette careful mild suction force to hold embryo near ICM <br />
-Cryopreservation<br />
<br />
<br />
[[File:Microscopic images of human blastocysts for biopsy.jpeg|thumb|(A) Some trophectoderm cells in a blastocyst started to hatch and (B) the trophectoderm cells were biopsied with assisted laser cutting. Images in C–D show the blastocysts after vitrification and warming. Blastocysts had been cultured for 2–4 hrs after warming, showing good (ICM and trophectoderm cells) hatched (C) and hatching (D) blastocysts. The hatching blastocyst in (E) has good ICM but fair trophectoderm while the blastocyst in (F) has both fair ICM and trophectoderm. Arrows indicate ICMs and arrow heads indicate trophectoderm cells. Bar = 40 µm<ref name="PMID2190846"><pubmed>2190846</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JI_TQ8d8tNM</html5media><br />
|-<br />
| Laser-assisted blastocyst biopsy (at 00:50 min)<ref>Coco, R. (2014, April 30) Trophectoderm biopsy in a Hatching blastocyst protruding ICM [Video file]. Retrieved from https://www.youtube.com/watch?v=JI_TQ8d8tNM</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
Blastocyst biopsies are believed to be less damaging to the embryo and appear to be unrelated to implantation rates. In addition, this biopsy method allows for a larger extraction of cells for genetic testing. However, since they are performed late in in vitro development, the time window for genetic testing is relatively small. Fast and accurate genetic testing methods are needed to ensure a successful and safe result from this biopsy. Thus, blastocyst biopsies may gain more popularity in the future whn such methods have been developed or improved<ref name="PMID22723007"/>. <br />
<br />
<br />
==Genetic Techniques==<br />
<br />
===PCR===<br />
====Description====<br />
Polymerase chain reaction (PCR) amplifies DNA specific to genetic sequence of interest . PCR was developed by Kay Mullis in the 1980s, for which he was awarded the Nobel prize for chemistry in 1993. <ref> Pubmed Docs (2015) Polymerase Chain Reaction (PCR) Pubmen. Retrieved from [http://www.ncbi.nlm.nih.gov/probe/docs/techpcr/]</ref> This technique enables clinicians to monitor and diagnose diseases using minute samples such as embryonic cells, blood & tissue. <ref>Roche (2015) PCR: How We Copy DNA. Roche Molecular Systems Inc. retrieved From [http://molecular.roche.com/pcr/Pages/Process.aspx]</ref> PCR has many important applications like DNA fingerprinting, genetic mapping, detection of viruses and bacteria as well as being used to detect genetic disorders, as a part of PGD, in conjunction with IVF. It is used to detect molecular abnormalities such as single gene disorders like Tay Sach, Cycstic fibrosis, Duchenne Muscular Dystrophy, Thalassemia, Huntington disease, Spinal muscular atrophy and many more. Molecular and Genetic analysis require a significant amount of DNA, which we would not have without PCR. It revolutionized the study of DNA, replacing all previous recombinant DNA technology. <ref> Mullins, K., Francois, F.& Gibbs R.A. (1994 ) The Polymerase Chain Reaction. p3. Springer- Science +Business Media. Birkhauser, Boston<br />
Available at [https://books.google.com.au/books?hl=en&lr=&id=gjrTBwAAQBAJ&oi=fnd&pg=PR5&dq=kary+mullis+PCR&ots=mpzAyRh5ZY&sig=PQ4goNoKJ90tb3-MkPk62zrTGbw#v=onepage&q=kary%20mullis%20PCR&f=false] </ref> <br />
<br />
[[File:PCR.jpg|thumb|right|Polymerase chain reaction (PCR) amplifies DNA specific to genetic sequence of interest, enabling the monitoring and diagnose molecular abnormalities such as single gene disorders using minute samples such as embryonic cells, blood & tissue <ref>NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref>]]<br />
<br />
====Procedure====<br />
<br />
Sample are obtained from the the blastocyst, a polar body biopsy or the blastomeres stages of the embryo. <br />
Stage 1 Denaturing: separating the target strands of DNA <br />
The obtained sample is heated to roughly 90 degrees celcius, this heat causes breaks the relatively weak bonds between nucleotides that form DNA. the double stranded DNA to split into 2 single strands of DNA that are used as templates.<br />
Stage 2 Annealing: Binding the Primers to the target DNA sequence <br />
PCR will only copy the target sequence of DNA specified by specific PCR primer. These synthesized primers Oligonucleotides are small artificial pieces of DNA. <br />
TAQ polymerase enzyme synthesize 2 new strands of DNA duplicate to the single sample DNA stand template indicated by these primers. During this stage the reaction is cooled to a temperature between 40-60 degrees Celsius. <br />
Stage 3- Extension- making copies <br />
Each of these 2 copies are then used again as templates generating 2 further replications This cycle can occur as many 30 -40 times within a couple hours leading to billions of extra copies of the original DNA segment. The optimal temperature for the further replication is roughly 72 degrees Celsius. <br />
<br />
This process mediated by a thermocycler machine that is programmed to alter the temperature of the reaction every couple of minutes, perpetuating the cycle of DNA denaturing and synthesis. <br />
This process, generates exponential exact copy of the original template DNA sequence. <br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
!PCR cycles<br />
<br />
|{|<br />
|-<br />
| '''PCR Cycle'''<br />
| '''Target Copies'''<br />
|-<br />
| 1<br />
| 2<br />
|-<br />
| 2<br />
| 4<br />
|-<br />
| 3<br />
| 8<br />
|-<br />
| 4<br />
| 16<br />
|-"<br />
| 5 <br />
| 32<br />
|-<br />
| 6 <br />
| 64<br />
|-<br />
| 7 <br />
| 128<br />
|-<br />
| 8<br />
| 256<br />
|- <br />
| 9<br />
| 512 <br />
|-<br />
| 10<br />
| 1024<br />
|-<br />
| 15<br />
| 32,768<br />
|-<br />
| 20 <br />
| 1,048,578<br />
|-<br />
| 25<br />
| 33,554,432<br />
|-<br />
| 30 <br />
| 1,073,741,842<br />
|-<br />
|}<br />
<br />
<br />
<br />
{| class="wikitable" <br />
|-bgcolor="#9ACD32" <br />
| rowspan="10" |'''Advantages'''<br />
|-bgcolor="#F0FFF0"<br />
| fast and inexpensive way of copying a target sequence of DNA<br />
|-bgcolor="#F0FFF0"<br />
| aids the diagnosis of single cell defects<br />
|-bgcolor="#F0FFF0"<br />
| rapid generation of results within a couple hours<br />
|-bgcolor="#F0FFF0"<br />
| can start from a single molecule of DNA, therefore is more sensitive <br />
|-bgcolor="#F0FFF0"<br />
| has a flexible primer design enabling<br />
|-bgcolor="#F0FFF0"<br />
| overcame previous issues associated with the limited availability of sites of end<br />
|-bgcolor="#F0FFF0"<br />
| generates the DNA copies exponentially<br />
|-bgcolor="#F0FFF0"<br />
| enables DNA amplification required for molecular and genetic analysis<br />
|-bgcolor="#F0FFF0"<br />
|Valid diagnostic method in selecting unaffected embryos for embryo transfer <ref> Dreesen, J., Drusedaul, M., Smeets, H., Die-Smulders, C., Coonen, E., Dumoulin, J., Gielen, M., Evers, J., Herbergers, J. & Geradets, J. (2008) Validation of preimplantation genetic diagnosis by PCR analysis: genotype comparison of the blastomere and corresponding embryo, implications for clinical practice. Mol. Hum. Reprod. 14 (10):573-579.doi: 10.1093/molehr/gan052. Retrieved from [http://molehr.oxfordjournals.org/content/14/10/573.short] </ref> <ref><pubmed>20966460</pubmed></ref><br />
|-bgcolor="#9ACD32"<br />
| rowspan="5"|'''Disadvantages'''<br />
|-bgcolor="#F0FFF0"<br />
| only during this exponential DNA replication phase can we determine the starting quantity sequence contained in the original sample ( template DNA strand)<br />
|-bgcolor="#F0FFF0"<br />
| PCR reaction is limited by the presence of inhibitors present in the sample : reagent inhibitors <br />
|-bgcolor="#F0FFF0"<br />
| self annealing due to the accumulation of the product -stopping exponential amplification for the target sequence and reach a plateau<br />
quantification of the end point of reaction of PCR products unreliable - therefore that is why we require real time quantitative RT-PCR necessary<br />
<ref> NIS (2015) Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref><br />
|}<br />
<br />
<br />
===Fluorescent In Situ Hybridisation (FISH)===<br />
<br />
<br />
====Description====<br />
Fluorescence in situ hybridization (FISH) the one of the most effective and rapid <ref name="PMID26338801"><pubmed>26338801</pubmed></ref> Preimplantation Genetic Diagnosis (PGD). This techniques used to locate a specific DNA sequences within a chromosome. FISH facilitates the clinical diagnosis of chromosomal abnormalities indicated by sequential duplications, deletions and rearrangements of chromosome, that are usually missed with microscopic analysis. This technique is especially relevant for female embryos with X-linked diseases,<ref name="PMID20809319"><pubmed>20809319</pubmed></ref> that have no other mutation specific tests [http://www.ncbi.nlm.nih.gov/pubmed/20809319] As part of PGD, samples are collected from various stages of the embyro,and they are able to conducted tests on the blastocyst, a polar body biopsy and the blastomeres <ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. FISH is 99% effective when used in conjunction with competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities<ref name="PMID26338801"/>.<br />
<br />
====Procedure==== <br />
<br />
Samples are collected from either the blastocyst, a polar body biopsy or the blastomeres stages of the embryo <ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
DNA strands are heated and denatured causing their the individual DNA strands to break apart<br />
Probes are single complimentary stands of DNA a that have been tagged with small chemical agents that glow brightly in the presence of a specific region on a chromosome. These specific probes then hybridize and join to their complementary DNA strand. <br />
The fluorescent tags enable the researchers to correctly identify the presence or lack thereof and location of the specific chromosomes that they are testing for. <ref name="PMID17876073"><pubmed>17876073</pubmed></ref><br />
Researcher analyse the results by identifying the number and the relative location of the fluorescent dots generated by the FISH images.<ref name="PMID17970921"><pubmed>17970921</pubmed></ref><br />
The probe will not fully hybridise if there has been a duplication or a deletion of the DNA - indicating chromosomal and sex chromosomal anomalies like trisomies and aneuploidies. <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref><br />
<br />
<br />
Different probes are used for different purposes: <ref>Unique, Rare Chromosome Disorder Support Group (2013) Fluorescence in situ hybridisation (FISH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/Other/FISH%20FTNW.pdf]</ref><br />
*'''Locus specific tags''' detect very small imbalances, and locate isolated small portions <br />
of genes within a chromosome<br />
*'''Alphoid/Centomeric Repeat probes''' are developed from the repetitive sequence located in the middle region of each chromosome, useful in determining the number of chromosomes , detecting rearrangement and when used in conjunction with locus probes to determine the absence of genetic material on a chromosome. <br />
*'''Paint Probes''' are collections of smaller probes with their own stains that bind to a different section on the chromosome - allowing the full chromosome too be labeled a unique colour, this "full colour map" can be used to know the spectral karyotype- full chromosomal mapping is useful in examining chromosomal abnormalities. <br />
<br />
[[File:Fluorescent In Situ Hybridisation (FISH).jpg|thumb|right|'''FISH''' We are able to tag Specific DNA sequences using Probes which have been tagged with fluorescent Labels.This technique enables the clinical diagnosis of chromosomal abnormalities, indicated by sequential duplication, deletions and rearrangements of chromosome <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref>]]<br />
<br />
{|class="wikitable" align="center"<br />
|-bgcolor="pink" <br />
| rowspan="8" |'''Advantages''' <br />
|-bgcolor="#FDE1F2" <br />
| FISH is 99% effective when used in conjunction with Competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities.<ref><pubmed>26338801</pubmed></ref><br />
|-bgcolor="#FDE1F2" <br />
| Rapid generation of results<br />
|-bgcolor="#FDE1F2" <br />
| Identifies very small translocations and aneuploidies that occur within chromosomes, that would usually be missed under microscopic analysis<br />
|-bgcolor="#FDE1F2" <br />
| Indicates whether the accessed chromosomes are normal <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|-bgcolor="#FDE1F2" <br />
| Tests for the most common chromosomal abnormalities - down syndrome chromosomes 13,16,18,21 and 22 <ref><pubmed>21749752</pubmed></ref><br />
|-bgcolor="#FDE1F2" <br />
| It may be used to compare the chromosomal gene arrangements in related species<br />
|-bgcolor="#FDE1F2" <br />
| can be used to identify and remove inheritable X-linked disease or sex chromasome anomalies such as Duchennes Muscular Dystrophy, hemophilia, ectodermal dysplasia <ref><pubmed>17876073</pubmed></ref><br />
|-bgcolor="#FEB745"<br />
| rowspan="5"|'''Disadvantages'''<br />
|-bgcolor="#FE1C5EA"<br />
| FISH destroys all cells tested <ref> O'Connor, C. (2008) Fluorescence in situ hybridization (FISH). Nature Education 1(1):171. retrieved from [http://www.nature.com/scitable/topicpage/fluorescence-in-situ-hybridization-fish-327] </ref><br />
|-bgcolor="#FE1C5EA"<br />
| It does not fully access all chromosomes (only ~ 12)<br />
|-bgcolor="#FE1C5EA"<br />
| Analysis of results is dependent upon the dot quality impacted by hybridisation efficiency or the camera sensitivity <ref><pubmed>17970921</pubmed></ref><br />
|-bgcolor="#FE1C5EA"<br />
| some studies indicate that using FISH on a day-3 embryo biopsy decreases the rate of live births <ref><pubmed>26168107</pubmed></ref><br />
|}<br />
<br />
===Array Comparative Genomic Hybridisation (aCGH)===<br />
====Description====<br />
<br />
aCGH also known as Microarray analysis efficiently scans the entire genome for chromosomal imbalances. CGH was initially developed to detect the number of changes in a solid tumor mass. It uses 2 genomes comparing the sample to the control, with each labeled in a different fluorescent dye<ref name="PMID1876176"><pubmed>1876176</pubmed></ref>. Earlier CGH techniques were limited by the resolution of the imaging <ref> Lichter, P., et al. Comparative genomic hybridization: Uses and limitations. Seminars in Hematology 37, 348–357 (2000)</ref> , these initial limitations were overcome by using Microarrays in conjunction with CGh to improve the resolution of the imaging, Array Comparative Genomic Hybridisation (aCGH). This method compares sample and control microarrayed slides containing small segments of DNA (probes). <ref> Lucito, R., et al. Representational oligonucleotide microarray analysis: A high-resolution method to detect genome copy number variation. Genome Research 13, 2291–2305 (2003) </ref> the Probes used will vary according from the small (25-85 base pairs) oligonucleotides manufactured to highlight different target sequences, to the very large genomic clones (80,000- 200,00 base pairs), and as these are significantly smaller than the traditional metaphase chromosomes used for CGH, generating a higher resolution of image. <ref name="PMID22467166"><pubmed>22467166</pubmed></ref>.aCGH is used as a diagnostic tool for prenatal detection f chromosomal abnormalities <ref name="PMID19012303"><pubmed>19012303</pubmed></ref>.<br />
<br />
<br />
====Procedure====<br />
<ref> Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432] </ref><br />
The sample is obtained (skin, blood or fetal cells) and DNA is obtained. <br />
As a part of PGD fetal cell samples are collected from; the fertilized egg polar bodies, the blastomere (day 3 embryo) or the blastocyst/tropoectoderm stage (day 5 embryo).<br />
Sample DNA is labeled with one fluorescent dye, and the control DNA is labeled with a different colored fluorescent dye. the control DNA is used as the base point of reference. <br />
heated and denatured single DNA strands then hybridize to their complementary single strand probes, which are then combined and applied to a microarray and the results are run through a computer program and a digital imaging system is used to quantify the results( fluorescent intensities of the labeled probes). <br />
<br />
[[File:aCGH.jpg|thumb|right|'''aCGH''' checks the entire genome for chromosomal imbalances, by comparing control and a sample slides contatining small segements of DNA sample microarrayed slides small segments of DNA. Illustrated by student z5020317 and adapted from <ref> NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation. retrieved from [http://www.phgfoundation.org/file/5237/]</ref> <ref>Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432]</ref>]]<br />
<br />
<br />
<br />
The fluorescent ratio and the hybridization signal at different locations on the genome of the control DNA are used to identify any variances present in the sample DNA. aCGH facilitates the clinical diagnosis of submicroscopic chromosomal duplication, deletion and rearrangements indicative of chromosomal disorders such as trisomies 1-22and specific sex linked disorders. <br />
Duplications in the DNA are displayed by the computer program as spikes/ peaks over an established threshold and deletions in DNA are displayed by the computer program as spikes/ toughs beneath this threshold <br />
<br />
<br />
<br />
<br />
{|border="1" align="center"<br />
|-bgcolor="pink" <br />
| '''Advantages''' <br />
| '''Disadvantages'''<br />
|-<br />
| multiple applications: prenatal genetic diagnosis, cancer diagnosis, <ref name="PMID20193845"><pubmed>20193845</pubmed></ref> genetic screening for developmental delay (learning disabilities) <ref name="PMID17309648"><pubmed>17309648</pubmed></ref>. or congenital anomalies that are suspected to be genetic in origin <ref>NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation . retrieved from [http://www.phgfoundation.org/file/5237/]</ref><br />
| translocations and inversions of DNA are not detected<br />
|-bgcolor="pink"<br />
| trace represents all chromosomes present in the human genome chromosomes 1-22 and the X & Y chromosomes, and therefore is the most accurate method for testing whole embryo aneuploidy<br />
| limited ability diagnosing specific polyploidies such as triploidy <ref> Unique, Rare Chromosome Disorder Support Group (2013) Microarray-based Comparative Genomic Hybridiation (array CGH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/other/array%20cgh%20ftnw.pdf] </ref><br />
|-<br />
| aCGH has been extensively tested, and Validated, and is now used world wide.<br />
| will not detect mosaicism detection <20% (cultures where >1 of 5 cells are trisomy 12)<br />
|-bgcolor="pink"<br />
| detects deletions and additions and rearrangements as well as amplification, of the WHOLE genome, simultaneously.<br />
| will not detect balanced chromosomal rearrangement<br />
|-<br />
| detects submicroscopic alterations<br />
| will not detect duplications or deletions <80kb<br />
|-bgcolor="pink"<br />
| used as a diagnostic tool for prenatal detection of chromosomal abnormalities <ref name="PMID22034057"><pubmed>22034057</pubmed></ref><br />
| will not detect point mutations within genes <ref>Washington department of education (CGH- FAQ for physicians. Signature Genomic LAboratories, LLC. Retrieved from [https://depts.washington.edu/dbpeds/Lab%20Tests/SignatureCGH-physician_FAQ.pdf]</ref><br />
|-<br />
| provides high resolution genomewide screening of segmental genomic copy number variations<br />
| will not detect chromosomal position of genomic gains<br />
|-bgcolor="pink"<br />
| very accurate when used in conjunction with FISH<br />
| will not detect loos of heterozygosity (LOH) or Absence of heterozygosity (AOH) <ref>WiCell Research Institute Inc. (2012) Comparative Genomic Hybridization Microarray. <br />
retrieved from [http://www.wicell.org/home/cytogenetic-services/cgh-microarray/array-comparative-genomic-hybridization-acgh.cmsx]</ref><br />
|-<br />
|Alone is more reliable and in detecting chromosomal abnormalities, with a higher implantation success rate, than FISH <ref name="PMID20494259"><pubmed>20494259</pubmed></ref><br />
|<br />
|-bgcolor="pink"<br />
|Allows an in depth research focus upon specific types of rearrangements within selected chromosomal regions, a recent particular area of interest is subtelomeric and pericentromeric rearrangements<br />
|<br />
|-<br />
|reduces the risk of failed implantation and miscarriage, improving the chance of a healthy baby <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|<br />
|}<br />
<br />
<br />
<br />
===Next Generation Sequencing===<br />
====Description====<br />
The development and advances within ART in the past 20 years, as well as the increasing popularity of IV, has lead to an influx of new technologies developed to screen embryos for chromosomal anomalies, which are covered by the umbrella term of Next generation Sequencing (NGS). NGS is a general term used to describe all of the new and emerging screening techniques currently being introduced and used as part of PGD for IVF . NGS screens for single gene disorders as well as conducting extensive and very comprehensive chromosome diagnosis by sequencing, counting, and accurately assembling millions of DNA reads, simultaneously. <ref name="PMID23499002"><pubmed>23499002</pubmed></ref> There is a movement for NGS to replace the other limited testing techniques and be used as the standard. <br />
====Procedure====<br />
Samples are collected from either blastomere or the blastocyst/tropoectoderm and processed for analysis by a computer system. <br />
The methodology of each process is unique to the technique being used. <br />
<br />
<br />
<br />
{|border="1" align="center"<br />
|-bgcolor="pink" <br />
| '''Advantages'''<br />
| '''Disadvantages'''<br />
|-bgcolor="white"<br />
| cheaper<br />
| there are limited information available to clinical applications of NGS <ref><pubmed>26100406</pubmed></ref><br />
|-bgcolor="pink"<br />
| opens new diagnostic possibilities<br />
|<br />
|-bgcolor="white"<br />
| accurately tests all 24 chromosomes<br />
| <br />
|-bgcolor="pink"<br />
| tests for the presence of monogenic diseases of known genetic background<br />
| <br />
|-bgcolor="white"<br />
| reduces the number of biopsies required for diagnosis<br />
| <br />
|-bgcolor="pink"<br />
| higher detection rate of small translocations<br />
| <br />
|-bgcolor="white"<br />
| highly accurate is testing for compound point mutations, chromosomal duplication, deletions and insertions <ref name="23312231"><pubmed>23312231</pubmed></ref><br />
| <br />
|-bgcolor="pink"<br />
| it accurately detects chromosomal aneuploidy and unbalanced rearrangement <ref name="PMID25685330"><pubmed>25685330</pubmed></ref><br />
| <br />
|-bgcolor="white"<br />
| NGS single gene disorder screenings can conducted in conjunction with PCR comprehensive chromosomal screening<br />
|<br />
|-bgcolor="pink"<br />
| Reduces human error <br />
|<br />
|-bgcolor="white"<br />
| better detects the presence of mosaicism<br />
|<br />
|-bgcolor="pink"<br />
| work well in conjunction with CGH and aCGH as part of PGD, improving the chances of IVF. <ref> Morris, R. S. (2015 ) Next generation sequencing for PCG|PGS|CCS. IVF1 retrieved from [http://www.ivf1.com/next-generation-sequencing for-pgd] </ref><br />
|<br />
|}<br />
<br />
<br />
<br />
<br />
<br />
<br />
==Diagnosis==<br />
There are a large amount of diseases that PGD can apply to, below are descriptions of the diseases that PGD are more commonly used for. Utilization of Diseased Cell Lines<br />
===Cystic Fibrosis===<br />
Cystic fibrosis is a single gene disorder. It is autosomal recessive and involves mutations in the cystic fibrosis transmembrane conductance regulator (CTFR) gene. The CTFR gene is normally responsible for the decrease in chloride and the transport of bicarbonate in epithelial cells thus playing a major physiological role. In PGD procedures, identification of the gene is assisted by microsatellite markers that have similar composition to the CTFR gene itself. Biopsy of two cells at the blastocyst stage is recommended if markers are not available. There are many variations of cystic fibrosis the most common being P.Phe508del <ref name="PMID26014425"><pubmed>26014425</pubmed></ref>.<br />
===Duchenne Muscular Dystrophy ===<br />
Duchenne Muscular Dystrophy is an X-linked recessive disease. It involves the Xp21 gene where majority of the mutations are chromosomal deletions with a smaller percentage resulting from duplications <ref name="PMID18359022"><pubmed>18359022</pubmed></ref>.<br />
<br />
===Autosomal Recessive MEckel-Gruber Syndrome===<br />
Autosomal recessive genetic defect caused by the TMEM67 gene. It results in cystic dysplasia of the kidneys with fibrotic change in the liber and occipital encephalocele. Other malformations could also be present in the central nervous system. In PGD whole genome amplification of single blastomeres are taken to identify the gene, this is also coupled with PCR techniques. Maternal plasma can also be extracted for PGS. <ref><pubmed>24039893</pubmed></ref> <br />
===β – Thalassemia=== <br />
β – Thalassemia is known as the most common type of autosomal recessive inherited disorder among haemoglobinopathies. It involves the adult β-globin gene and is associated with the absent or decreased expression of the gene. This is commonly caused by a single nucleotide change in the gene. PGD has been used successfully worldwide to identify the β-globin gene where its application is usually performed on a single blastomere or polar body <ref name="PMID19064120">19064120</pubmed></ref>.<br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
! Applicable diseases for PGD <ref>Genoma Group (2014). Retrieved September 18th, 2015, from http://www.preimplantationgeneticdiagnosis.it/genetic-diseases-diagnosed-by-pgd.htm </ref>, <ref>Genesis Genetics (2015). Retrieved September 18th, 2015, from http://genesisgenetics.org/pgd/what-we-test-for/</ref>, <ref>Human Fertilisation & Embryology Authority (2015). Retrieved Septembr 18th, 2015, from http://guide.hfea.gov.uk/pgd/</ref><br />
|-<br />
| '''Disease'''<br />
| '''Involved Genes'''<br />
|-<br />
| 5 Alpha Reductase Deficiency (5ARD)<br />
| SRD5A2 <br />
|-<br />
| Achondroplasia<br />
|FGFR3 <br />
|-<br />
| Acute Intermittent Porphyria <br />
| ALAD, ALAS2, CPOX, FECH, HMBS, PPOX, UROD, or UROS<br />
|-<br />
| Adrenoleukodystrophy (Adrenomyeloneuropathy)<br />
| ABCD1 <br />
|-<br />
| Agammaglobulinaemia (x-linked) <br />
|BTK <br />
|-<br />
| Agammaglobulinemia Bruton Tyrosine Kinase (BTK) <br />
|BTK <br />
|-<br />
| Aicardi Goutieres Syndrome 1 (AGS1) <br />
|TREX1, RNASEH2A, RNASEH2B, RNASEH2C, SAMHD1<br />
|-<br />
| Alagille Syndrome<br />
|JAG1 or NOTCH2<br />
|- <br />
| Alpers-Huttenlocher Syndrome <br />
|POLG <br />
|-<br />
| Alpha-1-antitrypsin deficiency <br />
|SERPINA1 <br />
|-<br />
| Alpha-Mannosidosis<br />
| MAN2B1 <br />
|-<br />
| Alpha Thalassemia <br />
|HBA1 or HBA2 <br />
|-<br />
| Alports Syndrome<br />
|COL4A3, COL4A4, COL4A5<br />
|-<br />
| Alzheimer's Disease - early onset (Type 3 and 4) <br />
|APP, PSEN1, or PSEN2<br />
|-<br />
| Amyotrophic Lateral Sclerosis 1 (ALS1) <br />
|C9orf72, SOD1, TARDBP, FUS, ANG, ALS2, SETX, VAPB <br />
|-<br />
| Argininosuccinic Aciduria <br />
| ASL<br />
|-<br />
| Arrhythmogenic Right Ventricular Cardiomyopathy/ Dysplasia (ARVC/D)<br />
| DSG2; DSP; PKP2<br />
|-<br />
| Ataxia Telangiectasia<br />
| ATM<br />
|-<br />
| Autosomal Recessive Meckel-Gruber Syndrome<br />
| TMEM67<br />
|-<br />
| Bardet-Biedl Syndrome (BBS)<br />
| BBS1; BBS10<br />
|-<br />
| Barth Syndrome<br />
| TAZ<br />
|-<br />
| Beta Thalassaemia<br />
| HBB<br />
|-<br />
| Birt-Hogg-Dubé Syndrome<br />
| FLCN<br />
|-<br />
| Breast Ovarian Cancer Familial Susceptibility (BRCA2)<br />
| BRCA1; BRCA2<br />
|-<br />
| Canavan Disease <br />
| ASPA<br />
|-<br />
| Carnitine-Acylcarnitine Translocase Deficiency <br />
| SLC25A20<br />
|-<br />
| Cerebral Arteriopathy with Subcortical Infarcts & Leukoencephalopathy (CADASIL)<br />
| NOTCH3<br />
|-<br />
| Cerebral Cavernous Malformation<br />
| CCM1<br />
|-<br />
| Charcot-Marie-Tooth Disease<br />
| GJB1; MPZ; NEFL; PMP22<br />
|-<br />
| CHARGE Syndrome<br />
| CHD7<br />
|-<br />
| Cherubism<br />
| SH3BP2<br />
|-<br />
| Choroideremia<br />
| CHM<br />
|-<br />
| Chronic Granulomatous Disease<br />
| CYBB; NCF1<br />
|-<br />
| Ciliary Dyskinesia<br />
| DNAH5<br />
|-<br />
| Citrullinemia<br />
| ASS1<br />
|-<br />
| Cleidocranial Dysplasia<br />
| RUNX2<br />
|-<br />
| Cockayne Syndrome<br />
| ERCC6<br />
|-<br />
| Congenital Adrenal Hyperplasia<br />
| CYP21A2<br />
|-<br />
| Congenital Cataracts<br />
| GJA8; VSX2<br />
|-<br />
| Congenital Diarrhea, Syndromic<br />
| SPINT2<br />
|-<br />
| Congenital Disorders of Glycosylation (CDG)<br />
| ALG1; ALG6; CDG1C; DOLK; PMM2<br />
|-<br />
| Cornelia de Lange Syndrome <br />
| NIPBL<br />
|-<br />
| Craniosynostosis<br />
| TWIST1<br />
|-<br />
| Crouzon Syndrome<br />
| FGFR2<br />
|-<br />
| Cysteinyl Leukotriene Receptor 1 Deficiency <br />
| CYSLTR1<br />
|-<br />
| Cystic Fibrosis<br />
| CFTR<br />
|-<br />
| Diamond –Blackfan Anemia <br />
| RPS19<br />
|-<br />
| Duchenne Muscular Dystrophy <br />
| DMD<br />
|-<br />
| Dyskeratosis congenita (Male embryos only)<br />
| DKC1<br />
|-<br />
| Ectodermal dysplasia (Hypohidrotic)<br />
| EDA; EDA1; GJB6; IKBKG<br />
|-<br />
| Familial Adenomatous polyposis coli (FAP)<br />
| APC<br />
|-<br />
| Familial Dysautonomia<br />
| IKBKAP<br />
|-<br />
| Fanconi Anemia <br />
| FANCA; FANCC; FANCD2; FANCF; FANCG; FANCJ<br />
|-<br />
| Fragile X Syndrome (FRAX)<br />
| FMR1<br />
|-<br />
| Galactosemia <br />
| GALT<br />
|-<br />
| Gangliosidosis<br />
| GLB1<br />
|-<br />
| Glanzmann Thrombasthenia <br />
| ITGA2B<br />
|-<br />
| Glutaric Acidemia (aciduria)<br />
| GCDH <br />
|-<br />
| Glycogen Storage Disease <br />
| G6PC; GAA; SLC37A4<br />
|-<br />
| Haemophilia A<br />
| F8<br />
|-<br />
| Haemophilia B<br />
| F9<br />
|-<br />
| Hereditary Nonpolyposis Colorectal Cancer: Lynch Syndrome<br />
| MLH1; MSH2; MSH6<br />
|-<br />
| Holt Oram Syndrome<br />
| TBX5<br />
|-<br />
| Huntington Disease<br />
| HD<br />
|-<br />
| Hydrocephalus<br />
| L1CAM<br />
|-<br />
| Ichthyosis <br />
| ABCA12; STS<br />
|-<br />
| Incontinentia Pigmenti (IP)<br />
| NEMO<br />
|-<br />
| Joubert Syndrome 5<br />
| INPP5E<br />
|-<br />
| Krabbe Disease<br />
| GALC<br />
|-<br />
| Leber Congenital Amaurosis (LCA)<br />
| CEP290; GUCY2D<br />
|-<br />
| Leigh Syndrome (Infantile Subacute Necrotising Encephalopathy)<br />
| LRPPRC<br />
|-<br />
| Lesch Nyan Syndrome<br />
| HPRT1<br />
|-<br />
| Leukocyte Adhesion Deficiency (Type I)<br />
| ITGB2<br />
|-<br />
| Li-Fraumeni Syndrome<br />
| TP53<br />
|-<br />
| Macular Dystrophy Retinal <br />
| VMD2<br />
|-<br />
| Maple Syrup Urine Disorder (MSUD)<br />
| BCKDHB<br />
|-<br />
| Marfan Syndrome <br />
| FBN1<br />
|-<br />
| Menkes Syndrome<br />
| ATP7A<br />
|-<br />
| Mitochondrial DNA Depletion Syndrom <br />
| POLG; RRM2B; SUCLA2; TK2<br />
|-<br />
| Mucolipidosis type II<br />
| GNPTAB<br />
|-<br />
| Multiple Endocrine Neoplasia<br />
| MEN1; MEN2A; MEN2B<br />
|-<br />
| Multiple Exostoses<br />
| EXT1; EXT2 <br />
|-<br />
| Myotubular myopathy<br />
| MTM1 <br />
|-<br />
| Nail-Patella Syndrome<br />
| LMX1B<br />
|-<br />
| Neurofibromatosis Type 1<br />
| NF1<br />
|-<br />
| Neurofibromatosis Type 2 <br />
| NF2<br />
|-<br />
| Noonan Syndrome<br />
| KRAS, PTPN11; SOS1<br />
|-<br />
| Norrie Disease<br />
| NDP<br />
|-<br />
| Ocular Albinism <br />
| GPR143<br />
|-<br />
| Oculocutaneous Albinism <br />
| OCA2; TYR <br />
|-<br />
| Oculodentaldigital Dysplasia<br />
| GJA1<br />
|-<br />
| Optic Atrophy<br />
| OPA1<br />
|-<br />
| Ornithine Transcarbamylase Deficiency <br />
| OTC<br />
|-<br />
| Osteogenesis imperfeca <br />
| COL1A1; COL1A2<br />
|-<br />
| Osteopetrosis <br />
| CLCN7; OSTM1; TCIRG1<br />
|-<br />
| Pachyonychia Congenita <br />
| KRT16; KRT6A<br />
|-<br />
| Pancreatitis, Hereditary<br />
| PRSS1 <br />
|-<br />
| Papillorenal syndrome <br />
| PAX2<br />
|-<br />
| Phenylketonuria <br />
| PAH <br />
|-<br />
| This table does not cover the complete list of diseases that PGD can be applied to.<br />
|}<br />
<br />
==Laws & Legal status==<br />
<br />
{ class="wikitable" <br />
|-<br />
| Australia<br />
| PGD is currently used to detect serious genetic conditions to improve the outcome of Assisted Reproductive Technologies (ART). In very rare cases it may be used to select an embryo with compatible tissue for a sibling who has a life-threatening disease where other means of treatment is unavailable. This is with the conditions that the use of PGD will not affect the welfare and interests of the child to be born. The parents must also receive adequate counselling and have full understanding of the procedures of PGD. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"> National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art</ref><br />
The use of PGD for sex-selection is prohibited with the exception of reducing the risk of the transmission of serious sex-linked genetic conditions. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"/><br />
|-<br />
| Brazil<br />
| The laws regarding PGD in Brazil are not strictly regulated. They are vague and there is limited information surround the activities of assisted reproduction in general in the country <ref name="PMID25493379"><pubmed>25493379</pubmed></ref>.<br />
|-<br />
| Czech Republic<br />
| The laws in the Czech Republic allow those with a “defined indication in order to exclude risk of serous genetically conditioned disease and defects with embryos before they are implanted into the cavity of the uterus”. Couples that undergo any assisted reproductive treatment including PGD have to be married. Sex-selection is illegal except in regards to serious sex-linked genetic diseases <ref name="PMID24777348"><pubmed>24777348</pubmed></ref>.<br />
|-<br />
| Greece<br />
| In Greece, ART is open to those up to the age of 50 with written consent. It can only be used if a medical necessity is present such as the susceptibility of serious hereditary diseases. Sex selection is banned apart from cases of sex-linked diseases and sexually transmitted diseases <ref name="PMID24777348"/>.<br />
|-<br />
| India<br />
| In India there is a cultural preference for boys thus the Prenatal Diagnostic Techniques (Regulation and Prevention of Misuse) Act was introduced in 1994. This law limits the use of PGD for sex determination except in cases of specific congenital diseases. These laws however are not strictly enforced. <ref>World Health Organisation (2015) Gender and Genetics Retrieved on October 21st 2015 from:http://www.who.int/genomics/gender/en/index4.html</ref><br />
|-<br />
| Portugal <br />
| ART is only available to those who are married or have a similar type of relationship for at least two years. The couples cannot be of the same sex and must be at least 18 years of age. Sex selection is illegal except in cases of sex-linked diseases. The use of PGD is illegal if the predictive value of genetic tests are very low <ref name="PMID24777348"/>.<br />
|-<br />
| Spain<br />
| PGD can be applied to “serious hereditary diseases not amenable to postnatal curative treatment” and “detection of other abnormalities which may compromise the viability of the pre-embryo”. If PGD is to be used for any other purpose authorisation must be acquired <ref name="PMID24777348"/>.<br />
|-<br />
| Sweden <br />
| The use of PGD is strictly regulated and couples must achieve authorisation of the National Board of Health and Welfare. It can only be used it can only be used if the child is at risk to inheriting a serious chromosomal or monogenetic disease. It cannot be used for selection of specific characteristics <ref name="PMID24777348"/>.<br />
|-<br />
| United Kingdom<br />
| Those involved with carrying out the IVF treatment must have a license from the Human Fertilisation and Embryology Authority (HFEA). Only embryos that are approved by the HFEA can be implanted where the embryonic nuclear or mitochondrial DNA cannot be altered with the exception of preventing mitochondrial diseases <ref name="PMID24777348"/>. <br />
|}<br />
<br />
==Future/Current Research==<br />
===Noninvasive Preimplantation Genetic Testing without Embryo Biopsy===<br />
Different parameters of gametes, zygotes, embryos (“vacuoles in sperm heads, spindle position in mature oocytes, cleavage intervals of zygote, and embryo developmental dynamics”) may correlate with aneuploidy rates. This knowledge may be applied in potential noninvasive preimplantation diagnostic methods. Several methods have been proposed and are currently further researched<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Sperm Selection====<br />
Intracytoplasmic morphologically selected sperm injection (IMSI) is common procedure in IVF treatment to improve fertilization rates in patients with poor semen quality. In addition, studies have found that IMSI improves embryo development and that spermatozoa with large vacuoles in their heads correlate with increased aneuploidy rates and disturbed chromosomal structures. Thus, selecting spermatozoa based on morphological hallmarks may decrease aneuploidy rates in the fertilized embryos. As with polar body biopsies, however, this approach will solely be applicable if evidence for severe male detrimental contribution is given<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Blastocoel Fluid Extraction====<br />
In addition, a less invasive retrieval of material for diagnosis could include the extraction of the blastocoel fluid. The cavity of the blastocyst, lined by the trophectoderm, is filled with this blastocoel fluid, which contains metabolites of both trophectoderm and inner cell mass origin. The retrieval does not require a biopsy but merely a small opening to extract the fluid and, thus, causes less harm to the embryo. Multiple studies have applied this method<ref name="PMID22020776"><pubmed>22020776</pubmed></ref> <ref name="PMID23148560"><pubmed>23148560</pubmed></ref> and it may in the future become of clinical relevance.<br />
<br />
<br />
[[File:Aspiration_of_the_Blastocoel_Fluid.jpeg|thumb|Aspiration of the Blastocoel Fluid using a ICSI pipette<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.]]<br />
<br />
<br />
Next to metabolites, the blastocoel fluid can contain DNA. Studies have shown that genomic DNA is present in about 90% of the blastocoel fluid samples tested. Typically the fluid is removed with an ICSI pipette from a day five blastocyst through its mural trophectoderm until the blastocyst fully collapses around the embryo. Several concerns regarding this method in a clinical setting have been raised. The collected DNA may be contaminated by the culture media that contains DNA fractions. The DNA may also be least representative of the actual embryos genome as the DNA may originate from abnormal or degenerated cells. Even though labelled noninvasive, the blastocyst still undergoes manipulation to some degree which may affect its viability. Thus, more research is required until this method can evolve from research to clinical use<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
====Proteomics====<br />
The protein secretome of blastocysts may be representative of its chromosome constitution Recent studies have found biomarkers such as lipocalin-1, interleukin-10, tumor necrosis factor, stem cell factor, and chemokine ligand 13 to be differently secreted by aneuploid blastocyst than by euploid ones. The most significant biomarker appears to be interleukin-10. Paired with novel proteomic technologies and mass spectrometry this knowledge when extended may contribute to a new invasive preimplantation genetic diagnosis method<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Embryo Morphology====<br />
Using time lapse imaging the embryo’s morphology can be closely observed and potential aneuploidy characteristics detected. Such characteristics may include the time of division to five cells, the time between the division from three to four cells, and the duration of the division from one to two and subsequently to three. In addition, the morphological quality of ICM an TE has been positively associated with aneuploidy or euploidy prognosis<ref name="PMID26246880"><pubmed>26246880</pubmed></ref>. These may give rise to an embryo quality screening prior to implantation<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
==References==<br />
<br />
<references/><br />
<br />
<br />
{{StudentPage2015}}</div>Z5017878https://embryology.med.unsw.edu.au/embryology/index.php?title=2015_Group_Project_6&diff=2069972015 Group Project 62015-10-21T06:29:11Z<p>Z5017878: </p>
<hr />
<div>{{ANAT2341Project2015header}}<br />
<br />
<br />
=Preimplantation Genetic Diagnosis and Screening=<br />
==Introduction==<br />
Preimplantation genetic diagnosis (PGD) and screening (PGS) are reproductive options for couples with known family histories of genetic disease or couples undergoing IVF procedures due to infertility issues. PGD can diagnose many genetic disorders caused by known chromosomal abnormalities (number and/or structure) or single gene mutations, and, thus decrease the risk of termination of pregnancy or miscarriages and enable such couples to have an unaffected child<ref name="PMID24907939"><pubmed>24907939</pubmed></ref>. Through major improvements in PGD/S and general laboratory technology, the testing for abnormalities in fetuses has shifted from prenatal diagnosis during the first 2 trimesters <ref> Blackburn, S.L. (2003) '''Maternal, Fetal & Neonatal physiology: a Clinical perspective''' (2nd ed.). Seattle: Saudners </ref>, testing for overall fetal growth, complications of pregnancy, and birth defects<ref> Sadler T.W.(2012) '''Langman's Medical Embryology''' (12th ed.) Philadelphia: Lipincott, Wiliams & Wilkins, a Wolters Kluwer Business </ref>, to an embryonic focus especially in advancements in Artificial Reproductive Technologies (ART)<ref><pubmed>20638568</pubmed></ref>. In 1990 PGD for a recessive X-linked disease resulted in the first live birth<ref><pubmed>2330030</pubmed></ref> and has since been incorporated in clinical routine and applied for a variety of genetic diseases, such as sickle cell anemia, thalassemia, or cystic fibrosis<ref name="PMID24907939"/>.<br />
[[File:Preimplantation Genetic Diagnosis Procedure.jpeg|700px|thumb|centre| Simplified steps for PGD<ref name="PMID24907939"/>]]<br />
<br />
==History==<br />
<br />
==Preimplantation Genetic Diagnosis==<br />
Preimplantation genetic diagnosis (PGD) is used to test the genetic makeup of embryos to detect single gene disorders, chromosomal abnormalities and mitochondrial disorders. It also has applications in gender selection for diseases with unequal gender distributions <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Some diseases commonly involved with PGD include cystic fibrosis, spinal muscular atrophy and beta – thalassaemia <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press.">Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press</ref> <ref name="PMID17823145"><pubmed>17823145</pubmed></ref>. It was first used in the United Kingdom in the 1980s of arenoleucodystrophy and primarily focusing on sex- linked disorders <ref name="PMID17823145"/><ref name="PMID23150080"><pubmed>23150080</pubmed></ref>. PGD is now capable of detecting single cell defects (molecular) and chromosomal disorders resulting from the inversion, translocation or deletion of chromosomes (cytogenic) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>,<ref name="PMID11325751"><pubmed>11325751</pubmed></ref>. PGD can be applied to the embryo at different stages. That is on polar bodies, blastomeres or blastocyst <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>.<br />
Depending on the type of genetic disorder, PGD utilises different methods of genetic testing. These include Fluorescence in situ hybridisation (FISH) which is used for sex – linked disorders and detects chromosomal rearrangements <ref name="PMID11325751"/><ref name="PMID17876073"><pubmed>17876073</pubmed></ref> and Embryo halotyping which allows the identification of chromosomes causing the inherited disorder through knowledge of the pattern of closely linked markers <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. Polymerase chain reaction (PCR) is also widely used to detect molecular abnormalities <ref name="PMID11325751"/>.<br />
PGD is tightly regulated and supported by large organisations namely The American Society for Reproductive Medicine, The European Society for Human Reproduction and Embryology (ESHRE), The European Society of Human Genetics and the Preimplantation Genetic Diagnosis International Society <ref name="PMID25500181><pubmed>25500181</pubmed></ref>.<br />
===Sex-linked disorders===<br />
The determination of a disease as gender specific usually correlates with the presence or absence of specific genes such as SRY on the Y chromosome. It is known that females have two X chromosomes and males have an X and a Y chromosome where abnormalities are more prevalent on the X chromosome. PGD can be used for sex selection where only male embryos are transferred to reduce the chance of inheriting X-linked disorders. However, this does not completely eradicate the problem as male embryos remain susceptible to inheriting an affected X chromosome. Sex determination is only used when the specific mutation is unknown and has yet to be discovered <ref name="PMID24866878"><pubmed>24866878</pubmed></ref>.<br />
===Single gene defects===<br />
Single gene defects can be dominant, recessive, autosomal or X-linked. They are commonly diagnosed using PCR and although the PCR available today is complex and capable of combatting a large range of disease the development of new protocols has been proven to be difficult due to the small DNA sample available <ref name="PMID26168107"><pubmed>26168107</pubmed></ref><br />
===Mitochondrial disorders===<br />
Mitochondrial disorders also known as oxidative phosphorylation disorders arise from mutations in the nuclear DNA or mitochondrial DNA <ref name="PMID26312584"><pubmed>26312584</pubmed></ref>. They pose as a problem because they are unrecognisable until the mutations in the cell reach a detrimental level <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Mitochondrial disorders cause miscarriages and stillbirths as well as death in children and young adults. The effects can either be contained in a single organ or more commonly involve multiple organ failure where organs with high energy demands such as the brain, liver muscle and heart and heavily influenced. They are usually occur spontaneously or result from inheritance from the mother. Since mitochondria are solely inherited from the mother oocyte donations have been used as a solution to combat mitochondrial disorders. Additionally, there has been an increasing use in PGD where embryos that stay under the given threshold of 18% gene-mutations are allowed to be transferred and result in normal development. New technology in the areas of nuclear gene transfer and genome editing are also being experimented with <ref name="PMID26312584"/>. <br />
===Chromosomal disorders===<br />
Chromosomal disorders can be reciprocal, Robertsonian translocations, inversions, deletions and insertions <ref name="PMID26168107"/>. . Data from ESHRE collected between 2010 and 2011 has shown that the most common chromosomal abnormality confronted in PGD are reciprocal chromosomal abnormalities <ref name"PMID26071418"><pubmed>26071418</pubmed></ref>. PGD has also been used successfully for Robertsonian translocations (RT), a type of structural translocation. Children who carry RT are phenotypically normal, however in their later years it is found that they will suffer from infertility and repeated miscarriages due to the high frequency of abnormal embryos <ref name="PMID22081077"><pubmed>22081077</pubmed></ref>. PCR and FISH are the two main techniques used for chromosomal disorders. To be able to conduct the examinations the cells are required to be at the metaphase stage <ref name="PMID26168107"/>. <br />
==Preimplantation Genetic Screening==<br />
Prenatal Genetic Screening (PGS) involves an array of methods or ideas that aim to segregate embryos that have genetic flaws and those that are healthy <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. The occurrence of aneuploidy is high around the stages of early embryonic development and they are the most common cause if miscarriages and congenital birth defects <ref name= "PMID26085841"><pubmed>26085841</pubmed></ref>. They have little effect on the morphology of the embryo making them difficult to identify thus identification heavily relies on genetic testing <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. <br />
Genetic sampling is most commonly conducted using Microarray Comparative Genomic Hybridisation (aCGH) as well as FISH, Quantitative PCR and Single Nucleotide Polymorphism (SNP) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. These methods collectively aim to assess numeral and structural chromosomal errors <ref name= "PMID26085841"/>. Studies have also introduced Next- Generation Sequencing (NGS) <ref name= "PMID26085841"/> and Whole Genome Amplification used to screen imbalances in the complete 24-chromosomes <ref name="PMID25953353"><pubmed>25953353</pubmed></ref><br />
Statistics from ESHRE have shown that the most common indications for PGS is advanced age, followed by repeated implantation failure or recurrent miscarriage and male infertility <ref name="PMID26071418"><pubmed>26071418</pubmed></ref>.<br />
====Indications====<br />
A low percentage of structural abnormalities in chromosomes are responsible for the cause of miscarriages. Despite this, they are the most prevalent type of chromosomal abnormality accounted for in PGD <ref name="PMID20638568"/>. The presence of specific gene cycles, initiation of embryonic protein synthesis and evident physiological development are all indicative of a successful in vitro fertilisation procedure <ref name="PMID11576737"><pubmed>11576737</pubmed></ref>. To eliminate further errors from occurring during the PGD procedure it is recommended to undertake further prenatal testing such as amniocentesis in the later stages <ref name="PMID20638568"/>. <br />
=====Advanced maternal age=====<br />
Data provided by the ESHRE has shown that the mean age of women undergoing PGS is 39 years <ref name="PMID26071418"/>. Women of advanced age have been shown to have a lower rate of pregnancies reaching childbirth <ref name="PMID18583331"><pubmed>18583331</pubmed></ref>. The highlighted concern revolves around the increased occurrence of aneuploidy following maternal age. The optimal age range for the lowest aneuploidy incidence was found to be between 27 to 37 years of age (6%) then progressively higher in women aged up to 42 (33%) and most common in those 44 and above (53%) <ref name="PMID24355045"><pubmed>24355045</pubmed></ref>. <br />
=====Recurrent pregnancy loss / IVF failure=====<br />
Recurrent pregnancy loss is defined as three or more IVF failures after cumulative transfer of more than 10 good-quality embryos. These are primarily caused by two main factors, reduced endometrium receptivity or embryonic defects. Endometrium receptivity can be negatively influences by instances including uterine pathologies such as thin endometrium, altered expression of adhesive molecules and immunological factors. Additionally, embryonic defects may be due to genetic abnormalities, embryonic aneuploidy or zona hardening. Endometriosis and hydrosalpinx has been known to effect both the endometrium and embryo <ref name="PMID23260857"><pubmed>23260857</pubmed></ref>.<br />
=====Human leukocyte antigen matching=====<br />
First used in 2001, HLA matching is an option given to parents to save a child with haematological or immunological disease through conceiving another child who would potentially be able to donate cord blood or haematopoietic stem cells from the bone marrow for transplantation. The process namely PGD-HLA has shown to improve haematopoietic stem cell transplant (HSCT). PGD-HLA can only be performed when HSCT is not needed urgently due to the time needed to conceive and delivery the baby <ref name="PMID25500181"><pubmed>25500181</pubmed></ref>. It is most commonly applied to children suffering from relapsed leukaemia <ref name="PMID22524201"><pubmed>22524201</pubmed></ref>. In a case study PGD-HLA was proven to successfully cure 10 diseases including Fanconi anaemia, Diamond-Blackfan anaemia and beta thalassemia <ref name="PMID25066893><pubmed>25066893</pubmed></ref>.<br />
==Biopsy Methods==<br />
Biopsy, the removal of genetic materials, from oocytes or embryos in the preimplantation stage is the primary step in PGD. For the past two decades these biopsies have been performed at three stages, the polar body, blastomere, and blastocyst, and the methodologies optimized to ensure the embryo’s viability. The most common approach involves biopsies at the cleavage stage. However, polar body and blastocyst biopsies are increasingly more often tested and applied. Approached for opening the zona pellucida involve next to the traditional mechanical and chemical means, novel approaches such as noncontact lasers. Their application may simplify and secure the procedure significantly. The most challenging question about PGD procedures remains at what stage biopsies should be taken. Much controversy has developed around this topic, highlighting the varying disadvantages and advantages of temporal biopsies. <ref name="PMID22723007"><pubmed>22723007</pubmed></ref><br />
<br />
{| class="wikitable"<br />
|- align="center" bgcolor="DDCEF2"<br />
|<br />
| Time of Biopsy<br />
| Advantages <br />
| Disadvantages<br />
|- bgcolor="FFFAFA"<br />
| Polar Body<br />
| Day 1<br />
| No harm to oocyte<br />
| Only maternal DNA is tested, often needs to be coupled with other biopsies<br />
|- bgcolor="FFFAFA"<br />
| Blastomere<br />
| Day 3<br />
| …<br />
| … <br />
|- bgcolor="FFFAFA"<br />
| Trophectoderm<br />
| Day 5 and 6 <br />
| Little harm, large amount of genetic material<br />
| Opening of blastocyst necessary, small time window for procedure<br />
|}<br />
<br />
<br />
[[File:Polar_Body,_Blastomere,_and_Trophectoderm_Biopsy.jpeg|thumb|Polar body (A), blastomere (B) and trophectoderm (C) biopsies<ref name="PMID25625041"><pubmed>25625041</pubmed></ref>.]]<br />
<br />
<br />
<br />
PMID 24305177<br />
===Polar Body Analysis===<br />
Day 1<br />
====Description====<br />
Polar body (PB) biopsy, which was introduced in 1990, offers a promising alternative to biopsies performed at the blastomere stage for PGD/S indications on legal and practical grounds. <br />
Description: Consequent embryo development does not necessitate the presence of the first and second PB and their removal may not be crucial. PB biopsy requires precise timing. Keeping track of the meiotic cell cycle is necessary to perform a successful biopsy and, therefore, PB biopsy usually is applied in combination with intracytoplasmic sperm injection (ICSI). During the maturation from the germinal vesicle stage to the metaphase-II stage the first PB is formed. A cytoplasmic bridge containing spindle remnants, that are still in contact with the cellular genetic material, links this PB to the oolemma for about 90 minutes after extrusion. It is possible to visualize these remnants by polarization microscopy and it is crucial to not perform the biopsy until the first PB is no longer firmly attached to the oolemma as this indicates an immature embryo.The oocyte tolerates mechanical zona dissection best during hours four until six after ICSI as the oolemma has stabilized by that time because of the cortical granule reaction. Over time the first PB degenerates stressing a temporal biopsy and its optimal extraction time window is four to 12 hours after ICSI. The second PB forms around two to four hours after ICSI. However, its optimal time window for biopsy is set to be eight to 16 hours after ICSI. This is due to the second PB being attached to the oolemma with spindle remnants until six hours after ICSI. Biopsy at this point may cause enucleation of the oocyte. In addition, studies have shown that the amplification efficiency of second PB’s DNA is worse if the PB is extracted prior to eight hours after ICSI. <br />
Thus, it is possible to perform sequential and simultaneous biopsies for the first and second PB. If performed, sequentially the first PB may be removed four to 12 hours and the second PB eight to 16 hours after ICSI. The optimal time window for a biopsy for both the first and second PB simultaneously is eight to 12 hours after ICSI. It is highly preferred to analyze both PBs due to potential aneuploidies in either PB and crossing overs during meiosis<ref name="PMID22723007"/>. <br />
====Procedure====<br />
Chemical opening achieved with for example acidic tyrode’s solution of the zona pellucida is not tolerated by the oocyte and may have detrimental effects on the embryo’s development. Therefore, the access to the perivitelline space of the oocyte is provided by mechanical zona dissection or by laser. Both techniques work well if performed by experienced embryologist. However, laser-assisted biopsy is less time consuming when compared to manual dissection. It is critical to consider the size of the introduced opening as it will remain permanent. If it is too large the blastomere may be lost during embryo development and if it is too small it may interfere with hatching of the embryo during blastocyst stage<ref name="PMID22723007"/><br />
<br />
[[File:Polar_Body_Biopsy.jpeg|thumb|The presence of a faint but clearly identifiable strand connecting PB2 to the <br />
oolemma. The biopsy was performed ∼9 h after ICSI<ref name="PMID21908464"><pubmed>21908464</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JTaQzszVr8o</html5media><br />
|-<br />
| Laser-assisted polar body biopsy<ref>RIUK, R. (2013, June 25) Polar Body Biopsy [Video file]. Retrieved from https://www.youtube.com/watch?v=JTaQzszVr8o</ref><br />
|}<br />
<br />
====Advantages & Disadvantages====<br />
PB biopsies can only investigate the maternal contributions to the embryo as they are of maternal origin. Thus, this procedure is appropriate for PGD solely for monogenetic diseases from the maternal side. Recessive diseases may be evaluated with PB biopsies on the basis that the embryo’s outcome will be determined by the paternal contribution. (...) It may still be applied for PGS as most aneuploidies either arise during meiosis or origin from the maternal genome. However, diagnosis error has been reported due to the lack of considering paternal contributions. <br />
Because PB biopsies are performed very early it is not yet known whether the oocyte will develop into a viable embryo. Thus, PBs are commonly frozen or fixed after biopsy and depending on the state of the embryo only chosen PBs will be tested. This is primarily an economic issue as many genetic testing procedures are very cost-intensive<ref name="PMID22723007"/>.<br />
<br />
[[File:Implantation_predictive_value_of_euploid_screening_results.jpeg|thumb|The sustained implantation predictive value (with 95 % confidence interval) of a euploid screening result obtained from the first polar body (PB1), PB1 and the second polar body (PB2), or a direct embryo biopsy for each stage of embryo transfer (cleavage-stage and blastocyst stage)<ref name="PMID25106935"><pubmed>25106935</pubmed></ref>.]]<br />
<br />
===Blastomere biopsy===<br />
Day 3 <br />
====Description====<br />
Blastomere biopsy has been the prevalent method for PGD and PGS in the last two decades. At least one, but up to two, blastomeres are biopsied on day three of the cleavage stage embryo. The right number of blastomeres removed is a controversial topic as two cells allow for more genetic material and more accurate results. However, removing two cells might be too invasive and damaging to the embryo. (Study)<ref name="PMID21748341"><pubmed>21748341</pubmed></ref><br />
====Procedure====<br />
Initially a hole was drilled into the zona pellucida using acid tyrodes and the blastomeres are removed via aspiration with a pipette<ref name="PMID21748341"/>.<br />
<br />
<br />
[[File:Aspiration_of_a_Blastomere.jpeg|thumb|Aspiration of a Blastomere into the biopsy pipette<ref name=" PMID24783200"><pubmed>24783200</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=TbridWVwipI</html5media><br />
|-<br />
| Laser-assisted blastomere biopsy<ref>Sukprasert, M. (2014, March 5) Day 3 Blastomere Biopsy 1 [Video file]. Retrieved from https://www.youtube.com/watch?v=TbridWVwipI</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
===Trophectoderm biopsy===<br />
Day 5 and 6<br />
====Description====<br />
The improvement of embryo culture media allowed the in vitro development of human embryos until the blastocyst stage and opened up the possibility to take blastocyst biopsies. During day three to day five the haploid maternal and paternal genomes work together for the first time to form the genome of the embryo. The maternal epigenetic control lessens significantly while preparing for implantation with precisely arranged events happening. The first event includes a rapid increase in the number of embryonic cells which are active in mitotic divisions and apoptosis of aberrant cells. This is followed by the formation of blastocoel (cavitation) which results from the flattening of cell located on the outside of the blastomere. Now the blastocyst will expand until the embryo hatches by rupturing the zona pellucida. The cells of the blastocyst will differentiate to form two distinct cell lineages, the outer trophectoderm and the inner cell mass<ref name="PMID22723007"/>.<br />
====Procedure====<br />
Trophectoderm biopsy is usually performed in Hepes buffered biopsy medium and opening approaches include needle cutting which has been replaced by lasers in past years. Different research groups report different timings of the opening to be the most successful. Some open the blastocyst on day three or four by creating a 25 µm which causes the trophectoderm to herniate through this hole and is, thus, accessible for biopsy. Others create this hole about four hours before biopsy which allows sufficient herniation of trophectoderm cells. It is also possible to open the blastocyst immediately before biopsy. This avoids an extra step and the inner cell mass usually is easy to locate. Blastocyst biopsies involve the removal of trophectoderm cells and the ideal time for the procedure is day five. Successful biopsies on day six have been performed, while little is known about the results of biopsies on day seven. However, since the window of implantation in humans is from day eight to ten after ovulation, day seven biopsies appear to be possible<ref name="PMID22723007"/>.<br />
-collapse of trophoblasts<br />
-possible: biopsy of hatched blastocyst, holding pipette careful mild suction force to hold embryo near ICM <br />
-Cryopreservation<br />
<br />
<br />
[[File:Microscopic images of human blastocysts for biopsy.jpeg|thumb|(A) Some trophectoderm cells in a blastocyst started to hatch and (B) the trophectoderm cells were biopsied with assisted laser cutting. Images in C–D show the blastocysts after vitrification and warming. Blastocysts had been cultured for 2–4 hrs after warming, showing good (ICM and trophectoderm cells) hatched (C) and hatching (D) blastocysts. The hatching blastocyst in (E) has good ICM but fair trophectoderm while the blastocyst in (F) has both fair ICM and trophectoderm. Arrows indicate ICMs and arrow heads indicate trophectoderm cells. Bar = 40 µm<ref name="PMID2190846"><pubmed>2190846</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JI_TQ8d8tNM</html5media><br />
|-<br />
| Laser-assisted blastocyst biopsy (at 00:50 min)<ref>Coco, R. (2014, April 30) Trophectoderm biopsy in a Hatching blastocyst protruding ICM [Video file]. Retrieved from https://www.youtube.com/watch?v=JI_TQ8d8tNM</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
Blastocyst biopsies are believed to be less damaging to the embryo and appear to be unrelated to implantation rates. In addition, this biopsy method allows for a larger extraction of cells for genetic testing. However, since they are performed late in in vitro development, the time window for genetic testing is relatively small. Fast and accurate genetic testing methods are needed to ensure a successful and safe result from this biopsy. Thus, blastocyst biopsies may gain more popularity in the future whn such methods have been developed or improved<ref name="PMID22723007"/>. <br />
<br />
<br />
==Genetic Techniques==<br />
<br />
===PCR===<br />
====Description====<br />
Polymerase chain reaction (PCR) amplifies DNA specific to genetic sequence of interest . PCR was developed by Kay Mullis in the 1980s, for which he was awarded the Nobel prize for chemistry in 1993. <ref> Pubmed Docs (2015) Polymerase Chain Reaction (PCR) Pubmen. Retrieved from [http://www.ncbi.nlm.nih.gov/probe/docs/techpcr/]</ref> This technique enables clinicians to monitor and diagnose diseases using minute samples such as embryonic cells, blood & tissue. <ref>Roche (2015) PCR: How We Copy DNA. Roche Molecular Systems Inc. retrieved From [http://molecular.roche.com/pcr/Pages/Process.aspx]</ref> PCR has many important applications like DNA fingerprinting, genetic mapping, detection of viruses and bacteria as well as being used to detect genetic disorders, as a part of PGD, in conjunction with IVF. It is used to detect molecular abnormalities such as single gene disorders like Tay Sach, Cycstic fibrosis, Duchenne Muscular Dystrophy, Thalassemia, Huntington disease, Spinal muscular atrophy and many more. Molecular and Genetic analysis require a significant amount of DNA, which we would not have without PCR. It revolutionized the study of DNA, replacing all previous recombinant DNA technology. <ref> Mullins, K., Francois, F.& Gibbs R.A. (1994 ) The Polymerase Chain Reaction. p3. Springer- Science +Business Media. Birkhauser, Boston<br />
Available at [https://books.google.com.au/books?hl=en&lr=&id=gjrTBwAAQBAJ&oi=fnd&pg=PR5&dq=kary+mullis+PCR&ots=mpzAyRh5ZY&sig=PQ4goNoKJ90tb3-MkPk62zrTGbw#v=onepage&q=kary%20mullis%20PCR&f=false] </ref> <br />
<br />
[[File:PCR.jpg|thumb|right|Polymerase chain reaction (PCR) amplifies DNA specific to genetic sequence of interest, enabling the monitoring and diagnose molecular abnormalities such as single gene disorders using minute samples such as embryonic cells, blood & tissue <ref>NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref>]]<br />
<br />
====Procedure====<br />
<br />
Sample are obtained from the the blastocyst, a polar body biopsy or the blastomeres stages of the embryo. <br />
Stage 1 Denaturing: separating the target strands of DNA <br />
The obtained sample is heated to roughly 90 degrees celcius, this heat causes breaks the relatively weak bonds between nucleotides that form DNA. the double stranded DNA to split into 2 single strands of DNA that are used as templates.<br />
Stage 2 Annealing: Binding the Primers to the target DNA sequence <br />
PCR will only copy the target sequence of DNA specified by specific PCR primer. These synthesized primers Oligonucleotides are small artificial pieces of DNA. <br />
TAQ polymerase enzyme synthesize 2 new strands of DNA duplicate to the single sample DNA stand template indicated by these primers. During this stage the reaction is cooled to a temperature between 40-60 degrees Celsius. <br />
Stage 3- Extension- making copies <br />
Each of these 2 copies are then used again as templates generating 2 further replications This cycle can occur as many 30 -40 times within a couple hours leading to billions of extra copies of the original DNA segment. The optimal temperature for the further replication is roughly 72 degrees Celsius. <br />
<br />
This process mediated by a thermocycler machine that is programmed to alter the temperature of the reaction every couple of minutes, perpetuating the cycle of DNA denaturing and synthesis. <br />
This process, generates exponential exact copy of the original template DNA sequence. <br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
!PCR cycles<br />
<br />
|{|<br />
|-<br />
| '''PCR Cycle'''<br />
| '''Target Copies'''<br />
|-<br />
| 1<br />
| 2<br />
|-<br />
| 2<br />
| 4<br />
|-<br />
| 3<br />
| 8<br />
|-<br />
| 4<br />
| 16<br />
|-"<br />
| 5 <br />
| 32<br />
|-<br />
| 6 <br />
| 64<br />
|-<br />
| 7 <br />
| 128<br />
|-<br />
| 8<br />
| 256<br />
|- <br />
| 9<br />
| 512 <br />
|-<br />
| 10<br />
| 1024<br />
|-<br />
| 15<br />
| 32,768<br />
|-<br />
| 20 <br />
| 1,048,578<br />
|-<br />
| 25<br />
| 33,554,432<br />
|-<br />
| 30 <br />
| 1,073,741,842<br />
|-<br />
|}<br />
<br />
<br />
<br />
{| class="wikitable" <br />
|-bgcolor="#9ACD32" <br />
| rowspan="10" |'''Advantages'''<br />
|-bgcolor="#F0FFF0"<br />
| fast and inexpensive way of copying a target sequence of DNA<br />
|-bgcolor="#F0FFF0"<br />
| aids the diagnosis of single cell defects<br />
|-bgcolor="#F0FFF0"<br />
| rapid generation of results within a couple hours<br />
|-bgcolor="#F0FFF0"<br />
| can start from a single molecule of DNA, therefore is more sensitive <br />
|-bgcolor="#F0FFF0"<br />
| has a flexible primer design enabling<br />
|-bgcolor="#F0FFF0"<br />
| overcame previous issues associated with the limited availability of sites of end<br />
|-bgcolor="#F0FFF0"<br />
| generates the DNA copies exponentially<br />
|-bgcolor="#F0FFF0"<br />
| enables DNA amplification required for molecular and genetic analysis<br />
|-bgcolor="#F0FFF0"<br />
|Valid diagnostic method in selecting unaffected embryos for embryo transfer <ref> Dreesen, J., Drusedaul, M., Smeets, H., Die-Smulders, C., Coonen, E., Dumoulin, J., Gielen, M., Evers, J., Herbergers, J. & Geradets, J. (2008) Validation of preimplantation genetic diagnosis by PCR analysis: genotype comparison of the blastomere and corresponding embryo, implications for clinical practice. Mol. Hum. Reprod. 14 (10):573-579.doi: 10.1093/molehr/gan052. Retrieved from [http://molehr.oxfordjournals.org/content/14/10/573.short] </ref> <ref><pubmed>20966460</pubmed></ref><br />
|-bgcolor="#9ACD32"<br />
| rowspan="5"|'''Disadvantages'''<br />
|-bgcolor="#F0FFF0"<br />
| only during this exponential DNA replication phase can we determine the starting quantity sequence contained in the original sample ( template DNA strand)<br />
|-bgcolor="#F0FFF0"<br />
| PCR reaction is limited by the presence of inhibitors present in the sample : reagent inhibitors <br />
|-bgcolor="#F0FFF0"<br />
| self annealing due to the accumulation of the product -stopping exponential amplification for the target sequence and reach a plateau<br />
quantification of the end point of reaction of PCR products unreliable - therefore that is why we require real time quantitative RT-PCR necessary<br />
<ref> NIS (2015) Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref><br />
|}<br />
<br />
<br />
===Fluorescent In Situ Hybridisation (FISH)===<br />
<br />
<br />
====Description====<br />
Fluorescence in situ hybridization (FISH) the one of the most effective and rapid <ref name="PMID26338801"><pubmed>26338801</pubmed></ref> Preimplantation Genetic Diagnosis (PGD). This techniques used to locate a specific DNA sequences within a chromosome. FISH facilitates the clinical diagnosis of chromosomal abnormalities indicated by sequential duplications, deletions and rearrangements of chromosome, that are usually missed with microscopic analysis. This technique is especially relevant for female embryos with X-linked diseases,<ref name="PMID20809319"><pubmed>20809319</pubmed></ref> that have no other mutation specific tests [http://www.ncbi.nlm.nih.gov/pubmed/20809319] As part of PGD, samples are collected from various stages of the embyro,and they are able to conducted tests on the blastocyst, a polar body biopsy and the blastomeres <ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. FISH is 99% effective when used in conjunction with competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities<ref name="PMID26338801"/>.<br />
<br />
====Procedure==== <br />
<br />
Samples are collected from either the blastocyst, a polar body biopsy or the blastomeres stages of the embryo <ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
DNA strands are heated and denatured causing their the individual DNA strands to break apart<br />
Probes are single complimentary stands of DNA a that have been tagged with small chemical agents that glow brightly in the presence of a specific region on a chromosome. These specific probes then hybridize and join to their complementary DNA strand. <br />
The fluorescent tags enable the researchers to correctly identify the presence or lack thereof and location of the specific chromosomes that they are testing for. <ref name="PMID17876073"><pubmed>17876073</pubmed></ref><br />
Researcher analyse the results by identifying the number and the relative location of the fluorescent dots generated by the FISH images.<ref name="PMID17970921"><pubmed>17970921</pubmed></ref><br />
The probe will not fully hybridise if there has been a duplication or a deletion of the DNA - indicating chromosomal and sex chromosomal anomalies like trisomies and aneuploidies. <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref><br />
<br />
<br />
Different probes are used for different purposes: <ref>Unique, Rare Chromosome Disorder Support Group (2013) Fluorescence in situ hybridisation (FISH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/Other/FISH%20FTNW.pdf]</ref><br />
*'''Locus specific tags''' detect very small imbalances, and locate isolated small portions <br />
of genes within a chromosome<br />
*'''Alphoid/Centomeric Repeat probes''' are developed from the repetitive sequence located in the middle region of each chromosome, useful in determining the number of chromosomes , detecting rearrangement and when used in conjunction with locus probes to determine the absence of genetic material on a chromosome. <br />
*'''Paint Probes''' are collections of smaller probes with their own stains that bind to a different section on the chromosome - allowing the full chromosome too be labeled a unique colour, this "full colour map" can be used to know the spectral karyotype- full chromosomal mapping is useful in examining chromosomal abnormalities. <br />
<br />
[[File:Fluorescent In Situ Hybridisation (FISH).jpg|thumb|right|'''FISH''' We are able to tag Specific DNA sequences using Probes which have been tagged with fluorescent Labels.This technique enables the clinical diagnosis of chromosomal abnormalities, indicated by sequential duplication, deletions and rearrangements of chromosome <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref>]]<br />
<br />
{|class="wikitable" align="center"<br />
|-bgcolor="pink" <br />
| rowspan="8" |'''Advantages''' <br />
|-bgcolor="#FDE1F2" <br />
| FISH is 99% effective when used in conjunction with Competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities.<ref><pubmed>26338801</pubmed></ref><br />
|-bgcolor="#FDE1F2" <br />
| Rapid generation of results<br />
|-bgcolor="#FDE1F2" <br />
| Identifies very small translocations and aneuploidies that occur within chromosomes, that would usually be missed under microscopic analysis<br />
|-bgcolor="#FDE1F2" <br />
| Indicates whether the accessed chromosomes are normal <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|-bgcolor="#FDE1F2" <br />
| Tests for the most common chromosomal abnormalities - down syndrome chromosomes 13,16,18,21 and 22 <ref><pubmed>21749752</pubmed></ref><br />
|-bgcolor="#FDE1F2" <br />
| It may be used to compare the chromosomal gene arrangements in related species<br />
|-bgcolor="#FDE1F2" <br />
| can be used to identify and remove inheritable X-linked disease or sex chromasome anomalies such as Duchennes Muscular Dystrophy, hemophilia, ectodermal dysplasia <ref><pubmed>17876073</pubmed></ref><br />
|-bgcolor="#FEB745"<br />
| rowspan="5"|'''Disadvantages'''<br />
|-bgcolor="#FE1C5EA"<br />
| FISH destroys all cells tested <ref> O'Connor, C. (2008) Fluorescence in situ hybridization (FISH). Nature Education 1(1):171. retrieved from [http://www.nature.com/scitable/topicpage/fluorescence-in-situ-hybridization-fish-327] </ref><br />
|-bgcolor="#FE1C5EA"<br />
| It does not fully access all chromosomes (only ~ 12)<br />
|-bgcolor="#FE1C5EA"<br />
| Analysis of results is dependent upon the dot quality impacted by hybridisation efficiency or the camera sensitivity <ref><pubmed>17970921</pubmed></ref><br />
|-bgcolor="#FE1C5EA"<br />
| some studies indicate that using FISH on a day-3 embryo biopsy decreases the rate of live births <ref><pubmed>26168107</pubmed></ref><br />
|}<br />
<br />
===Array Comparative Genomic Hybridisation (aCGH)===<br />
====Description====<br />
<br />
aCGH also known as Microarray analysis efficiently scans the entire genome for chromosomal imbalances. CGH was initially developed to detect the number of changes in a solid tumor mass. It uses 2 genomes comparing the sample to the control, with each labeled in a different fluorescent dye<ref name="PMID1876176"><pubmed>1876176</pubmed></ref>. Earlier CGH techniques were limited by the resolution of the imaging <ref> Lichter, P., et al. Comparative genomic hybridization: Uses and limitations. Seminars in Hematology 37, 348–357 (2000)</ref> , these initial limitations were overcome by using Microarrays in conjunction with CGh to improve the resolution of the imaging, Array Comparative Genomic Hybridisation (aCGH). This method compares sample and control microarrayed slides containing small segments of DNA (probes). <ref> Lucito, R., et al. Representational oligonucleotide microarray analysis: A high-resolution method to detect genome copy number variation. Genome Research 13, 2291–2305 (2003) </ref> the Probes used will vary according from the small (25-85 base pairs) oligonucleotides manufactured to highlight different target sequences, to the very large genomic clones (80,000- 200,00 base pairs), and as these are significantly smaller than the traditional metaphase chromosomes used for CGH, generating a higher resolution of image. <ref name="PMID22467166"><pubmed>22467166</pubmed></ref>.aCGH is used as a diagnostic tool for prenatal detection f chromosomal abnormalities <ref name="PMID19012303"><pubmed>19012303</pubmed></ref>.<br />
<br />
<br />
====Procedure====<br />
<ref> Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432] </ref><br />
The sample is obtained (skin, blood or fetal cells) and DNA is obtained. <br />
As a part of PGD fetal cell samples are collected from; the fertilized egg polar bodies, the blastomere (day 3 embryo) or the blastocyst/tropoectoderm stage (day 5 embryo).<br />
Sample DNA is labeled with one fluorescent dye, and the control DNA is labeled with a different colored fluorescent dye. the control DNA is used as the base point of reference. <br />
heated and denatured single DNA strands then hybridize to their complementary single strand probes, which are then combined and applied to a microarray and the results are run through a computer program and a digital imaging system is used to quantify the results( fluorescent intensities of the labeled probes). <br />
<br />
[[File:aCGH.jpg|thumb|right|'''aCGH''' checks the entire genome for chromosomal imbalances, by comparing control and a sample slides contatining small segements of DNA sample microarrayed slides small segments of DNA. Illustrated by student z5020317 and adapted from <ref> NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation. retrieved from [http://www.phgfoundation.org/file/5237/]</ref> <ref>Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432]</ref>]]<br />
<br />
<br />
<br />
The fluorescent ratio and the hybridization signal at different locations on the genome of the control DNA are used to identify any variances present in the sample DNA. aCGH facilitates the clinical diagnosis of submicroscopic chromosomal duplication, deletion and rearrangements indicative of chromosomal disorders such as trisomies 1-22and specific sex linked disorders. <br />
Duplications in the DNA are displayed by the computer program as spikes/ peaks over an established threshold and deletions in DNA are displayed by the computer program as spikes/ toughs beneath this threshold <br />
<br />
<br />
<br />
<br />
{|border="1" align="center"<br />
|-bgcolor="pink" <br />
| '''Advantages''' <br />
| '''Disadvantages'''<br />
|-<br />
| multiple applications: prenatal genetic diagnosis, cancer diagnosis, <ref name="PMID20193845"><pubmed>20193845</pubmed></ref> genetic screening for developmental delay (learning disabilities) <ref name="PMID17309648"><pubmed>17309648</pubmed></ref>. or congenital anomalies that are suspected to be genetic in origin <ref>NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation . retrieved from [http://www.phgfoundation.org/file/5237/]</ref><br />
| translocations and inversions of DNA are not detected<br />
|-bgcolor="pink"<br />
| trace represents all chromosomes present in the human genome chromosomes 1-22 and the X & Y chromosomes, and therefore is the most accurate method for testing whole embryo aneuploidy<br />
| limited ability diagnosing specific polyploidies such as triploidy <ref> Unique, Rare Chromosome Disorder Support Group (2013) Microarray-based Comparative Genomic Hybridiation (array CGH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/other/array%20cgh%20ftnw.pdf] </ref><br />
|-<br />
| aCGH has been extensively tested, and Validated, and is now used world wide.<br />
| will not detect mosaicism detection <20% (cultures where >1 of 5 cells are trisomy 12)<br />
|-bgcolor="pink"<br />
| detects deletions and additions and rearrangements as well as amplification, of the WHOLE genome, simultaneously.<br />
| will not detect balanced chromosomal rearrangement<br />
|-<br />
| detects submicroscopic alterations<br />
| will not detect duplications or deletions <80kb<br />
|-bgcolor="pink"<br />
| used as a diagnostic tool for prenatal detection of chromosomal abnormalities <ref name="PMID22034057"><pubmed>22034057</pubmed></ref><br />
| will not detect point mutations within genes <ref>Washington department of education (CGH- FAQ for physicians. Signature Genomic LAboratories, LLC. Retrieved from [https://depts.washington.edu/dbpeds/Lab%20Tests/SignatureCGH-physician_FAQ.pdf]</ref><br />
|-<br />
| provides high resolution genomewide screening of segmental genomic copy number variations<br />
| will not detect chromosomal position of genomic gains<br />
|-bgcolor="pink"<br />
| very accurate when used in conjunction with FISH<br />
| will not detect loos of heterozygosity (LOH) or Absence of heterozygosity (AOH) <ref>WiCell Research Institute Inc. (2012) Comparative Genomic Hybridization Microarray. <br />
retrieved from [http://www.wicell.org/home/cytogenetic-services/cgh-microarray/array-comparative-genomic-hybridization-acgh.cmsx]</ref><br />
|-<br />
|Alone is more reliable and in detecting chromosomal abnormalities, with a higher implantation success rate, than FISH <ref name="PMID20494259"><pubmed>20494259</pubmed></ref><br />
|<br />
|-bgcolor="pink"<br />
|Allows an in depth research focus upon specific types of rearrangements within selected chromosomal regions, a recent particular area of interest is subtelomeric and pericentromeric rearrangements<br />
|<br />
|-<br />
|reduces the risk of failed implantation and miscarriage, improving the chance of a healthy baby <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|<br />
|}<br />
<br />
<br />
<br />
===Next Generation Sequencing===<br />
====Description====<br />
The development and advances within ART in the past 20 years, as well as the increasing popularity of IV, has lead to an influx of new technologies developed to screen embryos for chromosomal anomalies, which are covered by the umbrella term of Next generation Sequencing (NGS). NGS is a general term used to describe all of the new and emerging screening techniques currently being introduced and used as part of PGD for IVF . NGS screens for single gene disorders as well as conducting extensive and very comprehensive chromosome diagnosis by sequencing, counting, and accurately assembling millions of DNA reads, simultaneously. <ref name="PMID23499002"><pubmed>23499002</pubmed></ref> There is a movement for NGS to replace the other limited testing techniques and be used as the standard. <br />
====Procedure====<br />
Samples are collected from either blastomere or the blastocyst/tropoectoderm and processed for analysis by a computer system. <br />
The methodology of each process is unique to the technique being used. <br />
<br />
<br />
<br />
{|border="1" align="center"<br />
|-bgcolor="pink" <br />
| '''Advantages'''<br />
| '''Disadvantages'''<br />
|-bgcolor="white"<br />
| cheaper<br />
| there are limited information available to clinical applications of NGS <ref><pubmed>26100406</pubmed></ref><br />
|-bgcolor="pink"<br />
| opens new diagnostic possibilities<br />
|<br />
|-bgcolor="white"<br />
| accurately tests all 24 chromosomes<br />
| <br />
|-bgcolor="pink"<br />
| tests for the presence of monogenic diseases of known genetic background<br />
| <br />
|-bgcolor="white"<br />
| reduces the number of biopsies required for diagnosis<br />
| <br />
|-bgcolor="pink"<br />
| higher detection rate of small translocations<br />
| <br />
|-bgcolor="white"<br />
| highly accurate is testing for compound point mutations, chromosomal duplication, deletions and insertions <ref name="23312231"><pubmed>23312231</pubmed></ref><br />
| <br />
|-bgcolor="pink"<br />
| it accurately detects chromosomal aneuploidy and unbalanced rearrangement <ref name="PMID25685330"><pubmed>25685330</pubmed></ref><br />
| <br />
|-bgcolor="white"<br />
| NGS single gene disorder screenings can conducted in conjunction with PCR comprehensive chromosomal screening<br />
|<br />
|-bgcolor="pink"<br />
| Reduces human error <br />
|<br />
|-bgcolor="white"<br />
| better detects the presence of mosaicism<br />
|<br />
|-bgcolor="pink"<br />
| work well in conjunction with CGH and aCGH as part of PGD, improving the chances of IVF. <ref> Morris, R. S. (2015 ) Next generation sequencing for PCG|PGS|CCS. IVF1 retrieved from [http://www.ivf1.com/next-generation-sequencing for-pgd] </ref><br />
|<br />
|}<br />
<br />
<br />
<br />
<br />
<br />
<br />
==Diagnosis==<br />
There are a large amount of diseases that PGD can apply to, below are descriptions of the diseases that PGD are more commonly used for. Utilization of Diseased Cell Lines<br />
===Cystic Fibrosis===<br />
Cystic fibrosis is a single gene disorder. It is autosomal recessive and involves mutations in the cystic fibrosis transmembrane conductance regulator (CTFR) gene. The CTFR gene is normally responsible for the decrease in chloride and the transport of bicarbonate in epithelial cells thus playing a major physiological role. In PGD procedures, identification of the gene is assisted by microsatellite markers that have similar composition to the CTFR gene itself. Biopsy of two cells at the blastocyst stage is recommended if markers are not available. There are many variations of cystic fibrosis the most common being P.Phe508del <ref name="PMID26014425"><pubmed>26014425</pubmed></ref>.<br />
===Duchenne Muscular Dystrophy ===<br />
Duchenne Muscular Dystrophy is an X-linked recessive disease. It involves the Xp21 gene where majority of the mutations are chromosomal deletions with a smaller percentage resulting from duplications <ref name="PMID18359022"><pubmed>18359022</pubmed></ref>.<br />
===β – Thalassemia=== <br />
β – Thalassemia is known as the most common type of autosomal recessive inherited disorder among haemoglobinopathies. It involves the adult β-globin gene and is associated with the absent or decreased expression of the gene. This is commonly caused by a single nucleotide change in the gene. PGD has been used successfully worldwide to identify the β-globin gene where its application is usually performed on a single blastomere or polar body <ref name="PMID19064120">19064120</pubmed></ref>.<br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
! Applicable diseases for PGD <ref>Genoma Group (2014). Retrieved September 18th, 2015, from http://www.preimplantationgeneticdiagnosis.it/genetic-diseases-diagnosed-by-pgd.htm </ref>, <ref>Genesis Genetics (2015). Retrieved September 18th, 2015, from http://genesisgenetics.org/pgd/what-we-test-for/</ref>, <ref>Human Fertilisation & Embryology Authority (2015). Retrieved Septembr 18th, 2015, from http://guide.hfea.gov.uk/pgd/</ref><br />
|-<br />
| '''Disease'''<br />
| '''Involved Genes'''<br />
|-<br />
| 5 Alpha Reductase Deficiency (5ARD)<br />
| SRD5A2 <br />
|-<br />
| Achondroplasia<br />
|FGFR3 <br />
|-<br />
| Acute Intermittent Porphyria <br />
| ALAD, ALAS2, CPOX, FECH, HMBS, PPOX, UROD, or UROS<br />
|-<br />
| Adrenoleukodystrophy (Adrenomyeloneuropathy)<br />
| ABCD1 <br />
|-<br />
| Agammaglobulinaemia (x-linked) <br />
|BTK <br />
|-<br />
| Agammaglobulinemia Bruton Tyrosine Kinase (BTK) <br />
|BTK <br />
|-<br />
| Aicardi Goutieres Syndrome 1 (AGS1) <br />
|TREX1, RNASEH2A, RNASEH2B, RNASEH2C, SAMHD1<br />
|-<br />
| Alagille Syndrome<br />
|JAG1 or NOTCH2<br />
|- <br />
| Alpers-Huttenlocher Syndrome <br />
|POLG <br />
|-<br />
| Alpha-1-antitrypsin deficiency <br />
|SERPINA1 <br />
|-<br />
| Alpha-Mannosidosis<br />
| MAN2B1 <br />
|-<br />
| Alpha Thalassemia <br />
|HBA1 or HBA2 <br />
|-<br />
| Alports Syndrome<br />
|COL4A3, COL4A4, COL4A5<br />
|-<br />
| Alzheimer's Disease - early onset (Type 3 and 4) <br />
|APP, PSEN1, or PSEN2<br />
|-<br />
| Amyotrophic Lateral Sclerosis 1 (ALS1) <br />
|C9orf72, SOD1, TARDBP, FUS, ANG, ALS2, SETX, VAPB <br />
|-<br />
| Argininosuccinic Aciduria <br />
| ASL<br />
|-<br />
| Arrhythmogenic Right Ventricular Cardiomyopathy/ Dysplasia (ARVC/D)<br />
| DSG2; DSP; PKP2<br />
|-<br />
| Ataxia Telangiectasia<br />
| ATM<br />
|-<br />
| Bardet-Biedl Syndrome (BBS)<br />
| BBS1; BBS10<br />
|-<br />
| Barth Syndrome<br />
| TAZ<br />
|-<br />
| Beta Thalassaemia<br />
| HBB<br />
|-<br />
| Birt-Hogg-Dubé Syndrome<br />
| FLCN<br />
|-<br />
| Breast Ovarian Cancer Familial Susceptibility (BRCA2)<br />
| BRCA1; BRCA2<br />
|-<br />
| Canavan Disease <br />
| ASPA<br />
|-<br />
| Carnitine-Acylcarnitine Translocase Deficiency <br />
| SLC25A20<br />
|-<br />
| Cerebral Arteriopathy with Subcortical Infarcts & Leukoencephalopathy (CADASIL)<br />
| NOTCH3<br />
|-<br />
| Cerebral Cavernous Malformation<br />
| CCM1<br />
|-<br />
| Charcot-Marie-Tooth Disease<br />
| GJB1; MPZ; NEFL; PMP22<br />
|-<br />
| CHARGE Syndrome<br />
| CHD7<br />
|-<br />
| Cherubism<br />
| SH3BP2<br />
|-<br />
| Choroideremia<br />
| CHM<br />
|-<br />
| Chronic Granulomatous Disease<br />
| CYBB; NCF1<br />
|-<br />
| Ciliary Dyskinesia<br />
| DNAH5<br />
|-<br />
| Citrullinemia<br />
| ASS1<br />
|-<br />
| Cleidocranial Dysplasia<br />
| RUNX2<br />
|-<br />
| Cockayne Syndrome<br />
| ERCC6<br />
|-<br />
| Congenital Adrenal Hyperplasia<br />
| CYP21A2<br />
|-<br />
| Congenital Cataracts<br />
| GJA8; VSX2<br />
|-<br />
| Congenital Diarrhea, Syndromic<br />
| SPINT2<br />
|-<br />
| Congenital Disorders of Glycosylation (CDG)<br />
| ALG1; ALG6; CDG1C; DOLK; PMM2<br />
|-<br />
| Cornelia de Lange Syndrome <br />
| NIPBL<br />
|-<br />
| Craniosynostosis<br />
| TWIST1<br />
|-<br />
| Crouzon Syndrome<br />
| FGFR2<br />
|-<br />
| Cysteinyl Leukotriene Receptor 1 Deficiency <br />
| CYSLTR1<br />
|-<br />
| Cystic Fibrosis<br />
| CFTR<br />
|-<br />
| Diamond –Blackfan Anemia <br />
| RPS19<br />
|-<br />
| Duchenne Muscular Dystrophy <br />
| DMD<br />
|-<br />
| Dyskeratosis congenita (Male embryos only)<br />
| DKC1<br />
|-<br />
| Ectodermal dysplasia (Hypohidrotic)<br />
| EDA; EDA1; GJB6; IKBKG<br />
|-<br />
| Familial Adenomatous polyposis coli (FAP)<br />
| APC<br />
|-<br />
| Familial Dysautonomia<br />
| IKBKAP<br />
|-<br />
| Fanconi Anemia <br />
| FANCA; FANCC; FANCD2; FANCF; FANCG; FANCJ<br />
|-<br />
| Fragile X Syndrome (FRAX)<br />
| FMR1<br />
|-<br />
| Galactosemia <br />
| GALT<br />
|-<br />
| Gangliosidosis<br />
| GLB1<br />
|-<br />
| Glanzmann Thrombasthenia <br />
| ITGA2B<br />
|-<br />
| Glutaric Acidemia (aciduria)<br />
| GCDH <br />
|-<br />
| Glycogen Storage Disease <br />
| G6PC; GAA; SLC37A4<br />
|-<br />
| Haemophilia A<br />
| F8<br />
|-<br />
| Haemophilia B<br />
| F9<br />
|-<br />
| Hereditary Nonpolyposis Colorectal Cancer: Lynch Syndrome<br />
| MLH1; MSH2; MSH6<br />
|-<br />
| Holt Oram Syndrome<br />
| TBX5<br />
|-<br />
| Huntington Disease<br />
| HD<br />
|-<br />
| Hydrocephalus<br />
| L1CAM<br />
|-<br />
| Ichthyosis <br />
| ABCA12; STS<br />
|-<br />
| Incontinentia Pigmenti (IP)<br />
| NEMO<br />
|-<br />
| Joubert Syndrome 5<br />
| INPP5E<br />
|-<br />
| Krabbe Disease<br />
| GALC<br />
|-<br />
| Leber Congenital Amaurosis (LCA)<br />
| CEP290; GUCY2D<br />
|-<br />
| Leigh Syndrome (Infantile Subacute Necrotising Encephalopathy)<br />
| LRPPRC<br />
|-<br />
| Lesch Nyan Syndrome<br />
| HPRT1<br />
|-<br />
| Leukocyte Adhesion Deficiency (Type I)<br />
| ITGB2<br />
|-<br />
| Li-Fraumeni Syndrome<br />
| TP53<br />
|-<br />
| Macular Dystrophy Retinal <br />
| VMD2<br />
|-<br />
| Maple Syrup Urine Disorder (MSUD)<br />
| BCKDHB<br />
|-<br />
| Marfan Syndrome <br />
| FBN1<br />
|-<br />
| Menkes Syndrome<br />
| ATP7A<br />
|-<br />
| Mitochondrial DNA Depletion Syndrom <br />
| POLG; RRM2B; SUCLA2; TK2<br />
|-<br />
| Mucolipidosis type II<br />
| GNPTAB<br />
|-<br />
| Multiple Endocrine Neoplasia<br />
| MEN1; MEN2A; MEN2B<br />
|-<br />
| Multiple Exostoses<br />
| EXT1; EXT2 <br />
|-<br />
| Myotubular myopathy<br />
| MTM1 <br />
|-<br />
| Nail-Patella Syndrome<br />
| LMX1B<br />
|-<br />
| Neurofibromatosis Type 1<br />
| NF1<br />
|-<br />
| Neurofibromatosis Type 2 <br />
| NF2<br />
|-<br />
| Noonan Syndrome<br />
| KRAS, PTPN11; SOS1<br />
|-<br />
| Norrie Disease<br />
| NDP<br />
|-<br />
| Ocular Albinism <br />
| GPR143<br />
|-<br />
| Oculocutaneous Albinism <br />
| OCA2; TYR <br />
|-<br />
| Oculodentaldigital Dysplasia<br />
| GJA1<br />
|-<br />
| Optic Atrophy<br />
| OPA1<br />
|-<br />
| Ornithine Transcarbamylase Deficiency <br />
| OTC<br />
|-<br />
| Osteogenesis imperfeca <br />
| COL1A1; COL1A2<br />
|-<br />
| Osteopetrosis <br />
| CLCN7; OSTM1; TCIRG1<br />
|-<br />
| Pachyonychia Congenita <br />
| KRT16; KRT6A<br />
|-<br />
| Pancreatitis, Hereditary<br />
| PRSS1 <br />
|-<br />
| Papillorenal syndrome <br />
| PAX2<br />
|-<br />
| Phenylketonuria <br />
| PAH <br />
|-<br />
| This table does not cover the complete list of diseases that PGD can be applied to.<br />
|}<br />
<br />
==Laws & Legal status==<br />
<br />
{ class="wikitable" <br />
|-<br />
| Australia<br />
| PGD is currently used to detect serious genetic conditions to improve the outcome of Assisted Reproductive Technologies (ART). In very rare cases it may be used to select an embryo with compatible tissue for a sibling who has a life-threatening disease where other means of treatment is unavailable. This is with the conditions that the use of PGD will not affect the welfare and interests of the child to be born. The parents must also receive adequate counselling and have full understanding of the procedures of PGD. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"> National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art</ref><br />
The use of PGD for sex-selection is prohibited with the exception of reducing the risk of the transmission of serious sex-linked genetic conditions. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"/><br />
|-<br />
| Brazil<br />
| The laws regarding PGD in Brazil are not strictly regulated. They are vague and there is limited information surround the activities of assisted reproduction in general in the country <ref name="PMID25493379"><pubmed>25493379</pubmed></ref>.<br />
|-<br />
| Czech Republic<br />
| The laws in the Czech Republic allow those with a “defined indication in order to exclude risk of serous genetically conditioned disease and defects with embryos before they are implanted into the cavity of the uterus”. Couples that undergo any assisted reproductive treatment including PGD have to be married. Sex-selection is illegal except in regards to serious sex-linked genetic diseases <ref name="PMID24777348"><pubmed>24777348</pubmed></ref>.<br />
|-<br />
| Greece<br />
| In Greece, ART is open to those up to the age of 50 with written consent. It can only be used if a medical necessity is present such as the susceptibility of serious hereditary diseases. Sex selection is banned apart from cases of sex-linked diseases and sexually transmitted diseases <ref name="PMID24777348"/>.<br />
|-<br />
| India<br />
| In India there is a cultural preference for boys thus the Prenatal Diagnostic Techniques (Regulation and Prevention of Misuse) Act was introduced in 1994. This law limits the use of PGD for sex determination except in cases of specific congenital diseases. These laws however are not strictly enforced. <ref>World Health Organisation (2015) Gender and Genetics Retrieved on October 21st 2015 from:http://www.who.int/genomics/gender/en/index4.html</ref><br />
|-<br />
| Portugal <br />
| ART is only available to those who are married or have a similar type of relationship for at least two years. The couples cannot be of the same sex and must be at least 18 years of age. Sex selection is illegal except in cases of sex-linked diseases. The use of PGD is illegal if the predictive value of genetic tests are very low <ref name="PMID24777348"/>.<br />
|-<br />
| Spain<br />
| PGD can be applied to “serious hereditary diseases not amenable to postnatal curative treatment” and “detection of other abnormalities which may compromise the viability of the pre-embryo”. If PGD is to be used for any other purpose authorisation must be acquired <ref name="PMID24777348"/>.<br />
|-<br />
| Sweden <br />
| The use of PGD is strictly regulated and couples must achieve authorisation of the National Board of Health and Welfare. It can only be used it can only be used if the child is at risk to inheriting a serious chromosomal or monogenetic disease. It cannot be used for selection of specific characteristics <ref name="PMID24777348"/>.<br />
|-<br />
| United Kingdom<br />
| Those involved with carrying out the IVF treatment must have a license from the Human Fertilisation and Embryology Authority (HFEA). Only embryos that are approved by the HFEA can be implanted where the embryonic nuclear or mitochondrial DNA cannot be altered with the exception of preventing mitochondrial diseases <ref name="PMID24777348"/>. <br />
|}<br />
<br />
==Future/Current Research==<br />
===Noninvasive Preimplantation Genetic Testing without Embryo Biopsy===<br />
Different parameters of gametes, zygotes, embryos (“vacuoles in sperm heads, spindle position in mature oocytes, cleavage intervals of zygote, and embryo developmental dynamics”) may correlate with aneuploidy rates. This knowledge may be applied in potential noninvasive preimplantation diagnostic methods. Several methods have been proposed and are currently further researched<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Sperm Selection====<br />
Intracytoplasmic morphologically selected sperm injection (IMSI) is common procedure in IVF treatment to improve fertilization rates in patients with poor semen quality. In addition, studies have found that IMSI improves embryo development and that spermatozoa with large vacuoles in their heads correlate with increased aneuploidy rates and disturbed chromosomal structures. Thus, selecting spermatozoa based on morphological hallmarks may decrease aneuploidy rates in the fertilized embryos. As with polar body biopsies, however, this approach will solely be applicable if evidence for severe male detrimental contribution is given<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Blastocoel Fluid Extraction====<br />
In addition, a less invasive retrieval of material for diagnosis could include the extraction of the blastocoel fluid. The cavity of the blastocyst, lined by the trophectoderm, is filled with this blastocoel fluid, which contains metabolites of both trophectoderm and inner cell mass origin. The retrieval does not require a biopsy but merely a small opening to extract the fluid and, thus, causes less harm to the embryo. Multiple studies have applied this method<ref name="PMID22020776"><pubmed>22020776</pubmed></ref> <ref name="PMID23148560"><pubmed>23148560</pubmed></ref> and it may in the future become of clinical relevance.<br />
<br />
<br />
[[File:Aspiration_of_the_Blastocoel_Fluid.jpeg|thumb|Aspiration of the Blastocoel Fluid using a ICSI pipette<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.]]<br />
<br />
<br />
Next to metabolites, the blastocoel fluid can contain DNA. Studies have shown that genomic DNA is present in about 90% of the blastocoel fluid samples tested. Typically the fluid is removed with an ICSI pipette from a day five blastocyst through its mural trophectoderm until the blastocyst fully collapses around the embryo. Several concerns regarding this method in a clinical setting have been raised. The collected DNA may be contaminated by the culture media that contains DNA fractions. The DNA may also be least representative of the actual embryos genome as the DNA may originate from abnormal or degenerated cells. Even though labelled noninvasive, the blastocyst still undergoes manipulation to some degree which may affect its viability. Thus, more research is required until this method can evolve from research to clinical use<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
====Proteomics====<br />
The protein secretome of blastocysts may be representative of its chromosome constitution Recent studies have found biomarkers such as lipocalin-1, interleukin-10, tumor necrosis factor, stem cell factor, and chemokine ligand 13 to be differently secreted by aneuploid blastocyst than by euploid ones. The most significant biomarker appears to be interleukin-10. Paired with novel proteomic technologies and mass spectrometry this knowledge when extended may contribute to a new invasive preimplantation genetic diagnosis method<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Embryo Morphology====<br />
Using time lapse imaging the embryo’s morphology can be closely observed and potential aneuploidy characteristics detected. Such characteristics may include the time of division to five cells, the time between the division from three to four cells, and the duration of the division from one to two and subsequently to three. In addition, the morphological quality of ICM an TE has been positively associated with aneuploidy or euploidy prognosis<ref name="PMID26246880"><pubmed>26246880</pubmed></ref>. These may give rise to an embryo quality screening prior to implantation<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
==References==<br />
<br />
<references/><br />
<br />
<br />
{{StudentPage2015}}</div>Z5017878https://embryology.med.unsw.edu.au/embryology/index.php?title=2015_Group_Project_6&diff=2069952015 Group Project 62015-10-21T06:26:08Z<p>Z5017878: </p>
<hr />
<div>{{ANAT2341Project2015header}}<br />
<br />
<br />
=Preimplantation Genetic Diagnosis and Screening=<br />
==Introduction==<br />
Preimplantation genetic diagnosis (PGD) and screening (PGS) are reproductive options for couples with known family histories of genetic disease or couples undergoing IVF procedures due to infertility issues. PGD can diagnose many genetic disorders caused by known chromosomal abnormalities (number and/or structure) or single gene mutations, and, thus decrease the risk of termination of pregnancy or miscarriages and enable such couples to have an unaffected child<ref name="PMID24907939"><pubmed>24907939</pubmed></ref>. Through major improvements in PGD/S and general laboratory technology, the testing for abnormalities in fetuses has shifted from prenatal diagnosis during the first 2 trimesters <ref> Blackburn, S.L. (2003) '''Maternal, Fetal & Neonatal physiology: a Clinical perspective''' (2nd ed.). Seattle: Saudners </ref>, testing for overall fetal growth, complications of pregnancy, and birth defects<ref> Sadler T.W.(2012) '''Langman's Medical Embryology''' (12th ed.) Philadelphia: Lipincott, Wiliams & Wilkins, a Wolters Kluwer Business </ref>, to an embryonic focus especially in advancements in Artificial Reproductive Technologies (ART)<ref><pubmed>20638568</pubmed></ref>. In 1990 PGD for a recessive X-linked disease resulted in the first live birth<ref><pubmed>2330030</pubmed></ref> and has since been incorporated in clinical routine and applied for a variety of genetic diseases, such as sickle cell anemia, thalassemia, or cystic fibrosis<ref name="PMID24907939"/>.<br />
[[File:Preimplantation Genetic Diagnosis Procedure.jpeg|700px|thumb|centre| Simplified steps for PGD<ref name="PMID24907939"/>]]<br />
<br />
==History==<br />
<br />
==Preimplantation Genetic Diagnosis==<br />
Preimplantation genetic diagnosis (PGD) is used to test the genetic makeup of embryos to detect single gene disorders, chromosomal abnormalities and mitochondrial disorders. It also has applications in gender selection for diseases with unequal gender distributions <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Some diseases commonly involved with PGD include cystic fibrosis, spinal muscular atrophy and beta – thalassaemia <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press.">Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press</ref> <ref name="PMID17823145"><pubmed>17823145</pubmed></ref>. It was first used in the United Kingdom in the 1980s of arenoleucodystrophy and primarily focusing on sex- linked disorders <ref name="PMID17823145"/><ref name="PMID23150080"><pubmed>23150080</pubmed></ref>. PGD is now capable of detecting single cell defects (molecular) and chromosomal disorders resulting from the inversion, translocation or deletion of chromosomes (cytogenic) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>,<ref name="PMID11325751"><pubmed>11325751</pubmed></ref>. PGD can be applied to the embryo at different stages. That is on polar bodies, blastomeres or blastocyst <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>.<br />
Depending on the type of genetic disorder, PGD utilises different methods of genetic testing. These include Fluorescence in situ hybridisation (FISH) which is used for sex – linked disorders and detects chromosomal rearrangements <ref name="PMID11325751"/><ref name="PMID17876073"><pubmed>17876073</pubmed></ref> and Embryo halotyping which allows the identification of chromosomes causing the inherited disorder through knowledge of the pattern of closely linked markers <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. Polymerase chain reaction (PCR) is also widely used to detect molecular abnormalities <ref name="PMID11325751"/>.<br />
PGD is tightly regulated and supported by large organisations namely The American Society for Reproductive Medicine, The European Society for Human Reproduction and Embryology (ESHRE), The European Society of Human Genetics and the Preimplantation Genetic Diagnosis International Society <ref name="PMID25500181><pubmed>25500181</pubmed></ref>.<br />
===Sex-linked disorders===<br />
The determination of a disease as gender specific usually correlates with the presence or absence of specific genes such as SRY on the Y chromosome. It is known that females have two X chromosomes and males have an X and a Y chromosome where abnormalities are more prevalent on the X chromosome. PGD can be used for sex selection where only male embryos are transferred to reduce the chance of inheriting X-linked disorders. However, this does not completely eradicate the problem as male embryos remain susceptible to inheriting an affected X chromosome. Sex determination is only used when the specific mutation is unknown and has yet to be discovered <ref name="PMID24866878"><pubmed>24866878</pubmed></ref>.<br />
===Single gene defects===<br />
Single gene defects can be dominant, recessive, autosomal or X-linked. They are commonly diagnosed using PCR and although the PCR available today is complex and capable of combatting a large range of disease the development of new protocols has been proven to be difficult due to the small DNA sample available <ref name="PMID26168107"><pubmed>26168107</pubmed></ref><br />
===Mitochondrial disorders===<br />
Mitochondrial disorders also known as oxidative phosphorylation disorders arise from mutations in the nuclear DNA or mitochondrial DNA <ref name="PMID26312584"><pubmed>26312584</pubmed></ref>. They pose as a problem because they are unrecognisable until the mutations in the cell reach a detrimental level <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Mitochondrial disorders cause miscarriages and stillbirths as well as death in children and young adults. The effects can either be contained in a single organ or more commonly involve multiple organ failure where organs with high energy demands such as the brain, liver muscle and heart and heavily influenced. They are usually occur spontaneously or result from inheritance from the mother. Since mitochondria are solely inherited from the mother oocyte donations have been used as a solution to combat mitochondrial disorders. Additionally, there has been an increasing use in PGD where embryos that stay under the given threshold of 18% gene-mutations are allowed to be transferred and result in normal development. New technology in the areas of nuclear gene transfer and genome editing are also being experimented with <ref name="PMID26312584"/>. <br />
===Chromosomal disorders===<br />
Chromosomal disorders can be reciprocal, Robertsonian translocations, inversions, deletions and insertions <ref name="PMID26168107"/>. . Data from ESHRE collected between 2010 and 2011 has shown that the most common chromosomal abnormality confronted in PGD are reciprocal chromosomal abnormalities <ref name"PMID26071418"><pubmed>26071418</pubmed></ref>. PGD has also been used successfully for Robertsonian translocations (RT), a type of structural translocation. Children who carry RT are phenotypically normal, however in their later years it is found that they will suffer from infertility and repeated miscarriages due to the high frequency of abnormal embryos <ref name="PMID22081077"><pubmed>22081077</pubmed></ref>. PCR and FISH are the two main techniques used for chromosomal disorders. To be able to conduct the examinations the cells are required to be at the metaphase stage <ref name="PMID26168107"/>. <br />
==Preimplantation Genetic Screening==<br />
Prenatal Genetic Screening (PGS) involves an array of methods or ideas that aim to segregate embryos that have genetic flaws and those that are healthy <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. The occurrence of aneuploidy is high around the stages of early embryonic development and they are the most common cause if miscarriages and congenital birth defects <ref name= "PMID26085841"><pubmed>26085841</pubmed></ref>. They have little effect on the morphology of the embryo making them difficult to identify thus identification heavily relies on genetic testing <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. <br />
Genetic sampling is most commonly conducted using Microarray Comparative Genomic Hybridisation (aCGH) as well as FISH, Quantitative PCR and Single Nucleotide Polymorphism (SNP) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. These methods collectively aim to assess numeral and structural chromosomal errors <ref name= "PMID26085841"/>. Studies have also introduced Next- Generation Sequencing (NGS) <ref name= "PMID26085841"/> and Whole Genome Amplification used to screen imbalances in the complete 24-chromosomes <ref name="PMID25953353"><pubmed>25953353</pubmed></ref><br />
Statistics from ESHRE have shown that the most common indications for PGS is advanced age, followed by repeated implantation failure or recurrent miscarriage and male infertility <ref name="PMID26071418"><pubmed>26071418</pubmed></ref>.<br />
====Indications====<br />
A low percentage of structural abnormalities in chromosomes are responsible for the cause of miscarriages. Despite this, they are the most prevalent type of chromosomal abnormality accounted for in PGD <ref name="PMID20638568"/>. The presence of specific gene cycles, initiation of embryonic protein synthesis and evident physiological development are all indicative of a successful in vitro fertilisation procedure <ref name="PMID11576737"><pubmed>11576737</pubmed></ref>. To eliminate further errors from occurring during the PGD procedure it is recommended to undertake further prenatal testing such as amniocentesis in the later stages <ref name="PMID20638568"/>. <br />
=====Advanced maternal age=====<br />
Data provided by the ESHRE has shown that the mean age of women undergoing PGS is 39 years <ref name="PMID26071418"/>. Women of advanced age have been shown to have a lower rate of pregnancies reaching childbirth <ref name="PMID18583331"><pubmed>18583331</pubmed></ref>. The highlighted concern revolves around the increased occurrence of aneuploidy following maternal age. The optimal age range for the lowest aneuploidy incidence was found to be between 27 to 37 years of age (6%) then progressively higher in women aged up to 42 (33%) and most common in those 44 and above (53%) <ref name="PMID24355045"><pubmed>24355045</pubmed></ref>. <br />
=====Recurrent pregnancy loss / IVF failure=====<br />
Recurrent pregnancy loss is defined as three or more IVF failures after cumulative transfer of more than 10 good-quality embryos. These are primarily caused by two main factors, reduced endometrium receptivity or embryonic defects. Endometrium receptivity can be negatively influences by instances including uterine pathologies such as thin endometrium, altered expression of adhesive molecules and immunological factors. Additionally, embryonic defects may be due to genetic abnormalities, embryonic aneuploidy or zona hardening. Endometriosis and hydrosalpinx has been known to effect both the endometrium and embryo <ref name="PMID23260857"><pubmed>23260857</pubmed></ref>.<br />
=====Human leukocyte antigen matching=====<br />
First used in 2001, HLA matching is an option given to parents to save a child with haematological or immunological disease through conceiving another child who would potentially be able to donate cord blood or haematopoietic stem cells from the bone marrow for transplantation. The process namely PGD-HLA has shown to improve haematopoietic stem cell transplant (HSCT). PGD-HLA can only be performed when HSCT is not needed urgently due to the time needed to conceive and delivery the baby <ref name="PMID25500181"><pubmed>25500181</pubmed></ref>. It is most commonly applied to children suffering from relapsed leukaemia <ref name="PMID22524201"><pubmed>22524201</pubmed></ref>. In a case study PGD-HLA was proven to successfully cure 10 diseases including Fanconi anaemia, Diamond-Blackfan anaemia and beta thalassemia <ref name="PMID25066893><pubmed>25066893</pubmed></ref>.<br />
==Biopsy Methods==<br />
Biopsy, the removal of genetic materials, from oocytes or embryos in the preimplantation stage is the primary step in PGD. For the past two decades these biopsies have been performed at three stages, the polar body, blastomere, and blastocyst, and the methodologies optimized to ensure the embryo’s viability. The most common approach involves biopsies at the cleavage stage. However, polar body and blastocyst biopsies are increasingly more often tested and applied. Approached for opening the zona pellucida involve next to the traditional mechanical and chemical means, novel approaches such as noncontact lasers. Their application may simplify and secure the procedure significantly. The most challenging question about PGD procedures remains at what stage biopsies should be taken. Much controversy has developed around this topic, highlighting the varying disadvantages and advantages of temporal biopsies. <ref name="PMID22723007"><pubmed>22723007</pubmed></ref><br />
<br />
{| class="wikitable"<br />
|- align="center" bgcolor="DDCEF2"<br />
|<br />
| Time of Biopsy<br />
| Advantages <br />
| Disadvantages<br />
|- bgcolor="FFFAFA"<br />
| Polar Body<br />
| Day 1<br />
| No harm to oocyte<br />
| Only maternal DNA is tested, often needs to be coupled with other biopsies<br />
|- bgcolor="FFFAFA"<br />
| Blastomere<br />
| Day 3<br />
| …<br />
| … <br />
|- bgcolor="FFFAFA"<br />
| Trophectoderm<br />
| Day 5 and 6 <br />
| Little harm, large amount of genetic material<br />
| Opening of blastocyst necessary, small time window for procedure<br />
|}<br />
<br />
<br />
[[File:Polar_Body,_Blastomere,_and_Trophectoderm_Biopsy.jpeg|thumb|Polar body (A), blastomere (B) and trophectoderm (C) biopsies<ref name="PMID25625041"><pubmed>25625041</pubmed></ref>.]]<br />
<br />
<br />
<br />
PMID 24305177<br />
===Polar Body Analysis===<br />
Day 1<br />
====Description====<br />
Polar body (PB) biopsy, which was introduced in 1990, offers a promising alternative to biopsies performed at the blastomere stage for PGD/S indications on legal and practical grounds. <br />
Description: Consequent embryo development does not necessitate the presence of the first and second PB and their removal may not be crucial. PB biopsy requires precise timing. Keeping track of the meiotic cell cycle is necessary to perform a successful biopsy and, therefore, PB biopsy usually is applied in combination with intracytoplasmic sperm injection (ICSI). During the maturation from the germinal vesicle stage to the metaphase-II stage the first PB is formed. A cytoplasmic bridge containing spindle remnants, that are still in contact with the cellular genetic material, links this PB to the oolemma for about 90 minutes after extrusion. It is possible to visualize these remnants by polarization microscopy and it is crucial to not perform the biopsy until the first PB is no longer firmly attached to the oolemma as this indicates an immature embryo.The oocyte tolerates mechanical zona dissection best during hours four until six after ICSI as the oolemma has stabilized by that time because of the cortical granule reaction. Over time the first PB degenerates stressing a temporal biopsy and its optimal extraction time window is four to 12 hours after ICSI. The second PB forms around two to four hours after ICSI. However, its optimal time window for biopsy is set to be eight to 16 hours after ICSI. This is due to the second PB being attached to the oolemma with spindle remnants until six hours after ICSI. Biopsy at this point may cause enucleation of the oocyte. In addition, studies have shown that the amplification efficiency of second PB’s DNA is worse if the PB is extracted prior to eight hours after ICSI. <br />
Thus, it is possible to perform sequential and simultaneous biopsies for the first and second PB. If performed, sequentially the first PB may be removed four to 12 hours and the second PB eight to 16 hours after ICSI. The optimal time window for a biopsy for both the first and second PB simultaneously is eight to 12 hours after ICSI. It is highly preferred to analyze both PBs due to potential aneuploidies in either PB and crossing overs during meiosis<ref name="PMID22723007"/>. <br />
====Procedure====<br />
Chemical opening achieved with for example acidic tyrode’s solution of the zona pellucida is not tolerated by the oocyte and may have detrimental effects on the embryo’s development. Therefore, the access to the perivitelline space of the oocyte is provided by mechanical zona dissection or by laser. Both techniques work well if performed by experienced embryologist. However, laser-assisted biopsy is less time consuming when compared to manual dissection. It is critical to consider the size of the introduced opening as it will remain permanent. If it is too large the blastomere may be lost during embryo development and if it is too small it may interfere with hatching of the embryo during blastocyst stage<ref name="PMID22723007"/><br />
<br />
[[File:Polar_Body_Biopsy.jpeg|thumb|The presence of a faint but clearly identifiable strand connecting PB2 to the <br />
oolemma. The biopsy was performed ∼9 h after ICSI<ref name="PMID21908464"><pubmed>21908464</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JTaQzszVr8o</html5media><br />
|-<br />
| Laser-assisted polar body biopsy<ref>RIUK, R. (2013, June 25) Polar Body Biopsy [Video file]. Retrieved from https://www.youtube.com/watch?v=JTaQzszVr8o</ref><br />
|}<br />
<br />
====Advantages & Disadvantages====<br />
PB biopsies can only investigate the maternal contributions to the embryo as they are of maternal origin. Thus, this procedure is appropriate for PGD solely for monogenetic diseases from the maternal side. Recessive diseases may be evaluated with PB biopsies on the basis that the embryo’s outcome will be determined by the paternal contribution. (...) It may still be applied for PGS as most aneuploidies either arise during meiosis or origin from the maternal genome. However, diagnosis error has been reported due to the lack of considering paternal contributions. <br />
Because PB biopsies are performed very early it is not yet known whether the oocyte will develop into a viable embryo. Thus, PBs are commonly frozen or fixed after biopsy and depending on the state of the embryo only chosen PBs will be tested. This is primarily an economic issue as many genetic testing procedures are very cost-intensive<ref name="PMID22723007"/>.<br />
<br />
[[File:Implantation_predictive_value_of_euploid_screening_results.jpeg|thumb|The sustained implantation predictive value (with 95 % confidence interval) of a euploid screening result obtained from the first polar body (PB1), PB1 and the second polar body (PB2), or a direct embryo biopsy for each stage of embryo transfer (cleavage-stage and blastocyst stage)<ref name="PMID25106935"><pubmed>25106935</pubmed></ref>.]]<br />
<br />
===Blastomere biopsy===<br />
Day 3 <br />
====Description====<br />
Blastomere biopsy has been the prevalent method for PGD and PGS in the last two decades. At least one, but up to two, blastomeres are biopsied on day three of the cleavage stage embryo. The right number of blastomeres removed is a controversial topic as two cells allow for more genetic material and more accurate results. However, removing two cells might be too invasive and damaging to the embryo. (Study)<ref name="PMID21748341"><pubmed>21748341</pubmed></ref><br />
====Procedure====<br />
Initially a hole was drilled into the zona pellucida using acid tyrodes and the blastomeres are removed via aspiration with a pipette<ref name="PMID21748341"/>.<br />
<br />
<br />
[[File:Aspiration_of_a_Blastomere.jpeg|thumb|Aspiration of a Blastomere into the biopsy pipette<ref name=" PMID24783200"><pubmed>24783200</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=TbridWVwipI</html5media><br />
|-<br />
| Laser-assisted blastomere biopsy<ref>Sukprasert, M. (2014, March 5) Day 3 Blastomere Biopsy 1 [Video file]. Retrieved from https://www.youtube.com/watch?v=TbridWVwipI</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
===Trophectoderm biopsy===<br />
Day 5 and 6<br />
====Description====<br />
The improvement of embryo culture media allowed the in vitro development of human embryos until the blastocyst stage and opened up the possibility to take blastocyst biopsies. During day three to day five the haploid maternal and paternal genomes work together for the first time to form the genome of the embryo. The maternal epigenetic control lessens significantly while preparing for implantation with precisely arranged events happening. The first event includes a rapid increase in the number of embryonic cells which are active in mitotic divisions and apoptosis of aberrant cells. This is followed by the formation of blastocoel (cavitation) which results from the flattening of cell located on the outside of the blastomere. Now the blastocyst will expand until the embryo hatches by rupturing the zona pellucida. The cells of the blastocyst will differentiate to form two distinct cell lineages, the outer trophectoderm and the inner cell mass<ref name="PMID22723007"/>.<br />
====Procedure====<br />
Trophectoderm biopsy is usually performed in Hepes buffered biopsy medium and opening approaches include needle cutting which has been replaced by lasers in past years. Different research groups report different timings of the opening to be the most successful. Some open the blastocyst on day three or four by creating a 25 µm which causes the trophectoderm to herniate through this hole and is, thus, accessible for biopsy. Others create this hole about four hours before biopsy which allows sufficient herniation of trophectoderm cells. It is also possible to open the blastocyst immediately before biopsy. This avoids an extra step and the inner cell mass usually is easy to locate. Blastocyst biopsies involve the removal of trophectoderm cells and the ideal time for the procedure is day five. Successful biopsies on day six have been performed, while little is known about the results of biopsies on day seven. However, since the window of implantation in humans is from day eight to ten after ovulation, day seven biopsies appear to be possible<ref name="PMID22723007"/>.<br />
-collapse of trophoblasts<br />
-possible: biopsy of hatched blastocyst, holding pipette careful mild suction force to hold embryo near ICM <br />
-Cryopreservation<br />
<br />
<br />
[[File:Microscopic images of human blastocysts for biopsy.jpeg|thumb|(A) Some trophectoderm cells in a blastocyst started to hatch and (B) the trophectoderm cells were biopsied with assisted laser cutting. Images in C–D show the blastocysts after vitrification and warming. Blastocysts had been cultured for 2–4 hrs after warming, showing good (ICM and trophectoderm cells) hatched (C) and hatching (D) blastocysts. The hatching blastocyst in (E) has good ICM but fair trophectoderm while the blastocyst in (F) has both fair ICM and trophectoderm. Arrows indicate ICMs and arrow heads indicate trophectoderm cells. Bar = 40 µm<ref name="PMID2190846"><pubmed>2190846</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JI_TQ8d8tNM</html5media><br />
|-<br />
| Laser-assisted blastocyst biopsy (at 00:50 min)<ref>Coco, R. (2014, April 30) Trophectoderm biopsy in a Hatching blastocyst protruding ICM [Video file]. Retrieved from https://www.youtube.com/watch?v=JI_TQ8d8tNM</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
Blastocyst biopsies are believed to be less damaging to the embryo and appear to be unrelated to implantation rates. In addition, this biopsy method allows for a larger extraction of cells for genetic testing. However, since they are performed late in in vitro development, the time window for genetic testing is relatively small. Fast and accurate genetic testing methods are needed to ensure a successful and safe result from this biopsy. Thus, blastocyst biopsies may gain more popularity in the future whn such methods have been developed or improved<ref name="PMID22723007"/>. <br />
<br />
<br />
==Genetic Techniques==<br />
<br />
===PCR===<br />
====Description====<br />
Polymerase chain reaction (PCR) amplifies DNA specific to genetic sequence of interest . PCR was developed by Kay Mullis in the 1980s, for which he was awarded the Nobel prize for chemistry in 1993. <ref> Pubmed Docs (2015) Polymerase Chain Reaction (PCR) Pubmen. Retrieved from [http://www.ncbi.nlm.nih.gov/probe/docs/techpcr/]</ref> This technique enables clinicians to monitor and diagnose diseases using minute samples such as embryonic cells, blood & tissue. <ref>Roche (2015) PCR: How We Copy DNA. Roche Molecular Systems Inc. retrieved From [http://molecular.roche.com/pcr/Pages/Process.aspx]</ref> PCR has many important applications like DNA fingerprinting, genetic mapping, detection of viruses and bacteria as well as being used to detect genetic disorders, as a part of PGD, in conjunction with IVF. It is used to detect molecular abnormalities such as single gene disorders like Tay Sach, Cycstic fibrosis, Duchenne Muscular Dystrophy, Thalassemia, Huntington disease, Spinal muscular atrophy and many more. Molecular and Genetic analysis require a significant amount of DNA, which we would not have without PCR. It revolutionized the study of DNA, replacing all previous recombinant DNA technology. <ref> Mullins, K., Francois, F.& Gibbs R.A. (1994 ) The Polymerase Chain Reaction. p3. Springer- Science +Business Media. Birkhauser, Boston<br />
Available at [https://books.google.com.au/books?hl=en&lr=&id=gjrTBwAAQBAJ&oi=fnd&pg=PR5&dq=kary+mullis+PCR&ots=mpzAyRh5ZY&sig=PQ4goNoKJ90tb3-MkPk62zrTGbw#v=onepage&q=kary%20mullis%20PCR&f=false] </ref> <br />
<br />
[[File:PCR.jpg|thumb|right|Polymerase chain reaction (PCR) amplifies DNA specific to genetic sequence of interest, enabling the monitoring and diagnose molecular abnormalities such as single gene disorders using minute samples such as embryonic cells, blood & tissue <ref>NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref>]]<br />
<br />
====Procedure====<br />
<br />
Sample are obtained from the the blastocyst, a polar body biopsy or the blastomeres stages of the embryo. <br />
Stage 1 Denaturing: separating the target strands of DNA <br />
The obtained sample is heated to roughly 90 degrees celcius, this heat causes breaks the relatively weak bonds between nucleotides that form DNA. the double stranded DNA to split into 2 single strands of DNA that are used as templates.<br />
Stage 2 Annealing: Binding the Primers to the target DNA sequence <br />
PCR will only copy the target sequence of DNA specified by specific PCR primer. These synthesized primers Oligonucleotides are small artificial pieces of DNA. <br />
TAQ polymerase enzyme synthesize 2 new strands of DNA duplicate to the single sample DNA stand template indicated by these primers. During this stage the reaction is cooled to a temperature between 40-60 degrees Celsius. <br />
Stage 3- Extension- making copies <br />
Each of these 2 copies are then used again as templates generating 2 further replications This cycle can occur as many 30 -40 times within a couple hours leading to billions of extra copies of the original DNA segment. The optimal temperature for the further replication is roughly 72 degrees Celsius. <br />
<br />
This process mediated by a thermocycler machine that is programmed to alter the temperature of the reaction every couple of minutes, perpetuating the cycle of DNA denaturing and synthesis. <br />
This process, generates exponential exact copy of the original template DNA sequence. <br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
!PCR cycles<br />
<br />
|{|<br />
|-<br />
| '''PCR Cycle'''<br />
| '''Target Copies'''<br />
|-<br />
| 1<br />
| 2<br />
|-<br />
| 2<br />
| 4<br />
|-<br />
| 3<br />
| 8<br />
|-<br />
| 4<br />
| 16<br />
|-"<br />
| 5 <br />
| 32<br />
|-<br />
| 6 <br />
| 64<br />
|-<br />
| 7 <br />
| 128<br />
|-<br />
| 8<br />
| 256<br />
|- <br />
| 9<br />
| 512 <br />
|-<br />
| 10<br />
| 1024<br />
|-<br />
| 15<br />
| 32,768<br />
|-<br />
| 20 <br />
| 1,048,578<br />
|-<br />
| 25<br />
| 33,554,432<br />
|-<br />
| 30 <br />
| 1,073,741,842<br />
|-<br />
|}<br />
<br />
<br />
<br />
{| class="wikitable" <br />
|-bgcolor="#9ACD32" <br />
| rowspan="10" |'''Advantages'''<br />
|-bgcolor="#F0FFF0"<br />
| fast and inexpensive way of copying a target sequence of DNA<br />
|-bgcolor="#F0FFF0"<br />
| aids the diagnosis of single cell defects<br />
|-bgcolor="#F0FFF0"<br />
| rapid generation of results within a couple hours<br />
|-bgcolor="#F0FFF0"<br />
| can start from a single molecule of DNA, therefore is more sensitive <br />
|-bgcolor="#F0FFF0"<br />
| has a flexible primer design enabling<br />
|-bgcolor="#F0FFF0"<br />
| overcame previous issues associated with the limited availability of sites of end<br />
|-bgcolor="#F0FFF0"<br />
| generates the DNA copies exponentially<br />
|-bgcolor="#F0FFF0"<br />
| enables DNA amplification required for molecular and genetic analysis<br />
|-bgcolor="#F0FFF0"<br />
|Valid diagnostic method in selecting unaffected embryos for embryo transfer <ref> Dreesen, J., Drusedaul, M., Smeets, H., Die-Smulders, C., Coonen, E., Dumoulin, J., Gielen, M., Evers, J., Herbergers, J. & Geradets, J. (2008) Validation of preimplantation genetic diagnosis by PCR analysis: genotype comparison of the blastomere and corresponding embryo, implications for clinical practice. Mol. Hum. Reprod. 14 (10):573-579.doi: 10.1093/molehr/gan052. Retrieved from [http://molehr.oxfordjournals.org/content/14/10/573.short] </ref> <ref><pubmed>20966460</pubmed></ref><br />
|-bgcolor="#9ACD32"<br />
| rowspan="5"|'''Disadvantages'''<br />
|-bgcolor="#F0FFF0"<br />
| only during this exponential DNA replication phase can we determine the starting quantity sequence contained in the original sample ( template DNA strand)<br />
|-bgcolor="#F0FFF0"<br />
| PCR reaction is limited by the presence of inhibitors present in the sample : reagent inhibitors <br />
|-bgcolor="#F0FFF0"<br />
| self annealing due to the accumulation of the product -stopping exponential amplification for the target sequence and reach a plateau<br />
quantification of the end point of reaction of PCR products unreliable - therefore that is why we require real time quantitative RT-PCR necessary<br />
<ref> NIS (2015) Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref><br />
|}<br />
<br />
<br />
===Fluorescent In Situ Hybridisation (FISH)===<br />
<br />
<br />
====Description====<br />
Fluorescence in situ hybridization (FISH) the one of the most effective and rapid <ref name="PMID26338801"><pubmed>26338801</pubmed></ref> Preimplantation Genetic Diagnosis (PGD). This techniques used to locate a specific DNA sequences within a chromosome. FISH facilitates the clinical diagnosis of chromosomal abnormalities indicated by sequential duplications, deletions and rearrangements of chromosome, that are usually missed with microscopic analysis. This technique is especially relevant for female embryos with X-linked diseases,<ref name="PMID20809319"><pubmed>20809319</pubmed></ref> that have no other mutation specific tests [http://www.ncbi.nlm.nih.gov/pubmed/20809319] As part of PGD, samples are collected from various stages of the embyro,and they are able to conducted tests on the blastocyst, a polar body biopsy and the blastomeres <ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. FISH is 99% effective when used in conjunction with competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities<ref name="PMID26338801"/>.<br />
<br />
====Procedure==== <br />
<br />
Samples are collected from either the blastocyst, a polar body biopsy or the blastomeres stages of the embryo <ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
DNA strands are heated and denatured causing their the individual DNA strands to break apart<br />
Probes are single complimentary stands of DNA a that have been tagged with small chemical agents that glow brightly in the presence of a specific region on a chromosome. These specific probes then hybridize and join to their complementary DNA strand. <br />
The fluorescent tags enable the researchers to correctly identify the presence or lack thereof and location of the specific chromosomes that they are testing for. <ref name="PMID17876073"><pubmed>17876073</pubmed></ref><br />
Researcher analyse the results by identifying the number and the relative location of the fluorescent dots generated by the FISH images.<ref name="PMID17970921"><pubmed>17970921</pubmed></ref><br />
The probe will not fully hybridise if there has been a duplication or a deletion of the DNA - indicating chromosomal and sex chromosomal anomalies like trisomies and aneuploidies. <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref><br />
<br />
<br />
Different probes are used for different purposes: <ref>Unique, Rare Chromosome Disorder Support Group (2013) Fluorescence in situ hybridisation (FISH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/Other/FISH%20FTNW.pdf]</ref><br />
*'''Locus specific tags''' detect very small imbalances, and locate isolated small portions <br />
of genes within a chromosome<br />
*'''Alphoid/Centomeric Repeat probes''' are developed from the repetitive sequence located in the middle region of each chromosome, useful in determining the number of chromosomes , detecting rearrangement and when used in conjunction with locus probes to determine the absence of genetic material on a chromosome. <br />
*'''Paint Probes''' are collections of smaller probes with their own stains that bind to a different section on the chromosome - allowing the full chromosome too be labeled a unique colour, this "full colour map" can be used to know the spectral karyotype- full chromosomal mapping is useful in examining chromosomal abnormalities. <br />
<br />
[[File:Fluorescent In Situ Hybridisation (FISH).jpg|thumb|right|'''FISH''' We are able to tag Specific DNA sequences using Probes which have been tagged with fluorescent Labels.This technique enables the clinical diagnosis of chromosomal abnormalities, indicated by sequential duplication, deletions and rearrangements of chromosome <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref>]]<br />
<br />
{|class="wikitable" align="center"<br />
|-bgcolor="pink" <br />
| rowspan="8" |'''Advantages''' <br />
|-bgcolor="#FDE1F2" <br />
| FISH is 99% effective when used in conjunction with Competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities.<ref><pubmed>26338801</pubmed></ref><br />
|-bgcolor="#FDE1F2" <br />
| Rapid generation of results<br />
|-bgcolor="#FDE1F2" <br />
| Identifies very small translocations and aneuploidies that occur within chromosomes, that would usually be missed under microscopic analysis<br />
|-bgcolor="#FDE1F2" <br />
| Indicates whether the accessed chromosomes are normal <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|-bgcolor="#FDE1F2" <br />
| Tests for the most common chromosomal abnormalities - down syndrome chromosomes 13,16,18,21 and 22 <ref><pubmed>21749752</pubmed></ref><br />
|-bgcolor="#FDE1F2" <br />
| It may be used to compare the chromosomal gene arrangements in related species<br />
|-bgcolor="#FDE1F2" <br />
| can be used to identify and remove inheritable X-linked disease or sex chromasome anomalies such as Duchennes Muscular Dystrophy, hemophilia, ectodermal dysplasia <ref><pubmed>17876073</pubmed></ref><br />
|-bgcolor="#FEB745"<br />
| rowspan="5"|'''Disadvantages'''<br />
|-bgcolor="#FE1C5EA"<br />
| FISH destroys all cells tested <ref> O'Connor, C. (2008) Fluorescence in situ hybridization (FISH). Nature Education 1(1):171. retrieved from [http://www.nature.com/scitable/topicpage/fluorescence-in-situ-hybridization-fish-327] </ref><br />
|-bgcolor="#FE1C5EA"<br />
| It does not fully access all chromosomes (only ~ 12)<br />
|-bgcolor="#FE1C5EA"<br />
| Analysis of results is dependent upon the dot quality impacted by hybridisation efficiency or the camera sensitivity <ref><pubmed>17970921</pubmed></ref><br />
|-bgcolor="#FE1C5EA"<br />
| some studies indicate that using FISH on a day-3 embryo biopsy decreases the rate of live births <ref><pubmed>26168107</pubmed></ref><br />
|}<br />
<br />
===Array Comparative Genomic Hybridisation (aCGH)===<br />
====Description====<br />
<br />
aCGH also known as Microarray analysis efficiently scans the entire genome for chromosomal imbalances. CGH was initially developed to detect the number of changes in a solid tumor mass. It uses 2 genomes comparing the sample to the control, with each labeled in a different fluorescent dye<ref name="PMID1876176"><pubmed>1876176</pubmed></ref>. Earlier CGH techniques were limited by the resolution of the imaging <ref> Lichter, P., et al. Comparative genomic hybridization: Uses and limitations. Seminars in Hematology 37, 348–357 (2000)</ref> , these initial limitations were overcome by using Microarrays in conjunction with CGh to improve the resolution of the imaging, Array Comparative Genomic Hybridisation (aCGH). This method compares sample and control microarrayed slides containing small segments of DNA (probes). <ref> Lucito, R., et al. Representational oligonucleotide microarray analysis: A high-resolution method to detect genome copy number variation. Genome Research 13, 2291–2305 (2003) </ref> the Probes used will vary according from the small (25-85 base pairs) oligonucleotides manufactured to highlight different target sequences, to the very large genomic clones (80,000- 200,00 base pairs), and as these are significantly smaller than the traditional metaphase chromosomes used for CGH, generating a higher resolution of image. <ref name="PMID22467166"><pubmed>22467166</pubmed></ref>.aCGH is used as a diagnostic tool for prenatal detection f chromosomal abnormalities <ref name="PMID19012303"><pubmed>19012303</pubmed></ref>.<br />
<br />
<br />
====Procedure====<br />
<ref> Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432] </ref><br />
The sample is obtained (skin, blood or fetal cells) and DNA is obtained. <br />
As a part of PGD fetal cell samples are collected from; the fertilized egg polar bodies, the blastomere (day 3 embryo) or the blastocyst/tropoectoderm stage (day 5 embryo).<br />
Sample DNA is labeled with one fluorescent dye, and the control DNA is labeled with a different colored fluorescent dye. the control DNA is used as the base point of reference. <br />
heated and denatured single DNA strands then hybridize to their complementary single strand probes, which are then combined and applied to a microarray and the results are run through a computer program and a digital imaging system is used to quantify the results( fluorescent intensities of the labeled probes). <br />
<br />
[[File:aCGH.jpg|thumb|right|'''aCGH''' checks the entire genome for chromosomal imbalances, by comparing control and a sample slides contatining small segements of DNA sample microarrayed slides small segments of DNA. Illustrated by student z5020317 and adapted from <ref> NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation. retrieved from [http://www.phgfoundation.org/file/5237/]</ref> <ref>Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432]</ref>]]<br />
<br />
<br />
<br />
The fluorescent ratio and the hybridization signal at different locations on the genome of the control DNA are used to identify any variances present in the sample DNA. aCGH facilitates the clinical diagnosis of submicroscopic chromosomal duplication, deletion and rearrangements indicative of chromosomal disorders such as trisomies 1-22and specific sex linked disorders. <br />
Duplications in the DNA are displayed by the computer program as spikes/ peaks over an established threshold and deletions in DNA are displayed by the computer program as spikes/ toughs beneath this threshold <br />
<br />
<br />
<br />
<br />
{|border="1" align="center"<br />
|-bgcolor="pink" <br />
| '''Advantages''' <br />
| '''Disadvantages'''<br />
|-<br />
| multiple applications: prenatal genetic diagnosis, cancer diagnosis, <ref name="PMID20193845"><pubmed>20193845</pubmed></ref> genetic screening for developmental delay (learning disabilities) <ref name="PMID17309648"><pubmed>17309648</pubmed></ref>. or congenital anomalies that are suspected to be genetic in origin <ref>NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation . retrieved from [http://www.phgfoundation.org/file/5237/]</ref><br />
| translocations and inversions of DNA are not detected<br />
|-bgcolor="pink"<br />
| trace represents all chromosomes present in the human genome chromosomes 1-22 and the X & Y chromosomes, and therefore is the most accurate method for testing whole embryo aneuploidy<br />
| limited ability diagnosing specific polyploidies such as triploidy <ref> Unique, Rare Chromosome Disorder Support Group (2013) Microarray-based Comparative Genomic Hybridiation (array CGH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/other/array%20cgh%20ftnw.pdf] </ref><br />
|-<br />
| aCGH has been extensively tested, and Validated, and is now used world wide.<br />
| will not detect mosaicism detection <20% (cultures where >1 of 5 cells are trisomy 12)<br />
|-bgcolor="pink"<br />
| detects deletions and additions and rearrangements as well as amplification, of the WHOLE genome, simultaneously.<br />
| will not detect balanced chromosomal rearrangement<br />
|-<br />
| detects submicroscopic alterations<br />
| will not detect duplications or deletions <80kb<br />
|-bgcolor="pink"<br />
| used as a diagnostic tool for prenatal detection of chromosomal abnormalities <ref name="PMID22034057"><pubmed>22034057</pubmed></ref><br />
| will not detect point mutations within genes <ref>Washington department of education (CGH- FAQ for physicians. Signature Genomic LAboratories, LLC. Retrieved from [https://depts.washington.edu/dbpeds/Lab%20Tests/SignatureCGH-physician_FAQ.pdf]</ref><br />
|-<br />
| provides high resolution genomewide screening of segmental genomic copy number variations<br />
| will not detect chromosomal position of genomic gains<br />
|-bgcolor="pink"<br />
| very accurate when used in conjunction with FISH<br />
| will not detect loos of heterozygosity (LOH) or Absence of heterozygosity (AOH) <ref>WiCell Research Institute Inc. (2012) Comparative Genomic Hybridization Microarray. <br />
retrieved from [http://www.wicell.org/home/cytogenetic-services/cgh-microarray/array-comparative-genomic-hybridization-acgh.cmsx]</ref><br />
|-<br />
|Alone is more reliable and in detecting chromosomal abnormalities, with a higher implantation success rate, than FISH <ref name="PMID20494259"><pubmed>20494259</pubmed></ref><br />
|<br />
|-bgcolor="pink"<br />
|Allows an in depth research focus upon specific types of rearrangements within selected chromosomal regions, a recent particular area of interest is subtelomeric and pericentromeric rearrangements<br />
|<br />
|-<br />
|reduces the risk of failed implantation and miscarriage, improving the chance of a healthy baby <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|<br />
|}<br />
<br />
<br />
<br />
===Next Generation Sequencing===<br />
====Description====<br />
The development and advances within ART in the past 20 years, as well as the increasing popularity of IV, has lead to an influx of new technologies developed to screen embryos for chromosomal anomalies, which are covered by the umbrella term of Next generation Sequencing (NGS). NGS is a general term used to describe all of the new and emerging screening techniques currently being introduced and used as part of PGD for IVF . NGS screens for single gene disorders as well as conducting extensive and very comprehensive chromosome diagnosis by sequencing, counting, and accurately assembling millions of DNA reads, simultaneously. <ref name="PMID23499002"><pubmed>23499002</pubmed></ref> There is a movement for NGS to replace the other limited testing techniques and be used as the standard. <br />
====Procedure====<br />
Samples are collected from either blastomere or the blastocyst/tropoectoderm and processed for analysis by a computer system. <br />
The methodology of each process is unique to the technique being used. <br />
<br />
<br />
<br />
{|border="1" align="center"<br />
|-bgcolor="pink" <br />
| '''Advantages'''<br />
| '''Disadvantages'''<br />
|-bgcolor="white"<br />
| cheaper<br />
| there are limited information available to clinical applications of NGS <ref><pubmed>26100406</pubmed></ref><br />
|-bgcolor="pink"<br />
| opens new diagnostic possibilities<br />
|<br />
|-bgcolor="white"<br />
| accurately tests all 24 chromosomes<br />
| <br />
|-bgcolor="pink"<br />
| tests for the presence of monogenic diseases of known genetic background<br />
| <br />
|-bgcolor="white"<br />
| reduces the number of biopsies required for diagnosis<br />
| <br />
|-bgcolor="pink"<br />
| higher detection rate of small translocations<br />
| <br />
|-bgcolor="white"<br />
| highly accurate is testing for compound point mutations, chromosomal duplication, deletions and insertions <ref name="23312231"><pubmed>23312231</pubmed></ref><br />
| <br />
|-bgcolor="pink"<br />
| it accurately detects chromosomal aneuploidy and unbalanced rearrangement <ref name="PMID25685330"><pubmed>25685330</pubmed></ref><br />
| <br />
|-bgcolor="white"<br />
| NGS single gene disorder screenings can conducted in conjunction with PCR comprehensive chromosomal screening<br />
|<br />
|-bgcolor="pink"<br />
| Reduces human error <br />
|<br />
|-bgcolor="white"<br />
| better detects the presence of mosaicism<br />
|<br />
|-bgcolor="pink"<br />
| work well in conjunction with CGH and aCGH as part of PGD, improving the chances of IVF. <ref> Morris, R. S. (2015 ) Next generation sequencing for PCG|PGS|CCS. IVF1 retrieved from [http://www.ivf1.com/next-generation-sequencing for-pgd] </ref><br />
|<br />
|}<br />
<br />
<br />
<br />
<br />
<br />
<br />
==Diagnosis==<br />
There are a large amount of diseases that PGD can apply to, below are descriptions of the diseases that PGD are more commonly used for. Utilization of Diseased Cell Lines<br />
===Cystic Fibrosis===<br />
Cystic fibrosis is a single gene disorder. It is autosomal recessive and involves mutations in the cystic fibrosis transmembrane conductance regulator (CTFR) gene. The CTFR gene is normally responsible for the decrease in chloride and the transport of bicarbonate in epithelial cells thus playing a major physiological role. In PGD procedures, identification of the gene is assisted by microsatellite markers that have similar composition to the CTFR gene itself. Biopsy of two cells at the blastocyst stage is recommended if markers are not available. There are many variations of cystic fibrosis the most common being P.Phe508del <ref name="PMID26014425"><pubmed>26014425</pubmed></ref>.<br />
===Duchenne Muscular Dystrophy ===<br />
Duchenne Muscular Dystrophy is an X-linked recessive disease. It involves the Xp21 gene where majority of the mutations are chromosomal deletions with a smaller percentage resulting from duplications <ref name="PMID18359022"><pubmed>18359022</pubmed></ref>.<br />
===β – Thalassemia=== <br />
β – Thalassemia is known as the most common type of autosomal recessive inherited disorder among haemoglobinopathies. It involves the adult β-globin gene and is associated with the absent or decreased expression of the gene. This is commonly caused by a single nucleotide change in the gene. PGD has been used successfully worldwide to identify the β-globin gene where its application is usually performed on a single blastomere or polar body <ref name="PMID19064120">19064120</pubmed></ref>.<br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
! Applicable diseases for PGD <ref>Genoma Group (2014). Retrieved September 18th, 2015, from http://www.preimplantationgeneticdiagnosis.it/genetic-diseases-diagnosed-by-pgd.htm </ref>, <ref>Genesis Genetics (2015). Retrieved September 18th, 2015, from http://genesisgenetics.org/pgd/what-we-test-for/</ref>, <ref>Human Fertilisation & Embryology Authority (2015). Retrieved Septembr 18th, 2015, from http://guide.hfea.gov.uk/pgd/</ref><br />
|-<br />
| '''Disease'''<br />
| '''Involved Genes'''<br />
|-<br />
| 5 Alpha Reductase Deficiency (5ARD)<br />
| SRD5A2 <br />
|-<br />
| Achondroplasia<br />
|FGFR3 <br />
|-<br />
| Acute Intermittent Porphyria <br />
| ALAD, ALAS2, CPOX, FECH, HMBS, PPOX, UROD, or UROS<br />
|-<br />
| Adrenoleukodystrophy (Adrenomyeloneuropathy)<br />
| ABCD1 <br />
|-<br />
| Agammaglobulinaemia (x-linked) <br />
|BTK <br />
|-<br />
| Agammaglobulinemia Bruton Tyrosine Kinase (BTK) <br />
|BTK <br />
|-<br />
| Aicardi Goutieres Syndrome 1 (AGS1) <br />
|TREX1, RNASEH2A, RNASEH2B, RNASEH2C, SAMHD1<br />
|-<br />
| Alagille Syndrome<br />
|JAG1 or NOTCH2<br />
|- <br />
| Alpers-Huttenlocher Syndrome <br />
|POLG <br />
|-<br />
| Alpha-1-antitrypsin deficiency <br />
|SERPINA1 <br />
|-<br />
| Alpha-Mannosidosis<br />
| MAN2B1 <br />
|-<br />
| Alpha Thalassemia <br />
|HBA1 or HBA2 <br />
|-<br />
| Alports Syndrome<br />
|COL4A3, COL4A4, COL4A5<br />
|-<br />
| Alzheimer's Disease - early onset (Type 3 and 4) <br />
|APP, PSEN1, or PSEN2<br />
|-<br />
| Amyotrophic Lateral Sclerosis 1 (ALS1) <br />
|C9orf72, SOD1, TARDBP, FUS, ANG, ALS2, SETX, VAPB <br />
|-<br />
| Argininosuccinic Aciduria <br />
| ASL<br />
|-<br />
| Arrhythmogenic Right Ventricular Cardiomyopathy/ Dysplasia (ARVC/D)<br />
| DSG2; DSP; PKP2<br />
|-<br />
| Ataxia Telangiectasia<br />
| ATM<br />
|-<br />
| Bardet-Biedl Syndrome (BBS)<br />
| BBS1; BBS10<br />
|-<br />
| Barth Syndrome<br />
| TAZ<br />
|-<br />
| Beta Thalassaemia<br />
| HBB<br />
|-<br />
| Birt-Hogg-Dubé Syndrome<br />
| FLCN<br />
|-<br />
| Breast Ovarian Cancer Familial Susceptibility (BRCA2)<br />
| BRCA1; BRCA2<br />
|-<br />
| Canavan Disease <br />
| ASPA<br />
|-<br />
| Carnitine-Acylcarnitine Translocase Deficiency <br />
| SLC25A20<br />
|-<br />
| Cerebral Arteriopathy with Subcortical Infarcts & Leukoencephalopathy (CADASIL)<br />
| NOTCH3<br />
|-<br />
| Cerebral Cavernous Malformation<br />
| CCM1<br />
|-<br />
| Charcot-Marie-Tooth Disease<br />
| GJB1; MPZ; NEFL; PMP22<br />
|-<br />
| CHARGE Syndrome<br />
| CHD7<br />
|-<br />
| Cherubism<br />
| SH3BP2<br />
|-<br />
| Choroideremia<br />
| CHM<br />
|-<br />
| Chronic Granulomatous Disease<br />
| CYBB; NCF1<br />
|-<br />
| Ciliary Dyskinesia<br />
| DNAH5<br />
|-<br />
| Citrullinemia<br />
| ASS1<br />
|-<br />
| Cleidocranial Dysplasia<br />
| RUNX2<br />
|-<br />
| Cockayne Syndrome<br />
| ERCC6<br />
|-<br />
| Congenital Adrenal Hyperplasia<br />
| CYP21A2<br />
|-<br />
| Congenital Cataracts<br />
| GJA8; VSX2<br />
|-<br />
| Congenital Diarrhea, Syndromic<br />
| SPINT2<br />
|-<br />
| Congenital Disorders of Glycosylation (CDG)<br />
| ALG1; ALG6; CDG1C; DOLK; PMM2<br />
|-<br />
| Cornelia de Lange Syndrome <br />
| NIPBL<br />
|-<br />
| Craniosynostosis<br />
| TWIST1<br />
|-<br />
| Crouzon Syndrome<br />
| FGFR2<br />
|-<br />
| Cysteinyl Leukotriene Receptor 1 Deficiency <br />
| CYSLTR1<br />
|-<br />
| Cystic Fibrosis<br />
| CFTR<br />
|-<br />
| Diamond –Blackfan Anemia <br />
| RPS19<br />
|-<br />
| Duchenne Muscular Dystrophy <br />
| DMD<br />
|-<br />
| Dyskeratosis congenita (Male embryos only)<br />
| DKC1<br />
|-<br />
| Ectodermal dysplasia (Hypohidrotic)<br />
| EDA; EDA1; GJB6; IKBKG<br />
|-<br />
| Familial Adenomatous polyposis coli (FAP)<br />
| APC<br />
|-<br />
| Familial Dysautonomia<br />
| IKBKAP<br />
|-<br />
| Fanconi Anemia <br />
| FANCA; FANCC; FANCD2; FANCF; FANCG; FANCJ<br />
|-<br />
| Fragile X Syndrome (FRAX)<br />
| FMR1<br />
|-<br />
| Galactosemia <br />
| GALT<br />
|-<br />
| Gangliosidosis<br />
| GLB1<br />
|-<br />
| Glanzmann Thrombasthenia <br />
| ITGA2B<br />
|-<br />
| Glutaric Acidemia (aciduria)<br />
| GCDH <br />
|-<br />
| Glycogen Storage Disease <br />
| G6PC; GAA; SLC37A4<br />
|-<br />
| Haemophilia A<br />
| F8<br />
|-<br />
| Haemophilia B<br />
| F9<br />
|-<br />
| Hereditary Nonpolyposis Colorectal Cancer: Lynch Syndrome<br />
| MLH1; MSH2; MSH6<br />
|-<br />
| Holt Oram Syndrome<br />
| TBX5<br />
|-<br />
| Huntington Disease<br />
| HD<br />
|-<br />
| Hydrocephalus<br />
| L1CAM<br />
|-<br />
| Ichthyosis <br />
| ABCA12; STS<br />
|-<br />
| Incontinentia Pigmenti (IP)<br />
| NEMO<br />
|-<br />
| Joubert Syndrome 5<br />
| INPP5E<br />
|-<br />
| Krabbe Disease<br />
| GALC<br />
|-<br />
| Leber Congenital Amaurosis (LCA)<br />
| CEP290; GUCY2D<br />
|-<br />
| Leigh Syndrome (Infantile Subacute Necrotising Encephalopathy)<br />
| LRPPRC<br />
|-<br />
| Lesch Nyan Syndrome<br />
| HPRT1<br />
|-<br />
| Leukocyte Adhesion Deficiency (Type I)<br />
| ITGB2<br />
|-<br />
| Li-Fraumeni Syndrome<br />
| TP53<br />
|-<br />
| Macular Dystrophy Retinal <br />
| VMD2<br />
|-<br />
| Maple Syrup Urine Disorder (MSUD)<br />
| BCKDHB<br />
|-<br />
| Marfan Syndrome <br />
| FBN1<br />
|-<br />
| Menkes Syndrome<br />
| ATP7A<br />
|-<br />
| Mitochondrial DNA Depletion Syndrom <br />
| POLG; RRM2B; SUCLA2; TK2<br />
|-<br />
| Mucolipidosis type II<br />
| GNPTAB<br />
|-<br />
| Multiple Endocrine Neoplasia<br />
| MEN1; MEN2A; MEN2B<br />
|-<br />
| Multiple Exostoses<br />
| EXT1; EXT2 <br />
|-<br />
| Myotubular myopathy<br />
| MTM1 <br />
|-<br />
| Nail-Patella Syndrome<br />
| LMX1B<br />
|-<br />
| Neurofibromatosis Type 1<br />
| NF1<br />
|-<br />
| Neurofibromatosis Type 2 <br />
| NF2<br />
|-<br />
| Noonan Syndrome<br />
| KRAS, PTPN11; SOS1<br />
|-<br />
| Norrie Disease<br />
| NDP<br />
|-<br />
| Ocular Albinism <br />
| GPR143<br />
|-<br />
| Oculocutaneous Albinism <br />
| OCA2; TYR <br />
|-<br />
| Oculodentaldigital Dysplasia<br />
| GJA1<br />
|-<br />
| Optic Atrophy<br />
| OPA1<br />
|-<br />
| Ornithine Transcarbamylase Deficiency <br />
| OTC<br />
|-<br />
| Osteogenesis imperfeca <br />
| COL1A1; COL1A2<br />
|-<br />
| Osteopetrosis <br />
| CLCN7; OSTM1; TCIRG1<br />
|-<br />
| Pachyonychia Congenita <br />
| KRT16; KRT6A<br />
|-<br />
| Pancreatitis, Hereditary<br />
| PRSS1 <br />
|-<br />
| Papillorenal syndrome <br />
| PAX2<br />
|-<br />
| Phenylketonuria <br />
| PAH <br />
|-<br />
| This table does not cover the complete list of diseases that PGD can be applied to.<br />
|}<br />
<br />
==Laws & Legal status==<br />
<br />
{|border="1" align="center"<br />
|-<br />
| Australia<br />
| PGD is currently used to detect serious genetic conditions to improve the outcome of Assisted Reproductive Technologies (ART). In very rare cases it may be used to select an embryo with compatible tissue for a sibling who has a life-threatening disease where other means of treatment is unavailable. This is with the conditions that the use of PGD will not affect the welfare and interests of the child to be born. The parents must also receive adequate counselling and have full understanding of the procedures of PGD. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"> National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art</ref><br />
The use of PGD for sex-selection is prohibited with the exception of reducing the risk of the transmission of serious sex-linked genetic conditions. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"/><br />
|-<br />
| Brazil<br />
| The laws regarding PGD in Brazil are not strictly regulated. They are vague and there is limited information surround the activities of assisted reproduction in general in the country <ref name="PMID25493379"><pubmed>25493379</pubmed></ref>.<br />
|-<br />
| Czech Republic<br />
| The laws in the Czech Republic allow those with a “defined indication in order to exclude risk of serous genetically conditioned disease and defects with embryos before they are implanted into the cavity of the uterus”. Couples that undergo any assisted reproductive treatment including PGD have to be married. Sex-selection is illegal except in regards to serious sex-linked genetic diseases <ref name="PMID24777348"><pubmed>24777348</pubmed></ref>.<br />
|-<br />
| Greece<br />
| In Greece, ART is open to those up to the age of 50 with written consent. It can only be used if a medical necessity is present such as the susceptibility of serious hereditary diseases. Sex selection is banned apart from cases of sex-linked diseases and sexually transmitted diseases <ref name="PMID24777348"/>.<br />
|-<br />
| India<br />
| In India there is a cultural preference for boys thus the Prenatal Diagnostic Techniques (Regulation and Prevention of Misuse) Act was introduced in 1994. This law limits the use of PGD for sex determination except in cases of specific congenital diseases. These laws however are not strictly enforced. <ref>World Health Organisation (2015) Gender and Genetics Retrieved on October 21st 2015 from:http://www.who.int/genomics/gender/en/index4.html</ref><br />
|-<br />
| Portugal <br />
| ART is only available to those who are married or have a similar type of relationship for at least two years. The couples cannot be of the same sex and must be at least 18 years of age. Sex selection is illegal except in cases of sex-linked diseases. The use of PGD is illegal if the predictive value of genetic tests are very low <ref name="PMID24777348"/>.<br />
|-<br />
| Spain<br />
| PGD can be applied to “serious hereditary diseases not amenable to postnatal curative treatment” and “detection of other abnormalities which may compromise the viability of the pre-embryo”. If PGD is to be used for any other purpose authorisation must be acquired <ref name="PMID24777348"/>.<br />
|-<br />
| Sweden <br />
| The use of PGD is strictly regulated and couples must achieve authorisation of the National Board of Health and Welfare. It can only be used it can only be used if the child is at risk to inheriting a serious chromosomal or monogenetic disease. It cannot be used for selection of specific characteristics <ref name="PMID24777348"/>.<br />
|-<br />
| United Kingdom<br />
| Those involved with carrying out the IVF treatment must have a license from the Human Fertilisation and Embryology Authority (HFEA). Only embryos that are approved by the HFEA can be implanted where the embryonic nuclear or mitochondrial DNA cannot be altered with the exception of preventing mitochondrial diseases <ref name="PMID24777348"/>. <br />
|}<br />
<br />
==Future/Current Research==<br />
===Noninvasive Preimplantation Genetic Testing without Embryo Biopsy===<br />
Different parameters of gametes, zygotes, embryos (“vacuoles in sperm heads, spindle position in mature oocytes, cleavage intervals of zygote, and embryo developmental dynamics”) may correlate with aneuploidy rates. This knowledge may be applied in potential noninvasive preimplantation diagnostic methods. Several methods have been proposed and are currently further researched<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Sperm Selection====<br />
Intracytoplasmic morphologically selected sperm injection (IMSI) is common procedure in IVF treatment to improve fertilization rates in patients with poor semen quality. In addition, studies have found that IMSI improves embryo development and that spermatozoa with large vacuoles in their heads correlate with increased aneuploidy rates and disturbed chromosomal structures. Thus, selecting spermatozoa based on morphological hallmarks may decrease aneuploidy rates in the fertilized embryos. As with polar body biopsies, however, this approach will solely be applicable if evidence for severe male detrimental contribution is given<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Blastocoel Fluid Extraction====<br />
In addition, a less invasive retrieval of material for diagnosis could include the extraction of the blastocoel fluid. The cavity of the blastocyst, lined by the trophectoderm, is filled with this blastocoel fluid, which contains metabolites of both trophectoderm and inner cell mass origin. The retrieval does not require a biopsy but merely a small opening to extract the fluid and, thus, causes less harm to the embryo. Multiple studies have applied this method<ref name="PMID22020776"><pubmed>22020776</pubmed></ref> <ref name="PMID23148560"><pubmed>23148560</pubmed></ref> and it may in the future become of clinical relevance.<br />
<br />
<br />
[[File:Aspiration_of_the_Blastocoel_Fluid.jpeg|thumb|Aspiration of the Blastocoel Fluid using a ICSI pipette<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.]]<br />
<br />
<br />
Next to metabolites, the blastocoel fluid can contain DNA. Studies have shown that genomic DNA is present in about 90% of the blastocoel fluid samples tested. Typically the fluid is removed with an ICSI pipette from a day five blastocyst through its mural trophectoderm until the blastocyst fully collapses around the embryo. Several concerns regarding this method in a clinical setting have been raised. The collected DNA may be contaminated by the culture media that contains DNA fractions. The DNA may also be least representative of the actual embryos genome as the DNA may originate from abnormal or degenerated cells. Even though labelled noninvasive, the blastocyst still undergoes manipulation to some degree which may affect its viability. Thus, more research is required until this method can evolve from research to clinical use<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
====Proteomics====<br />
The protein secretome of blastocysts may be representative of its chromosome constitution Recent studies have found biomarkers such as lipocalin-1, interleukin-10, tumor necrosis factor, stem cell factor, and chemokine ligand 13 to be differently secreted by aneuploid blastocyst than by euploid ones. The most significant biomarker appears to be interleukin-10. Paired with novel proteomic technologies and mass spectrometry this knowledge when extended may contribute to a new invasive preimplantation genetic diagnosis method<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Embryo Morphology====<br />
Using time lapse imaging the embryo’s morphology can be closely observed and potential aneuploidy characteristics detected. Such characteristics may include the time of division to five cells, the time between the division from three to four cells, and the duration of the division from one to two and subsequently to three. In addition, the morphological quality of ICM an TE has been positively associated with aneuploidy or euploidy prognosis<ref name="PMID26246880"><pubmed>26246880</pubmed></ref>. These may give rise to an embryo quality screening prior to implantation<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
==References==<br />
<br />
<references/><br />
<br />
<br />
{{StudentPage2015}}</div>Z5017878https://embryology.med.unsw.edu.au/embryology/index.php?title=2015_Group_Project_6&diff=2069932015 Group Project 62015-10-21T06:22:36Z<p>Z5017878: </p>
<hr />
<div>{{ANAT2341Project2015header}}<br />
<br />
<br />
=Preimplantation Genetic Diagnosis and Screening=<br />
==Introduction==<br />
Preimplantation genetic diagnosis (PGD) and screening (PGS) are reproductive options for couples with known family histories of genetic disease or couples undergoing IVF procedures due to infertility issues. PGD can diagnose many genetic disorders caused by known chromosomal abnormalities (number and/or structure) or single gene mutations, and, thus decrease the risk of termination of pregnancy or miscarriages and enable such couples to have an unaffected child<ref name="PMID24907939"><pubmed>24907939</pubmed></ref>. Through major improvements in PGD/S and general laboratory technology, the testing for abnormalities in fetuses has shifted from prenatal diagnosis during the first 2 trimesters <ref> Blackburn, S.L. (2003) '''Maternal, Fetal & Neonatal physiology: a Clinical perspective''' (2nd ed.). Seattle: Saudners </ref>, testing for overall fetal growth, complications of pregnancy, and birth defects<ref> Sadler T.W.(2012) '''Langman's Medical Embryology''' (12th ed.) Philadelphia: Lipincott, Wiliams & Wilkins, a Wolters Kluwer Business </ref>, to an embryonic focus especially in advancements in Artificial Reproductive Technologies (ART)<ref><pubmed>20638568</pubmed></ref>. In 1990 PGD for a recessive X-linked disease resulted in the first live birth<ref><pubmed>2330030</pubmed></ref> and has since been incorporated in clinical routine and applied for a variety of genetic diseases, such as sickle cell anemia, thalassemia, or cystic fibrosis<ref name="PMID24907939"/>.<br />
[[File:Preimplantation Genetic Diagnosis Procedure.jpeg|700px|thumb|centre| Simplified steps for PGD<ref name="PMID24907939"/>]]<br />
<br />
==History==<br />
<br />
==Preimplantation Genetic Diagnosis==<br />
Preimplantation genetic diagnosis (PGD) is used to test the genetic makeup of embryos to detect single gene disorders, chromosomal abnormalities and mitochondrial disorders. It also has applications in gender selection for diseases with unequal gender distributions <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Some diseases commonly involved with PGD include cystic fibrosis, spinal muscular atrophy and beta – thalassaemia <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press.">Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press</ref> <ref name="PMID17823145"><pubmed>17823145</pubmed></ref>. It was first used in the United Kingdom in the 1980s of arenoleucodystrophy and primarily focusing on sex- linked disorders <ref name="PMID17823145"/><ref name="PMID23150080"><pubmed>23150080</pubmed></ref>. PGD is now capable of detecting single cell defects (molecular) and chromosomal disorders resulting from the inversion, translocation or deletion of chromosomes (cytogenic) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>,<ref name="PMID11325751"><pubmed>11325751</pubmed></ref>. PGD can be applied to the embryo at different stages. That is on polar bodies, blastomeres or blastocyst <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>.<br />
Depending on the type of genetic disorder, PGD utilises different methods of genetic testing. These include Fluorescence in situ hybridisation (FISH) which is used for sex – linked disorders and detects chromosomal rearrangements <ref name="PMID11325751"/><ref name="PMID17876073"><pubmed>17876073</pubmed></ref> and Embryo halotyping which allows the identification of chromosomes causing the inherited disorder through knowledge of the pattern of closely linked markers <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. Polymerase chain reaction (PCR) is also widely used to detect molecular abnormalities <ref name="PMID11325751"/>.<br />
PGD is tightly regulated and supported by large organisations namely The American Society for Reproductive Medicine, The European Society for Human Reproduction and Embryology (ESHRE), The European Society of Human Genetics and the Preimplantation Genetic Diagnosis International Society <ref name="PMID25500181><pubmed>25500181</pubmed></ref>.<br />
===Sex-linked disorders===<br />
The determination of a disease as gender specific usually correlates with the presence or absence of specific genes such as SRY on the Y chromosome. It is known that females have two X chromosomes and males have an X and a Y chromosome where abnormalities are more prevalent on the X chromosome. PGD can be used for sex selection where only male embryos are transferred to reduce the chance of inheriting X-linked disorders. However, this does not completely eradicate the problem as male embryos remain susceptible to inheriting an affected X chromosome. Sex determination is only used when the specific mutation is unknown and has yet to be discovered <ref name="PMID24866878"><pubmed>24866878</pubmed></ref>.<br />
===Single gene defects===<br />
Single gene defects can be dominant, recessive, autosomal or X-linked. They are commonly diagnosed using PCR and although the PCR available today is complex and capable of combatting a large range of disease the development of new protocols has been proven to be difficult due to the small DNA sample available <ref name="PMID26168107"><pubmed>26168107</pubmed></ref><br />
===Mitochondrial disorders===<br />
Mitochondrial disorders also known as oxidative phosphorylation disorders arise from mutations in the nuclear DNA or mitochondrial DNA <ref name="PMID26312584"><pubmed>26312584</pubmed></ref>. They pose as a problem because they are unrecognisable until the mutations in the cell reach a detrimental level <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Mitochondrial disorders cause miscarriages and stillbirths as well as death in children and young adults. The effects can either be contained in a single organ or more commonly involve multiple organ failure where organs with high energy demands such as the brain, liver muscle and heart and heavily influenced. They are usually occur spontaneously or result from inheritance from the mother. Since mitochondria are solely inherited from the mother oocyte donations have been used as a solution to combat mitochondrial disorders. Additionally, there has been an increasing use in PGD where embryos that stay under the given threshold of 18% gene-mutations are allowed to be transferred and result in normal development. New technology in the areas of nuclear gene transfer and genome editing are also being experimented with <ref name="PMID26312584"/>. <br />
===Chromosomal disorders===<br />
Chromosomal disorders can be reciprocal, Robertsonian translocations, inversions, deletions and insertions <ref name="PMID26168107"/>. . Data from ESHRE collected between 2010 and 2011 has shown that the most common chromosomal abnormality confronted in PGD are reciprocal chromosomal abnormalities <ref name"PMID26071418"><pubmed>26071418</pubmed></ref>. PGD has also been used successfully for Robertsonian translocations (RT), a type of structural translocation. Children who carry RT are phenotypically normal, however in their later years it is found that they will suffer from infertility and repeated miscarriages due to the high frequency of abnormal embryos <ref name="PMID22081077"><pubmed>22081077</pubmed></ref>. PCR and FISH are the two main techniques used for chromosomal disorders. To be able to conduct the examinations the cells are required to be at the metaphase stage <ref name="PMID26168107"/>. <br />
==Preimplantation Genetic Screening==<br />
Prenatal Genetic Screening (PGS) involves an array of methods or ideas that aim to segregate embryos that have genetic flaws and those that are healthy <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. The occurrence of aneuploidy is high around the stages of early embryonic development and they are the most common cause if miscarriages and congenital birth defects <ref name= "PMID26085841"><pubmed>26085841</pubmed></ref>. They have little effect on the morphology of the embryo making them difficult to identify thus identification heavily relies on genetic testing <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. <br />
Genetic sampling is most commonly conducted using Microarray Comparative Genomic Hybridisation (aCGH) as well as FISH, Quantitative PCR and Single Nucleotide Polymorphism (SNP) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. These methods collectively aim to assess numeral and structural chromosomal errors <ref name= "PMID26085841"/>. Studies have also introduced Next- Generation Sequencing (NGS) <ref name= "PMID26085841"/> and Whole Genome Amplification used to screen imbalances in the complete 24-chromosomes <ref name="PMID25953353"><pubmed>25953353</pubmed></ref><br />
Statistics from ESHRE have shown that the most common indications for PGS is advanced age, followed by repeated implantation failure or recurrent miscarriage and male infertility <ref name="PMID26071418"><pubmed>26071418</pubmed></ref>.<br />
====Indications====<br />
A low percentage of structural abnormalities in chromosomes are responsible for the cause of miscarriages. Despite this, they are the most prevalent type of chromosomal abnormality accounted for in PGD <ref name="PMID20638568"/>. The presence of specific gene cycles, initiation of embryonic protein synthesis and evident physiological development are all indicative of a successful in vitro fertilisation procedure <ref name="PMID11576737"><pubmed>11576737</pubmed></ref>. To eliminate further errors from occurring during the PGD procedure it is recommended to undertake further prenatal testing such as amniocentesis in the later stages <ref name="PMID20638568"/>. <br />
=====Advanced maternal age=====<br />
Data provided by the ESHRE has shown that the mean age of women undergoing PGS is 39 years <ref name="PMID26071418"/>. Women of advanced age have been shown to have a lower rate of pregnancies reaching childbirth <ref name="PMID18583331"><pubmed>18583331</pubmed></ref>. The highlighted concern revolves around the increased occurrence of aneuploidy following maternal age. The optimal age range for the lowest aneuploidy incidence was found to be between 27 to 37 years of age (6%) then progressively higher in women aged up to 42 (33%) and most common in those 44 and above (53%) <ref name="PMID24355045"><pubmed>24355045</pubmed></ref>. <br />
=====Recurrent pregnancy loss / IVF failure=====<br />
Recurrent pregnancy loss is defined as three or more IVF failures after cumulative transfer of more than 10 good-quality embryos. These are primarily caused by two main factors, reduced endometrium receptivity or embryonic defects. Endometrium receptivity can be negatively influences by instances including uterine pathologies such as thin endometrium, altered expression of adhesive molecules and immunological factors. Additionally, embryonic defects may be due to genetic abnormalities, embryonic aneuploidy or zona hardening. Endometriosis and hydrosalpinx has been known to effect both the endometrium and embryo <ref name="PMID23260857"><pubmed>23260857</pubmed></ref>.<br />
=====Human leukocyte antigen matching=====<br />
First used in 2001, HLA matching is an option given to parents to save a child with haematological or immunological disease through conceiving another child who would potentially be able to donate cord blood or haematopoietic stem cells from the bone marrow for transplantation. The process namely PGD-HLA has shown to improve haematopoietic stem cell transplant (HSCT). PGD-HLA can only be performed when HSCT is not needed urgently due to the time needed to conceive and delivery the baby <ref name="PMID25500181"><pubmed>25500181</pubmed></ref>. It is most commonly applied to children suffering from relapsed leukaemia <ref name="PMID22524201"><pubmed>22524201</pubmed></ref>. In a case study PGD-HLA was proven to successfully cure 10 diseases including Fanconi anaemia, Diamond-Blackfan anaemia and beta thalassemia <ref name="PMID25066893><pubmed>25066893</pubmed></ref>.<br />
==Biopsy Methods==<br />
Biopsy, the removal of genetic materials, from oocytes or embryos in the preimplantation stage is the primary step in PGD. For the past two decades these biopsies have been performed at three stages, the polar body, blastomere, and blastocyst, and the methodologies optimized to ensure the embryo’s viability. The most common approach involves biopsies at the cleavage stage. However, polar body and blastocyst biopsies are increasingly more often tested and applied. Approached for opening the zona pellucida involve next to the traditional mechanical and chemical means, novel approaches such as noncontact lasers. Their application may simplify and secure the procedure significantly. The most challenging question about PGD procedures remains at what stage biopsies should be taken. Much controversy has developed around this topic, highlighting the varying disadvantages and advantages of temporal biopsies. <ref name="PMID22723007"><pubmed>22723007</pubmed></ref><br />
<br />
{| class="wikitable"<br />
|- align="center" bgcolor="DDCEF2"<br />
|<br />
| Time of Biopsy<br />
| Advantages <br />
| Disadvantages<br />
|- bgcolor="FFFAFA"<br />
| Polar Body<br />
| Day 1<br />
| No harm to oocyte<br />
| Only maternal DNA is tested, often needs to be coupled with other biopsies<br />
|- bgcolor="FFFAFA"<br />
| Blastomere<br />
| Day 3<br />
| …<br />
| … <br />
|- bgcolor="FFFAFA"<br />
| Trophectoderm<br />
| Day 5 and 6 <br />
| Little harm, large amount of genetic material<br />
| Opening of blastocyst necessary, small time window for procedure<br />
|}<br />
<br />
<br />
[[File:Polar_Body,_Blastomere,_and_Trophectoderm_Biopsy.jpeg|thumb|Polar body (A), blastomere (B) and trophectoderm (C) biopsies<ref name="PMID25625041"><pubmed>25625041</pubmed></ref>.]]<br />
<br />
<br />
<br />
PMID 24305177<br />
===Polar Body Analysis===<br />
Day 1<br />
====Description====<br />
Polar body (PB) biopsy, which was introduced in 1990, offers a promising alternative to biopsies performed at the blastomere stage for PGD/S indications on legal and practical grounds. <br />
Description: Consequent embryo development does not necessitate the presence of the first and second PB and their removal may not be crucial. PB biopsy requires precise timing. Keeping track of the meiotic cell cycle is necessary to perform a successful biopsy and, therefore, PB biopsy usually is applied in combination with intracytoplasmic sperm injection (ICSI). During the maturation from the germinal vesicle stage to the metaphase-II stage the first PB is formed. A cytoplasmic bridge containing spindle remnants, that are still in contact with the cellular genetic material, links this PB to the oolemma for about 90 minutes after extrusion. It is possible to visualize these remnants by polarization microscopy and it is crucial to not perform the biopsy until the first PB is no longer firmly attached to the oolemma as this indicates an immature embryo.The oocyte tolerates mechanical zona dissection best during hours four until six after ICSI as the oolemma has stabilized by that time because of the cortical granule reaction. Over time the first PB degenerates stressing a temporal biopsy and its optimal extraction time window is four to 12 hours after ICSI. The second PB forms around two to four hours after ICSI. However, its optimal time window for biopsy is set to be eight to 16 hours after ICSI. This is due to the second PB being attached to the oolemma with spindle remnants until six hours after ICSI. Biopsy at this point may cause enucleation of the oocyte. In addition, studies have shown that the amplification efficiency of second PB’s DNA is worse if the PB is extracted prior to eight hours after ICSI. <br />
Thus, it is possible to perform sequential and simultaneous biopsies for the first and second PB. If performed, sequentially the first PB may be removed four to 12 hours and the second PB eight to 16 hours after ICSI. The optimal time window for a biopsy for both the first and second PB simultaneously is eight to 12 hours after ICSI. It is highly preferred to analyze both PBs due to potential aneuploidies in either PB and crossing overs during meiosis<ref name="PMID22723007"/>. <br />
====Procedure====<br />
Chemical opening achieved with for example acidic tyrode’s solution of the zona pellucida is not tolerated by the oocyte and may have detrimental effects on the embryo’s development. Therefore, the access to the perivitelline space of the oocyte is provided by mechanical zona dissection or by laser. Both techniques work well if performed by experienced embryologist. However, laser-assisted biopsy is less time consuming when compared to manual dissection. It is critical to consider the size of the introduced opening as it will remain permanent. If it is too large the blastomere may be lost during embryo development and if it is too small it may interfere with hatching of the embryo during blastocyst stage<ref name="PMID22723007"/><br />
<br />
[[File:Polar_Body_Biopsy.jpeg|thumb|The presence of a faint but clearly identifiable strand connecting PB2 to the <br />
oolemma. The biopsy was performed ∼9 h after ICSI<ref name="PMID21908464"><pubmed>21908464</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JTaQzszVr8o</html5media><br />
|-<br />
| Laser-assisted polar body biopsy<ref>RIUK, R. (2013, June 25) Polar Body Biopsy [Video file]. Retrieved from https://www.youtube.com/watch?v=JTaQzszVr8o</ref><br />
|}<br />
<br />
====Advantages & Disadvantages====<br />
PB biopsies can only investigate the maternal contributions to the embryo as they are of maternal origin. Thus, this procedure is appropriate for PGD solely for monogenetic diseases from the maternal side. Recessive diseases may be evaluated with PB biopsies on the basis that the embryo’s outcome will be determined by the paternal contribution. (...) It may still be applied for PGS as most aneuploidies either arise during meiosis or origin from the maternal genome. However, diagnosis error has been reported due to the lack of considering paternal contributions. <br />
Because PB biopsies are performed very early it is not yet known whether the oocyte will develop into a viable embryo. Thus, PBs are commonly frozen or fixed after biopsy and depending on the state of the embryo only chosen PBs will be tested. This is primarily an economic issue as many genetic testing procedures are very cost-intensive<ref name="PMID22723007"/>.<br />
<br />
[[File:Implantation_predictive_value_of_euploid_screening_results.jpeg|thumb|The sustained implantation predictive value (with 95 % confidence interval) of a euploid screening result obtained from the first polar body (PB1), PB1 and the second polar body (PB2), or a direct embryo biopsy for each stage of embryo transfer (cleavage-stage and blastocyst stage)<ref name="PMID25106935"><pubmed>25106935</pubmed></ref>.]]<br />
<br />
===Blastomere biopsy===<br />
Day 3 <br />
====Description====<br />
Blastomere biopsy has been the prevalent method for PGD and PGS in the last two decades. At least one, but up to two, blastomeres are biopsied on day three of the cleavage stage embryo. The right number of blastomeres removed is a controversial topic as two cells allow for more genetic material and more accurate results. However, removing two cells might be too invasive and damaging to the embryo. (Study)<ref name="PMID21748341"><pubmed>21748341</pubmed></ref><br />
====Procedure====<br />
Initially a hole was drilled into the zona pellucida using acid tyrodes and the blastomeres are removed via aspiration with a pipette<ref name="PMID21748341"/>.<br />
<br />
<br />
[[File:Aspiration_of_a_Blastomere.jpeg|thumb|Aspiration of a Blastomere into the biopsy pipette<ref name=" PMID24783200"><pubmed>24783200</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=TbridWVwipI</html5media><br />
|-<br />
| Laser-assisted blastomere biopsy<ref>Sukprasert, M. (2014, March 5) Day 3 Blastomere Biopsy 1 [Video file]. Retrieved from https://www.youtube.com/watch?v=TbridWVwipI</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
===Trophectoderm biopsy===<br />
Day 5 and 6<br />
====Description====<br />
The improvement of embryo culture media allowed the in vitro development of human embryos until the blastocyst stage and opened up the possibility to take blastocyst biopsies. During day three to day five the haploid maternal and paternal genomes work together for the first time to form the genome of the embryo. The maternal epigenetic control lessens significantly while preparing for implantation with precisely arranged events happening. The first event includes a rapid increase in the number of embryonic cells which are active in mitotic divisions and apoptosis of aberrant cells. This is followed by the formation of blastocoel (cavitation) which results from the flattening of cell located on the outside of the blastomere. Now the blastocyst will expand until the embryo hatches by rupturing the zona pellucida. The cells of the blastocyst will differentiate to form two distinct cell lineages, the outer trophectoderm and the inner cell mass<ref name="PMID22723007"/>.<br />
====Procedure====<br />
Trophectoderm biopsy is usually performed in Hepes buffered biopsy medium and opening approaches include needle cutting which has been replaced by lasers in past years. Different research groups report different timings of the opening to be the most successful. Some open the blastocyst on day three or four by creating a 25 µm which causes the trophectoderm to herniate through this hole and is, thus, accessible for biopsy. Others create this hole about four hours before biopsy which allows sufficient herniation of trophectoderm cells. It is also possible to open the blastocyst immediately before biopsy. This avoids an extra step and the inner cell mass usually is easy to locate. Blastocyst biopsies involve the removal of trophectoderm cells and the ideal time for the procedure is day five. Successful biopsies on day six have been performed, while little is known about the results of biopsies on day seven. However, since the window of implantation in humans is from day eight to ten after ovulation, day seven biopsies appear to be possible<ref name="PMID22723007"/>.<br />
-collapse of trophoblasts<br />
-possible: biopsy of hatched blastocyst, holding pipette careful mild suction force to hold embryo near ICM <br />
-Cryopreservation<br />
<br />
<br />
[[File:Microscopic images of human blastocysts for biopsy.jpeg|thumb|(A) Some trophectoderm cells in a blastocyst started to hatch and (B) the trophectoderm cells were biopsied with assisted laser cutting. Images in C–D show the blastocysts after vitrification and warming. Blastocysts had been cultured for 2–4 hrs after warming, showing good (ICM and trophectoderm cells) hatched (C) and hatching (D) blastocysts. The hatching blastocyst in (E) has good ICM but fair trophectoderm while the blastocyst in (F) has both fair ICM and trophectoderm. Arrows indicate ICMs and arrow heads indicate trophectoderm cells. Bar = 40 µm<ref name="PMID2190846"><pubmed>2190846</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JI_TQ8d8tNM</html5media><br />
|-<br />
| Laser-assisted blastocyst biopsy (at 00:50 min)<ref>Coco, R. (2014, April 30) Trophectoderm biopsy in a Hatching blastocyst protruding ICM [Video file]. Retrieved from https://www.youtube.com/watch?v=JI_TQ8d8tNM</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
Blastocyst biopsies are believed to be less damaging to the embryo and appear to be unrelated to implantation rates. In addition, this biopsy method allows for a larger extraction of cells for genetic testing. However, since they are performed late in in vitro development, the time window for genetic testing is relatively small. Fast and accurate genetic testing methods are needed to ensure a successful and safe result from this biopsy. Thus, blastocyst biopsies may gain more popularity in the future whn such methods have been developed or improved<ref name="PMID22723007"/>. <br />
<br />
<br />
==Genetic Techniques==<br />
<br />
===PCR===<br />
====Description====<br />
Polymerase chain reaction (PCR) amplifies DNA specific to genetic sequence of interest . PCR was developed by Kay Mullis in the 1980s, for which he was awarded the Nobel prize for chemistry in 1993. <ref> Pubmed Docs (2015) Polymerase Chain Reaction (PCR) Pubmen. Retrieved from [http://www.ncbi.nlm.nih.gov/probe/docs/techpcr/]</ref> This technique enables clinicians to monitor and diagnose diseases using minute samples such as embryonic cells, blood & tissue. <ref>Roche (2015) PCR: How We Copy DNA. Roche Molecular Systems Inc. retrieved From [http://molecular.roche.com/pcr/Pages/Process.aspx]</ref> PCR has many important applications like DNA fingerprinting, genetic mapping, detection of viruses and bacteria as well as being used to detect genetic disorders, as a part of PGD, in conjunction with IVF. It is used to detect molecular abnormalities such as single gene disorders like Tay Sach, Cycstic fibrosis, Duchenne Muscular Dystrophy, Thalassemia, Huntington disease, Spinal muscular atrophy and many more. Molecular and Genetic analysis require a significant amount of DNA, which we would not have without PCR. It revolutionized the study of DNA, replacing all previous recombinant DNA technology. <ref> Mullins, K., Francois, F.& Gibbs R.A. (1994 ) The Polymerase Chain Reaction. p3. Springer- Science +Business Media. Birkhauser, Boston<br />
Available at [https://books.google.com.au/books?hl=en&lr=&id=gjrTBwAAQBAJ&oi=fnd&pg=PR5&dq=kary+mullis+PCR&ots=mpzAyRh5ZY&sig=PQ4goNoKJ90tb3-MkPk62zrTGbw#v=onepage&q=kary%20mullis%20PCR&f=false] </ref> <br />
<br />
[[File:PCR.jpg|thumb|right|Polymerase chain reaction (PCR) amplifies DNA specific to genetic sequence of interest, enabling the monitoring and diagnose molecular abnormalities such as single gene disorders using minute samples such as embryonic cells, blood & tissue <ref>NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref>]]<br />
<br />
====Procedure====<br />
<br />
Sample are obtained from the the blastocyst, a polar body biopsy or the blastomeres stages of the embryo. <br />
Stage 1 Denaturing: separating the target strands of DNA <br />
The obtained sample is heated to roughly 90 degrees celcius, this heat causes breaks the relatively weak bonds between nucleotides that form DNA. the double stranded DNA to split into 2 single strands of DNA that are used as templates.<br />
Stage 2 Annealing: Binding the Primers to the target DNA sequence <br />
PCR will only copy the target sequence of DNA specified by specific PCR primer. These synthesized primers Oligonucleotides are small artificial pieces of DNA. <br />
TAQ polymerase enzyme synthesize 2 new strands of DNA duplicate to the single sample DNA stand template indicated by these primers. During this stage the reaction is cooled to a temperature between 40-60 degrees Celsius. <br />
Stage 3- Extension- making copies <br />
Each of these 2 copies are then used again as templates generating 2 further replications This cycle can occur as many 30 -40 times within a couple hours leading to billions of extra copies of the original DNA segment. The optimal temperature for the further replication is roughly 72 degrees Celsius. <br />
<br />
This process mediated by a thermocycler machine that is programmed to alter the temperature of the reaction every couple of minutes, perpetuating the cycle of DNA denaturing and synthesis. <br />
This process, generates exponential exact copy of the original template DNA sequence. <br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
!PCR cycles<br />
<br />
|{|<br />
|-<br />
| '''PCR Cycle'''<br />
| '''Target Copies'''<br />
|-<br />
| 1<br />
| 2<br />
|-<br />
| 2<br />
| 4<br />
|-<br />
| 3<br />
| 8<br />
|-<br />
| 4<br />
| 16<br />
|-"<br />
| 5 <br />
| 32<br />
|-<br />
| 6 <br />
| 64<br />
|-<br />
| 7 <br />
| 128<br />
|-<br />
| 8<br />
| 256<br />
|- <br />
| 9<br />
| 512 <br />
|-<br />
| 10<br />
| 1024<br />
|-<br />
| 15<br />
| 32,768<br />
|-<br />
| 20 <br />
| 1,048,578<br />
|-<br />
| 25<br />
| 33,554,432<br />
|-<br />
| 30 <br />
| 1,073,741,842<br />
|-<br />
|}<br />
<br />
<br />
<br />
{| class="wikitable" <br />
|-bgcolor="#9ACD32" <br />
| rowspan="10" |'''Advantages'''<br />
|-bgcolor="#F0FFF0"<br />
| fast and inexpensive way of copying a target sequence of DNA<br />
|-bgcolor="#F0FFF0"<br />
| aids the diagnosis of single cell defects<br />
|-bgcolor="#F0FFF0"<br />
| rapid generation of results within a couple hours<br />
|-bgcolor="#F0FFF0"<br />
| can start from a single molecule of DNA, therefore is more sensitive <br />
|-bgcolor="#F0FFF0"<br />
| has a flexible primer design enabling<br />
|-bgcolor="#F0FFF0"<br />
| overcame previous issues associated with the limited availability of sites of end<br />
|-bgcolor="#F0FFF0"<br />
| generates the DNA copies exponentially<br />
|-bgcolor="#F0FFF0"<br />
| enables DNA amplification required for molecular and genetic analysis<br />
|-bgcolor="#F0FFF0"<br />
|Valid diagnostic method in selecting unaffected embryos for embryo transfer <ref> Dreesen, J., Drusedaul, M., Smeets, H., Die-Smulders, C., Coonen, E., Dumoulin, J., Gielen, M., Evers, J., Herbergers, J. & Geradets, J. (2008) Validation of preimplantation genetic diagnosis by PCR analysis: genotype comparison of the blastomere and corresponding embryo, implications for clinical practice. Mol. Hum. Reprod. 14 (10):573-579.doi: 10.1093/molehr/gan052. Retrieved from [http://molehr.oxfordjournals.org/content/14/10/573.short] </ref> <ref><pubmed>20966460</pubmed></ref><br />
|-bgcolor="#9ACD32"<br />
| rowspan="5"|'''Disadvantages'''<br />
|-bgcolor="#F0FFF0"<br />
| only during this exponential DNA replication phase can we determine the starting quantity sequence contained in the original sample ( template DNA strand)<br />
|-bgcolor="#F0FFF0"<br />
| PCR reaction is limited by the presence of inhibitors present in the sample : reagent inhibitors <br />
|-bgcolor="#F0FFF0"<br />
| self annealing due to the accumulation of the product -stopping exponential amplification for the target sequence and reach a plateau<br />
quantification of the end point of reaction of PCR products unreliable - therefore that is why we require real time quantitative RT-PCR necessary<br />
<ref> NIS (2015) Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref><br />
|}<br />
<br />
<br />
===Fluorescent In Situ Hybridisation (FISH)===<br />
<br />
<br />
====Description====<br />
Fluorescence in situ hybridization (FISH) the one of the most effective and rapid <ref name="PMID26338801"><pubmed>26338801</pubmed></ref> Preimplantation Genetic Diagnosis (PGD). This techniques used to locate a specific DNA sequences within a chromosome. FISH facilitates the clinical diagnosis of chromosomal abnormalities indicated by sequential duplications, deletions and rearrangements of chromosome, that are usually missed with microscopic analysis. This technique is especially relevant for female embryos with X-linked diseases,<ref name="PMID20809319"><pubmed>20809319</pubmed></ref> that have no other mutation specific tests [http://www.ncbi.nlm.nih.gov/pubmed/20809319] As part of PGD, samples are collected from various stages of the embyro,and they are able to conducted tests on the blastocyst, a polar body biopsy and the blastomeres <ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. FISH is 99% effective when used in conjunction with competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities<ref name="PMID26338801"/>.<br />
<br />
====Procedure==== <br />
<br />
Samples are collected from either the blastocyst, a polar body biopsy or the blastomeres stages of the embryo <ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
DNA strands are heated and denatured causing their the individual DNA strands to break apart<br />
Probes are single complimentary stands of DNA a that have been tagged with small chemical agents that glow brightly in the presence of a specific region on a chromosome. These specific probes then hybridize and join to their complementary DNA strand. <br />
The fluorescent tags enable the researchers to correctly identify the presence or lack thereof and location of the specific chromosomes that they are testing for. <ref name="PMID17876073"><pubmed>17876073</pubmed></ref><br />
Researcher analyse the results by identifying the number and the relative location of the fluorescent dots generated by the FISH images.<ref name="PMID17970921"><pubmed>17970921</pubmed></ref><br />
The probe will not fully hybridise if there has been a duplication or a deletion of the DNA - indicating chromosomal and sex chromosomal anomalies like trisomies and aneuploidies. <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref><br />
<br />
<br />
Different probes are used for different purposes: <ref>Unique, Rare Chromosome Disorder Support Group (2013) Fluorescence in situ hybridisation (FISH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/Other/FISH%20FTNW.pdf]</ref><br />
*'''Locus specific tags''' detect very small imbalances, and locate isolated small portions <br />
of genes within a chromosome<br />
*'''Alphoid/Centomeric Repeat probes''' are developed from the repetitive sequence located in the middle region of each chromosome, useful in determining the number of chromosomes , detecting rearrangement and when used in conjunction with locus probes to determine the absence of genetic material on a chromosome. <br />
*'''Paint Probes''' are collections of smaller probes with their own stains that bind to a different section on the chromosome - allowing the full chromosome too be labeled a unique colour, this "full colour map" can be used to know the spectral karyotype- full chromosomal mapping is useful in examining chromosomal abnormalities. <br />
<br />
[[File:Fluorescent In Situ Hybridisation (FISH).jpg|thumb|right|'''FISH''' We are able to tag Specific DNA sequences using Probes which have been tagged with fluorescent Labels.This technique enables the clinical diagnosis of chromosomal abnormalities, indicated by sequential duplication, deletions and rearrangements of chromosome <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref>]]<br />
<br />
{|class="wikitable" align="center"<br />
|-bgcolor="pink" <br />
| rowspan="8" |'''Advantages''' <br />
|-bgcolor="#FDE1F2" <br />
| FISH is 99% effective when used in conjunction with Competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities.<ref><pubmed>26338801</pubmed></ref><br />
|-bgcolor="#FDE1F2" <br />
| Rapid generation of results<br />
|-bgcolor="#FDE1F2" <br />
| Identifies very small translocations and aneuploidies that occur within chromosomes, that would usually be missed under microscopic analysis<br />
|-bgcolor="#FDE1F2" <br />
| Indicates whether the accessed chromosomes are normal <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|-bgcolor="#FDE1F2" <br />
| Tests for the most common chromosomal abnormalities - down syndrome chromosomes 13,16,18,21 and 22 <ref><pubmed>21749752</pubmed></ref><br />
|-bgcolor="#FDE1F2" <br />
| It may be used to compare the chromosomal gene arrangements in related species<br />
|-bgcolor="#FDE1F2" <br />
| can be used to identify and remove inheritable X-linked disease or sex chromasome anomalies such as Duchennes Muscular Dystrophy, hemophilia, ectodermal dysplasia <ref><pubmed>17876073</pubmed></ref><br />
|-bgcolor="#FEB745"<br />
| rowspan="5"|'''Disadvantages'''<br />
|-bgcolor="#FE1C5EA"<br />
| FISH destroys all cells tested <ref> O'Connor, C. (2008) Fluorescence in situ hybridization (FISH). Nature Education 1(1):171. retrieved from [http://www.nature.com/scitable/topicpage/fluorescence-in-situ-hybridization-fish-327] </ref><br />
|-bgcolor="#FE1C5EA"<br />
| It does not fully access all chromosomes (only ~ 12)<br />
|-bgcolor="#FE1C5EA"<br />
| Analysis of results is dependent upon the dot quality impacted by hybridisation efficiency or the camera sensitivity <ref><pubmed>17970921</pubmed></ref><br />
|-bgcolor="#FE1C5EA"<br />
| some studies indicate that using FISH on a day-3 embryo biopsy decreases the rate of live births <ref><pubmed>26168107</pubmed></ref><br />
|}<br />
<br />
===Array Comparative Genomic Hybridisation (aCGH)===<br />
====Description====<br />
<br />
aCGH also known as Microarray analysis efficiently scans the entire genome for chromosomal imbalances. CGH was initially developed to detect the number of changes in a solid tumor mass. It uses 2 genomes comparing the sample to the control, with each labeled in a different fluorescent dye<ref name="PMID1876176"><pubmed>1876176</pubmed></ref>. Earlier CGH techniques were limited by the resolution of the imaging <ref> Lichter, P., et al. Comparative genomic hybridization: Uses and limitations. Seminars in Hematology 37, 348–357 (2000)</ref> , these initial limitations were overcome by using Microarrays in conjunction with CGh to improve the resolution of the imaging, Array Comparative Genomic Hybridisation (aCGH). This method compares sample and control microarrayed slides containing small segments of DNA (probes). <ref> Lucito, R., et al. Representational oligonucleotide microarray analysis: A high-resolution method to detect genome copy number variation. Genome Research 13, 2291–2305 (2003) </ref> the Probes used will vary according from the small (25-85 base pairs) oligonucleotides manufactured to highlight different target sequences, to the very large genomic clones (80,000- 200,00 base pairs), and as these are significantly smaller than the traditional metaphase chromosomes used for CGH, generating a higher resolution of image. <ref name="PMID22467166"><pubmed>22467166</pubmed></ref>.aCGH is used as a diagnostic tool for prenatal detection f chromosomal abnormalities <ref name="PMID19012303"><pubmed>19012303</pubmed></ref>.<br />
<br />
<br />
====Procedure====<br />
<ref> Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432] </ref><br />
The sample is obtained (skin, blood or fetal cells) and DNA is obtained. <br />
As a part of PGD fetal cell samples are collected from; the fertilized egg polar bodies, the blastomere (day 3 embryo) or the blastocyst/tropoectoderm stage (day 5 embryo).<br />
Sample DNA is labeled with one fluorescent dye, and the control DNA is labeled with a different colored fluorescent dye. the control DNA is used as the base point of reference. <br />
heated and denatured single DNA strands then hybridize to their complementary single strand probes, which are then combined and applied to a microarray and the results are run through a computer program and a digital imaging system is used to quantify the results( fluorescent intensities of the labeled probes). <br />
<br />
[[File:aCGH.jpg|thumb|right|'''aCGH''' checks the entire genome for chromosomal imbalances, by comparing control and a sample slides contatining small segements of DNA sample microarrayed slides small segments of DNA. Illustrated by student z5020317 and adapted from <ref> NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation. retrieved from [http://www.phgfoundation.org/file/5237/]</ref> <ref>Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432]</ref>]]<br />
<br />
<br />
<br />
The fluorescent ratio and the hybridization signal at different locations on the genome of the control DNA are used to identify any variances present in the sample DNA. aCGH facilitates the clinical diagnosis of submicroscopic chromosomal duplication, deletion and rearrangements indicative of chromosomal disorders such as trisomies 1-22and specific sex linked disorders. <br />
Duplications in the DNA are displayed by the computer program as spikes/ peaks over an established threshold and deletions in DNA are displayed by the computer program as spikes/ toughs beneath this threshold <br />
<br />
<br />
<br />
<br />
{|border="1" align="center"<br />
|-bgcolor="pink" <br />
| '''Advantages''' <br />
| '''Disadvantages'''<br />
|-<br />
| multiple applications: prenatal genetic diagnosis, cancer diagnosis, <ref name="PMID20193845"><pubmed>20193845</pubmed></ref> genetic screening for developmental delay (learning disabilities) <ref name="PMID17309648"><pubmed>17309648</pubmed></ref>. or congenital anomalies that are suspected to be genetic in origin <ref>NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation . retrieved from [http://www.phgfoundation.org/file/5237/]</ref><br />
| translocations and inversions of DNA are not detected<br />
|-bgcolor="pink"<br />
| trace represents all chromosomes present in the human genome chromosomes 1-22 and the X & Y chromosomes, and therefore is the most accurate method for testing whole embryo aneuploidy<br />
| limited ability diagnosing specific polyploidies such as triploidy <ref> Unique, Rare Chromosome Disorder Support Group (2013) Microarray-based Comparative Genomic Hybridiation (array CGH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/other/array%20cgh%20ftnw.pdf] </ref><br />
|-<br />
| aCGH has been extensively tested, and Validated, and is now used world wide.<br />
| will not detect mosaicism detection <20% (cultures where >1 of 5 cells are trisomy 12)<br />
|-bgcolor="pink"<br />
| detects deletions and additions and rearrangements as well as amplification, of the WHOLE genome, simultaneously.<br />
| will not detect balanced chromosomal rearrangement<br />
|-<br />
| detects submicroscopic alterations<br />
| will not detect duplications or deletions <80kb<br />
|-bgcolor="pink"<br />
| used as a diagnostic tool for prenatal detection of chromosomal abnormalities <ref name="PMID22034057"><pubmed>22034057</pubmed></ref><br />
| will not detect point mutations within genes <ref>Washington department of education (CGH- FAQ for physicians. Signature Genomic LAboratories, LLC. Retrieved from [https://depts.washington.edu/dbpeds/Lab%20Tests/SignatureCGH-physician_FAQ.pdf]</ref><br />
|-<br />
| provides high resolution genomewide screening of segmental genomic copy number variations<br />
| will not detect chromosomal position of genomic gains<br />
|-bgcolor="pink"<br />
| very accurate when used in conjunction with FISH<br />
| will not detect loos of heterozygosity (LOH) or Absence of heterozygosity (AOH) <ref>WiCell Research Institute Inc. (2012) Comparative Genomic Hybridization Microarray. <br />
retrieved from [http://www.wicell.org/home/cytogenetic-services/cgh-microarray/array-comparative-genomic-hybridization-acgh.cmsx]</ref><br />
|-<br />
|Alone is more reliable and in detecting chromosomal abnormalities, with a higher implantation success rate, than FISH <ref name="PMID20494259"><pubmed>20494259</pubmed></ref><br />
|<br />
|-bgcolor="pink"<br />
|Allows an in depth research focus upon specific types of rearrangements within selected chromosomal regions, a recent particular area of interest is subtelomeric and pericentromeric rearrangements<br />
|<br />
|-<br />
|reduces the risk of failed implantation and miscarriage, improving the chance of a healthy baby <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|<br />
|}<br />
<br />
<br />
<br />
===Next Generation Sequencing===<br />
====Description====<br />
The development and advances within ART in the past 20 years, as well as the increasing popularity of IV, has lead to an influx of new technologies developed to screen embryos for chromosomal anomalies, which are covered by the umbrella term of Next generation Sequencing (NGS). NGS is a general term used to describe all of the new and emerging screening techniques currently being introduced and used as part of PGD for IVF . NGS screens for single gene disorders as well as conducting extensive and very comprehensive chromosome diagnosis by sequencing, counting, and accurately assembling millions of DNA reads, simultaneously. <ref name="PMID23499002"><pubmed>23499002</pubmed></ref> There is a movement for NGS to replace the other limited testing techniques and be used as the standard. <br />
====Procedure====<br />
Samples are collected from either blastomere or the blastocyst/tropoectoderm and processed for analysis by a computer system. <br />
The methodology of each process is unique to the technique being used. <br />
<br />
<br />
<br />
{|border="1" align="center"<br />
|-bgcolor="pink" <br />
| '''Advantages'''<br />
| '''Disadvantages'''<br />
|-bgcolor="white"<br />
| cheaper<br />
| there are limited information available to clinical applications of NGS <ref><pubmed>26100406</pubmed></ref><br />
|-bgcolor="pink"<br />
| opens new diagnostic possibilities<br />
|<br />
|-bgcolor="white"<br />
| accurately tests all 24 chromosomes<br />
| <br />
|-bgcolor="pink"<br />
| tests for the presence of monogenic diseases of known genetic background<br />
| <br />
|-bgcolor="white"<br />
| reduces the number of biopsies required for diagnosis<br />
| <br />
|-bgcolor="pink"<br />
| higher detection rate of small translocations<br />
| <br />
|-bgcolor="white"<br />
| highly accurate is testing for compound point mutations, chromosomal duplication, deletions and insertions <ref name="23312231"><pubmed>23312231</pubmed></ref><br />
| <br />
|-bgcolor="pink"<br />
| it accurately detects chromosomal aneuploidy and unbalanced rearrangement <ref name="PMID25685330"><pubmed>25685330</pubmed></ref><br />
| <br />
|-bgcolor="white"<br />
| NGS single gene disorder screenings can conducted in conjunction with PCR comprehensive chromosomal screening<br />
|<br />
|-bgcolor="pink"<br />
| Reduces human error <br />
|<br />
|-bgcolor="white"<br />
| better detects the presence of mosaicism<br />
|<br />
|-bgcolor="pink"<br />
| work well in conjunction with CGH and aCGH as part of PGD, improving the chances of IVF. <ref> Morris, R. S. (2015 ) Next generation sequencing for PCG|PGS|CCS. IVF1 retrieved from [http://www.ivf1.com/next-generation-sequencing for-pgd] </ref><br />
|<br />
|}<br />
<br />
<br />
<br />
<br />
<br />
<br />
==Diagnosis==<br />
There are a large amount of diseases that PGD can apply to, below are descriptions of the diseases that PGD are more commonly used for. Utilization of Diseased Cell Lines<br />
===Cystic Fibrosis===<br />
Cystic fibrosis is a single gene disorder. It is autosomal recessive and involves mutations in the cystic fibrosis transmembrane conductance regulator (CTFR) gene. The CTFR gene is normally responsible for the decrease in chloride and the transport of bicarbonate in epithelial cells thus playing a major physiological role. In PGD procedures, identification of the gene is assisted by microsatellite markers that have similar composition to the CTFR gene itself. Biopsy of two cells at the blastocyst stage is recommended if markers are not available. There are many variations of cystic fibrosis the most common being P.Phe508del <ref name="PMID26014425"><pubmed>26014425</pubmed></ref>.<br />
===Duchenne Muscular Dystrophy ===<br />
Duchenne Muscular Dystrophy is an X-linked recessive disease. It involves the Xp21 gene where majority of the mutations are chromosomal deletions with a smaller percentage resulting from duplications <ref name="PMID18359022"><pubmed>18359022</pubmed></ref>.<br />
===β – Thalassemia=== <br />
β – Thalassemia is known as the most common type of autosomal recessive inherited disorder among haemoglobinopathies. It involves the adult β-globin gene and is associated with the absent or decreased expression of the gene. This is commonly caused by a single nucleotide change in the gene. PGD has been used successfully worldwide to identify the β-globin gene where its application is usually performed on a single blastomere or polar body <ref name="PMID19064120">19064120</pubmed></ref>.<br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
! Applicable diseases for PGD <ref>Genoma Group (2014). Retrieved September 18th, 2015, from http://www.preimplantationgeneticdiagnosis.it/genetic-diseases-diagnosed-by-pgd.htm </ref>, <ref>Genesis Genetics (2015). Retrieved September 18th, 2015, from http://genesisgenetics.org/pgd/what-we-test-for/</ref>, <ref>Human Fertilisation & Embryology Authority (2015). Retrieved Septembr 18th, 2015, from http://guide.hfea.gov.uk/pgd/</ref><br />
|-<br />
| '''Disease'''<br />
| '''Involved Genes'''<br />
|-<br />
| 5 Alpha Reductase Deficiency (5ARD)<br />
| SRD5A2 <br />
|-<br />
| Achondroplasia<br />
|FGFR3 <br />
|-<br />
| Acute Intermittent Porphyria <br />
| ALAD, ALAS2, CPOX, FECH, HMBS, PPOX, UROD, or UROS<br />
|-<br />
| Adrenoleukodystrophy (Adrenomyeloneuropathy)<br />
| ABCD1 <br />
|-<br />
| Agammaglobulinaemia (x-linked) <br />
|BTK <br />
|-<br />
| Agammaglobulinemia Bruton Tyrosine Kinase (BTK) <br />
|BTK <br />
|-<br />
| Aicardi Goutieres Syndrome 1 (AGS1) <br />
|TREX1, RNASEH2A, RNASEH2B, RNASEH2C, SAMHD1<br />
|-<br />
| Alagille Syndrome<br />
|JAG1 or NOTCH2<br />
|- <br />
| Alpers-Huttenlocher Syndrome <br />
|POLG <br />
|-<br />
| Alpha-1-antitrypsin deficiency <br />
|SERPINA1 <br />
|-<br />
| Alpha-Mannosidosis<br />
| MAN2B1 <br />
|-<br />
| Alpha Thalassemia <br />
|HBA1 or HBA2 <br />
|-<br />
| Alports Syndrome<br />
|COL4A3, COL4A4, COL4A5<br />
|-<br />
| Alzheimer's Disease - early onset (Type 3 and 4) <br />
|APP, PSEN1, or PSEN2<br />
|-<br />
| Amyotrophic Lateral Sclerosis 1 (ALS1) <br />
|C9orf72, SOD1, TARDBP, FUS, ANG, ALS2, SETX, VAPB <br />
|-<br />
| Argininosuccinic Aciduria <br />
| ASL<br />
|-<br />
| Arrhythmogenic Right Ventricular Cardiomyopathy/ Dysplasia (ARVC/D)<br />
| DSG2; DSP; PKP2<br />
|-<br />
| Ataxia Telangiectasia<br />
| ATM<br />
|-<br />
| Bardet-Biedl Syndrome (BBS)<br />
| BBS1; BBS10<br />
|-<br />
| Barth Syndrome<br />
| TAZ<br />
|-<br />
| Beta Thalassaemia<br />
| HBB<br />
|-<br />
| Birt-Hogg-Dubé Syndrome<br />
| FLCN<br />
|-<br />
| Breast Ovarian Cancer Familial Susceptibility (BRCA2)<br />
| BRCA1; BRCA2<br />
|-<br />
| Canavan Disease <br />
| ASPA<br />
|-<br />
| Carnitine-Acylcarnitine Translocase Deficiency <br />
| SLC25A20<br />
|-<br />
| Cerebral Arteriopathy with Subcortical Infarcts & Leukoencephalopathy (CADASIL)<br />
| NOTCH3<br />
|-<br />
| Cerebral Cavernous Malformation<br />
| CCM1<br />
|-<br />
| Charcot-Marie-Tooth Disease<br />
| GJB1; MPZ; NEFL; PMP22<br />
|-<br />
| CHARGE Syndrome<br />
| CHD7<br />
|-<br />
| Cherubism<br />
| SH3BP2<br />
|-<br />
| Choroideremia<br />
| CHM<br />
|-<br />
| Chronic Granulomatous Disease<br />
| CYBB; NCF1<br />
|-<br />
| Ciliary Dyskinesia<br />
| DNAH5<br />
|-<br />
| Citrullinemia<br />
| ASS1<br />
|-<br />
| Cleidocranial Dysplasia<br />
| RUNX2<br />
|-<br />
| Cockayne Syndrome<br />
| ERCC6<br />
|-<br />
| Congenital Adrenal Hyperplasia<br />
| CYP21A2<br />
|-<br />
| Congenital Cataracts<br />
| GJA8; VSX2<br />
|-<br />
| Congenital Diarrhea, Syndromic<br />
| SPINT2<br />
|-<br />
| Congenital Disorders of Glycosylation (CDG)<br />
| ALG1; ALG6; CDG1C; DOLK; PMM2<br />
|-<br />
| Cornelia de Lange Syndrome <br />
| NIPBL<br />
|-<br />
| Craniosynostosis<br />
| TWIST1<br />
|-<br />
| Crouzon Syndrome<br />
| FGFR2<br />
|-<br />
| Cysteinyl Leukotriene Receptor 1 Deficiency <br />
| CYSLTR1<br />
|-<br />
| Cystic Fibrosis<br />
| CFTR<br />
|-<br />
| Diamond –Blackfan Anemia <br />
| RPS19<br />
|-<br />
| Duchenne Muscular Dystrophy <br />
| DMD<br />
|-<br />
| Dyskeratosis congenita (Male embryos only)<br />
| DKC1<br />
|-<br />
| Ectodermal dysplasia (Hypohidrotic)<br />
| EDA; EDA1; GJB6; IKBKG<br />
|-<br />
| Familial Adenomatous polyposis coli (FAP)<br />
| APC<br />
|-<br />
| Familial Dysautonomia<br />
| IKBKAP<br />
|-<br />
| Fanconi Anemia <br />
| FANCA; FANCC; FANCD2; FANCF; FANCG; FANCJ<br />
|-<br />
| Fragile X Syndrome (FRAX)<br />
| FMR1<br />
|-<br />
| Galactosemia <br />
| GALT<br />
|-<br />
| Gangliosidosis<br />
| GLB1<br />
|-<br />
| Glanzmann Thrombasthenia <br />
| ITGA2B<br />
|-<br />
| Glutaric Acidemia (aciduria)<br />
| GCDH <br />
|-<br />
| Glycogen Storage Disease <br />
| G6PC; GAA; SLC37A4<br />
|-<br />
| Haemophilia A<br />
| F8<br />
|-<br />
| Haemophilia B<br />
| F9<br />
|-<br />
| Hereditary Nonpolyposis Colorectal Cancer: Lynch Syndrome<br />
| MLH1; MSH2; MSH6<br />
|-<br />
| Holt Oram Syndrome<br />
| TBX5<br />
|-<br />
| Huntington Disease<br />
| HD<br />
|-<br />
| Hydrocephalus<br />
| L1CAM<br />
|-<br />
| Ichthyosis <br />
| ABCA12; STS<br />
|-<br />
| Incontinentia Pigmenti (IP)<br />
| NEMO<br />
|-<br />
| Joubert Syndrome 5<br />
| INPP5E<br />
|-<br />
| Krabbe Disease<br />
| GALC<br />
|-<br />
| Leber Congenital Amaurosis (LCA)<br />
| CEP290; GUCY2D<br />
|-<br />
| Leigh Syndrome (Infantile Subacute Necrotising Encephalopathy)<br />
| LRPPRC<br />
|-<br />
| Lesch Nyan Syndrome<br />
| HPRT1<br />
|-<br />
| Leukocyte Adhesion Deficiency (Type I)<br />
| ITGB2<br />
|-<br />
| Li-Fraumeni Syndrome<br />
| TP53<br />
|-<br />
| Macular Dystrophy Retinal <br />
| VMD2<br />
|-<br />
| Maple Syrup Urine Disorder (MSUD)<br />
| BCKDHB<br />
|-<br />
| Marfan Syndrome <br />
| FBN1<br />
|-<br />
| Menkes Syndrome<br />
| ATP7A<br />
|-<br />
| Mitochondrial DNA Depletion Syndrom <br />
| POLG; RRM2B; SUCLA2; TK2<br />
|-<br />
| Mucolipidosis type II<br />
| GNPTAB<br />
|-<br />
| Multiple Endocrine Neoplasia<br />
| MEN1; MEN2A; MEN2B<br />
|-<br />
| Multiple Exostoses<br />
| EXT1; EXT2 <br />
|-<br />
| Myotubular myopathy<br />
| MTM1 <br />
|-<br />
| Nail-Patella Syndrome<br />
| LMX1B<br />
|-<br />
| Neurofibromatosis Type 1<br />
| NF1<br />
|-<br />
| Neurofibromatosis Type 2 <br />
| NF2<br />
|-<br />
| Noonan Syndrome<br />
| KRAS, PTPN11; SOS1<br />
|-<br />
| Norrie Disease<br />
| NDP<br />
|-<br />
| Ocular Albinism <br />
| GPR143<br />
|-<br />
| Oculocutaneous Albinism <br />
| OCA2; TYR <br />
|-<br />
| Oculodentaldigital Dysplasia<br />
| GJA1<br />
|-<br />
| Optic Atrophy<br />
| OPA1<br />
|-<br />
| Ornithine Transcarbamylase Deficiency <br />
| OTC<br />
|-<br />
| Osteogenesis imperfeca <br />
| COL1A1; COL1A2<br />
|-<br />
| Osteopetrosis <br />
| CLCN7; OSTM1; TCIRG1<br />
|-<br />
| Pachyonychia Congenita <br />
| KRT16; KRT6A<br />
|-<br />
| Pancreatitis, Hereditary<br />
| PRSS1 <br />
|-<br />
| Papillorenal syndrome <br />
| PAX2<br />
|-<br />
| Phenylketonuria <br />
| PAH <br />
|-<br />
| This table does not cover the complete list of diseases that PGD can be applied to.<br />
|}<br />
<br />
==Laws & Legal status==<br />
<br />
{|border="1" align="center"<br />
|-<br />
| Australia<br />
| PGD is currently used to detect serious genetic conditions to improve the outcome of Assisted Reproductive Technologies (ART). In very rare cases it may be used to select an embryo with compatible tissue for a sibling who has a life-threatening disease where other means of treatment is unavailable. This is with the conditions that the use of PGD will not affect the welfare and interests of the child to be born. The parents must also receive adequate counselling and have full understanding of the procedures of PGD. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"> National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art</ref><br />
The use of PGD for sex-selection is prohibited with the exception of reducing the risk of the transmission of serious sex-linked genetic conditions. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"/><br />
|-<br />
| Brazil<br />
| The laws regarding PGD in Brazil are not strictly regulated. They are vague and there is limited information surround the activities of assisted reproduction in general in the country <ref name="PMID25493379"><pubmed>25493379</pubmed></ref>.<br />
|-<br />
| Czech Republic<br />
| The laws in the Czech Republic allow those with a “defined indication in order to exclude risk of serous genetically conditioned disease and defects with embryos before they are implanted into the cavity of the uterus”. Couples that undergo any assisted reproductive treatment including PGD have to be married. Sex-selection is illegal except in regards to serious sex-linked genetic diseases <ref name="PMID24777348"><pubmed>24777348</pubmed></ref>.<br />
|-<br />
| Greece<br />
| In Greece, ART is open to those up to the age of 50 with written consent. It can only be used if a medical necessity is present such as the susceptibility of serious hereditary diseases. Sex selection is banned apart from cases of sex-linked diseases and sexually transmitted diseases <ref name="PMID24777348"/>.<br />
|-<br />
| India<br />
| In India there is a cultural preference for boys thus the Prenatal Diagnostic Techniques (Regulation and Prevention of Misuse) Act was introduced in 1994. This law limits the use of PGD for sex determination except in cases of specific congenital diseases. These laws however are not strictly enforced. <ref>World Health Organisation (2015) Gender and Genetics Retrieved on October 21st 2015 from:http://www.who.int/genomics/gender/en/index4.html<ref/><br />
|-<br />
| Portugal <br />
| ART is only available to those who are married or have a similar type of relationship for at least two years. The couples cannot be of the same sex and must be at least 18 years of age. Sex selection is illegal except in cases of sex-linked diseases. The use of PGD is illegal if the predictive value of genetic tests are very low <ref name="PMID24777348"/>.<br />
|-<br />
| Spain<br />
| PGD can be applied to “serious hereditary diseases not amenable to postnatal curative treatment” and “detection of other abnormalities which may compromise the viability of the pre-embryo”. If PGD is to be used for any other purpose authorisation must be acquired <ref name="PMID24777348"/>.<br />
|-<br />
| Sweden <br />
| The use of PGD is strictly regulated and couples must achieve authorisation of the National Board of Health and Welfare. It can only be used it can only be used if the child is at risk to inheriting a serious chromosomal or monogenetic disease. It cannot be used for selection of specific characteristics <ref name="PMID24777348"/>.<br />
|-<br />
| United Kingdom<br />
| Those involved with carrying out the IVF treatment must have a license from the Human Fertilisation and Embryology Authority (HFEA). Only embryos that are approved by the HFEA can be implanted where the embryonic nuclear or mitochondrial DNA cannot be altered with the exception of preventing mitochondrial diseases <ref name="PMID24777348"/>. <br />
|}<br />
<br />
==Future/Current Research==<br />
===Noninvasive Preimplantation Genetic Testing without Embryo Biopsy===<br />
Different parameters of gametes, zygotes, embryos (“vacuoles in sperm heads, spindle position in mature oocytes, cleavage intervals of zygote, and embryo developmental dynamics”) may correlate with aneuploidy rates. This knowledge may be applied in potential noninvasive preimplantation diagnostic methods. Several methods have been proposed and are currently further researched<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Sperm Selection====<br />
Intracytoplasmic morphologically selected sperm injection (IMSI) is common procedure in IVF treatment to improve fertilization rates in patients with poor semen quality. In addition, studies have found that IMSI improves embryo development and that spermatozoa with large vacuoles in their heads correlate with increased aneuploidy rates and disturbed chromosomal structures. Thus, selecting spermatozoa based on morphological hallmarks may decrease aneuploidy rates in the fertilized embryos. As with polar body biopsies, however, this approach will solely be applicable if evidence for severe male detrimental contribution is given<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Blastocoel Fluid Extraction====<br />
In addition, a less invasive retrieval of material for diagnosis could include the extraction of the blastocoel fluid. The cavity of the blastocyst, lined by the trophectoderm, is filled with this blastocoel fluid, which contains metabolites of both trophectoderm and inner cell mass origin. The retrieval does not require a biopsy but merely a small opening to extract the fluid and, thus, causes less harm to the embryo. Multiple studies have applied this method<ref name="PMID22020776"><pubmed>22020776</pubmed></ref> <ref name="PMID23148560"><pubmed>23148560</pubmed></ref> and it may in the future become of clinical relevance.<br />
<br />
<br />
[[File:Aspiration_of_the_Blastocoel_Fluid.jpeg|thumb|Aspiration of the Blastocoel Fluid using a ICSI pipette<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.]]<br />
<br />
<br />
Next to metabolites, the blastocoel fluid can contain DNA. Studies have shown that genomic DNA is present in about 90% of the blastocoel fluid samples tested. Typically the fluid is removed with an ICSI pipette from a day five blastocyst through its mural trophectoderm until the blastocyst fully collapses around the embryo. Several concerns regarding this method in a clinical setting have been raised. The collected DNA may be contaminated by the culture media that contains DNA fractions. The DNA may also be least representative of the actual embryos genome as the DNA may originate from abnormal or degenerated cells. Even though labelled noninvasive, the blastocyst still undergoes manipulation to some degree which may affect its viability. Thus, more research is required until this method can evolve from research to clinical use<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
====Proteomics====<br />
The protein secretome of blastocysts may be representative of its chromosome constitution Recent studies have found biomarkers such as lipocalin-1, interleukin-10, tumor necrosis factor, stem cell factor, and chemokine ligand 13 to be differently secreted by aneuploid blastocyst than by euploid ones. The most significant biomarker appears to be interleukin-10. Paired with novel proteomic technologies and mass spectrometry this knowledge when extended may contribute to a new invasive preimplantation genetic diagnosis method<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Embryo Morphology====<br />
Using time lapse imaging the embryo’s morphology can be closely observed and potential aneuploidy characteristics detected. Such characteristics may include the time of division to five cells, the time between the division from three to four cells, and the duration of the division from one to two and subsequently to three. In addition, the morphological quality of ICM an TE has been positively associated with aneuploidy or euploidy prognosis<ref name="PMID26246880"><pubmed>26246880</pubmed></ref>. These may give rise to an embryo quality screening prior to implantation<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
==References==<br />
<br />
<references/><br />
<br />
<br />
{{StudentPage2015}}</div>Z5017878https://embryology.med.unsw.edu.au/embryology/index.php?title=2015_Group_Project_6&diff=2069912015 Group Project 62015-10-21T06:20:09Z<p>Z5017878: </p>
<hr />
<div>{{ANAT2341Project2015header}}<br />
<br />
<br />
=Preimplantation Genetic Diagnosis and Screening=<br />
==Introduction==<br />
Preimplantation genetic diagnosis (PGD) and screening (PGS) are reproductive options for couples with known family histories of genetic disease or couples undergoing IVF procedures due to infertility issues. PGD can diagnose many genetic disorders caused by known chromosomal abnormalities (number and/or structure) or single gene mutations, and, thus decrease the risk of termination of pregnancy or miscarriages and enable such couples to have an unaffected child<ref name="PMID24907939"><pubmed>24907939</pubmed></ref>. Through major improvements in PGD/S and general laboratory technology, the testing for abnormalities in fetuses has shifted from prenatal diagnosis during the first 2 trimesters <ref> Blackburn, S.L. (2003) '''Maternal, Fetal & Neonatal physiology: a Clinical perspective''' (2nd ed.). Seattle: Saudners </ref>, testing for overall fetal growth, complications of pregnancy, and birth defects<ref> Sadler T.W.(2012) '''Langman's Medical Embryology''' (12th ed.) Philadelphia: Lipincott, Wiliams & Wilkins, a Wolters Kluwer Business </ref>, to an embryonic focus especially in advancements in Artificial Reproductive Technologies (ART)<ref><pubmed>20638568</pubmed></ref>. In 1990 PGD for a recessive X-linked disease resulted in the first live birth<ref><pubmed>2330030</pubmed></ref> and has since been incorporated in clinical routine and applied for a variety of genetic diseases, such as sickle cell anemia, thalassemia, or cystic fibrosis<ref name="PMID24907939"/>.<br />
[[File:Preimplantation Genetic Diagnosis Procedure.jpeg|700px|thumb|centre| Simplified steps for PGD<ref name="PMID24907939"/>]]<br />
<br />
==History==<br />
<br />
==Preimplantation Genetic Diagnosis==<br />
Preimplantation genetic diagnosis (PGD) is used to test the genetic makeup of embryos to detect single gene disorders, chromosomal abnormalities and mitochondrial disorders. It also has applications in gender selection for diseases with unequal gender distributions <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Some diseases commonly involved with PGD include cystic fibrosis, spinal muscular atrophy and beta – thalassaemia <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press.">Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press</ref> <ref name="PMID17823145"><pubmed>17823145</pubmed></ref>. It was first used in the United Kingdom in the 1980s of arenoleucodystrophy and primarily focusing on sex- linked disorders <ref name="PMID17823145"/><ref name="PMID23150080"><pubmed>23150080</pubmed></ref>. PGD is now capable of detecting single cell defects (molecular) and chromosomal disorders resulting from the inversion, translocation or deletion of chromosomes (cytogenic) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>,<ref name="PMID11325751"><pubmed>11325751</pubmed></ref>. PGD can be applied to the embryo at different stages. That is on polar bodies, blastomeres or blastocyst <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>.<br />
Depending on the type of genetic disorder, PGD utilises different methods of genetic testing. These include Fluorescence in situ hybridisation (FISH) which is used for sex – linked disorders and detects chromosomal rearrangements <ref name="PMID11325751"/><ref name="PMID17876073"><pubmed>17876073</pubmed></ref> and Embryo halotyping which allows the identification of chromosomes causing the inherited disorder through knowledge of the pattern of closely linked markers <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. Polymerase chain reaction (PCR) is also widely used to detect molecular abnormalities <ref name="PMID11325751"/>.<br />
PGD is tightly regulated and supported by large organisations namely The American Society for Reproductive Medicine, The European Society for Human Reproduction and Embryology (ESHRE), The European Society of Human Genetics and the Preimplantation Genetic Diagnosis International Society <ref name="PMID25500181><pubmed>25500181</pubmed></ref>.<br />
===Sex-linked disorders===<br />
The determination of a disease as gender specific usually correlates with the presence or absence of specific genes such as SRY on the Y chromosome. It is known that females have two X chromosomes and males have an X and a Y chromosome where abnormalities are more prevalent on the X chromosome. PGD can be used for sex selection where only male embryos are transferred to reduce the chance of inheriting X-linked disorders. However, this does not completely eradicate the problem as male embryos remain susceptible to inheriting an affected X chromosome. Sex determination is only used when the specific mutation is unknown and has yet to be discovered <ref name="PMID24866878"><pubmed>24866878</pubmed></ref>.<br />
===Single gene defects===<br />
Single gene defects can be dominant, recessive, autosomal or X-linked. They are commonly diagnosed using PCR and although the PCR available today is complex and capable of combatting a large range of disease the development of new protocols has been proven to be difficult due to the small DNA sample available <ref name="PMID26168107"><pubmed>26168107</pubmed></ref><br />
===Mitochondrial disorders===<br />
Mitochondrial disorders also known as oxidative phosphorylation disorders arise from mutations in the nuclear DNA or mitochondrial DNA <ref name="PMID26312584"><pubmed>26312584</pubmed></ref>. They pose as a problem because they are unrecognisable until the mutations in the cell reach a detrimental level <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Mitochondrial disorders cause miscarriages and stillbirths as well as death in children and young adults. The effects can either be contained in a single organ or more commonly involve multiple organ failure where organs with high energy demands such as the brain, liver muscle and heart and heavily influenced. They are usually occur spontaneously or result from inheritance from the mother. Since mitochondria are solely inherited from the mother oocyte donations have been used as a solution to combat mitochondrial disorders. Additionally, there has been an increasing use in PGD where embryos that stay under the given threshold of 18% gene-mutations are allowed to be transferred and result in normal development. New technology in the areas of nuclear gene transfer and genome editing are also being experimented with <ref name="PMID26312584"/>. <br />
===Chromosomal disorders===<br />
Chromosomal disorders can be reciprocal, Robertsonian translocations, inversions, deletions and insertions <ref name="PMID26168107"/>. . Data from ESHRE collected between 2010 and 2011 has shown that the most common chromosomal abnormality confronted in PGD are reciprocal chromosomal abnormalities <ref name"PMID26071418"><pubmed>26071418</pubmed></ref>. PGD has also been used successfully for Robertsonian translocations (RT), a type of structural translocation. Children who carry RT are phenotypically normal, however in their later years it is found that they will suffer from infertility and repeated miscarriages due to the high frequency of abnormal embryos <ref name="PMID22081077"><pubmed>22081077</pubmed></ref>. PCR and FISH are the two main techniques used for chromosomal disorders. To be able to conduct the examinations the cells are required to be at the metaphase stage <ref name="PMID26168107"/>. <br />
==Preimplantation Genetic Screening==<br />
Prenatal Genetic Screening (PGS) involves an array of methods or ideas that aim to segregate embryos that have genetic flaws and those that are healthy <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. The occurrence of aneuploidy is high around the stages of early embryonic development and they are the most common cause if miscarriages and congenital birth defects <ref name= "PMID26085841"><pubmed>26085841</pubmed></ref>. They have little effect on the morphology of the embryo making them difficult to identify thus identification heavily relies on genetic testing <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. <br />
Genetic sampling is most commonly conducted using Microarray Comparative Genomic Hybridisation (aCGH) as well as FISH, Quantitative PCR and Single Nucleotide Polymorphism (SNP) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. These methods collectively aim to assess numeral and structural chromosomal errors <ref name= "PMID26085841"/>. Studies have also introduced Next- Generation Sequencing (NGS) <ref name= "PMID26085841"/> and Whole Genome Amplification used to screen imbalances in the complete 24-chromosomes <ref name="PMID25953353"><pubmed>25953353</pubmed></ref><br />
Statistics from ESHRE have shown that the most common indications for PGS is advanced age, followed by repeated implantation failure or recurrent miscarriage and male infertility <ref name="PMID26071418"><pubmed>26071418</pubmed></ref>.<br />
====Indications====<br />
A low percentage of structural abnormalities in chromosomes are responsible for the cause of miscarriages. Despite this, they are the most prevalent type of chromosomal abnormality accounted for in PGD <ref name="PMID20638568"/>. The presence of specific gene cycles, initiation of embryonic protein synthesis and evident physiological development are all indicative of a successful in vitro fertilisation procedure <ref name="PMID11576737"><pubmed>11576737</pubmed></ref>. To eliminate further errors from occurring during the PGD procedure it is recommended to undertake further prenatal testing such as amniocentesis in the later stages <ref name="PMID20638568"/>. <br />
=====Advanced maternal age=====<br />
Data provided by the ESHRE has shown that the mean age of women undergoing PGS is 39 years <ref name="PMID26071418"/>. Women of advanced age have been shown to have a lower rate of pregnancies reaching childbirth <ref name="PMID18583331"><pubmed>18583331</pubmed></ref>. The highlighted concern revolves around the increased occurrence of aneuploidy following maternal age. The optimal age range for the lowest aneuploidy incidence was found to be between 27 to 37 years of age (6%) then progressively higher in women aged up to 42 (33%) and most common in those 44 and above (53%) <ref name="PMID24355045"><pubmed>24355045</pubmed></ref>. <br />
=====Recurrent pregnancy loss / IVF failure=====<br />
Recurrent pregnancy loss is defined as three or more IVF failures after cumulative transfer of more than 10 good-quality embryos. These are primarily caused by two main factors, reduced endometrium receptivity or embryonic defects. Endometrium receptivity can be negatively influences by instances including uterine pathologies such as thin endometrium, altered expression of adhesive molecules and immunological factors. Additionally, embryonic defects may be due to genetic abnormalities, embryonic aneuploidy or zona hardening. Endometriosis and hydrosalpinx has been known to effect both the endometrium and embryo <ref name="PMID23260857"><pubmed>23260857</pubmed></ref>.<br />
=====Human leukocyte antigen matching=====<br />
First used in 2001, HLA matching is an option given to parents to save a child with haematological or immunological disease through conceiving another child who would potentially be able to donate cord blood or haematopoietic stem cells from the bone marrow for transplantation. The process namely PGD-HLA has shown to improve haematopoietic stem cell transplant (HSCT). PGD-HLA can only be performed when HSCT is not needed urgently due to the time needed to conceive and delivery the baby <ref name="PMID25500181"><pubmed>25500181</pubmed></ref>. It is most commonly applied to children suffering from relapsed leukaemia <ref name="PMID22524201"><pubmed>22524201</pubmed></ref>. In a case study PGD-HLA was proven to successfully cure 10 diseases including Fanconi anaemia, Diamond-Blackfan anaemia and beta thalassemia <ref name="PMID25066893><pubmed>25066893</pubmed></ref>.<br />
==Biopsy Methods==<br />
Biopsy, the removal of genetic materials, from oocytes or embryos in the preimplantation stage is the primary step in PGD. For the past two decades these biopsies have been performed at three stages, the polar body, blastomere, and blastocyst, and the methodologies optimized to ensure the embryo’s viability. The most common approach involves biopsies at the cleavage stage. However, polar body and blastocyst biopsies are increasingly more often tested and applied. Approached for opening the zona pellucida involve next to the traditional mechanical and chemical means, novel approaches such as noncontact lasers. Their application may simplify and secure the procedure significantly. The most challenging question about PGD procedures remains at what stage biopsies should be taken. Much controversy has developed around this topic, highlighting the varying disadvantages and advantages of temporal biopsies. <ref name="PMID22723007"><pubmed>22723007</pubmed></ref><br />
<br />
{| class="wikitable"<br />
|- align="center" bgcolor="DDCEF2"<br />
|<br />
| Time of Biopsy<br />
| Advantages <br />
| Disadvantages<br />
|- bgcolor="FFFAFA"<br />
| Polar Body<br />
| Day 1<br />
| No harm to oocyte<br />
| Only maternal DNA is tested, often needs to be coupled with other biopsies<br />
|- bgcolor="FFFAFA"<br />
| Blastomere<br />
| Day 3<br />
| …<br />
| … <br />
|- bgcolor="FFFAFA"<br />
| Trophectoderm<br />
| Day 5 and 6 <br />
| Little harm, large amount of genetic material<br />
| Opening of blastocyst necessary, small time window for procedure<br />
|}<br />
<br />
<br />
[[File:Polar_Body,_Blastomere,_and_Trophectoderm_Biopsy.jpeg|thumb|Polar body (A), blastomere (B) and trophectoderm (C) biopsies<ref name="PMID25625041"><pubmed>25625041</pubmed></ref>.]]<br />
<br />
<br />
<br />
PMID 24305177<br />
===Polar Body Analysis===<br />
Day 1<br />
====Description====<br />
Polar body (PB) biopsy, which was introduced in 1990, offers a promising alternative to biopsies performed at the blastomere stage for PGD/S indications on legal and practical grounds. <br />
Description: Consequent embryo development does not necessitate the presence of the first and second PB and their removal may not be crucial. PB biopsy requires precise timing. Keeping track of the meiotic cell cycle is necessary to perform a successful biopsy and, therefore, PB biopsy usually is applied in combination with intracytoplasmic sperm injection (ICSI). During the maturation from the germinal vesicle stage to the metaphase-II stage the first PB is formed. A cytoplasmic bridge containing spindle remnants, that are still in contact with the cellular genetic material, links this PB to the oolemma for about 90 minutes after extrusion. It is possible to visualize these remnants by polarization microscopy and it is crucial to not perform the biopsy until the first PB is no longer firmly attached to the oolemma as this indicates an immature embryo.The oocyte tolerates mechanical zona dissection best during hours four until six after ICSI as the oolemma has stabilized by that time because of the cortical granule reaction. Over time the first PB degenerates stressing a temporal biopsy and its optimal extraction time window is four to 12 hours after ICSI. The second PB forms around two to four hours after ICSI. However, its optimal time window for biopsy is set to be eight to 16 hours after ICSI. This is due to the second PB being attached to the oolemma with spindle remnants until six hours after ICSI. Biopsy at this point may cause enucleation of the oocyte. In addition, studies have shown that the amplification efficiency of second PB’s DNA is worse if the PB is extracted prior to eight hours after ICSI. <br />
Thus, it is possible to perform sequential and simultaneous biopsies for the first and second PB. If performed, sequentially the first PB may be removed four to 12 hours and the second PB eight to 16 hours after ICSI. The optimal time window for a biopsy for both the first and second PB simultaneously is eight to 12 hours after ICSI. It is highly preferred to analyze both PBs due to potential aneuploidies in either PB and crossing overs during meiosis<ref name="PMID22723007"/>. <br />
====Procedure====<br />
Chemical opening achieved with for example acidic tyrode’s solution of the zona pellucida is not tolerated by the oocyte and may have detrimental effects on the embryo’s development. Therefore, the access to the perivitelline space of the oocyte is provided by mechanical zona dissection or by laser. Both techniques work well if performed by experienced embryologist. However, laser-assisted biopsy is less time consuming when compared to manual dissection. It is critical to consider the size of the introduced opening as it will remain permanent. If it is too large the blastomere may be lost during embryo development and if it is too small it may interfere with hatching of the embryo during blastocyst stage<ref name="PMID22723007"/><br />
<br />
[[File:Polar_Body_Biopsy.jpeg|thumb|The presence of a faint but clearly identifiable strand connecting PB2 to the <br />
oolemma. The biopsy was performed ∼9 h after ICSI<ref name="PMID21908464"><pubmed>21908464</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JTaQzszVr8o</html5media><br />
|-<br />
| Laser-assisted polar body biopsy<ref>RIUK, R. (2013, June 25) Polar Body Biopsy [Video file]. Retrieved from https://www.youtube.com/watch?v=JTaQzszVr8o</ref><br />
|}<br />
<br />
====Advantages & Disadvantages====<br />
PB biopsies can only investigate the maternal contributions to the embryo as they are of maternal origin. Thus, this procedure is appropriate for PGD solely for monogenetic diseases from the maternal side. Recessive diseases may be evaluated with PB biopsies on the basis that the embryo’s outcome will be determined by the paternal contribution. (...) It may still be applied for PGS as most aneuploidies either arise during meiosis or origin from the maternal genome. However, diagnosis error has been reported due to the lack of considering paternal contributions. <br />
Because PB biopsies are performed very early it is not yet known whether the oocyte will develop into a viable embryo. Thus, PBs are commonly frozen or fixed after biopsy and depending on the state of the embryo only chosen PBs will be tested. This is primarily an economic issue as many genetic testing procedures are very cost-intensive<ref name="PMID22723007"/>.<br />
<br />
[[File:Implantation_predictive_value_of_euploid_screening_results.jpeg|thumb|The sustained implantation predictive value (with 95 % confidence interval) of a euploid screening result obtained from the first polar body (PB1), PB1 and the second polar body (PB2), or a direct embryo biopsy for each stage of embryo transfer (cleavage-stage and blastocyst stage)<ref name="PMID25106935"><pubmed>25106935</pubmed></ref>.]]<br />
<br />
===Blastomere biopsy===<br />
Day 3 <br />
====Description====<br />
Blastomere biopsy has been the prevalent method for PGD and PGS in the last two decades. At least one, but up to two, blastomeres are biopsied on day three of the cleavage stage embryo. The right number of blastomeres removed is a controversial topic as two cells allow for more genetic material and more accurate results. However, removing two cells might be too invasive and damaging to the embryo. (Study)<ref name="PMID21748341"><pubmed>21748341</pubmed></ref><br />
====Procedure====<br />
Initially a hole was drilled into the zona pellucida using acid tyrodes and the blastomeres are removed via aspiration with a pipette<ref name="PMID21748341"/>.<br />
<br />
<br />
[[File:Aspiration_of_a_Blastomere.jpeg|thumb|Aspiration of a Blastomere into the biopsy pipette<ref name=" PMID24783200"><pubmed>24783200</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=TbridWVwipI</html5media><br />
|-<br />
| Laser-assisted blastomere biopsy<ref>Sukprasert, M. (2014, March 5) Day 3 Blastomere Biopsy 1 [Video file]. Retrieved from https://www.youtube.com/watch?v=TbridWVwipI</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
===Trophectoderm biopsy===<br />
Day 5 and 6<br />
====Description====<br />
The improvement of embryo culture media allowed the in vitro development of human embryos until the blastocyst stage and opened up the possibility to take blastocyst biopsies. During day three to day five the haploid maternal and paternal genomes work together for the first time to form the genome of the embryo. The maternal epigenetic control lessens significantly while preparing for implantation with precisely arranged events happening. The first event includes a rapid increase in the number of embryonic cells which are active in mitotic divisions and apoptosis of aberrant cells. This is followed by the formation of blastocoel (cavitation) which results from the flattening of cell located on the outside of the blastomere. Now the blastocyst will expand until the embryo hatches by rupturing the zona pellucida. The cells of the blastocyst will differentiate to form two distinct cell lineages, the outer trophectoderm and the inner cell mass<ref name="PMID22723007"/>.<br />
====Procedure====<br />
Trophectoderm biopsy is usually performed in Hepes buffered biopsy medium and opening approaches include needle cutting which has been replaced by lasers in past years. Different research groups report different timings of the opening to be the most successful. Some open the blastocyst on day three or four by creating a 25 µm which causes the trophectoderm to herniate through this hole and is, thus, accessible for biopsy. Others create this hole about four hours before biopsy which allows sufficient herniation of trophectoderm cells. It is also possible to open the blastocyst immediately before biopsy. This avoids an extra step and the inner cell mass usually is easy to locate. Blastocyst biopsies involve the removal of trophectoderm cells and the ideal time for the procedure is day five. Successful biopsies on day six have been performed, while little is known about the results of biopsies on day seven. However, since the window of implantation in humans is from day eight to ten after ovulation, day seven biopsies appear to be possible<ref name="PMID22723007"/>.<br />
-collapse of trophoblasts<br />
-possible: biopsy of hatched blastocyst, holding pipette careful mild suction force to hold embryo near ICM <br />
-Cryopreservation<br />
<br />
<br />
[[File:Microscopic images of human blastocysts for biopsy.jpeg|thumb|(A) Some trophectoderm cells in a blastocyst started to hatch and (B) the trophectoderm cells were biopsied with assisted laser cutting. Images in C–D show the blastocysts after vitrification and warming. Blastocysts had been cultured for 2–4 hrs after warming, showing good (ICM and trophectoderm cells) hatched (C) and hatching (D) blastocysts. The hatching blastocyst in (E) has good ICM but fair trophectoderm while the blastocyst in (F) has both fair ICM and trophectoderm. Arrows indicate ICMs and arrow heads indicate trophectoderm cells. Bar = 40 µm<ref name="PMID2190846"><pubmed>2190846</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JI_TQ8d8tNM</html5media><br />
|-<br />
| Laser-assisted blastocyst biopsy (at 00:50 min)<ref>Coco, R. (2014, April 30) Trophectoderm biopsy in a Hatching blastocyst protruding ICM [Video file]. Retrieved from https://www.youtube.com/watch?v=JI_TQ8d8tNM</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
Blastocyst biopsies are believed to be less damaging to the embryo and appear to be unrelated to implantation rates. In addition, this biopsy method allows for a larger extraction of cells for genetic testing. However, since they are performed late in in vitro development, the time window for genetic testing is relatively small. Fast and accurate genetic testing methods are needed to ensure a successful and safe result from this biopsy. Thus, blastocyst biopsies may gain more popularity in the future whn such methods have been developed or improved<ref name="PMID22723007"/>. <br />
<br />
<br />
==Genetic Techniques==<br />
<br />
===PCR===<br />
====Description====<br />
Polymerase chain reaction (PCR) amplifies DNA specific to genetic sequence of interest . PCR was developed by Kay Mullis in the 1980s, for which he was awarded the Nobel prize for chemistry in 1993. <ref> Pubmed Docs (2015) Polymerase Chain Reaction (PCR) Pubmen. Retrieved from [http://www.ncbi.nlm.nih.gov/probe/docs/techpcr/]</ref> This technique enables clinicians to monitor and diagnose diseases using minute samples such as embryonic cells, blood & tissue. <ref>Roche (2015) PCR: How We Copy DNA. Roche Molecular Systems Inc. retrieved From [http://molecular.roche.com/pcr/Pages/Process.aspx]</ref> PCR has many important applications like DNA fingerprinting, genetic mapping, detection of viruses and bacteria as well as being used to detect genetic disorders, as a part of PGD, in conjunction with IVF. It is used to detect molecular abnormalities such as single gene disorders like Tay Sach, Cycstic fibrosis, Duchenne Muscular Dystrophy, Thalassemia, Huntington disease, Spinal muscular atrophy and many more. Molecular and Genetic analysis require a significant amount of DNA, which we would not have without PCR. It revolutionized the study of DNA, replacing all previous recombinant DNA technology. <ref> Mullins, K., Francois, F.& Gibbs R.A. (1994 ) The Polymerase Chain Reaction. p3. Springer- Science +Business Media. Birkhauser, Boston<br />
Available at [https://books.google.com.au/books?hl=en&lr=&id=gjrTBwAAQBAJ&oi=fnd&pg=PR5&dq=kary+mullis+PCR&ots=mpzAyRh5ZY&sig=PQ4goNoKJ90tb3-MkPk62zrTGbw#v=onepage&q=kary%20mullis%20PCR&f=false] </ref> <br />
<br />
[[File:PCR.jpg|thumb|right|Polymerase chain reaction (PCR) amplifies DNA specific to genetic sequence of interest, enabling the monitoring and diagnose molecular abnormalities such as single gene disorders using minute samples such as embryonic cells, blood & tissue <ref>NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref>]]<br />
<br />
====Procedure====<br />
<br />
Sample are obtained from the the blastocyst, a polar body biopsy or the blastomeres stages of the embryo. <br />
Stage 1 Denaturing: separating the target strands of DNA <br />
The obtained sample is heated to roughly 90 degrees celcius, this heat causes breaks the relatively weak bonds between nucleotides that form DNA. the double stranded DNA to split into 2 single strands of DNA that are used as templates.<br />
Stage 2 Annealing: Binding the Primers to the target DNA sequence <br />
PCR will only copy the target sequence of DNA specified by specific PCR primer. These synthesized primers Oligonucleotides are small artificial pieces of DNA. <br />
TAQ polymerase enzyme synthesize 2 new strands of DNA duplicate to the single sample DNA stand template indicated by these primers. During this stage the reaction is cooled to a temperature between 40-60 degrees Celsius. <br />
Stage 3- Extension- making copies <br />
Each of these 2 copies are then used again as templates generating 2 further replications This cycle can occur as many 30 -40 times within a couple hours leading to billions of extra copies of the original DNA segment. The optimal temperature for the further replication is roughly 72 degrees Celsius. <br />
<br />
This process mediated by a thermocycler machine that is programmed to alter the temperature of the reaction every couple of minutes, perpetuating the cycle of DNA denaturing and synthesis. <br />
This process, generates exponential exact copy of the original template DNA sequence. <br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
!PCR cycles<br />
<br />
|{|<br />
|-<br />
| '''PCR Cycle'''<br />
| '''Target Copies'''<br />
|-<br />
| 1<br />
| 2<br />
|-<br />
| 2<br />
| 4<br />
|-<br />
| 3<br />
| 8<br />
|-<br />
| 4<br />
| 16<br />
|-"<br />
| 5 <br />
| 32<br />
|-<br />
| 6 <br />
| 64<br />
|-<br />
| 7 <br />
| 128<br />
|-<br />
| 8<br />
| 256<br />
|- <br />
| 9<br />
| 512 <br />
|-<br />
| 10<br />
| 1024<br />
|-<br />
| 15<br />
| 32,768<br />
|-<br />
| 20 <br />
| 1,048,578<br />
|-<br />
| 25<br />
| 33,554,432<br />
|-<br />
| 30 <br />
| 1,073,741,842<br />
|-<br />
|}<br />
<br />
<br />
<br />
{| class="wikitable" <br />
|-bgcolor="#9ACD32" <br />
| rowspan="10" |'''Advantages'''<br />
|-bgcolor="#F0FFF0"<br />
| fast and inexpensive way of copying a target sequence of DNA<br />
|-bgcolor="#F0FFF0"<br />
| aids the diagnosis of single cell defects<br />
|-bgcolor="#F0FFF0"<br />
| rapid generation of results within a couple hours<br />
|-bgcolor="#F0FFF0"<br />
| can start from a single molecule of DNA, therefore is more sensitive <br />
|-bgcolor="#F0FFF0"<br />
| has a flexible primer design enabling<br />
|-bgcolor="#F0FFF0"<br />
| overcame previous issues associated with the limited availability of sites of end<br />
|-bgcolor="#F0FFF0"<br />
| generates the DNA copies exponentially<br />
|-bgcolor="#F0FFF0"<br />
| enables DNA amplification required for molecular and genetic analysis<br />
|-bgcolor="#F0FFF0"<br />
|Valid diagnostic method in selecting unaffected embryos for embryo transfer <ref> Dreesen, J., Drusedaul, M., Smeets, H., Die-Smulders, C., Coonen, E., Dumoulin, J., Gielen, M., Evers, J., Herbergers, J. & Geradets, J. (2008) Validation of preimplantation genetic diagnosis by PCR analysis: genotype comparison of the blastomere and corresponding embryo, implications for clinical practice. Mol. Hum. Reprod. 14 (10):573-579.doi: 10.1093/molehr/gan052. Retrieved from [http://molehr.oxfordjournals.org/content/14/10/573.short] </ref> <ref><pubmed>20966460</pubmed></ref><br />
|-bgcolor="#9ACD32"<br />
| rowspan="5"|'''Disadvantages'''<br />
|-bgcolor="#F0FFF0"<br />
| only during this exponential DNA replication phase can we determine the starting quantity sequence contained in the original sample ( template DNA strand)<br />
|-bgcolor="#F0FFF0"<br />
| PCR reaction is limited by the presence of inhibitors present in the sample : reagent inhibitors <br />
|-bgcolor="#F0FFF0"<br />
| self annealing due to the accumulation of the product -stopping exponential amplification for the target sequence and reach a plateau<br />
quantification of the end point of reaction of PCR products unreliable - therefore that is why we require real time quantitative RT-PCR necessary<br />
<ref> NIS (2015) Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref><br />
|}<br />
<br />
<br />
===Fluorescent In Situ Hybridisation (FISH)===<br />
<br />
<br />
====Description====<br />
Fluorescence in situ hybridization (FISH) the one of the most effective and rapid <ref name="PMID26338801"><pubmed>26338801</pubmed></ref> Preimplantation Genetic Diagnosis (PGD). This techniques used to locate a specific DNA sequences within a chromosome. FISH facilitates the clinical diagnosis of chromosomal abnormalities indicated by sequential duplications, deletions and rearrangements of chromosome, that are usually missed with microscopic analysis. This technique is especially relevant for female embryos with X-linked diseases,<ref name="PMID20809319"><pubmed>20809319</pubmed></ref> that have no other mutation specific tests [http://www.ncbi.nlm.nih.gov/pubmed/20809319] As part of PGD, samples are collected from various stages of the embyro,and they are able to conducted tests on the blastocyst, a polar body biopsy and the blastomeres <ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. FISH is 99% effective when used in conjunction with competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities<ref name="PMID26338801"/>.<br />
<br />
====Procedure==== <br />
<br />
Samples are collected from either the blastocyst, a polar body biopsy or the blastomeres stages of the embryo <ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
DNA strands are heated and denatured causing their the individual DNA strands to break apart<br />
Probes are single complimentary stands of DNA a that have been tagged with small chemical agents that glow brightly in the presence of a specific region on a chromosome. These specific probes then hybridize and join to their complementary DNA strand. <br />
The fluorescent tags enable the researchers to correctly identify the presence or lack thereof and location of the specific chromosomes that they are testing for. <ref name="PMID17876073"><pubmed>17876073</pubmed></ref><br />
Researcher analyse the results by identifying the number and the relative location of the fluorescent dots generated by the FISH images.<ref name="PMID17970921"><pubmed>17970921</pubmed></ref><br />
The probe will not fully hybridise if there has been a duplication or a deletion of the DNA - indicating chromosomal and sex chromosomal anomalies like trisomies and aneuploidies. <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref><br />
<br />
<br />
Different probes are used for different purposes: <ref>Unique, Rare Chromosome Disorder Support Group (2013) Fluorescence in situ hybridisation (FISH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/Other/FISH%20FTNW.pdf]</ref><br />
*'''Locus specific tags''' detect very small imbalances, and locate isolated small portions <br />
of genes within a chromosome<br />
*'''Alphoid/Centomeric Repeat probes''' are developed from the repetitive sequence located in the middle region of each chromosome, useful in determining the number of chromosomes , detecting rearrangement and when used in conjunction with locus probes to determine the absence of genetic material on a chromosome. <br />
*'''Paint Probes''' are collections of smaller probes with their own stains that bind to a different section on the chromosome - allowing the full chromosome too be labeled a unique colour, this "full colour map" can be used to know the spectral karyotype- full chromosomal mapping is useful in examining chromosomal abnormalities. <br />
<br />
[[File:Fluorescent In Situ Hybridisation (FISH).jpg|thumb|right|'''FISH''' We are able to tag Specific DNA sequences using Probes which have been tagged with fluorescent Labels.This technique enables the clinical diagnosis of chromosomal abnormalities, indicated by sequential duplication, deletions and rearrangements of chromosome <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref>]]<br />
<br />
{|class="wikitable" align="center"<br />
|-bgcolor="pink" <br />
| rowspan="8" |'''Advantages''' <br />
|-bgcolor="#FDE1F2" <br />
| FISH is 99% effective when used in conjunction with Competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities.<ref><pubmed>26338801</pubmed></ref><br />
|-bgcolor="#FDE1F2" <br />
| Rapid generation of results<br />
|-bgcolor="#FDE1F2" <br />
| Identifies very small translocations and aneuploidies that occur within chromosomes, that would usually be missed under microscopic analysis<br />
|-bgcolor="#FDE1F2" <br />
| Indicates whether the accessed chromosomes are normal <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|-bgcolor="#FDE1F2" <br />
| Tests for the most common chromosomal abnormalities - down syndrome chromosomes 13,16,18,21 and 22 <ref><pubmed>21749752</pubmed></ref><br />
|-bgcolor="#FDE1F2" <br />
| It may be used to compare the chromosomal gene arrangements in related species<br />
|-bgcolor="#FDE1F2" <br />
| can be used to identify and remove inheritable X-linked disease or sex chromasome anomalies such as Duchennes Muscular Dystrophy, hemophilia, ectodermal dysplasia <ref><pubmed>17876073</pubmed></ref><br />
|-bgcolor="#FEB745"<br />
| rowspan="5"|'''Disadvantages'''<br />
|-bgcolor="#FE1C5EA"<br />
| FISH destroys all cells tested <ref> O'Connor, C. (2008) Fluorescence in situ hybridization (FISH). Nature Education 1(1):171. retrieved from [http://www.nature.com/scitable/topicpage/fluorescence-in-situ-hybridization-fish-327] </ref><br />
|-bgcolor="#FE1C5EA"<br />
| It does not fully access all chromosomes (only ~ 12)<br />
|-bgcolor="#FE1C5EA"<br />
| Analysis of results is dependent upon the dot quality impacted by hybridisation efficiency or the camera sensitivity <ref><pubmed>17970921</pubmed></ref><br />
|-bgcolor="#FE1C5EA"<br />
| some studies indicate that using FISH on a day-3 embryo biopsy decreases the rate of live births <ref><pubmed>26168107</pubmed></ref><br />
|}<br />
<br />
===Array Comparative Genomic Hybridisation (aCGH)===<br />
====Description====<br />
<br />
aCGH also known as Microarray analysis efficiently scans the entire genome for chromosomal imbalances. CGH was initially developed to detect the number of changes in a solid tumor mass. It uses 2 genomes comparing the sample to the control, with each labeled in a different fluorescent dye<ref name="PMID1876176"><pubmed>1876176</pubmed></ref>. Earlier CGH techniques were limited by the resolution of the imaging <ref> Lichter, P., et al. Comparative genomic hybridization: Uses and limitations. Seminars in Hematology 37, 348–357 (2000)</ref> , these initial limitations were overcome by using Microarrays in conjunction with CGh to improve the resolution of the imaging, Array Comparative Genomic Hybridisation (aCGH). This method compares sample and control microarrayed slides containing small segments of DNA (probes). <ref> Lucito, R., et al. Representational oligonucleotide microarray analysis: A high-resolution method to detect genome copy number variation. Genome Research 13, 2291–2305 (2003) </ref> the Probes used will vary according from the small (25-85 base pairs) oligonucleotides manufactured to highlight different target sequences, to the very large genomic clones (80,000- 200,00 base pairs), and as these are significantly smaller than the traditional metaphase chromosomes used for CGH, generating a higher resolution of image. <ref name="PMID22467166"><pubmed>22467166</pubmed></ref>.aCGH is used as a diagnostic tool for prenatal detection f chromosomal abnormalities <ref name="PMID19012303"><pubmed>19012303</pubmed></ref>.<br />
<br />
<br />
====Procedure====<br />
<ref> Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432] </ref><br />
The sample is obtained (skin, blood or fetal cells) and DNA is obtained. <br />
As a part of PGD fetal cell samples are collected from; the fertilized egg polar bodies, the blastomere (day 3 embryo) or the blastocyst/tropoectoderm stage (day 5 embryo).<br />
Sample DNA is labeled with one fluorescent dye, and the control DNA is labeled with a different colored fluorescent dye. the control DNA is used as the base point of reference. <br />
heated and denatured single DNA strands then hybridize to their complementary single strand probes, which are then combined and applied to a microarray and the results are run through a computer program and a digital imaging system is used to quantify the results( fluorescent intensities of the labeled probes). <br />
<br />
[[File:aCGH.jpg|thumb|right|'''aCGH''' checks the entire genome for chromosomal imbalances, by comparing control and a sample slides contatining small segements of DNA sample microarrayed slides small segments of DNA. Illustrated by student z5020317 and adapted from <ref> NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation. retrieved from [http://www.phgfoundation.org/file/5237/]</ref> <ref>Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432]</ref>]]<br />
<br />
<br />
<br />
The fluorescent ratio and the hybridization signal at different locations on the genome of the control DNA are used to identify any variances present in the sample DNA. aCGH facilitates the clinical diagnosis of submicroscopic chromosomal duplication, deletion and rearrangements indicative of chromosomal disorders such as trisomies 1-22and specific sex linked disorders. <br />
Duplications in the DNA are displayed by the computer program as spikes/ peaks over an established threshold and deletions in DNA are displayed by the computer program as spikes/ toughs beneath this threshold <br />
<br />
<br />
<br />
<br />
{|border="1" align="center"<br />
|-bgcolor="pink" <br />
| '''Advantages''' <br />
| '''Disadvantages'''<br />
|-<br />
| multiple applications: prenatal genetic diagnosis, cancer diagnosis, <ref name="PMID20193845"><pubmed>20193845</pubmed></ref> genetic screening for developmental delay (learning disabilities) <ref name="PMID17309648"><pubmed>17309648</pubmed></ref>. or congenital anomalies that are suspected to be genetic in origin <ref>NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation . retrieved from [http://www.phgfoundation.org/file/5237/]</ref><br />
| translocations and inversions of DNA are not detected<br />
|-bgcolor="pink"<br />
| trace represents all chromosomes present in the human genome chromosomes 1-22 and the X & Y chromosomes, and therefore is the most accurate method for testing whole embryo aneuploidy<br />
| limited ability diagnosing specific polyploidies such as triploidy <ref> Unique, Rare Chromosome Disorder Support Group (2013) Microarray-based Comparative Genomic Hybridiation (array CGH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/other/array%20cgh%20ftnw.pdf] </ref><br />
|-<br />
| aCGH has been extensively tested, and Validated, and is now used world wide.<br />
| will not detect mosaicism detection <20% (cultures where >1 of 5 cells are trisomy 12)<br />
|-bgcolor="pink"<br />
| detects deletions and additions and rearrangements as well as amplification, of the WHOLE genome, simultaneously.<br />
| will not detect balanced chromosomal rearrangement<br />
|-<br />
| detects submicroscopic alterations<br />
| will not detect duplications or deletions <80kb<br />
|-bgcolor="pink"<br />
| used as a diagnostic tool for prenatal detection of chromosomal abnormalities <ref name="PMID22034057"><pubmed>22034057</pubmed></ref><br />
| will not detect point mutations within genes <ref>Washington department of education (CGH- FAQ for physicians. Signature Genomic LAboratories, LLC. Retrieved from [https://depts.washington.edu/dbpeds/Lab%20Tests/SignatureCGH-physician_FAQ.pdf]</ref><br />
|-<br />
| provides high resolution genomewide screening of segmental genomic copy number variations<br />
| will not detect chromosomal position of genomic gains<br />
|-bgcolor="pink"<br />
| very accurate when used in conjunction with FISH<br />
| will not detect loos of heterozygosity (LOH) or Absence of heterozygosity (AOH) <ref>WiCell Research Institute Inc. (2012) Comparative Genomic Hybridization Microarray. <br />
retrieved from [http://www.wicell.org/home/cytogenetic-services/cgh-microarray/array-comparative-genomic-hybridization-acgh.cmsx]</ref><br />
|-<br />
|Alone is more reliable and in detecting chromosomal abnormalities, with a higher implantation success rate, than FISH <ref name="PMID20494259"><pubmed>20494259</pubmed></ref><br />
|<br />
|-bgcolor="pink"<br />
|Allows an in depth research focus upon specific types of rearrangements within selected chromosomal regions, a recent particular area of interest is subtelomeric and pericentromeric rearrangements<br />
|<br />
|-<br />
|reduces the risk of failed implantation and miscarriage, improving the chance of a healthy baby <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|<br />
|}<br />
<br />
<br />
<br />
===Next Generation Sequencing===<br />
====Description====<br />
The development and advances within ART in the past 20 years, as well as the increasing popularity of IV, has lead to an influx of new technologies developed to screen embryos for chromosomal anomalies, which are covered by the umbrella term of Next generation Sequencing (NGS). NGS is a general term used to describe all of the new and emerging screening techniques currently being introduced and used as part of PGD for IVF . NGS screens for single gene disorders as well as conducting extensive and very comprehensive chromosome diagnosis by sequencing, counting, and accurately assembling millions of DNA reads, simultaneously. <ref name="PMID23499002"><pubmed>23499002</pubmed></ref> There is a movement for NGS to replace the other limited testing techniques and be used as the standard. <br />
====Procedure====<br />
Samples are collected from either blastomere or the blastocyst/tropoectoderm and processed for analysis by a computer system. <br />
The methodology of each process is unique to the technique being used. <br />
<br />
<br />
<br />
{|border="1" align="center"<br />
|-bgcolor="pink" <br />
| '''Advantages'''<br />
| '''Disadvantages'''<br />
|-bgcolor="white"<br />
| cheaper<br />
| there are limited information available to clinical applications of NGS <ref><pubmed>26100406</pubmed></ref><br />
|-bgcolor="pink"<br />
| opens new diagnostic possibilities<br />
|<br />
|-bgcolor="white"<br />
| accurately tests all 24 chromosomes<br />
| <br />
|-bgcolor="pink"<br />
| tests for the presence of monogenic diseases of known genetic background<br />
| <br />
|-bgcolor="white"<br />
| reduces the number of biopsies required for diagnosis<br />
| <br />
|-bgcolor="pink"<br />
| higher detection rate of small translocations<br />
| <br />
|-bgcolor="white"<br />
| highly accurate is testing for compound point mutations, chromosomal duplication, deletions and insertions <ref name="23312231"><pubmed>23312231</pubmed></ref><br />
| <br />
|-bgcolor="pink"<br />
| it accurately detects chromosomal aneuploidy and unbalanced rearrangement <ref name="PMID25685330"><pubmed>25685330</pubmed></ref><br />
| <br />
|-bgcolor="white"<br />
| NGS single gene disorder screenings can conducted in conjunction with PCR comprehensive chromosomal screening<br />
|<br />
|-bgcolor="pink"<br />
| Reduces human error <br />
|<br />
|-bgcolor="white"<br />
| better detects the presence of mosaicism<br />
|<br />
|-bgcolor="pink"<br />
| work well in conjunction with CGH and aCGH as part of PGD, improving the chances of IVF. <ref> Morris, R. S. (2015 ) Next generation sequencing for PCG|PGS|CCS. IVF1 retrieved from [http://www.ivf1.com/next-generation-sequencing for-pgd] </ref><br />
|<br />
|}<br />
<br />
<br />
<br />
<br />
<br />
<br />
==Diagnosis==<br />
There are a large amount of diseases that PGD can apply to, below are descriptions of the diseases that PGD are more commonly used for. Utilization of Diseased Cell Lines<br />
===Cystic Fibrosis===<br />
Cystic fibrosis is a single gene disorder. It is autosomal recessive and involves mutations in the cystic fibrosis transmembrane conductance regulator (CTFR) gene. The CTFR gene is normally responsible for the decrease in chloride and the transport of bicarbonate in epithelial cells thus playing a major physiological role. In PGD procedures, identification of the gene is assisted by microsatellite markers that have similar composition to the CTFR gene itself. Biopsy of two cells at the blastocyst stage is recommended if markers are not available. There are many variations of cystic fibrosis the most common being P.Phe508del <ref name="PMID26014425"><pubmed>26014425</pubmed></ref>.<br />
===Duchenne Muscular Dystrophy ===<br />
Duchenne Muscular Dystrophy is an X-linked recessive disease. It involves the Xp21 gene where majority of the mutations are chromosomal deletions with a smaller percentage resulting from duplications <ref name="PMID18359022"><pubmed>18359022</pubmed></ref>.<br />
===β – Thalassemia=== <br />
β – Thalassemia is known as the most common type of autosomal recessive inherited disorder among haemoglobinopathies. It involves the adult β-globin gene and is associated with the absent or decreased expression of the gene. This is commonly caused by a single nucleotide change in the gene. PGD has been used successfully worldwide to identify the β-globin gene where its application is usually performed on a single blastomere or polar body <ref name="PMID19064120">19064120</pubmed></ref>.<br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
! Applicable diseases for PGD <ref>Genoma Group (2014). Retrieved September 18th, 2015, from http://www.preimplantationgeneticdiagnosis.it/genetic-diseases-diagnosed-by-pgd.htm </ref>, <ref>Genesis Genetics (2015). Retrieved September 18th, 2015, from http://genesisgenetics.org/pgd/what-we-test-for/</ref>, <ref>Human Fertilisation & Embryology Authority (2015). Retrieved Septembr 18th, 2015, from http://guide.hfea.gov.uk/pgd/</ref><br />
|-<br />
| '''Disease'''<br />
| '''Involved Genes'''<br />
|-<br />
| 5 Alpha Reductase Deficiency (5ARD)<br />
| SRD5A2 <br />
|-<br />
| Achondroplasia<br />
|FGFR3 <br />
|-<br />
| Acute Intermittent Porphyria <br />
| ALAD, ALAS2, CPOX, FECH, HMBS, PPOX, UROD, or UROS<br />
|-<br />
| Adrenoleukodystrophy (Adrenomyeloneuropathy)<br />
| ABCD1 <br />
|-<br />
| Agammaglobulinaemia (x-linked) <br />
|BTK <br />
|-<br />
| Agammaglobulinemia Bruton Tyrosine Kinase (BTK) <br />
|BTK <br />
|-<br />
| Aicardi Goutieres Syndrome 1 (AGS1) <br />
|TREX1, RNASEH2A, RNASEH2B, RNASEH2C, SAMHD1<br />
|-<br />
| Alagille Syndrome<br />
|JAG1 or NOTCH2<br />
|- <br />
| Alpers-Huttenlocher Syndrome <br />
|POLG <br />
|-<br />
| Alpha-1-antitrypsin deficiency <br />
|SERPINA1 <br />
|-<br />
| Alpha-Mannosidosis<br />
| MAN2B1 <br />
|-<br />
| Alpha Thalassemia <br />
|HBA1 or HBA2 <br />
|-<br />
| Alports Syndrome<br />
|COL4A3, COL4A4, COL4A5<br />
|-<br />
| Alzheimer's Disease - early onset (Type 3 and 4) <br />
|APP, PSEN1, or PSEN2<br />
|-<br />
| Amyotrophic Lateral Sclerosis 1 (ALS1) <br />
|C9orf72, SOD1, TARDBP, FUS, ANG, ALS2, SETX, VAPB <br />
|-<br />
| Argininosuccinic Aciduria <br />
| ASL<br />
|-<br />
| Arrhythmogenic Right Ventricular Cardiomyopathy/ Dysplasia (ARVC/D)<br />
| DSG2; DSP; PKP2<br />
|-<br />
| Ataxia Telangiectasia<br />
| ATM<br />
|-<br />
| Bardet-Biedl Syndrome (BBS)<br />
| BBS1; BBS10<br />
|-<br />
| Barth Syndrome<br />
| TAZ<br />
|-<br />
| Beta Thalassaemia<br />
| HBB<br />
|-<br />
| Birt-Hogg-Dubé Syndrome<br />
| FLCN<br />
|-<br />
| Breast Ovarian Cancer Familial Susceptibility (BRCA2)<br />
| BRCA1; BRCA2<br />
|-<br />
| Canavan Disease <br />
| ASPA<br />
|-<br />
| Carnitine-Acylcarnitine Translocase Deficiency <br />
| SLC25A20<br />
|-<br />
| Cerebral Arteriopathy with Subcortical Infarcts & Leukoencephalopathy (CADASIL)<br />
| NOTCH3<br />
|-<br />
| Cerebral Cavernous Malformation<br />
| CCM1<br />
|-<br />
| Charcot-Marie-Tooth Disease<br />
| GJB1; MPZ; NEFL; PMP22<br />
|-<br />
| CHARGE Syndrome<br />
| CHD7<br />
|-<br />
| Cherubism<br />
| SH3BP2<br />
|-<br />
| Choroideremia<br />
| CHM<br />
|-<br />
| Chronic Granulomatous Disease<br />
| CYBB; NCF1<br />
|-<br />
| Ciliary Dyskinesia<br />
| DNAH5<br />
|-<br />
| Citrullinemia<br />
| ASS1<br />
|-<br />
| Cleidocranial Dysplasia<br />
| RUNX2<br />
|-<br />
| Cockayne Syndrome<br />
| ERCC6<br />
|-<br />
| Congenital Adrenal Hyperplasia<br />
| CYP21A2<br />
|-<br />
| Congenital Cataracts<br />
| GJA8; VSX2<br />
|-<br />
| Congenital Diarrhea, Syndromic<br />
| SPINT2<br />
|-<br />
| Congenital Disorders of Glycosylation (CDG)<br />
| ALG1; ALG6; CDG1C; DOLK; PMM2<br />
|-<br />
| Cornelia de Lange Syndrome <br />
| NIPBL<br />
|-<br />
| Craniosynostosis<br />
| TWIST1<br />
|-<br />
| Crouzon Syndrome<br />
| FGFR2<br />
|-<br />
| Cysteinyl Leukotriene Receptor 1 Deficiency <br />
| CYSLTR1<br />
|-<br />
| Cystic Fibrosis<br />
| CFTR<br />
|-<br />
| Diamond –Blackfan Anemia <br />
| RPS19<br />
|-<br />
| Duchenne Muscular Dystrophy <br />
| DMD<br />
|-<br />
| Dyskeratosis congenita (Male embryos only)<br />
| DKC1<br />
|-<br />
| Ectodermal dysplasia (Hypohidrotic)<br />
| EDA; EDA1; GJB6; IKBKG<br />
|-<br />
| Familial Adenomatous polyposis coli (FAP)<br />
| APC<br />
|-<br />
| Familial Dysautonomia<br />
| IKBKAP<br />
|-<br />
| Fanconi Anemia <br />
| FANCA; FANCC; FANCD2; FANCF; FANCG; FANCJ<br />
|-<br />
| Fragile X Syndrome (FRAX)<br />
| FMR1<br />
|-<br />
| Galactosemia <br />
| GALT<br />
|-<br />
| Gangliosidosis<br />
| GLB1<br />
|-<br />
| Glanzmann Thrombasthenia <br />
| ITGA2B<br />
|-<br />
| Glutaric Acidemia (aciduria)<br />
| GCDH <br />
|-<br />
| Glycogen Storage Disease <br />
| G6PC; GAA; SLC37A4<br />
|-<br />
| Haemophilia A<br />
| F8<br />
|-<br />
| Haemophilia B<br />
| F9<br />
|-<br />
| Hereditary Nonpolyposis Colorectal Cancer: Lynch Syndrome<br />
| MLH1; MSH2; MSH6<br />
|-<br />
| Holt Oram Syndrome<br />
| TBX5<br />
|-<br />
| Huntington Disease<br />
| HD<br />
|-<br />
| Hydrocephalus<br />
| L1CAM<br />
|-<br />
| Ichthyosis <br />
| ABCA12; STS<br />
|-<br />
| Incontinentia Pigmenti (IP)<br />
| NEMO<br />
|-<br />
| Joubert Syndrome 5<br />
| INPP5E<br />
|-<br />
| Krabbe Disease<br />
| GALC<br />
|-<br />
| Leber Congenital Amaurosis (LCA)<br />
| CEP290; GUCY2D<br />
|-<br />
| Leigh Syndrome (Infantile Subacute Necrotising Encephalopathy)<br />
| LRPPRC<br />
|-<br />
| Lesch Nyan Syndrome<br />
| HPRT1<br />
|-<br />
| Leukocyte Adhesion Deficiency (Type I)<br />
| ITGB2<br />
|-<br />
| Li-Fraumeni Syndrome<br />
| TP53<br />
|-<br />
| Macular Dystrophy Retinal <br />
| VMD2<br />
|-<br />
| Maple Syrup Urine Disorder (MSUD)<br />
| BCKDHB<br />
|-<br />
| Marfan Syndrome <br />
| FBN1<br />
|-<br />
| Menkes Syndrome<br />
| ATP7A<br />
|-<br />
| Mitochondrial DNA Depletion Syndrom <br />
| POLG; RRM2B; SUCLA2; TK2<br />
|-<br />
| Mucolipidosis type II<br />
| GNPTAB<br />
|-<br />
| Multiple Endocrine Neoplasia<br />
| MEN1; MEN2A; MEN2B<br />
|-<br />
| Multiple Exostoses<br />
| EXT1; EXT2 <br />
|-<br />
| Myotubular myopathy<br />
| MTM1 <br />
|-<br />
| Nail-Patella Syndrome<br />
| LMX1B<br />
|-<br />
| Neurofibromatosis Type 1<br />
| NF1<br />
|-<br />
| Neurofibromatosis Type 2 <br />
| NF2<br />
|-<br />
| Noonan Syndrome<br />
| KRAS, PTPN11; SOS1<br />
|-<br />
| Norrie Disease<br />
| NDP<br />
|-<br />
| Ocular Albinism <br />
| GPR143<br />
|-<br />
| Oculocutaneous Albinism <br />
| OCA2; TYR <br />
|-<br />
| Oculodentaldigital Dysplasia<br />
| GJA1<br />
|-<br />
| Optic Atrophy<br />
| OPA1<br />
|-<br />
| Ornithine Transcarbamylase Deficiency <br />
| OTC<br />
|-<br />
| Osteogenesis imperfeca <br />
| COL1A1; COL1A2<br />
|-<br />
| Osteopetrosis <br />
| CLCN7; OSTM1; TCIRG1<br />
|-<br />
| Pachyonychia Congenita <br />
| KRT16; KRT6A<br />
|-<br />
| Pancreatitis, Hereditary<br />
| PRSS1 <br />
|-<br />
| Papillorenal syndrome <br />
| PAX2<br />
|-<br />
| Phenylketonuria <br />
| PAH <br />
|-<br />
| This table does not cover the complete list of diseases that PGD can be applied to.<br />
|}<br />
<br />
==Laws & Legal status==<br />
<br />
{|<br />
|-<br />
| Australia<br />
| PGD is currently used to detect serious genetic conditions to improve the outcome of Assisted Reproductive Technologies (ART). In very rare cases it may be used to select an embryo with compatible tissue for a sibling who has a life-threatening disease where other means of treatment is unavailable. This is with the conditions that the use of PGD will not affect the welfare and interests of the child to be born. The parents must also receive adequate counselling and have full understanding of the procedures of PGD. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"> National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art</ref><br />
The use of PGD for sex-selection is prohibited with the exception of reducing the risk of the transmission of serious sex-linked genetic conditions. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"/><br />
|-<br />
| Brazil<br />
| The laws regarding PGD in Brazil are not strictly regulated. They are vague and there is limited information surround the activities of assisted reproduction in general in the country <ref name="PMID25493379"><pubmed>25493379</pubmed></ref>.<br />
|-<br />
| Czech Republic<br />
| The laws in the Czech Republic allow those with a “defined indication in order to exclude risk of serous genetically conditioned disease and defects with embryos before they are implanted into the cavity of the uterus”. Couples that undergo any assisted reproductive treatment including PGD have to be married. Sex-selection is illegal except in regards to serious sex-linked genetic diseases <ref name="PMID24777348"><pubmed>24777348</pubmed></ref>.<br />
|-<br />
| Greece<br />
| In Greece, ART is open to those up to the age of 50 with written consent. It can only be used if a medical necessity is present such as the susceptibility of serious hereditary diseases. Sex selection is banned apart from cases of sex-linked diseases and sexually transmitted diseases <ref name="PMID24777348"/>.<br />
|-<br />
| India<br />
| In India there is a cultural preference for boys thus the Prenatal Diagnostic Techniques (Regulation and Prevention of Misuse) Act was introduced in 1994. This law limits the use of PGD for sex determination except in cases of specific congenital diseases. These laws however are not strictly enforced. <ref>World Health Organisation (2015) Gender and Genetics Retrieved on October 21st 2015 from:http://www.who.int/genomics/gender/en/index4.html<ref/><br />
|-<br />
| Portugal <br />
| ART is only available to those who are married or have a similar type of relationship for at least two years. The couples cannot be of the same sex and must be at least 18 years of age. Sex selection is illegal except in cases of sex-linked diseases. The use of PGD is illegal if the predictive value of genetic tests are very low <ref name="PMID24777348"/>.<br />
|-<br />
| Spain<br />
| PGD can be applied to “serious hereditary diseases not amenable to postnatal curative treatment” and “detection of other abnormalities which may compromise the viability of the pre-embryo”. If PGD is to be used for any other purpose authorisation must be acquired <ref name="PMID24777348"/>.<br />
|-<br />
| Sweden <br />
| The use of PGD is strictly regulated and couples must achieve authorisation of the National Board of Health and Welfare. It can only be used it can only be used if the child is at risk to inheriting a serious chromosomal or monogenetic disease. It cannot be used for selection of specific characteristics <ref name="PMID24777348"/>.<br />
|-<br />
| United Kingdom<br />
| Those involved with carrying out the IVF treatment must have a license from the Human Fertilisation and Embryology Authority (HFEA). Only embryos that are approved by the HFEA can be implanted where the embryonic nuclear or mitochondrial DNA cannot be altered with the exception of preventing mitochondrial diseases <ref name="PMID24777348"/>. <br />
|}<br />
<br />
==Future/Current Research==<br />
===Noninvasive Preimplantation Genetic Testing without Embryo Biopsy===<br />
Different parameters of gametes, zygotes, embryos (“vacuoles in sperm heads, spindle position in mature oocytes, cleavage intervals of zygote, and embryo developmental dynamics”) may correlate with aneuploidy rates. This knowledge may be applied in potential noninvasive preimplantation diagnostic methods. Several methods have been proposed and are currently further researched<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Sperm Selection====<br />
Intracytoplasmic morphologically selected sperm injection (IMSI) is common procedure in IVF treatment to improve fertilization rates in patients with poor semen quality. In addition, studies have found that IMSI improves embryo development and that spermatozoa with large vacuoles in their heads correlate with increased aneuploidy rates and disturbed chromosomal structures. Thus, selecting spermatozoa based on morphological hallmarks may decrease aneuploidy rates in the fertilized embryos. As with polar body biopsies, however, this approach will solely be applicable if evidence for severe male detrimental contribution is given<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Blastocoel Fluid Extraction====<br />
In addition, a less invasive retrieval of material for diagnosis could include the extraction of the blastocoel fluid. The cavity of the blastocyst, lined by the trophectoderm, is filled with this blastocoel fluid, which contains metabolites of both trophectoderm and inner cell mass origin. The retrieval does not require a biopsy but merely a small opening to extract the fluid and, thus, causes less harm to the embryo. Multiple studies have applied this method<ref name="PMID22020776"><pubmed>22020776</pubmed></ref> <ref name="PMID23148560"><pubmed>23148560</pubmed></ref> and it may in the future become of clinical relevance.<br />
<br />
<br />
[[File:Aspiration_of_the_Blastocoel_Fluid.jpeg|thumb|Aspiration of the Blastocoel Fluid using a ICSI pipette<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.]]<br />
<br />
<br />
Next to metabolites, the blastocoel fluid can contain DNA. Studies have shown that genomic DNA is present in about 90% of the blastocoel fluid samples tested. Typically the fluid is removed with an ICSI pipette from a day five blastocyst through its mural trophectoderm until the blastocyst fully collapses around the embryo. Several concerns regarding this method in a clinical setting have been raised. The collected DNA may be contaminated by the culture media that contains DNA fractions. The DNA may also be least representative of the actual embryos genome as the DNA may originate from abnormal or degenerated cells. Even though labelled noninvasive, the blastocyst still undergoes manipulation to some degree which may affect its viability. Thus, more research is required until this method can evolve from research to clinical use<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
====Proteomics====<br />
The protein secretome of blastocysts may be representative of its chromosome constitution Recent studies have found biomarkers such as lipocalin-1, interleukin-10, tumor necrosis factor, stem cell factor, and chemokine ligand 13 to be differently secreted by aneuploid blastocyst than by euploid ones. The most significant biomarker appears to be interleukin-10. Paired with novel proteomic technologies and mass spectrometry this knowledge when extended may contribute to a new invasive preimplantation genetic diagnosis method<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Embryo Morphology====<br />
Using time lapse imaging the embryo’s morphology can be closely observed and potential aneuploidy characteristics detected. Such characteristics may include the time of division to five cells, the time between the division from three to four cells, and the duration of the division from one to two and subsequently to three. In addition, the morphological quality of ICM an TE has been positively associated with aneuploidy or euploidy prognosis<ref name="PMID26246880"><pubmed>26246880</pubmed></ref>. These may give rise to an embryo quality screening prior to implantation<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
==References==<br />
<br />
<references/><br />
<br />
<br />
{{StudentPage2015}}</div>Z5017878https://embryology.med.unsw.edu.au/embryology/index.php?title=2015_Group_Project_6&diff=2069892015 Group Project 62015-10-21T06:17:46Z<p>Z5017878: </p>
<hr />
<div>{{ANAT2341Project2015header}}<br />
<br />
<br />
=Preimplantation Genetic Diagnosis and Screening=<br />
==Introduction==<br />
Preimplantation genetic diagnosis (PGD) and screening (PGS) are reproductive options for couples with known family histories of genetic disease or couples undergoing IVF procedures due to infertility issues. PGD can diagnose many genetic disorders caused by known chromosomal abnormalities (number and/or structure) or single gene mutations, and, thus decrease the risk of termination of pregnancy or miscarriages and enable such couples to have an unaffected child<ref name="PMID24907939"><pubmed>24907939</pubmed></ref>. Through major improvements in PGD/S and general laboratory technology, the testing for abnormalities in fetuses has shifted from prenatal diagnosis during the first 2 trimesters <ref> Blackburn, S.L. (2003) '''Maternal, Fetal & Neonatal physiology: a Clinical perspective''' (2nd ed.). Seattle: Saudners </ref>, testing for overall fetal growth, complications of pregnancy, and birth defects<ref> Sadler T.W.(2012) '''Langman's Medical Embryology''' (12th ed.) Philadelphia: Lipincott, Wiliams & Wilkins, a Wolters Kluwer Business </ref>, to an embryonic focus especially in advancements in Artificial Reproductive Technologies (ART)<ref><pubmed>20638568</pubmed></ref>. In 1990 PGD for a recessive X-linked disease resulted in the first live birth<ref><pubmed>2330030</pubmed></ref> and has since been incorporated in clinical routine and applied for a variety of genetic diseases, such as sickle cell anemia, thalassemia, or cystic fibrosis<ref name="PMID24907939"/>.<br />
[[File:Preimplantation Genetic Diagnosis Procedure.jpeg|700px|thumb|centre| Simplified steps for PGD<ref name="PMID24907939"/>]]<br />
<br />
==History==<br />
<br />
==Preimplantation Genetic Diagnosis==<br />
Preimplantation genetic diagnosis (PGD) is used to test the genetic makeup of embryos to detect single gene disorders, chromosomal abnormalities and mitochondrial disorders. It also has applications in gender selection for diseases with unequal gender distributions <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Some diseases commonly involved with PGD include cystic fibrosis, spinal muscular atrophy and beta – thalassaemia <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press.">Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press</ref> <ref name="PMID17823145"><pubmed>17823145</pubmed></ref>. It was first used in the United Kingdom in the 1980s of arenoleucodystrophy and primarily focusing on sex- linked disorders <ref name="PMID17823145"/><ref name="PMID23150080"><pubmed>23150080</pubmed></ref>. PGD is now capable of detecting single cell defects (molecular) and chromosomal disorders resulting from the inversion, translocation or deletion of chromosomes (cytogenic) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>,<ref name="PMID11325751"><pubmed>11325751</pubmed></ref>. PGD can be applied to the embryo at different stages. That is on polar bodies, blastomeres or blastocyst <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>.<br />
Depending on the type of genetic disorder, PGD utilises different methods of genetic testing. These include Fluorescence in situ hybridisation (FISH) which is used for sex – linked disorders and detects chromosomal rearrangements <ref name="PMID11325751"/><ref name="PMID17876073"><pubmed>17876073</pubmed></ref> and Embryo halotyping which allows the identification of chromosomes causing the inherited disorder through knowledge of the pattern of closely linked markers <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. Polymerase chain reaction (PCR) is also widely used to detect molecular abnormalities <ref name="PMID11325751"/>.<br />
PGD is tightly regulated and supported by large organisations namely The American Society for Reproductive Medicine, The European Society for Human Reproduction and Embryology (ESHRE), The European Society of Human Genetics and the Preimplantation Genetic Diagnosis International Society <ref name="PMID25500181><pubmed>25500181</pubmed></ref>.<br />
===Sex-linked disorders===<br />
The determination of a disease as gender specific usually correlates with the presence or absence of specific genes such as SRY on the Y chromosome. It is known that females have two X chromosomes and males have an X and a Y chromosome where abnormalities are more prevalent on the X chromosome. PGD can be used for sex selection where only male embryos are transferred to reduce the chance of inheriting X-linked disorders. However, this does not completely eradicate the problem as male embryos remain susceptible to inheriting an affected X chromosome. Sex determination is only used when the specific mutation is unknown and has yet to be discovered <ref name="PMID24866878"><pubmed>24866878</pubmed></ref>.<br />
===Single gene defects===<br />
Single gene defects can be dominant, recessive, autosomal or X-linked. They are commonly diagnosed using PCR and although the PCR available today is complex and capable of combatting a large range of disease the development of new protocols has been proven to be difficult due to the small DNA sample available <ref name="PMID26168107"><pubmed>26168107</pubmed></ref><br />
===Mitochondrial disorders===<br />
Mitochondrial disorders also known as oxidative phosphorylation disorders arise from mutations in the nuclear DNA or mitochondrial DNA <ref name="PMID26312584"><pubmed>26312584</pubmed></ref>. They pose as a problem because they are unrecognisable until the mutations in the cell reach a detrimental level <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Mitochondrial disorders cause miscarriages and stillbirths as well as death in children and young adults. The effects can either be contained in a single organ or more commonly involve multiple organ failure where organs with high energy demands such as the brain, liver muscle and heart and heavily influenced. They are usually occur spontaneously or result from inheritance from the mother. Since mitochondria are solely inherited from the mother oocyte donations have been used as a solution to combat mitochondrial disorders. Additionally, there has been an increasing use in PGD where embryos that stay under the given threshold of 18% gene-mutations are allowed to be transferred and result in normal development. New technology in the areas of nuclear gene transfer and genome editing are also being experimented with <ref name="PMID26312584"/>. <br />
===Chromosomal disorders===<br />
Chromosomal disorders can be reciprocal, Robertsonian translocations, inversions, deletions and insertions <ref name="PMID26168107"/>. . Data from ESHRE collected between 2010 and 2011 has shown that the most common chromosomal abnormality confronted in PGD are reciprocal chromosomal abnormalities <ref name"PMID26071418"><pubmed>26071418</pubmed></ref>. PGD has also been used successfully for Robertsonian translocations (RT), a type of structural translocation. Children who carry RT are phenotypically normal, however in their later years it is found that they will suffer from infertility and repeated miscarriages due to the high frequency of abnormal embryos <ref name="PMID22081077"><pubmed>22081077</pubmed></ref>. PCR and FISH are the two main techniques used for chromosomal disorders. To be able to conduct the examinations the cells are required to be at the metaphase stage <ref name="PMID26168107"/>. <br />
==Preimplantation Genetic Screening==<br />
Prenatal Genetic Screening (PGS) involves an array of methods or ideas that aim to segregate embryos that have genetic flaws and those that are healthy <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. The occurrence of aneuploidy is high around the stages of early embryonic development and they are the most common cause if miscarriages and congenital birth defects <ref name= "PMID26085841"><pubmed>26085841</pubmed></ref>. They have little effect on the morphology of the embryo making them difficult to identify thus identification heavily relies on genetic testing <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. <br />
Genetic sampling is most commonly conducted using Microarray Comparative Genomic Hybridisation (aCGH) as well as FISH, Quantitative PCR and Single Nucleotide Polymorphism (SNP) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. These methods collectively aim to assess numeral and structural chromosomal errors <ref name= "PMID26085841"/>. Studies have also introduced Next- Generation Sequencing (NGS) <ref name= "PMID26085841"/> and Whole Genome Amplification used to screen imbalances in the complete 24-chromosomes <ref name="PMID25953353"><pubmed>25953353</pubmed></ref><br />
Statistics from ESHRE have shown that the most common indications for PGS is advanced age, followed by repeated implantation failure or recurrent miscarriage and male infertility <ref name="PMID26071418"><pubmed>26071418</pubmed></ref>.<br />
====Indications====<br />
A low percentage of structural abnormalities in chromosomes are responsible for the cause of miscarriages. Despite this, they are the most prevalent type of chromosomal abnormality accounted for in PGD <ref name="PMID20638568"/>. The presence of specific gene cycles, initiation of embryonic protein synthesis and evident physiological development are all indicative of a successful in vitro fertilisation procedure <ref name="PMID11576737"><pubmed>11576737</pubmed></ref>. To eliminate further errors from occurring during the PGD procedure it is recommended to undertake further prenatal testing such as amniocentesis in the later stages <ref name="PMID20638568"/>. <br />
=====Advanced maternal age=====<br />
Data provided by the ESHRE has shown that the mean age of women undergoing PGS is 39 years <ref name="PMID26071418"/>. Women of advanced age have been shown to have a lower rate of pregnancies reaching childbirth <ref name="PMID18583331"><pubmed>18583331</pubmed></ref>. The highlighted concern revolves around the increased occurrence of aneuploidy following maternal age. The optimal age range for the lowest aneuploidy incidence was found to be between 27 to 37 years of age (6%) then progressively higher in women aged up to 42 (33%) and most common in those 44 and above (53%) <ref name="PMID24355045"><pubmed>24355045</pubmed></ref>. <br />
=====Recurrent pregnancy loss / IVF failure=====<br />
Recurrent pregnancy loss is defined as three or more IVF failures after cumulative transfer of more than 10 good-quality embryos. These are primarily caused by two main factors, reduced endometrium receptivity or embryonic defects. Endometrium receptivity can be negatively influences by instances including uterine pathologies such as thin endometrium, altered expression of adhesive molecules and immunological factors. Additionally, embryonic defects may be due to genetic abnormalities, embryonic aneuploidy or zona hardening. Endometriosis and hydrosalpinx has been known to effect both the endometrium and embryo <ref name="PMID23260857"><pubmed>23260857</pubmed></ref>.<br />
=====Human leukocyte antigen matching=====<br />
First used in 2001, HLA matching is an option given to parents to save a child with haematological or immunological disease through conceiving another child who would potentially be able to donate cord blood or haematopoietic stem cells from the bone marrow for transplantation. The process namely PGD-HLA has shown to improve haematopoietic stem cell transplant (HSCT). PGD-HLA can only be performed when HSCT is not needed urgently due to the time needed to conceive and delivery the baby <ref name="PMID25500181"><pubmed>25500181</pubmed></ref>. It is most commonly applied to children suffering from relapsed leukaemia <ref name="PMID22524201"><pubmed>22524201</pubmed></ref>. In a case study PGD-HLA was proven to successfully cure 10 diseases including Fanconi anaemia, Diamond-Blackfan anaemia and beta thalassemia <ref name="PMID25066893><pubmed>25066893</pubmed></ref>.<br />
==Biopsy Methods==<br />
Biopsy, the removal of genetic materials, from oocytes or embryos in the preimplantation stage is the primary step in PGD. For the past two decades these biopsies have been performed at three stages, the polar body, blastomere, and blastocyst, and the methodologies optimized to ensure the embryo’s viability. The most common approach involves biopsies at the cleavage stage. However, polar body and blastocyst biopsies are increasingly more often tested and applied. Approached for opening the zona pellucida involve next to the traditional mechanical and chemical means, novel approaches such as noncontact lasers. Their application may simplify and secure the procedure significantly. The most challenging question about PGD procedures remains at what stage biopsies should be taken. Much controversy has developed around this topic, highlighting the varying disadvantages and advantages of temporal biopsies. <ref name="PMID22723007"><pubmed>22723007</pubmed></ref><br />
<br />
{| class="wikitable"<br />
|- align="center" bgcolor="DDCEF2"<br />
|<br />
| Time of Biopsy<br />
| Advantages <br />
| Disadvantages<br />
|- bgcolor="FFFAFA"<br />
| Polar Body<br />
| Day 1<br />
| No harm to oocyte<br />
| Only maternal DNA is tested, often needs to be coupled with other biopsies<br />
|- bgcolor="FFFAFA"<br />
| Blastomere<br />
| Day 3<br />
| …<br />
| … <br />
|- bgcolor="FFFAFA"<br />
| Trophectoderm<br />
| Day 5 and 6 <br />
| Little harm, large amount of genetic material<br />
| Opening of blastocyst necessary, small time window for procedure<br />
|}<br />
<br />
<br />
[[File:Polar_Body,_Blastomere,_and_Trophectoderm_Biopsy.jpeg|thumb|Polar body (A), blastomere (B) and trophectoderm (C) biopsies<ref name="PMID25625041"><pubmed>25625041</pubmed></ref>.]]<br />
<br />
<br />
<br />
PMID 24305177<br />
===Polar Body Analysis===<br />
Day 1<br />
====Description====<br />
Polar body (PB) biopsy, which was introduced in 1990, offers a promising alternative to biopsies performed at the blastomere stage for PGD/S indications on legal and practical grounds. <br />
Description: Consequent embryo development does not necessitate the presence of the first and second PB and their removal may not be crucial. PB biopsy requires precise timing. Keeping track of the meiotic cell cycle is necessary to perform a successful biopsy and, therefore, PB biopsy usually is applied in combination with intracytoplasmic sperm injection (ICSI). During the maturation from the germinal vesicle stage to the metaphase-II stage the first PB is formed. A cytoplasmic bridge containing spindle remnants, that are still in contact with the cellular genetic material, links this PB to the oolemma for about 90 minutes after extrusion. It is possible to visualize these remnants by polarization microscopy and it is crucial to not perform the biopsy until the first PB is no longer firmly attached to the oolemma as this indicates an immature embryo.The oocyte tolerates mechanical zona dissection best during hours four until six after ICSI as the oolemma has stabilized by that time because of the cortical granule reaction. Over time the first PB degenerates stressing a temporal biopsy and its optimal extraction time window is four to 12 hours after ICSI. The second PB forms around two to four hours after ICSI. However, its optimal time window for biopsy is set to be eight to 16 hours after ICSI. This is due to the second PB being attached to the oolemma with spindle remnants until six hours after ICSI. Biopsy at this point may cause enucleation of the oocyte. In addition, studies have shown that the amplification efficiency of second PB’s DNA is worse if the PB is extracted prior to eight hours after ICSI. <br />
Thus, it is possible to perform sequential and simultaneous biopsies for the first and second PB. If performed, sequentially the first PB may be removed four to 12 hours and the second PB eight to 16 hours after ICSI. The optimal time window for a biopsy for both the first and second PB simultaneously is eight to 12 hours after ICSI. It is highly preferred to analyze both PBs due to potential aneuploidies in either PB and crossing overs during meiosis<ref name="PMID22723007"/>. <br />
====Procedure====<br />
Chemical opening achieved with for example acidic tyrode’s solution of the zona pellucida is not tolerated by the oocyte and may have detrimental effects on the embryo’s development. Therefore, the access to the perivitelline space of the oocyte is provided by mechanical zona dissection or by laser. Both techniques work well if performed by experienced embryologist. However, laser-assisted biopsy is less time consuming when compared to manual dissection. It is critical to consider the size of the introduced opening as it will remain permanent. If it is too large the blastomere may be lost during embryo development and if it is too small it may interfere with hatching of the embryo during blastocyst stage<ref name="PMID22723007"/><br />
<br />
[[File:Polar_Body_Biopsy.jpeg|thumb|The presence of a faint but clearly identifiable strand connecting PB2 to the <br />
oolemma. The biopsy was performed ∼9 h after ICSI<ref name="PMID21908464"><pubmed>21908464</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JTaQzszVr8o</html5media><br />
|-<br />
| Laser-assisted polar body biopsy<ref>RIUK, R. (2013, June 25) Polar Body Biopsy [Video file]. Retrieved from https://www.youtube.com/watch?v=JTaQzszVr8o</ref><br />
|}<br />
<br />
====Advantages & Disadvantages====<br />
PB biopsies can only investigate the maternal contributions to the embryo as they are of maternal origin. Thus, this procedure is appropriate for PGD solely for monogenetic diseases from the maternal side. Recessive diseases may be evaluated with PB biopsies on the basis that the embryo’s outcome will be determined by the paternal contribution. (...) It may still be applied for PGS as most aneuploidies either arise during meiosis or origin from the maternal genome. However, diagnosis error has been reported due to the lack of considering paternal contributions. <br />
Because PB biopsies are performed very early it is not yet known whether the oocyte will develop into a viable embryo. Thus, PBs are commonly frozen or fixed after biopsy and depending on the state of the embryo only chosen PBs will be tested. This is primarily an economic issue as many genetic testing procedures are very cost-intensive<ref name="PMID22723007"/>.<br />
<br />
[[File:Implantation_predictive_value_of_euploid_screening_results.jpeg|thumb|The sustained implantation predictive value (with 95 % confidence interval) of a euploid screening result obtained from the first polar body (PB1), PB1 and the second polar body (PB2), or a direct embryo biopsy for each stage of embryo transfer (cleavage-stage and blastocyst stage)<ref name="PMID25106935"><pubmed>25106935</pubmed></ref>.]]<br />
<br />
===Blastomere biopsy===<br />
Day 3 <br />
====Description====<br />
Blastomere biopsy has been the prevalent method for PGD and PGS in the last two decades. At least one, but up to two, blastomeres are biopsied on day three of the cleavage stage embryo. The right number of blastomeres removed is a controversial topic as two cells allow for more genetic material and more accurate results. However, removing two cells might be too invasive and damaging to the embryo. (Study)<ref name="PMID21748341"><pubmed>21748341</pubmed></ref><br />
====Procedure====<br />
Initially a hole was drilled into the zona pellucida using acid tyrodes and the blastomeres are removed via aspiration with a pipette<ref name="PMID21748341"/>.<br />
<br />
<br />
[[File:Aspiration_of_a_Blastomere.jpeg|thumb|Aspiration of a Blastomere into the biopsy pipette<ref name=" PMID24783200"><pubmed>24783200</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=TbridWVwipI</html5media><br />
|-<br />
| Laser-assisted blastomere biopsy<ref>Sukprasert, M. (2014, March 5) Day 3 Blastomere Biopsy 1 [Video file]. Retrieved from https://www.youtube.com/watch?v=TbridWVwipI</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
===Trophectoderm biopsy===<br />
Day 5 and 6<br />
====Description====<br />
The improvement of embryo culture media allowed the in vitro development of human embryos until the blastocyst stage and opened up the possibility to take blastocyst biopsies. During day three to day five the haploid maternal and paternal genomes work together for the first time to form the genome of the embryo. The maternal epigenetic control lessens significantly while preparing for implantation with precisely arranged events happening. The first event includes a rapid increase in the number of embryonic cells which are active in mitotic divisions and apoptosis of aberrant cells. This is followed by the formation of blastocoel (cavitation) which results from the flattening of cell located on the outside of the blastomere. Now the blastocyst will expand until the embryo hatches by rupturing the zona pellucida. The cells of the blastocyst will differentiate to form two distinct cell lineages, the outer trophectoderm and the inner cell mass<ref name="PMID22723007"/>.<br />
====Procedure====<br />
Trophectoderm biopsy is usually performed in Hepes buffered biopsy medium and opening approaches include needle cutting which has been replaced by lasers in past years. Different research groups report different timings of the opening to be the most successful. Some open the blastocyst on day three or four by creating a 25 µm which causes the trophectoderm to herniate through this hole and is, thus, accessible for biopsy. Others create this hole about four hours before biopsy which allows sufficient herniation of trophectoderm cells. It is also possible to open the blastocyst immediately before biopsy. This avoids an extra step and the inner cell mass usually is easy to locate. Blastocyst biopsies involve the removal of trophectoderm cells and the ideal time for the procedure is day five. Successful biopsies on day six have been performed, while little is known about the results of biopsies on day seven. However, since the window of implantation in humans is from day eight to ten after ovulation, day seven biopsies appear to be possible<ref name="PMID22723007"/>.<br />
-collapse of trophoblasts<br />
-possible: biopsy of hatched blastocyst, holding pipette careful mild suction force to hold embryo near ICM <br />
-Cryopreservation<br />
<br />
<br />
[[File:Microscopic images of human blastocysts for biopsy.jpeg|thumb|(A) Some trophectoderm cells in a blastocyst started to hatch and (B) the trophectoderm cells were biopsied with assisted laser cutting. Images in C–D show the blastocysts after vitrification and warming. Blastocysts had been cultured for 2–4 hrs after warming, showing good (ICM and trophectoderm cells) hatched (C) and hatching (D) blastocysts. The hatching blastocyst in (E) has good ICM but fair trophectoderm while the blastocyst in (F) has both fair ICM and trophectoderm. Arrows indicate ICMs and arrow heads indicate trophectoderm cells. Bar = 40 µm<ref name="PMID2190846"><pubmed>2190846</pubmed></ref>.]]<br />
<br />
<br />
{|class="wikitable"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JI_TQ8d8tNM</html5media><br />
|-<br />
| Laser-assisted blastocyst biopsy (at 00:50 min)<ref>Coco, R. (2014, April 30) Trophectoderm biopsy in a Hatching blastocyst protruding ICM [Video file]. Retrieved from https://www.youtube.com/watch?v=JI_TQ8d8tNM</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
Blastocyst biopsies are believed to be less damaging to the embryo and appear to be unrelated to implantation rates. In addition, this biopsy method allows for a larger extraction of cells for genetic testing. However, since they are performed late in in vitro development, the time window for genetic testing is relatively small. Fast and accurate genetic testing methods are needed to ensure a successful and safe result from this biopsy. Thus, blastocyst biopsies may gain more popularity in the future whn such methods have been developed or improved<ref name="PMID22723007"/>. <br />
<br />
<br />
==Genetic Techniques==<br />
<br />
===PCR===<br />
====Description====<br />
Polymerase chain reaction (PCR) amplifies DNA specific to genetic sequence of interest . PCR was developed by Kay Mullis in the 1980s, for which he was awarded the Nobel prize for chemistry in 1993. <ref> Pubmed Docs (2015) Polymerase Chain Reaction (PCR) Pubmen. Retrieved from [http://www.ncbi.nlm.nih.gov/probe/docs/techpcr/]</ref> This technique enables clinicians to monitor and diagnose diseases using minute samples such as embryonic cells, blood & tissue. <ref>Roche (2015) PCR: How We Copy DNA. Roche Molecular Systems Inc. retrieved From [http://molecular.roche.com/pcr/Pages/Process.aspx]</ref> PCR has many important applications like DNA fingerprinting, genetic mapping, detection of viruses and bacteria as well as being used to detect genetic disorders, as a part of PGD, in conjunction with IVF. It is used to detect molecular abnormalities such as single gene disorders like Tay Sach, Cycstic fibrosis, Duchenne Muscular Dystrophy, Thalassemia, Huntington disease, Spinal muscular atrophy and many more. Molecular and Genetic analysis require a significant amount of DNA, which we would not have without PCR. It revolutionized the study of DNA, replacing all previous recombinant DNA technology. <ref> Mullins, K., Francois, F.& Gibbs R.A. (1994 ) The Polymerase Chain Reaction. p3. Springer- Science +Business Media. Birkhauser, Boston<br />
Available at [https://books.google.com.au/books?hl=en&lr=&id=gjrTBwAAQBAJ&oi=fnd&pg=PR5&dq=kary+mullis+PCR&ots=mpzAyRh5ZY&sig=PQ4goNoKJ90tb3-MkPk62zrTGbw#v=onepage&q=kary%20mullis%20PCR&f=false] </ref> <br />
<br />
[[File:PCR.jpg|thumb|right|Polymerase chain reaction (PCR) amplifies DNA specific to genetic sequence of interest, enabling the monitoring and diagnose molecular abnormalities such as single gene disorders using minute samples such as embryonic cells, blood & tissue <ref>NIS (2015)Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref>]]<br />
<br />
====Procedure====<br />
<br />
Sample are obtained from the the blastocyst, a polar body biopsy or the blastomeres stages of the embryo. <br />
Stage 1 Denaturing: separating the target strands of DNA <br />
The obtained sample is heated to roughly 90 degrees celcius, this heat causes breaks the relatively weak bonds between nucleotides that form DNA. the double stranded DNA to split into 2 single strands of DNA that are used as templates.<br />
Stage 2 Annealing: Binding the Primers to the target DNA sequence <br />
PCR will only copy the target sequence of DNA specified by specific PCR primer. These synthesized primers Oligonucleotides are small artificial pieces of DNA. <br />
TAQ polymerase enzyme synthesize 2 new strands of DNA duplicate to the single sample DNA stand template indicated by these primers. During this stage the reaction is cooled to a temperature between 40-60 degrees Celsius. <br />
Stage 3- Extension- making copies <br />
Each of these 2 copies are then used again as templates generating 2 further replications This cycle can occur as many 30 -40 times within a couple hours leading to billions of extra copies of the original DNA segment. The optimal temperature for the further replication is roughly 72 degrees Celsius. <br />
<br />
This process mediated by a thermocycler machine that is programmed to alter the temperature of the reaction every couple of minutes, perpetuating the cycle of DNA denaturing and synthesis. <br />
This process, generates exponential exact copy of the original template DNA sequence. <br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
!PCR cycles<br />
<br />
|{|<br />
|-<br />
| '''PCR Cycle'''<br />
| '''Target Copies'''<br />
|-<br />
| 1<br />
| 2<br />
|-<br />
| 2<br />
| 4<br />
|-<br />
| 3<br />
| 8<br />
|-<br />
| 4<br />
| 16<br />
|-"<br />
| 5 <br />
| 32<br />
|-<br />
| 6 <br />
| 64<br />
|-<br />
| 7 <br />
| 128<br />
|-<br />
| 8<br />
| 256<br />
|- <br />
| 9<br />
| 512 <br />
|-<br />
| 10<br />
| 1024<br />
|-<br />
| 15<br />
| 32,768<br />
|-<br />
| 20 <br />
| 1,048,578<br />
|-<br />
| 25<br />
| 33,554,432<br />
|-<br />
| 30 <br />
| 1,073,741,842<br />
|-<br />
|}<br />
<br />
<br />
<br />
{| class="wikitable" <br />
|-bgcolor="#9ACD32" <br />
| rowspan="10" |'''Advantages'''<br />
|-bgcolor="#F0FFF0"<br />
| fast and inexpensive way of copying a target sequence of DNA<br />
|-bgcolor="#F0FFF0"<br />
| aids the diagnosis of single cell defects<br />
|-bgcolor="#F0FFF0"<br />
| rapid generation of results within a couple hours<br />
|-bgcolor="#F0FFF0"<br />
| can start from a single molecule of DNA, therefore is more sensitive <br />
|-bgcolor="#F0FFF0"<br />
| has a flexible primer design enabling<br />
|-bgcolor="#F0FFF0"<br />
| overcame previous issues associated with the limited availability of sites of end<br />
|-bgcolor="#F0FFF0"<br />
| generates the DNA copies exponentially<br />
|-bgcolor="#F0FFF0"<br />
| enables DNA amplification required for molecular and genetic analysis<br />
|-bgcolor="#F0FFF0"<br />
|Valid diagnostic method in selecting unaffected embryos for embryo transfer <ref> Dreesen, J., Drusedaul, M., Smeets, H., Die-Smulders, C., Coonen, E., Dumoulin, J., Gielen, M., Evers, J., Herbergers, J. & Geradets, J. (2008) Validation of preimplantation genetic diagnosis by PCR analysis: genotype comparison of the blastomere and corresponding embryo, implications for clinical practice. Mol. Hum. Reprod. 14 (10):573-579.doi: 10.1093/molehr/gan052. Retrieved from [http://molehr.oxfordjournals.org/content/14/10/573.short] </ref> <ref><pubmed>20966460</pubmed></ref><br />
|-bgcolor="#9ACD32"<br />
| rowspan="5"|'''Disadvantages'''<br />
|-bgcolor="#F0FFF0"<br />
| only during this exponential DNA replication phase can we determine the starting quantity sequence contained in the original sample ( template DNA strand)<br />
|-bgcolor="#F0FFF0"<br />
| PCR reaction is limited by the presence of inhibitors present in the sample : reagent inhibitors <br />
|-bgcolor="#F0FFF0"<br />
| self annealing due to the accumulation of the product -stopping exponential amplification for the target sequence and reach a plateau<br />
quantification of the end point of reaction of PCR products unreliable - therefore that is why we require real time quantitative RT-PCR necessary<br />
<ref> NIS (2015) Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref><br />
|}<br />
<br />
<br />
===Fluorescent In Situ Hybridisation (FISH)===<br />
<br />
<br />
====Description====<br />
Fluorescence in situ hybridization (FISH) the one of the most effective and rapid <ref name="PMID26338801"><pubmed>26338801</pubmed></ref> Preimplantation Genetic Diagnosis (PGD). This techniques used to locate a specific DNA sequences within a chromosome. FISH facilitates the clinical diagnosis of chromosomal abnormalities indicated by sequential duplications, deletions and rearrangements of chromosome, that are usually missed with microscopic analysis. This technique is especially relevant for female embryos with X-linked diseases,<ref name="PMID20809319"><pubmed>20809319</pubmed></ref> that have no other mutation specific tests [http://www.ncbi.nlm.nih.gov/pubmed/20809319] As part of PGD, samples are collected from various stages of the embyro,and they are able to conducted tests on the blastocyst, a polar body biopsy and the blastomeres <ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. FISH is 99% effective when used in conjunction with competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities<ref name="PMID26338801"/>.<br />
<br />
====Procedure==== <br />
<br />
Samples are collected from either the blastocyst, a polar body biopsy or the blastomeres stages of the embryo <ref name="PMID21748341"><pubmed>21748341</pubmed></ref>. <br />
DNA strands are heated and denatured causing their the individual DNA strands to break apart<br />
Probes are single complimentary stands of DNA a that have been tagged with small chemical agents that glow brightly in the presence of a specific region on a chromosome. These specific probes then hybridize and join to their complementary DNA strand. <br />
The fluorescent tags enable the researchers to correctly identify the presence or lack thereof and location of the specific chromosomes that they are testing for. <ref name="PMID17876073"><pubmed>17876073</pubmed></ref><br />
Researcher analyse the results by identifying the number and the relative location of the fluorescent dots generated by the FISH images.<ref name="PMID17970921"><pubmed>17970921</pubmed></ref><br />
The probe will not fully hybridise if there has been a duplication or a deletion of the DNA - indicating chromosomal and sex chromosomal anomalies like trisomies and aneuploidies. <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref><br />
<br />
<br />
Different probes are used for different purposes: <ref>Unique, Rare Chromosome Disorder Support Group (2013) Fluorescence in situ hybridisation (FISH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/Other/FISH%20FTNW.pdf]</ref><br />
*'''Locus specific tags''' detect very small imbalances, and locate isolated small portions <br />
of genes within a chromosome<br />
*'''Alphoid/Centomeric Repeat probes''' are developed from the repetitive sequence located in the middle region of each chromosome, useful in determining the number of chromosomes , detecting rearrangement and when used in conjunction with locus probes to determine the absence of genetic material on a chromosome. <br />
*'''Paint Probes''' are collections of smaller probes with their own stains that bind to a different section on the chromosome - allowing the full chromosome too be labeled a unique colour, this "full colour map" can be used to know the spectral karyotype- full chromosomal mapping is useful in examining chromosomal abnormalities. <br />
<br />
[[File:Fluorescent In Situ Hybridisation (FISH).jpg|thumb|right|'''FISH''' We are able to tag Specific DNA sequences using Probes which have been tagged with fluorescent Labels.This technique enables the clinical diagnosis of chromosomal abnormalities, indicated by sequential duplication, deletions and rearrangements of chromosome <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref>]]<br />
<br />
{|class="wikitable" align="center"<br />
|-bgcolor="pink" <br />
| rowspan="8" |'''Advantages''' <br />
|-bgcolor="#FDE1F2" <br />
| FISH is 99% effective when used in conjunction with Competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities.<ref><pubmed>26338801</pubmed></ref><br />
|-bgcolor="#FDE1F2" <br />
| Rapid generation of results<br />
|-bgcolor="#FDE1F2" <br />
| Identifies very small translocations and aneuploidies that occur within chromosomes, that would usually be missed under microscopic analysis<br />
|-bgcolor="#FDE1F2" <br />
| Indicates whether the accessed chromosomes are normal <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|-bgcolor="#FDE1F2" <br />
| Tests for the most common chromosomal abnormalities - down syndrome chromosomes 13,16,18,21 and 22 <ref><pubmed>21749752</pubmed></ref><br />
|-bgcolor="#FDE1F2" <br />
| It may be used to compare the chromosomal gene arrangements in related species<br />
|-bgcolor="#FDE1F2" <br />
| can be used to identify and remove inheritable X-linked disease or sex chromasome anomalies such as Duchennes Muscular Dystrophy, hemophilia, ectodermal dysplasia <ref><pubmed>17876073</pubmed></ref><br />
|-bgcolor="#FEB745"<br />
| rowspan="5"|'''Disadvantages'''<br />
|-bgcolor="#FE1C5EA"<br />
| FISH destroys all cells tested <ref> O'Connor, C. (2008) Fluorescence in situ hybridization (FISH). Nature Education 1(1):171. retrieved from [http://www.nature.com/scitable/topicpage/fluorescence-in-situ-hybridization-fish-327] </ref><br />
|-bgcolor="#FE1C5EA"<br />
| It does not fully access all chromosomes (only ~ 12)<br />
|-bgcolor="#FE1C5EA"<br />
| Analysis of results is dependent upon the dot quality impacted by hybridisation efficiency or the camera sensitivity <ref><pubmed>17970921</pubmed></ref><br />
|-bgcolor="#FE1C5EA"<br />
| some studies indicate that using FISH on a day-3 embryo biopsy decreases the rate of live births <ref><pubmed>26168107</pubmed></ref><br />
|}<br />
<br />
===Array Comparative Genomic Hybridisation (aCGH)===<br />
====Description====<br />
<br />
aCGH also known as Microarray analysis efficiently scans the entire genome for chromosomal imbalances. CGH was initially developed to detect the number of changes in a solid tumor mass. It uses 2 genomes comparing the sample to the control, with each labeled in a different fluorescent dye<ref name="PMID1876176"><pubmed>1876176</pubmed></ref>. Earlier CGH techniques were limited by the resolution of the imaging <ref> Lichter, P., et al. Comparative genomic hybridization: Uses and limitations. Seminars in Hematology 37, 348–357 (2000)</ref> , these initial limitations were overcome by using Microarrays in conjunction with CGh to improve the resolution of the imaging, Array Comparative Genomic Hybridisation (aCGH). This method compares sample and control microarrayed slides containing small segments of DNA (probes). <ref> Lucito, R., et al. Representational oligonucleotide microarray analysis: A high-resolution method to detect genome copy number variation. Genome Research 13, 2291–2305 (2003) </ref> the Probes used will vary according from the small (25-85 base pairs) oligonucleotides manufactured to highlight different target sequences, to the very large genomic clones (80,000- 200,00 base pairs), and as these are significantly smaller than the traditional metaphase chromosomes used for CGH, generating a higher resolution of image. <ref name="PMID22467166"><pubmed>22467166</pubmed></ref>.aCGH is used as a diagnostic tool for prenatal detection f chromosomal abnormalities <ref name="PMID19012303"><pubmed>19012303</pubmed></ref>.<br />
<br />
<br />
====Procedure====<br />
<ref> Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432] </ref><br />
The sample is obtained (skin, blood or fetal cells) and DNA is obtained. <br />
As a part of PGD fetal cell samples are collected from; the fertilized egg polar bodies, the blastomere (day 3 embryo) or the blastocyst/tropoectoderm stage (day 5 embryo).<br />
Sample DNA is labeled with one fluorescent dye, and the control DNA is labeled with a different colored fluorescent dye. the control DNA is used as the base point of reference. <br />
heated and denatured single DNA strands then hybridize to their complementary single strand probes, which are then combined and applied to a microarray and the results are run through a computer program and a digital imaging system is used to quantify the results( fluorescent intensities of the labeled probes). <br />
<br />
[[File:aCGH.jpg|thumb|right|'''aCGH''' checks the entire genome for chromosomal imbalances, by comparing control and a sample slides contatining small segements of DNA sample microarrayed slides small segments of DNA. Illustrated by student z5020317 and adapted from <ref> NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation. retrieved from [http://www.phgfoundation.org/file/5237/]</ref> <ref>Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432]</ref>]]<br />
<br />
<br />
<br />
The fluorescent ratio and the hybridization signal at different locations on the genome of the control DNA are used to identify any variances present in the sample DNA. aCGH facilitates the clinical diagnosis of submicroscopic chromosomal duplication, deletion and rearrangements indicative of chromosomal disorders such as trisomies 1-22and specific sex linked disorders. <br />
Duplications in the DNA are displayed by the computer program as spikes/ peaks over an established threshold and deletions in DNA are displayed by the computer program as spikes/ toughs beneath this threshold <br />
<br />
<br />
<br />
<br />
{|border="1" align="center"<br />
|-bgcolor="pink" <br />
| '''Advantages''' <br />
| '''Disadvantages'''<br />
|-<br />
| multiple applications: prenatal genetic diagnosis, cancer diagnosis, <ref name="PMID20193845"><pubmed>20193845</pubmed></ref> genetic screening for developmental delay (learning disabilities) <ref name="PMID17309648"><pubmed>17309648</pubmed></ref>. or congenital anomalies that are suspected to be genetic in origin <ref>NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation . retrieved from [http://www.phgfoundation.org/file/5237/]</ref><br />
| translocations and inversions of DNA are not detected<br />
|-bgcolor="pink"<br />
| trace represents all chromosomes present in the human genome chromosomes 1-22 and the X & Y chromosomes, and therefore is the most accurate method for testing whole embryo aneuploidy<br />
| limited ability diagnosing specific polyploidies such as triploidy <ref> Unique, Rare Chromosome Disorder Support Group (2013) Microarray-based Comparative Genomic Hybridiation (array CGH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/other/array%20cgh%20ftnw.pdf] </ref><br />
|-<br />
| aCGH has been extensively tested, and Validated, and is now used world wide.<br />
| will not detect mosaicism detection <20% (cultures where >1 of 5 cells are trisomy 12)<br />
|-bgcolor="pink"<br />
| detects deletions and additions and rearrangements as well as amplification, of the WHOLE genome, simultaneously.<br />
| will not detect balanced chromosomal rearrangement<br />
|-<br />
| detects submicroscopic alterations<br />
| will not detect duplications or deletions <80kb<br />
|-bgcolor="pink"<br />
| used as a diagnostic tool for prenatal detection of chromosomal abnormalities <ref name="PMID22034057"><pubmed>22034057</pubmed></ref><br />
| will not detect point mutations within genes <ref>Washington department of education (CGH- FAQ for physicians. Signature Genomic LAboratories, LLC. Retrieved from [https://depts.washington.edu/dbpeds/Lab%20Tests/SignatureCGH-physician_FAQ.pdf]</ref><br />
|-<br />
| provides high resolution genomewide screening of segmental genomic copy number variations<br />
| will not detect chromosomal position of genomic gains<br />
|-bgcolor="pink"<br />
| very accurate when used in conjunction with FISH<br />
| will not detect loos of heterozygosity (LOH) or Absence of heterozygosity (AOH) <ref>WiCell Research Institute Inc. (2012) Comparative Genomic Hybridization Microarray. <br />
retrieved from [http://www.wicell.org/home/cytogenetic-services/cgh-microarray/array-comparative-genomic-hybridization-acgh.cmsx]</ref><br />
|-<br />
|Alone is more reliable and in detecting chromosomal abnormalities, with a higher implantation success rate, than FISH <ref name="PMID20494259"><pubmed>20494259</pubmed></ref><br />
|<br />
|-bgcolor="pink"<br />
|Allows an in depth research focus upon specific types of rearrangements within selected chromosomal regions, a recent particular area of interest is subtelomeric and pericentromeric rearrangements<br />
|<br />
|-<br />
|reduces the risk of failed implantation and miscarriage, improving the chance of a healthy baby <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|<br />
|}<br />
<br />
<br />
<br />
===Next Generation Sequencing===<br />
====Description====<br />
The development and advances within ART in the past 20 years, as well as the increasing popularity of IV, has lead to an influx of new technologies developed to screen embryos for chromosomal anomalies, which are covered by the umbrella term of Next generation Sequencing (NGS). NGS is a general term used to describe all of the new and emerging screening techniques currently being introduced and used as part of PGD for IVF . NGS screens for single gene disorders as well as conducting extensive and very comprehensive chromosome diagnosis by sequencing, counting, and accurately assembling millions of DNA reads, simultaneously. <ref name="PMID23499002"><pubmed>23499002</pubmed></ref> There is a movement for NGS to replace the other limited testing techniques and be used as the standard. <br />
====Procedure====<br />
Samples are collected from either blastomere or the blastocyst/tropoectoderm and processed for analysis by a computer system. <br />
The methodology of each process is unique to the technique being used. <br />
<br />
<br />
<br />
{|border="1" align="center"<br />
|-bgcolor="pink" <br />
| '''Advantages'''<br />
| '''Disadvantages'''<br />
|-bgcolor="white"<br />
| cheaper<br />
| there are limited information available to clinical applications of NGS <ref><pubmed>26100406</pubmed></ref><br />
|-bgcolor="pink"<br />
| opens new diagnostic possibilities<br />
|<br />
|-bgcolor="white"<br />
| accurately tests all 24 chromosomes<br />
| <br />
|-bgcolor="pink"<br />
| tests for the presence of monogenic diseases of known genetic background<br />
| <br />
|-bgcolor="white"<br />
| reduces the number of biopsies required for diagnosis<br />
| <br />
|-bgcolor="pink"<br />
| higher detection rate of small translocations<br />
| <br />
|-bgcolor="white"<br />
| highly accurate is testing for compound point mutations, chromosomal duplication, deletions and insertions <ref name="23312231"><pubmed>23312231</pubmed></ref><br />
| <br />
|-bgcolor="pink"<br />
| it accurately detects chromosomal aneuploidy and unbalanced rearrangement <ref name="PMID25685330"><pubmed>25685330</pubmed></ref><br />
| <br />
|-bgcolor="white"<br />
| NGS single gene disorder screenings can conducted in conjunction with PCR comprehensive chromosomal screening<br />
|<br />
|-bgcolor="pink"<br />
| Reduces human error <br />
|<br />
|-bgcolor="white"<br />
| better detects the presence of mosaicism<br />
|<br />
|-bgcolor="pink"<br />
| work well in conjunction with CGH and aCGH as part of PGD, improving the chances of IVF. <ref> Morris, R. S. (2015 ) Next generation sequencing for PCG|PGS|CCS. IVF1 retrieved from [http://www.ivf1.com/next-generation-sequencing for-pgd] </ref><br />
|<br />
|}<br />
<br />
<br />
<br />
<br />
<br />
<br />
==Diagnosis==<br />
There are a large amount of diseases that PGD can apply to, below are descriptions of the diseases that PGD are more commonly used for. Utilization of Diseased Cell Lines<br />
===Cystic Fibrosis===<br />
Cystic fibrosis is a single gene disorder. It is autosomal recessive and involves mutations in the cystic fibrosis transmembrane conductance regulator (CTFR) gene. The CTFR gene is normally responsible for the decrease in chloride and the transport of bicarbonate in epithelial cells thus playing a major physiological role. In PGD procedures, identification of the gene is assisted by microsatellite markers that have similar composition to the CTFR gene itself. Biopsy of two cells at the blastocyst stage is recommended if markers are not available. There are many variations of cystic fibrosis the most common being P.Phe508del <ref name="PMID26014425"><pubmed>26014425</pubmed></ref>.<br />
===Duchenne Muscular Dystrophy ===<br />
Duchenne Muscular Dystrophy is an X-linked recessive disease. It involves the Xp21 gene where majority of the mutations are chromosomal deletions with a smaller percentage resulting from duplications <ref name="PMID18359022"><pubmed>18359022</pubmed></ref>.<br />
===β – Thalassemia=== <br />
β – Thalassemia is known as the most common type of autosomal recessive inherited disorder among haemoglobinopathies. It involves the adult β-globin gene and is associated with the absent or decreased expression of the gene. This is commonly caused by a single nucleotide change in the gene. PGD has been used successfully worldwide to identify the β-globin gene where its application is usually performed on a single blastomere or polar body <ref name="PMID19064120">19064120</pubmed></ref>.<br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
! Applicable diseases for PGD <ref>Genoma Group (2014). Retrieved September 18th, 2015, from http://www.preimplantationgeneticdiagnosis.it/genetic-diseases-diagnosed-by-pgd.htm </ref>, <ref>Genesis Genetics (2015). Retrieved September 18th, 2015, from http://genesisgenetics.org/pgd/what-we-test-for/</ref>, <ref>Human Fertilisation & Embryology Authority (2015). Retrieved Septembr 18th, 2015, from http://guide.hfea.gov.uk/pgd/</ref><br />
|-<br />
| '''Disease'''<br />
| '''Involved Genes'''<br />
|-<br />
| 5 Alpha Reductase Deficiency (5ARD)<br />
| SRD5A2 <br />
|-<br />
| Achondroplasia<br />
|FGFR3 <br />
|-<br />
| Acute Intermittent Porphyria <br />
| ALAD, ALAS2, CPOX, FECH, HMBS, PPOX, UROD, or UROS<br />
|-<br />
| Adrenoleukodystrophy (Adrenomyeloneuropathy)<br />
| ABCD1 <br />
|-<br />
| Agammaglobulinaemia (x-linked) <br />
|BTK <br />
|-<br />
| Agammaglobulinemia Bruton Tyrosine Kinase (BTK) <br />
|BTK <br />
|-<br />
| Aicardi Goutieres Syndrome 1 (AGS1) <br />
|TREX1, RNASEH2A, RNASEH2B, RNASEH2C, SAMHD1<br />
|-<br />
| Alagille Syndrome<br />
|JAG1 or NOTCH2<br />
|- <br />
| Alpers-Huttenlocher Syndrome <br />
|POLG <br />
|-<br />
| Alpha-1-antitrypsin deficiency <br />
|SERPINA1 <br />
|-<br />
| Alpha-Mannosidosis<br />
| MAN2B1 <br />
|-<br />
| Alpha Thalassemia <br />
|HBA1 or HBA2 <br />
|-<br />
| Alports Syndrome<br />
|COL4A3, COL4A4, COL4A5<br />
|-<br />
| Alzheimer's Disease - early onset (Type 3 and 4) <br />
|APP, PSEN1, or PSEN2<br />
|-<br />
| Amyotrophic Lateral Sclerosis 1 (ALS1) <br />
|C9orf72, SOD1, TARDBP, FUS, ANG, ALS2, SETX, VAPB <br />
|-<br />
| Argininosuccinic Aciduria <br />
| ASL<br />
|-<br />
| Arrhythmogenic Right Ventricular Cardiomyopathy/ Dysplasia (ARVC/D)<br />
| DSG2; DSP; PKP2<br />
|-<br />
| Ataxia Telangiectasia<br />
| ATM<br />
|-<br />
| Bardet-Biedl Syndrome (BBS)<br />
| BBS1; BBS10<br />
|-<br />
| Barth Syndrome<br />
| TAZ<br />
|-<br />
| Beta Thalassaemia<br />
| HBB<br />
|-<br />
| Birt-Hogg-Dubé Syndrome<br />
| FLCN<br />
|-<br />
| Breast Ovarian Cancer Familial Susceptibility (BRCA2)<br />
| BRCA1; BRCA2<br />
|-<br />
| Canavan Disease <br />
| ASPA<br />
|-<br />
| Carnitine-Acylcarnitine Translocase Deficiency <br />
| SLC25A20<br />
|-<br />
| Cerebral Arteriopathy with Subcortical Infarcts & Leukoencephalopathy (CADASIL)<br />
| NOTCH3<br />
|-<br />
| Cerebral Cavernous Malformation<br />
| CCM1<br />
|-<br />
| Charcot-Marie-Tooth Disease<br />
| GJB1; MPZ; NEFL; PMP22<br />
|-<br />
| CHARGE Syndrome<br />
| CHD7<br />
|-<br />
| Cherubism<br />
| SH3BP2<br />
|-<br />
| Choroideremia<br />
| CHM<br />
|-<br />
| Chronic Granulomatous Disease<br />
| CYBB; NCF1<br />
|-<br />
| Ciliary Dyskinesia<br />
| DNAH5<br />
|-<br />
| Citrullinemia<br />
| ASS1<br />
|-<br />
| Cleidocranial Dysplasia<br />
| RUNX2<br />
|-<br />
| Cockayne Syndrome<br />
| ERCC6<br />
|-<br />
| Congenital Adrenal Hyperplasia<br />
| CYP21A2<br />
|-<br />
| Congenital Cataracts<br />
| GJA8; VSX2<br />
|-<br />
| Congenital Diarrhea, Syndromic<br />
| SPINT2<br />
|-<br />
| Congenital Disorders of Glycosylation (CDG)<br />
| ALG1; ALG6; CDG1C; DOLK; PMM2<br />
|-<br />
| Cornelia de Lange Syndrome <br />
| NIPBL<br />
|-<br />
| Craniosynostosis<br />
| TWIST1<br />
|-<br />
| Crouzon Syndrome<br />
| FGFR2<br />
|-<br />
| Cysteinyl Leukotriene Receptor 1 Deficiency <br />
| CYSLTR1<br />
|-<br />
| Cystic Fibrosis<br />
| CFTR<br />
|-<br />
| Diamond –Blackfan Anemia <br />
| RPS19<br />
|-<br />
| Duchenne Muscular Dystrophy <br />
| DMD<br />
|-<br />
| Dyskeratosis congenita (Male embryos only)<br />
| DKC1<br />
|-<br />
| Ectodermal dysplasia (Hypohidrotic)<br />
| EDA; EDA1; GJB6; IKBKG<br />
|-<br />
| Familial Adenomatous polyposis coli (FAP)<br />
| APC<br />
|-<br />
| Familial Dysautonomia<br />
| IKBKAP<br />
|-<br />
| Fanconi Anemia <br />
| FANCA; FANCC; FANCD2; FANCF; FANCG; FANCJ<br />
|-<br />
| Fragile X Syndrome (FRAX)<br />
| FMR1<br />
|-<br />
| Galactosemia <br />
| GALT<br />
|-<br />
| Gangliosidosis<br />
| GLB1<br />
|-<br />
| Glanzmann Thrombasthenia <br />
| ITGA2B<br />
|-<br />
| Glutaric Acidemia (aciduria)<br />
| GCDH <br />
|-<br />
| Glycogen Storage Disease <br />
| G6PC; GAA; SLC37A4<br />
|-<br />
| Haemophilia A<br />
| F8<br />
|-<br />
| Haemophilia B<br />
| F9<br />
|-<br />
| Hereditary Nonpolyposis Colorectal Cancer: Lynch Syndrome<br />
| MLH1; MSH2; MSH6<br />
|-<br />
| Holt Oram Syndrome<br />
| TBX5<br />
|-<br />
| Huntington Disease<br />
| HD<br />
|-<br />
| Hydrocephalus<br />
| L1CAM<br />
|-<br />
| Ichthyosis <br />
| ABCA12; STS<br />
|-<br />
| Incontinentia Pigmenti (IP)<br />
| NEMO<br />
|-<br />
| Joubert Syndrome 5<br />
| INPP5E<br />
|-<br />
| Krabbe Disease<br />
| GALC<br />
|-<br />
| Leber Congenital Amaurosis (LCA)<br />
| CEP290; GUCY2D<br />
|-<br />
| Leigh Syndrome (Infantile Subacute Necrotising Encephalopathy)<br />
| LRPPRC<br />
|-<br />
| Lesch Nyan Syndrome<br />
| HPRT1<br />
|-<br />
| Leukocyte Adhesion Deficiency (Type I)<br />
| ITGB2<br />
|-<br />
| Li-Fraumeni Syndrome<br />
| TP53<br />
|-<br />
| Macular Dystrophy Retinal <br />
| VMD2<br />
|-<br />
| Maple Syrup Urine Disorder (MSUD)<br />
| BCKDHB<br />
|-<br />
| Marfan Syndrome <br />
| FBN1<br />
|-<br />
| Menkes Syndrome<br />
| ATP7A<br />
|-<br />
| Mitochondrial DNA Depletion Syndrom <br />
| POLG; RRM2B; SUCLA2; TK2<br />
|-<br />
| Mucolipidosis type II<br />
| GNPTAB<br />
|-<br />
| Multiple Endocrine Neoplasia<br />
| MEN1; MEN2A; MEN2B<br />
|-<br />
| Multiple Exostoses<br />
| EXT1; EXT2 <br />
|-<br />
| Myotubular myopathy<br />
| MTM1 <br />
|-<br />
| Nail-Patella Syndrome<br />
| LMX1B<br />
|-<br />
| Neurofibromatosis Type 1<br />
| NF1<br />
|-<br />
| Neurofibromatosis Type 2 <br />
| NF2<br />
|-<br />
| Noonan Syndrome<br />
| KRAS, PTPN11; SOS1<br />
|-<br />
| Norrie Disease<br />
| NDP<br />
|-<br />
| Ocular Albinism <br />
| GPR143<br />
|-<br />
| Oculocutaneous Albinism <br />
| OCA2; TYR <br />
|-<br />
| Oculodentaldigital Dysplasia<br />
| GJA1<br />
|-<br />
| Optic Atrophy<br />
| OPA1<br />
|-<br />
| Ornithine Transcarbamylase Deficiency <br />
| OTC<br />
|-<br />
| Osteogenesis imperfeca <br />
| COL1A1; COL1A2<br />
|-<br />
| Osteopetrosis <br />
| CLCN7; OSTM1; TCIRG1<br />
|-<br />
| Pachyonychia Congenita <br />
| KRT16; KRT6A<br />
|-<br />
| Pancreatitis, Hereditary<br />
| PRSS1 <br />
|-<br />
| Papillorenal syndrome <br />
| PAX2<br />
|-<br />
| Phenylketonuria <br />
| PAH <br />
|-<br />
| This table does not cover the complete list of diseases that PGD can be applied to.<br />
|}<br />
<br />
==Laws & Legal status==<br />
<br />
{|<br />
|-<br />
|Australia<br />
|PGD is currently used to detect serious genetic conditions to improve the outcome of Assisted Reproductive Technologies (ART). In very rare cases it may be used to select an embryo with compatible tissue for a sibling who has a life-threatening disease where other means of treatment is unavailable. This is with the conditions that the use of PGD will not affect the welfare and interests of the child to be born. The parents must also receive adequate counselling and have full understanding of the procedures of PGD. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"> National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art</ref><br />
The use of PGD for sex-selection is prohibited with the exception of reducing the risk of the transmission of serious sex-linked genetic conditions. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"/><br />
|-<br />
|Brazil<br />
|The laws regarding PGD in Brazil are not strictly regulated. They are vague and there is limited information surround the activities of assisted reproduction in general in the country <ref name="PMID25493379"><pubmed>25493379</pubmed></ref>.<br />
|-<br />
|Czech Republic<br />
|The laws in the Czech Republic allow those with a “defined indication in order to exclude risk of serous genetically conditioned disease and defects with embryos before they are implanted into the cavity of the uterus”. Couples that undergo any assisted reproductive treatment including PGD have to be married. Sex-selection is illegal except in regards to serious sex-linked genetic diseases <ref name="PMID24777348"><pubmed>24777348</pubmed></ref>.<br />
|-<br />
|Greece<br />
|In Greece, ART is open to those up to the age of 50 with written consent. It can only be used if a medical necessity is present such as the susceptibility of serious hereditary diseases. Sex selection is banned apart from cases of sex-linked diseases and sexually transmitted diseases <ref name="PMID24777348"/>.<br />
|-<br />
|India<br />
|In India there is a cultural preference for boys thus the Prenatal Diagnostic Techniques (Regulation and Prevention of Misuse) Act was introduced in 1994. This law limits the use of PGD for sex determination except in cases of specific congenital diseases. These laws however are not strictly enforced. <ref>World Health Organisation (2015) Gender and Genetics Retrieved on October 21st 2015 from:http://www.who.int/genomics/gender/en/index4.html<ref/><br />
|-<br />
|Portugal <br />
|ART is only available to those who are married or have a similar type of relationship for at least two years. The couples cannot be of the same sex and must be at least 18 years of age. Sex selection is illegal except in cases of sex-linked diseases. The use of PGD is illegal if the predictive value of genetic tests are very low <ref name="PMID24777348"/>.<br />
|-<br />
|Spain<br />
|PGD can be applied to “serious hereditary diseases not amenable to postnatal curative treatment” and “detection of other abnormalities which may compromise the viability of the pre-embryo”. If PGD is to be used for any other purpose authorisation must be acquired <ref name="PMID24777348"/>.<br />
|-<br />
|Sweden <br />
|The use of PGD is strictly regulated and couples must achieve authorisation of the National Board of Health and Welfare. It can only be used it can only be used if the child is at risk to inheriting a serious chromosomal or monogenetic disease. It cannot be used for selection of specific characteristics <ref name="PMID24777348"/>.<br />
|-<br />
|United Kingdom<br />
|Those involved with carrying out the IVF treatment must have a license from the Human Fertilisation and Embryology Authority (HFEA). Only embryos that are approved by the HFEA can be implanted where the embryonic nuclear or mitochondrial DNA cannot be altered with the exception of preventing mitochondrial diseases <ref name="PMID24777348"/>. <br />
|}<br />
<br />
==Future/Current Research==<br />
===Noninvasive Preimplantation Genetic Testing without Embryo Biopsy===<br />
Different parameters of gametes, zygotes, embryos (“vacuoles in sperm heads, spindle position in mature oocytes, cleavage intervals of zygote, and embryo developmental dynamics”) may correlate with aneuploidy rates. This knowledge may be applied in potential noninvasive preimplantation diagnostic methods. Several methods have been proposed and are currently further researched<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Sperm Selection====<br />
Intracytoplasmic morphologically selected sperm injection (IMSI) is common procedure in IVF treatment to improve fertilization rates in patients with poor semen quality. In addition, studies have found that IMSI improves embryo development and that spermatozoa with large vacuoles in their heads correlate with increased aneuploidy rates and disturbed chromosomal structures. Thus, selecting spermatozoa based on morphological hallmarks may decrease aneuploidy rates in the fertilized embryos. As with polar body biopsies, however, this approach will solely be applicable if evidence for severe male detrimental contribution is given<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Blastocoel Fluid Extraction====<br />
In addition, a less invasive retrieval of material for diagnosis could include the extraction of the blastocoel fluid. The cavity of the blastocyst, lined by the trophectoderm, is filled with this blastocoel fluid, which contains metabolites of both trophectoderm and inner cell mass origin. The retrieval does not require a biopsy but merely a small opening to extract the fluid and, thus, causes less harm to the embryo. Multiple studies have applied this method<ref name="PMID22020776"><pubmed>22020776</pubmed></ref> <ref name="PMID23148560"><pubmed>23148560</pubmed></ref> and it may in the future become of clinical relevance.<br />
<br />
<br />
[[File:Aspiration_of_the_Blastocoel_Fluid.jpeg|thumb|Aspiration of the Blastocoel Fluid using a ICSI pipette<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.]]<br />
<br />
<br />
Next to metabolites, the blastocoel fluid can contain DNA. Studies have shown that genomic DNA is present in about 90% of the blastocoel fluid samples tested. Typically the fluid is removed with an ICSI pipette from a day five blastocyst through its mural trophectoderm until the blastocyst fully collapses around the embryo. Several concerns regarding this method in a clinical setting have been raised. The collected DNA may be contaminated by the culture media that contains DNA fractions. The DNA may also be least representative of the actual embryos genome as the DNA may originate from abnormal or degenerated cells. Even though labelled noninvasive, the blastocyst still undergoes manipulation to some degree which may affect its viability. Thus, more research is required until this method can evolve from research to clinical use<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
====Proteomics====<br />
The protein secretome of blastocysts may be representative of its chromosome constitution Recent studies have found biomarkers such as lipocalin-1, interleukin-10, tumor necrosis factor, stem cell factor, and chemokine ligand 13 to be differently secreted by aneuploid blastocyst than by euploid ones. The most significant biomarker appears to be interleukin-10. Paired with novel proteomic technologies and mass spectrometry this knowledge when extended may contribute to a new invasive preimplantation genetic diagnosis method<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Embryo Morphology====<br />
Using time lapse imaging the embryo’s morphology can be closely observed and potential aneuploidy characteristics detected. Such characteristics may include the time of division to five cells, the time between the division from three to four cells, and the duration of the division from one to two and subsequently to three. In addition, the morphological quality of ICM an TE has been positively associated with aneuploidy or euploidy prognosis<ref name="PMID26246880"><pubmed>26246880</pubmed></ref>. These may give rise to an embryo quality screening prior to implantation<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
==References==<br />
<br />
<references/><br />
<br />
<br />
{{StudentPage2015}}</div>Z5017878https://embryology.med.unsw.edu.au/embryology/index.php?title=User:Z5017878&diff=206969User:Z50178782015-10-21T05:17:42Z<p>Z5017878: </p>
<hr />
<div>--[[User:Z8600021|Mark Hill]] ([[User talk:Z8600021|talk]]) 10:47, 6 August 2015 (AEST) Thanks for setting up your page. We will be talking more about this in the [[ANAT2341_Lab_1_-_Online_Assessment|Practical on Friday]].<br />
<br />
==Lab Attendance==<br />
--[[User:Z5017878|Z5017878]] ([[User talk:Z5017878|talk]]) 13:46, 7 August 2015 (AEST)<br />
<br />
--[[User:Z5017878|Z5017878]] ([[User talk:Z5017878|talk]]) 14:57, 14 August 2015 (AEST)<br />
<br />
--[[User:Z5017878|Z5017878]] ([[User talk:Z5017878|talk]]) 12:51, 21 August 2015 (AEST)<br />
<br />
--[[User:Z5017878|Z5017878]] ([[User talk:Z5017878|talk]]) 12:11, 28 August 2015 (AEST)<br />
<br />
--[[User:Z5017878|Z5017878]] ([[User talk:Z5017878|talk]]) 12:37, 4 September 2015 (AEST)<br />
<br />
--[[User:Z5017878|Z5017878]] ([[User talk:Z5017878|talk]]) 13:24, 11 September 2015 (AEST)<br />
<br />
--[[User:Z5017878|Z5017878]] ([[User talk:Z5017878|talk]]) 14:05, 18 September 2015 (AEST)<br />
<br />
--[[User:Z5017878|Z5017878]] ([[User talk:Z5017878|talk]]) 12:43, 25 September 2015 (AEST)<br />
<br />
--[[User:Z5017878|Z5017878]] ([[User talk:Z5017878|talk]]) 13:55, 9 October 2015 (AEDT)<br />
<br />
--[[User:Z5017878|Z5017878]] ([[User talk:Z5017878|talk]]) 12:03, 16 October 2015 (AEDT)<br />
<br />
==Online Assessments==<br />
<br />
===Lab 1 Assessment===<br />
<br />
'''Relationship of polar bodies morphology to embryo quality'''<br />
<br />
This study was conducted in hopes to find a method to forecast the quality of embryo derived from reproductive technology. 355 patients that were undergoing In-Vitro Fertilisation or Intracytoplasmic Sperm Injection (ICSI) were a part of this study. From these patients 3048 zygotes were extracted and placed into two groups; intact or fragmented. <br />
<br />
The oocyte was extracted 37 to 28 hours after recombinant human chorionic gonadotropin administration followed immediately by the collection of semen sample. The semen sample was then treated and prepared for fertilisation of the oocyte. The zygotes were recruited after 16 to 18 hours and their polar bodies examined and placed into their respective groups based on morphology. The development of the zygotes were then closely studied and graded against systems such as the Istanbul consensus and Gardner's grading system. <br />
<br />
At the conclusion of the study it was deduced that the zygotes with intact polar bodies performed remarkably better than those with fragmented polar bodies. During the third day the intact polar body group had better embryo rates, blastocyst rates and available embryo rates. The pregnancy rate and implantation rate of the two groups however were found to have no differences. <br />
<br />
<ref><pubmed>26198980</pubmed></ref><br />
<br />
'''Microdroplet In Vitro Fertilization Can Reduce the Number of Spermatozoa Necessary for Fertilizing Oocytes'''<br />
<br />
During In vitro fertilisation (IVF) usually a large sample of spermatozoa is needed. In the female body only a few spermatozoa reach the oocyte. This study introduces the idea of micro droplet IVF in hopes of mimicking the in vivo conditions and lowering the amount of spermatozoa needed. Mice were used as the subjects for all the experiments performed and the procedures were conducted using HTF fertilisation medium. <br />
<br />
This study involved several counterparts where each experiment tackled different factors that may affect the microdroplet IVF procedure. The microdroplets conprised of only one microlitre containing either 5, 10, 20 or 50 spermatozoa in comparison to the usual 80 - 500 microlitres. Each of the experiments were replicated four times using spermatozoa from different males and either cyropreserved or fresh samples. The first experiment tested the effects that the cumulus cells, GSH and sperm number, the second on varying numbers of oocytes and spermatozoa, third on the effect of using cyropreserved sperm, the fourth on the effects of using volumes of suspension larger than the optimal for the preparation of the cyropreserved sperm and the fifth was to ensure normal development of embryo. <br />
<br />
The study was deemed successful where as little as 5 spermatozoa could fertilise an oocyte. The rate of success was also found to be heightened depending on factors, for example the presence of cumulus cells was found to be beneficial to the spermatozoa fertilisation rate. Microdroplet IVF could be the alternative pathway for those who have depleted numbers of spermatozoa due to factors such as age, genetic conditions or damages to sperm over time.<br />
<br />
<ref><pubmed>24583808</pubmed></ref><br />
<br />
--[[User:Z8600021|Mark Hill]] ([[User talk:Z8600021|talk]]) 17:02, 3 September 2015 (AEST) These are reasonable summaries of these 2 papers. If you intend to use acronyms, they should be spelt out in full the first time they appear with the acronym then in brackets. (5/5)<br />
<br />
===Lab 2 Assessment ===<br />
<br />
{{Uploading Images in 5 Easy Steps table}}<br />
<br />
[[File:Zona Pellucida and ZPC-ubiquitin.jpg]]<br />
<br />
Zona Pellucida and ZPC-ubiquitin<ref><pubmed>21383844</pubmed>| [http://www.ncbi.nlm.nih.gov/pmc/articles/PMC3044170/]</ref><br />
<br />
PMID 21383844<br />
<br />
--[[User:Z8600021|Mark Hill]] ([[User talk:Z8600021|talk]]) 17:07, 3 September 2015 (AEST) The image has now been uploaded correctly and contains reference, copyright and student template. (5/5)<br />
<br />
===Lab 3 Assessment===<br />
<br />
Here are the articles related to 'Prenatal Genetic Diagnosis':<br />
<br />
<pubmed>24810687</pubmed><br />
<br />
<pubmed>23773313</pubmed><br />
<br />
<pubmed>26201722</pubmed><br />
<br />
--[[User:Z8600021|Mark Hill]] ([[User talk:Z8600021|talk]]) 17:10, 3 September 2015 (AEST) These papers are relevant to Prenatal Genetic Diagnosis. Would have been nice to include a sentence abut each paper though. (5/5)<br />
<br />
===Lab 4 Assessment===<br />
<br />
<quiz display=simple><br />
<br />
{Which ONE of the following is true with regard to the male reproductive system?<br />
|type="()"}<br />
+ The midpiece of spermatozoa is responsible for motility <br />
- The male sex hormone, testosterone is produced by spermatozoa<br />
- Only one spermatozoa has to reach the oocyte for fertilisation to occur<br />
- Spermatozoa primarily use their chemotaxic response to oestrogen to locate the oocyte<br />
||The midpiece of spermatozoa contains a large amount of mitochondria which is responsible for producing ATP to drive motility. <br />
<br />
{Which statement is INCORRECT with regard to the female menstrual cycle:<br />
|type="()"}<br />
+ Gonadotropin releasing hormone is only responsible for signalling the release of luteinising hormone (LH)<br />
- The peak of oestrogen occurs during ovulation <br />
- The female body experiences a rise in temperature during the luteal phase and is an indication of menstruation<br />
- Rising levels of progesterone occur in the luteal phase<br />
||GRH is released by the hypothalamus and is responsible for the release of both LH and FSH in the anterior pituitary.<br />
<br />
{Select the CORRECT statement:<br />
|type="()"}<br />
- Fertilisation usually occurs two thirds down the fallopian tube<br />
- Upon entering the vagina, spermatozoa have up to four days to fertilise the oocyte<br />
+ Spermatozoa contributes to only 10% of seminal fluid upon ejaculation.<br />
- Capacitation is the inactivation of spermatozoa motility<br />
||While 10% of the seminal fluid comprises of spermatozoa, the remaining are contributed from accessory glands (60% seminal vesicle, 10% bulbourethral and 30% prostate). The secretions from these glands provide optimal conditions for the spermatozoa to thrive in. <br />
<br />
</quiz><br />
<br />
[[ANAT2341 Student 2015 Quiz Questions]]<br />
<br />
--[[User:Z8600021|Mark Hill]] ([[User talk:Z8600021|talk]]) 17:15, 3 September 2015 (AEST) You left off the closing quiz code, I have added it above. Q1 is not technically correct as the mid piece provides the energy for motility, not actual motility. You need to also explain in your revealed answer why the other options are incorrect. Q3 first option is not a clear statement 2/3 from which end? (8/10)<br />
<br />
===Lab 5 Assessment===<br />
<br />
'''What is the difference between gastroschisis and omphalocele?'''<br />
<br />
Gastroschisis and omphalocele (also known as exomphalos) are gastrointestinal abnormalities. They are the two most common defects of the anterior abdominal wall where gastroschisis occurs in 2.6 per 10,000 babies and omphalocele occurs in 2.1 per 10,000 babies <ref name="PMID19302857"><pubmed>19302857</pubmed></ref> <ref>Abeywardana, S. Sullivan, EA. (2008) '''Congenital anomalies in Australia 2002-2003''' Birth anomalies series no. 3. Cat. No. PER 41. Canberra: AIHW. Retrieved from: {http://npesu.unsw.edu.au/sites/default/files/npesu/surveillances/Congenital%20anomalies%20in%20Australia%202002-2003.pdf}</ref>. Gastroschisis is usually diagnosed around week 6 of gestation and the mothers are most likely to be under 20, undernourished and are smokers where as omphalocele is usually diagnosed 17 weeks into gestation and occurs predominately in women over the age of 30 <br />
<ref name="PMID23915861"><pubmed>23915861</pubmed></ref> <ref name="PMID22004141"><pubmed>22004141</pubmed></ref>.<br />
<br />
Gastroschisis is a congenital anomaly which affects the abdominal wall, most commonly in the area to the right of the umbilicus <ref name="PMID22004141"/>. It is due to the lack of membranous covering over the wall causing herniation of viscera through the abdominal wall <ref name="PMID17560199"><pubmed>17560199</pubmed></ref>. Gastroschisis is caused by the regression of the omphalomesenteric arteries which connect the yolk sac to the dorsal aorta <ref name="PMID19302857"/>. However factors that also link to its occurrence include failure in mesenchymal differentiation, first trimester vascular accident and use of tobacco and illicit drugs <ref name="PMID17560199"/>.<br />
<br />
Omphalocele on the other hand is the herniation of the abdominal viscera into the base of the umbilicus <ref name="PMID23915861"/>. It is mainly caused by failure to complete lateral body fold migration leading to an open body wall and failure of the intestines to return to the abdominal cavity <ref name="PMID19302857"/> <ref name="PMID23915861"/>. Another cause includes the persistence of the primitive stalk <ref name="PMID23915861"/><br />
<br />
===Lab 7 Assessment===<br />
<br />
'''Identify and write a brief description of the findings of a recent research paper on development of one of the endocrine organs covered in today's practical.'''<br />
<br />
Mechanisms involved in glucocorticoid induction of pituitary GH expression during embryonic development.<br />
<br />
Through the use of chicken embryos the study investigates the pathways in which glucocorticoids undergo to initiate growth hormone in the pituitary during embryo development. The research discovered the pathway namely the ERK1/2 pathway. The ERK1/2 pathway was stimulated by corticosterone treatment, however repetitive stimulation of the pathway was also found to suppress corticosterone thus suppressing the release of growth hormone. Corticosterone is the primary type of glucocorticoid in rodents and birds thus this knowledge was applied to glucocorticoids as a whole and provided the conclusion that the ERK1/2 is a strictly regulated cyclical pathway. <br />
<br />
Somatotrophs are responsible for producing growth hormone in the anterior pituitary. Increased circulation of corticosterone lead to maturation of somatotrophs thus an increase production of growth hormone. The study also used exogenous glucocorticoids and found that it had the same effects. <br />
<br />
PMID 25560830<br />
<br />
'''Identify the embryonic layers and tissues that contribute to the developing teeth.'''<br />
<br />
The embryonic origin of developing teeth are from the ectoderm and mesoderm layers of the trilaminar embryo coupled with neural crest contribution as well. Teeth are primarily derived from two types of cells, the odontoblast and ameloblasts. Odontoblasts are neural crest derived mesenchyme cells. They differentiate under the influence of enamel epithelium to form predentin which later calcifies to form dentin. On the other hand, ameloblasts produce enamel. Growth of teeth occurs in ossifying jaws and the periodontal ligament is responsible for holding the tooth in the bone sockets. <br />
<br />
===Lab 9 Assessment (Peer Reviews)===<br />
<br />
'''Group 1'''<br />
<br />
The entire project is presented simplistically and all the content is relevant and easy to understand. Majority of the flaws I found were based around poor grammar and syntax which could be fixed up with some editing. Below is a more detailed breakdown of some of the things you could fix.<br />
<br />
Firstly, I liked that the introduction was brief and concise and gives the reader a basic understanding of the topic of three person embryo. The video was also informative and provided some background information around the topic. I was informed that mitochondrial DNA was the major factor concerning this topic however there was a lack of information about its importance to the body so a short summary could be included along with some examples of diseases it could cause. <br />
<br />
Also, the use of a timeline to present the history is a great idea and I think it could be improved and would look more aesthetically pleasing if it were to be placed into a table. I also think the 1990s, 2000s and 2010s label could be removed to make it look less clustered since they aren’t particularly necessary. <br />
<br />
Some information under the heading ‘Technical Progression’ has yet to be filled in but from what is there I’d like to suggest exchanging the bullet points for numbering instead for the information under ‘Pronuclear transfer’ and ‘Polar body transfer’ since they sounded like sequence steps as opposed to separate points. <br />
<br />
Finally, I found the layout of the table under the heading ‘Legal status’ to be very well put together. There are however some countries placed under the incorrect continents and I found that the order was easily changed and mixed up. I also noticed that several of the countries were linked to the same sources which made the information very unspecific. Instead of just links I think a few sentences explaining the legislation would be more informative. <br />
<br />
'''Group 2''' <br />
<br />
This wikipage is very well put together. Your choice of headings, subheadings and tables and images is remarkable, it definitely makes the whole page flow very well. I particularly like the hand-drawn image which does a great job at simplifying the process of the pathogenesis of OHSS. <br />
<br />
The introduction very concisely explains the contents of the page and I liked how it was finished off with a statement about the aim of the page. I thought it really brought the introduction together nicely. I can’t say much about the content except that it is very engaging and very well written so well done guys! Keep up the good work!<br />
<br />
Some suggestions I have that could improve your page include adding more images. It would be nice to have some graphs to complement the statistical date from the epidemiology. Also, in some of the paragraphs e.g. in the last paragraph of ‘Epidemiology’ there isn’t a citation that accounts for the information at the end of the paragraph so that should be fixed. <br />
<br />
'''Group 3'''<br />
<br />
First and foremost the PCOS Ovary Vs Non-PCOS Ovary hand drawn image is amazing and its placement at the beginning really drew in my attention to the topic. I also particularly liked the purple theme set up throughout the wikipage, I thought it really helped bring the page together.The headings, subheadings and images are all set out neatly making it very presentable and easy to follow. The language used was also very engaging which is always a plus. Content wise there seems to be sufficient information under most of the headings which really showed your efforts and elaborate research on the topic. The only portion that wasn’t particularly well present was the environmental factors. I felt like it needs the inclusion of some examples. <br />
<br />
To improve your page I would like to suggest the addition of a glossary that you could use to briefly define some terms such as ‘Hirsutism’ to allow a better understanding of the text. Additionally, I also noticed that under the ‘Hyperandrogenemia’ heading there was the use of the acronyms ‘GnRH’ and ‘LH’. Be sure to express the full term placing the acronym in brackets upon their first appearance before extensive use. I saw that this was done in the following paragraph where LH was initially correctly expressed as Luteinising Hormone but again this should be done at its very first appearance. The page also lacked some history surrounding the origin of the disease and how some of the treatments were established so that could also be included. <br />
<br />
Overall, the presentation of the page gave me the impression of a good understanding of the topic so well done guys! Keep up the good work. <br />
<br />
'''Group 4''' <br />
<br />
The wikipage is very well organised and the headings, subheadings and tables made everything easy to follow. I particularly liked the blue theme you kept with all the tables, it is very aesthetically pleasing. In terms of content the background information provided a clear overview of the subject especially the information about the physiology of fertility in males which laid down the foundation some basic knowledge surrounding male fertility under normal circumstances which I found useful in grasping other concepts throughout the page. The page is filled with an extensive amount of content and along with the long list of references I was given the impression of good understanding of the topic and commendable effort placed into the research.<br />
<br />
One thing I found that wasn’t quite compatible with your page was the inclusion of the video in the ‘Causes of infertility section’. Although I do agree that it is a very good video, it had little information surrounding male infertility and was more about infertility in general. Perhaps a video exclusively about male infertility would be more suitable for your page. <br />
<br />
As for some additional improvements, it would be beneficial to include a glossary to explain some difficult terms that would help the audience gain a better understanding of the content. Also, the addition of a hand-drawn image would also be nice. A suggestion would be to exchange your existing ‘components and structure of spermatozoa’ image with a more simplified and schematic diagram of the structure of sperm. <br />
<br />
Overall, I enjoyed reading about male infertility and the page is coming together very nicely.<br />
<br />
'''Group 5''' <br />
<br />
The wikipage looks like it’s progressing very well, especially with the amount of content and references I can safely say you guys have worked hard on it and have done a substantial amount of research so well done guys. I liked the flow chart that you guys inserted, it really simplified the understanding of the IVF procedure as opposed to reading lengthy text. I also particularly liked the collapsible timeline which was presented very nicely and summarised the progress of oncofertility over time very well. <br />
<br />
As for improvements, the references definitely need to be fixed up. There were multiple appearances of the same reference and some of the links also did not work such as reference 24 and 25. On top of that the referencing for the websites were not in a consistent format and some were also done incorrectly so be sure to fix that up. I would also look out for the type of sources used such as webmd and medianews today. I’m not entirely sure if they are reliable or acceptable but I suggest you consult Mark about that. <br />
<br />
Additionally, the use of tables is a very good way of presenting information however, for the tables under the topic of fertility preservation for both men and women I initially though that each of the columns was a comparison against each other. Only later did I realise that each of the columns contained an individual list of treatments. To minimise the confusion I suggest rearranging the table and labelling row 1 as ‘Before treatment’, then row 2 as ‘During treatment’ and finally row 3 as ‘After treatment’ then collectively placing the treatments in their rightful spaces in the following column. <br />
<br />
A glossary is also missing from this page, having the definitions of the more difficult terms would assist with understanding the topic. Also on another note in the ‘Types of Chemotherapy drugs’ section, I think it would look more aesthetically pleasing if bullet points were used rather than the dashes. <br />
<br />
Overall, there is a substantial amount of content, and great use of images, videos and tables. Keep up the good work! <br />
<br />
===Lab 10 Assessment===<br />
<br />
[https://embryology.med.unsw.edu.au/embryology/Slides/Embryo_Stages/Stage22/11/Stage22-11.html?zoom=6&lat=-4224.26847&lon=7932.01847&layers=B Ossicles]<br />
<br />
<br />
===References===<br />
<br />
<references/><br />
<br />
==Test Student 2015==<br />
<br />
===References===<br />
<br />
PMID 26244658<br />
<br />
look at this<ref><pubmed>26244658</pubmed></ref><br />
<br />
Here's the list<br />
<references/><br />
<br />
{{StudentPage2015}}</div>Z5017878https://embryology.med.unsw.edu.au/embryology/index.php?title=2015_Group_Project_6&diff=2065672015 Group Project 62015-10-19T12:20:31Z<p>Z5017878: </p>
<hr />
<div>{{ANAT2341Project2015header}}<br />
<br />
<br />
=Prenatal Genetic Diagnosis=<br />
==Introduction==<br />
==History==<br />
Prenatal Genetic Diagnosis was historically conducted post-implantation in the first 2 trimesters <ref> Blackburn, S.L. (2003) '''Maternal, Fetal & Neonatal physiology: a Clinical perspective''' (2nd ed.). Seattle: Saudners </ref>, testing for overall fetal growth, complications of pregnancy, birth defects as well as chromosomal or genetic abnormalities<ref> Sadler T.W.(2012) '''Langman's Medical Embryology''' (12th ed.) Philadelphia: Lipincott, Wiliams & Wilkins, a Wolters Kluwer Business </ref>. Due to advancements in Artificial Reproductive Technologies ( ART) in the past 2 decades , these genetic tests are now conducted as a part of Preimplantation Genetic Diagnosis (PGD) <ref><pubmed>20638568</pubmed></ref> and art used to eliminate the rsik of passing on a genetic disorder to an offspring, before implantation, it ha now become a preventative measure. . In 1990 Preimplantation genetic testing was first used in 1990 on humans to diagnose recessive X-linked diseases in the embryos of pregnant women undergoing IVF. <ref><pubmed>2330030</pubmed></ref> PGD is offered as an alternative to prenatal diagnosis in detecting genetic disorders in high risk couples <ref><pubmed>26168107</pubmed></ref> and avoid passing an inherited disease to the offspring, by selecting genetically "normal" embryos for implantation ,to give the best chance of successful implantation , stable pregnancies and healthy children. <br />
<ref><pubmed>23499002</pubmed></ref><br />
<br />
==Preimplantation Genetic Diagnosis==<br />
[[File:Preimplantation Genetic Diagnosis Procedure.jpeg|700px|thumb|centre| Simplified steps for PGD]]<br />
<br />
<br />
Preimplantation genetic diagnosis (PGD) is used to test the genetic makeup of embryos to detect single gene disorders, chromosomal abnormalities and mitochondrial disorders. It also has applications in gender selection for diseases with unequal gender distributions <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Some diseases commonly involved with PGD include cystic fibrosis, spinal muscular atrophy and beta – thalassaemia <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press.">Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press</ref> <ref name="PMID17823145"><pubmed>17823145</pubmed></ref>. It was first used in the United Kingdom in the 1980s of arenoleucodystrophy and primarily focusing on sex- linked disorders <ref name="PMID17823145"/><ref name="PMID23150080"><pubmed>23150080</pubmed></ref>. PGD is now capable of detecting single cell defects (molecular) and chromosomal disorders resulting from the inversion, translocation or deletion of chromosomes (cytogenic) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>,<ref name="PMID11325751"><pubmed>11325751</pubmed></ref>. PGD can be applied to the embryo at different stages. That is on polar bodies, blastomeres or blastocyst <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>.<br />
Depending on the type of genetic disorder, PGD utilises different methods of genetic testing. These include Fluorescence in situ hybridisation (FISH) which is used for sex – linked disorders and detects chromosomal rearrangements <ref name="PMID11325751"/><ref name="PMID17876073"><pubmed>17876073</pubmed></ref> and Embryo halotyping which allows the identification of chromosomes causing the inherited disorder through knowledge of the pattern of closely linked markers <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. Polymerase chain reaction (PCR) is also widely used to detect molecular abnormalities <ref name="PMID11325751"/>.<br />
PGD is tightly regulated and supported by large organisations namely The American Society for Reproductive Medicine, The European Society for Human Reproduction and Embryology (ESHRE), The European Society of Human Genetics and the Preimplantation Genetic Diagnosis International Society <ref name="PMID25500181><pubmed>25500181</pubmed></ref>.<br />
===Sex-linked disorders===<br />
The determination of a disease as gender specific usually correlates with the presence or absence of specific genes such as SRY on the Y chromosome. It is known that females have two X chromosomes and males have an X and a Y chromosome where abnormalities are more prevalent on the X chromosome. PGD can be used for sex selection where only male embryos are transferred to reduce the chance of inheriting X-linked disorders. However, this does not completely eradicate the problem as male embryos remain susceptible to inheriting an affected X chromosome. Sex determination is only used when the specific mutation is unknown and has yet to be discovered <ref name="PMID24866878"><pubmed>24866878</pubmed></ref>.<br />
===Single gene defects===<br />
Single gene defects can be dominant, recessive, autosomal or X-linked. They are commonly diagnosed using PCR and although the PCR available today is complex and capable of combatting a large range of disease the development of new protocols has been proven to be difficult due to the small DNA sample available <ref name="PMID26168107"><pubmed>26168107</pubmed></ref><br />
===Mitochondrial disorders===<br />
Mitochondrial disorders also known as oxidative phosphorylation disorders arise from mutations in the nuclear DNA or mitochondrial DNA <ref name="PMID26312584"><pubmed>26312584</pubmed></ref>. They pose as a problem because they are unrecognisable until the mutations in the cell reach a detrimental level <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Mitochondrial disorders cause miscarriages and stillbirths as well as death in children and young adults. The effects can either be contained in a single organ or more commonly involve multiple organ failure where organs with high energy demands such as the brain, liver muscle and heart and heavily influenced. They are usually occur spontaneously or result from inheritance from the mother. Since mitochondria are solely inherited from the mother oocyte donations have been used as a solution to combat mitochondrial disorders. Additionally, there has been an increasing use in PGD where embryos that stay under the given threshold of 18% gene-mutations are allowed to be transferred and result in normal development. New technology in the areas of nuclear gene transfer and genome editing are also being experimented with <ref name="PMID26312584"/>. <br />
===Chromosomal disorders===<br />
Chromosomal disorders can be reciprocal, Robertsonian translocations, inversions, deletions and insertions <ref name="PMID26168107"/>. . Data from ESHRE collected between 2010 and 2011 has shown that the most common chromosomal abnormality confronted in PGD are reciprocal chromosomal abnormalities <ref name"PMID26071418"><pubmed>26071418</pubmed></ref>. PGD has also been used successfully for Robertsonian translocations (RT), a type of structural translocation. Children who carry RT are phenotypically normal, however in their later years it is found that they will suffer from infertility and repeated miscarriages due to the high frequency of abnormal embryos <ref name="PMID22081077"><pubmed>22081077</pubmed></ref>. PCR and FISH are the two main techniques used for chromosomal disorders. To be able to conduct the examinations the cells are required to be at the metaphase stage <ref name="PMID26168107"/>. <br />
==Preimplantation Genetic Screening==<br />
Prenatal Genetic Screening (PGS) involves an array of methods or ideas that aim to segregate embryos that have genetic flaws and those that are healthy <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. The occurrence of aneuploidy is high around the stages of early embryonic development and they are the most common cause if miscarriages and congenital birth defects <ref name= "PMID26085841"><pubmed>26085841</pubmed></ref>. They have little effect on the morphology of the embryo making them difficult to identify thus identification heavily relies on genetic testing <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. <br />
Genetic sampling is most commonly conducted using Microarray Comparative Genomic Hybridisation (aCGH) as well as FISH, Quantitative PCR and Single Nucleotide Polymorphism (SNP) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. These methods collectively aim to assess numeral and structural chromosomal errors <ref name= "PMID26085841"/>. Studies have also introduced Next- Generation Sequencing (NGS) <ref name= "PMID26085841"/> and Whole Genome Amplification used to screen imbalances in the complete 24-chromosomes <ref name="PMID25953353"><pubmed>25953353</pubmed></ref><br />
Statistics from ESHRE have shown that the most common indications for PGS is advanced age, followed by repeated implantation failure or recurrent miscarriage and male infertility <ref name="PMID26071418"><pubmed>26071418</pubmed></ref>.<br />
====Indications====<br />
A low percentage of structural abnormalities in chromosomes are responsible for the cause of miscarriages. Despite this, they are the most prevalent type of chromosomal abnormality accounted for in PGD <ref name="PMID20638568"/>. The presence of specific gene cycles, initiation of embryonic protein synthesis and evident physiological development are all indicative of a successful in vitro fertilisation procedure <ref name="PMID11576737"><pubmed>11576737</pubmed></ref>. To eliminate further errors from occurring during the PGD procedure it is recommended to undertake further prenatal testing such as amniocentesis in the later stages <ref name="PMID20638568"/>. <br />
=====Advanced maternal age=====<br />
Data provided by the ESHRE has shown that the mean age of women undergoing PGS is 39 years <ref name="PMID26071418"/>. Women of advanced age have been shown to have a lower rate of pregnancies reaching childbirth <ref name="PMID18583331"><pubmed>18583331</pubmed></ref>. The highlighted concern revolves around the increased occurrence of aneuploidy following maternal age. The optimal age range for the lowest aneuploidy incidence was found to be between 27 to 37 years of age (6%) then progressively higher in women aged up to 42 (33%) and most common in those 44 and above (53%) <ref name="PMID24355045"><pubmed>24355045</pubmed></ref>. <br />
=====Recurrent pregnancy loss / IVF failure=====<br />
Recurrent pregnancy loss is defined as three or more IVF failures after cumulative transfer of more than 10 good-quality embryos. These are primarily caused by two main factors, reduced endometrium receptivity or embryonic defects. Endometrium receptivity can be negatively influences by instances including uterine pathologies such as thin endometrium, altered expression of adhesive molecules and immunological factors. Additionally, embryonic defects may be due to genetic abnormalities, embryonic aneuploidy or zona hardening. Endometriosis and hydrosalpinx has been known to effect both the endometrium and embryo <ref name="PMID23260857"><pubmed>23260857</pubmed></ref>.<br />
=====Human leukocyte antigen matching=====<br />
First used in 2001, HLA matching is an option given to parents to save a child with haematological or immunological disease through conceiving another child who would potentially be able to donate cord blood or haematopoietic stem cells from the bone marrow for transplantation. The process namely PGD-HLA has shown to improve haematopoietic stem cell transplant (HSCT). PGD-HLA can only be performed when HSCT is not needed urgently due to the time needed to conceive and delivery the baby <ref name="PMID25500181"><pubmed>25500181</pubmed></ref>. It is most commonly applied to children suffering from relapsed leukaemia <ref name="PMID22524201"><pubmed>22524201</pubmed></ref>. In a case study PGD-HLA was proven to successfully cure 10 diseases including Fanconi anaemia, Diamond-Blackfan anaemia and beta thalassemia <ref name="PMID25066893><pubmed>25066893</pubmed></ref>.<br />
==Biopsy Methods==<br />
Biopsy, the removal of genetic materials, from oocytes or embryos in the preimplantation stage is the primary step in PGD. For the past two decades these biopsies have been performed at three stages, the polar body, blastomere, and blastocyst, and the methodologies optimized to ensure the embryo’s viability. The most common approach involves biopsies at the cleavage stage. However, polar body and blastocyst biopsies are increasingly more often tested and applied. Approached for opening the zona pellucida involve next to the traditional mechanical and chemical means, novel approaches such as noncontact lasers. Their application may simplify and secure the procedure significantly. The most challenging question about PGD procedures remains at what stage biopsies should be taken. Much controversy has developed around this topic, highlighting the varying disadvantages and advantages of temporal biopsies. <ref name="PMID22723007"><pubmed>22723007</pubmed></ref><br />
<br />
{|border="1" align="left"<br />
|-bgcolor="pink" <br />
|<br />
| Time of Biopsy<br />
| Advantages <br />
| Disadvantages<br />
|- <br />
| Polar Body<br />
| Day 1<br />
| No harm to oocyte<br />
| Only maternal DNA is tested, often needs to be coupled with other biopsies<br />
|-bgcolor="pink"<br />
| Blastomere<br />
| Day 3<br />
| …<br />
| … <br />
|-<br />
| Trophectoderm<br />
| Day 5 and 6 <br />
| Little harm, large amount of genetic material<br />
| Opening of blastocyst necessary, small time window for procedure<br />
|}<br />
<br />
{|border="1"<br />
| [[File:Polar_Body,_Blastomere,_and_Trophectoderm_Biopsy.jpeg]]<br />
|-<br />
| Polar body (A), blastomere (B) and trophectoderm (C) biopsies<ref name="PMID25625041"><pubmed>25625041</pubmed></ref>.<br />
|}<br />
<br />
PMID 24305177<br />
===Polar Body Analysis===<br />
Day 1<br />
====Description====<br />
Polar body (PB) biopsy, which was introduced in 1990, offers a promising alternative to biopsies performed at the blastomere stage for PGD/S indications on legal and practical grounds. <br />
Description: Consequent embryo development does not necessitate the presence of the first and second PB and their removal may not be crucial. PB biopsy requires precise timing. Keeping track of the meiotic cell cycle is necessary to perform a successful biopsy and, therefore, PB biopsy usually is applied in combination with intracytoplasmic sperm injection (ICSI). During the maturation from the germinal vesicle stage to the metaphase-II stage the first PB is formed. A cytoplasmic bridge containing spindle remnants, that are still in contact with the cellular genetic material, links this PB to the oolemma for about 90 minutes after extrusion. It is possible to visualize these remnants by polarization microscopy and it is crucial to not perform the biopsy until the first PB is no longer firmly attached to the oolemma as this indicates an immature embryo.The oocyte tolerates mechanical zona dissection best during hours four until six after ICSI as the oolemma has stabilized by that time because of the cortical granule reaction. Over time the first PB degenerates stressing a temporal biopsy and its optimal extraction time window is four to 12 hours after ICSI. The second PB forms around two to four hours after ICSI. However, its optimal time window for biopsy is set to be eight to 16 hours after ICSI. This is due to the second PB being attached to the oolemma with spindle remnants until six hours after ICSI. Biopsy at this point may cause enucleation of the oocyte. In addition, studies have shown that the amplification efficiency of second PB’s DNA is worse if the PB is extracted prior to eight hours after ICSI. <br />
Thus, it is possible to perform sequential and simultaneous biopsies for the first and second PB. If performed, sequentially the first PB may be removed four to 12 hours and the second PB eight to 16 hours after ICSI. The optimal time window for a biopsy for both the first and second PB simultaneously is eight to 12 hours after ICSI. It is highly preferred to analyze both PBs due to potential aneuploidies in either PB and crossing overs during meiosis<ref name="PMID22723007"/>. <br />
====Procedure====<br />
Chemical opening achieved with for example acidic tyrode’s solution of the zona pellucida is not tolerated by the oocyte and may have detrimental effects on the embryo’s development. Therefore, the access to the perivitelline space of the oocyte is provided by mechanical zona dissection or by laser. Both techniques work well if performed by experienced embryologist. However, laser-assisted biopsy is less time consuming when compared to manual dissection. It is critical to consider the size of the introduced opening as it will remain permanent. If it is too large the blastomere may be lost during embryo development and if it is too small it may interfere with hatching of the embryo during blastocyst stage<ref name="PMID22723007"/><br />
<br />
{|border="1"<br />
| [[File:Polar_Body_Biopsy.jpeg]]<br />
|-<br />
| The presence of a faint but clearly identifiable strand connecting PB2 to the <br />
oolemma. The biopsy was performed ∼9 h after ICSI<ref name="PMID21908464"><pubmed>21908464</pubmed></ref>.<br />
|}<br />
<br />
{|border="1"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JTaQzszVr8o</html5media><br />
|-<br />
| Laser-assisted polar body biopsy<ref>RIUK, R. (2013, June 25) Polar Body Biopsy [Video file]. Retrieved from https://www.youtube.com/watch?v=JTaQzszVr8o</ref><br />
|}<br />
<br />
====Advantages & Disadvantages====<br />
PB biopsies can only investigate the maternal contributions to the embryo as they are of maternal origin. Thus, this procedure is appropriate for PGD solely for monogenetic diseases from the maternal side. Recessive diseases may be evaluated with PB biopsies on the basis that the embryo’s outcome will be determined by the paternal contribution. (...) It may still be applied for PGS as most aneuploidies either arise during meiosis or origin from the maternal genome. However, diagnosis error has been reported due to the lack of considering paternal contributions. <br />
Because PB biopsies are performed very early it is not yet known whether the oocyte will develop into a viable embryo. Thus, PBs are commonly frozen or fixed after biopsy and depending on the state of the embryo only chosen PBs will be tested. This is primarily an economic issue as many genetic testing procedures are very cost-intensive<ref name="PMID22723007"/>.<br />
<br />
{|border="1"<br />
| [[File:Implantation_predictive_value_of_euploid_screening_results.jpeg]]<br />
|-<br />
| The sustained implantation predictive value (with 95 % confidence interval) of a euploid screening result obtained from the first polar body (PB1), PB1 and the second polar body (PB2), or a direct embryo biopsy for each stage of embryo transfer (cleavage-stage and blastocyst stage)<ref name="PMID25106935"><pubmed>25106935</pubmed></ref>.<br />
|}<br />
<br />
===Blastomere biopsy===<br />
Day 3 <br />
====Description====<br />
Blastomere biopsy has been the prevalent method for PGD and PGS in the last two decades. At least one, but up to two, blastomeres are biopsied on day three of the cleavage stage embryo. The right number of blastomeres removed is a controversial topic as two cells allow for more genetic material and more accurate results. However, removing two cells might be too invasive and damaging to the embryo. (Study)<ref name="PMID21748341"><pubmed>21748341</pubmed></ref><br />
====Procedure====<br />
Initially a hole was drilled into the zona pellucida using acid tyrodes and the blastomeres are removed via aspiration with a pipette<ref name="PMID21748341"/>.<br />
<br />
{|border="1"<br />
| [[File:Aspiration_of_a_Blastomere.jpeg]]<br />
|-<br />
| Aspiration of a Blastomere into the biopsy pipette<ref name=" PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
|}<br />
<br />
{|border="1"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=TbridWVwipI</html5media><br />
|-<br />
| Laser-assisted blastomere biopsy<ref>Sukprasert, M. (2014, March 5) Day 3 Blastomere Biopsy 1 [Video file]. Retrieved from https://www.youtube.com/watch?v=TbridWVwipI</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
===Trophectoderm biopsy===<br />
Day 5 and 6<br />
====Description====<br />
The improvement of embryo culture media allowed the in vitro development of human embryos until the blastocyst stage and opened up the possibility to take blastocyst biopsies. During day three to day five the haploid maternal and paternal genomes work together for the first time to form the genome of the embryo. The maternal epigenetic control lessens significantly while preparing for implantation with precisely arranged events happening. The first event includes a rapid increase in the number of embryonic cells which are active in mitotic divisions and apoptosis of aberrant cells. This is followed by the formation of blastocoel (cavitation) which results from the flattening of cell located on the outside of the blastomere. Now the blastocyst will expand until the embryo hatches by rupturing the zona pellucida. The cells of the blastocyst will differentiate to form two distinct cell lineages, the outer trophectoderm and the inner cell mass<ref name="PMID22723007"/>.<br />
====Procedure====<br />
Trophectoderm biopsy is usually performed in Hepes buffered biopsy medium and opening approaches include needle cutting which has been replaced by lasers in past years. Different research groups report different timings of the opening to be the most successful. Some open the blastocyst on day three or four by creating a 25 µm which causes the trophectoderm to herniate through this hole and is, thus, accessible for biopsy. Others create this hole about four hours before biopsy which allows sufficient herniation of trophectoderm cells. It is also possible to open the blastocyst immediately before biopsy. This avoids an extra step and the inner cell mass usually is easy to locate. Blastocyst biopsies involve the removal of trophectoderm cells and the ideal time for the procedure is day five. Successful biopsies on day six have been performed, while little is known about the results of biopsies on day seven. However, since the window of implantation in humans is from day eight to ten after ovulation, day seven biopsies appear to be possible<ref name="PMID22723007"/>.<br />
-collapse of trophoblasts<br />
-possible: biopsy of hatched blastocyst, holding pipette careful mild suction force to hold embryo near ICM <br />
-Cryopreservation<br />
<br />
{|border="1"<br />
| [[File:Microscopic images of human blastocysts for biopsy.jpeg]]<br />
|-<br />
| (A) Some trophectoderm cells in a blastocyst started to hatch and (B) the trophectoderm cells were biopsied with assisted laser cutting. Images in C–D show the blastocysts after vitrification and warming. Blastocysts had been cultured for 2–4 hrs after warming, showing good (ICM and trophectoderm cells) hatched (C) and hatching (D) blastocysts. The hatching blastocyst in (E) has good ICM but fair trophectoderm while the blastocyst in (F) has both fair ICM and trophectoderm. Arrows indicate ICMs and arrow heads indicate trophectoderm cells. Bar = 40 µm<ref name="PMID2190846"><pubmed>2190846</pubmed></ref>.<br />
|}<br />
<br />
<br />
{|border="1"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JI_TQ8d8tNM</html5media><br />
|-<br />
| Laser-assisted blastocyst biopsy (at 00:50 min)<ref>Coco, R. (2014, April 30) Trophectoderm biopsy in a Hatching blastocyst protruding ICM [Video file]. Retrieved from https://www.youtube.com/watch?v=JI_TQ8d8tNM</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
Blastocyst biopsies are believed to be less damaging to the embryo and appear to be unrelated to implantation rates. In addition, this biopsy method allows for a larger extraction of cells for genetic testing. However, since they are performed late in in vitro development, the time window for genetic testing is relatively small. Fast and accurate genetic testing methods are needed to ensure a successful and safe result from this biopsy. Thus, blastocyst biopsies may gain more popularity in the future whn such methods have been developed or improved<ref name="PMID22723007"/>. <br />
<br />
<br />
==Genetic Techniques==<br />
<br />
===PCR===<br />
====Description====<br />
Polymerase chain reaction (PCR) amplifies DNA specific to genetic sequence of interest . PCR was developed by Kay Mullis in the 1980s, for which he was awarded the Nobel prize for chemistry in 1993. <ref> Pubmed Docs (2015) Polymerase Chain Reaction (PCR) Pubmen. Retrieved from [http://www.ncbi.nlm.nih.gov/probe/docs/techpcr/]</ref> This technique enables clinicians to monitor and diagnose diseases using minute samples such as embryonic cells, blood & tissue. <ref>Roche (2015) PCR: How We Copy DNA. Roche Molecular Systems Inc. retrieved From [http://molecular.roche.com/pcr/Pages/Process.aspx]</ref> PCR has many important applications like DNA fingerprinting, genetic mapping, detection of viruses and bacteria as well as being used to detect genetic disorders, as a part of PGD, in conjunction with IVF. It is used to detect molecular abnormalities such as single gene disorders like Tay Sach, Cycstic fibrosis, Duchenne Muscular Dystrophy, Thalassemia, Huntington disease, Spinal muscular atrophy and many more. Molecular and Genetic analysis require a significant amount of DNA, which we would not have without PCR. It revolutionized the study of DNA, replacing all previous recombinant DNA technology. <ref> Mullins, K., Francois, F.& Gibbs R.A. (1994 ) The Polymerase Chain Reaction. p3. Springer- Science +Business Media. Birkhauser, Boston<br />
Available at [https://books.google.com.au/books?hl=en&lr=&id=gjrTBwAAQBAJ&oi=fnd&pg=PR5&dq=kary+mullis+PCR&ots=mpzAyRh5ZY&sig=PQ4goNoKJ90tb3-MkPk62zrTGbw#v=onepage&q=kary%20mullis%20PCR&f=false] </ref> <br />
<br />
====Procedure====<br />
<br />
Sample are obtained from the the blastocyst, a polar body biopsy or the blastomeres stages of the embryo. <br />
Stage 1 Denaturing: separating the target strands of DNA <br />
The obtained sample is heated to roughly 90 degrees celcius, this heat causes breaks the relatively weak bonds between nucleotides that form DNA. the double stranded DNA to split into 2 single strands of DNA that are used as templates.<br />
Stage 2 Annealing: Binding the Primers to the target DNA sequence <br />
PCR will only copy the target sequence of DNA specified by specific PCR primer. These synthesized primers Oligonucleotides are small artificial pieces of DNA. <br />
TAQ polymerase enzyme synthesize 2 new strands of DNA duplicate to the single sample DNA stand template indicated by these primers. During this stage the reaction is cooled to a temperature between 40-60 degrees Celsius. <br />
Stage 3- Extension- making copies <br />
Each of these 2 copies are then used again as templates generating 2 further replications This cycle can occur as many 30 -40 times within a couple hours leading to billions of extra copies of the original DNA segment. The optimal temperature for the further replication is roughly 72 degrees Celsius. <br />
<br />
This process mediated by a thermocycler machine that is programmed to alter the temperature of the reaction every couple of minutes, perpetuating the cycle of DNA denaturing and synthesis. <br />
This process, generates exponential exact copy of the original template DNA sequence. <br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
!PCR cycles<br />
<br />
|{|<br />
|-bgcolor="lightpink"<br />
| '''PCR Cycle'''<br />
| '''Target Copies'''<br />
|-<br />
| 1<br />
| 2<br />
|-bgcolor="pink"<br />
| 2<br />
| 4<br />
|-<br />
| 3<br />
| 8<br />
|-bgcolor="pink"<br />
| 4<br />
| 16<br />
|-"<br />
| 5 <br />
| 32<br />
|-bgcolor="pink"<br />
| 6 <br />
| 64<br />
|-<br />
| 7 <br />
| 128<br />
|-bgcolor="pink"<br />
| 8<br />
| 256<br />
|- <br />
| 9<br />
| 512 <br />
|-bgcolor="pink"<br />
| 10<br />
| 1024<br />
|-<br />
| 15<br />
| 32,768<br />
|-bgcolor="pink"<br />
| 20 <br />
| 1,048,578<br />
|-<br />
| 25<br />
| 33,554,432<br />
|-bgcolor="pink"<br />
| 30 <br />
| 1,073,741,842<br />
|-<br />
|}<br />
<br />
<br />
<br />
<br />
{|border="1" align="center"<br />
|-bgcolor="pink" <br />
| '''Advantages''' <br />
|'''Disadvantages'''<br />
|- <br />
| fast and inexpensive way of copying a target sequence of DNA<br />
| only during this exponential DNA replication phase can we determine the starting quantity sequence contained in the original sample ( template DNA strand)<br />
|-bgcolor="pink"<br />
| aids the diagnosis of single cell defects<br />
| PCR reaction is limited by the presence of inhibitors present in the sample : reagent inhibitors <br />
|-<br />
| rapid generation of results within a couple hours<br />
| self annealing due to the accumulation of the product -stopping exponential amplification for the target sequence and reach a plateau<br />
quantification of the end point of reaction of PCR products unreliable - therefore that is why we require real time quantitative RT-PCR necessary<br />
<ref> NIS (2015) Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref><br />
|-bgcolor="pink"<br />
| can start from a single molecule of DNA, therefore is more sensitive <br />
| <br />
|-<br />
| has a flexible primer design enabling<br />
| <br />
|-bgcolor="pink"<br />
| overcame previous issues associated with the limited availability of sites of end<br />
| <br />
|-<br />
| generates the DNA copies exponentially<br />
| <br />
|-bgcolor="pink"<br />
| enables DNA amplification required for molecular and genetic analysis<br />
| <br />
|-<br />
|Valid diagnostic method in selecting unaffected embryos for embryo transfer <ref> Dreesen, J., Drusedaul, M., Smeets, H., Die-Smulders, C., Coonen, E., Dumoulin, J., Gielen, M., Evers, J., Herbergers, J. & Geradets, J. (2008) Validation of preimplantation genetic diagnosis by PCR analysis: genotype comparison of the blastomere and corresponding embryo, implications for clinical practice. Mol. Hum. Reprod. 14 (10):573-579.doi: 10.1093/molehr/gan052. Retrieved from [http://molehr.oxfordjournals.org/content/14/10/573.short] </ref> <ref><pubmed>20966460</pubmed></ref><br />
|<br />
|}<br />
<br />
<br />
<br />
<br />
<br />
<br />
<br />
<br />
<br />
===Fluorescent In Situ Hybridisation (FISH)===<br />
<br />
<br />
====Description====<br />
Fluorescence in situ hybridization (FISH) the one of the most effective and rapid <ref name="PMID26338801"><pubmed>26338801</pubmed></ref> Preimplantation Genetic Diagnosis (PGD). This techniques used to locate a specific DNA sequences within a chromosome. FISH facilitates the clinical diagnosis of chromosomal abnormalities indicated by sequential duplications, deletions and rearrangements of chromosome, that are usually missed with microscopic analysis. This technique is especially relevant for female embryos with X-linked diseases,<ref><pubmed>20809319</pubmed></ref> that have no other mutation specific tests [http://www.ncbi.nlm.nih.gov/pubmed/20809319] As part of PGD, samples are collected from various stages of the embyro,and they are able to conducted tests on the blastocyst, a polar body biopsy and the blastomeres <ref><pubmed>21748341</pubmed></ref>. FISH is 99% effective when used in conjunction with competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities<ref name="PMID26338801"/>.<br />
<br />
====Procedure==== <br />
<br />
Samples are collected from either the blastocyst, a polar body biopsy or the blastomeres stages of the embryo <ref><pubmed>21748341</pubmed></ref>. <br />
DNA strands are heated and denatured causing their the individual DNA strands to break apart<br />
Probes are single complimentary stands of DNA a that have been tagged with small chemical agents that glow brightly in the presence of a specific region on a chromosome. These specific probes then hybridize and join to their complementary DNA strand. <br />
The fluorescent tags enable the researchers to correctly identify the presence or lack thereof and location of the specific chromosomes that they are testing for. <ref><pubmed>17876073</pubmed></ref><br />
Researcher analyse the results by identifying the number and the relative location of the fluorescent dots generated by the FISH images.<ref><pubmed>17970921</pubmed></ref><br />
The probe will not fully hybridise if there has been a duplication or a deletion of the DNA - indicating chromosomal and sex chromosomal anomalies like trisomies and aneuploidies. <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref><br />
<br />
<br />
Different probes are used for different purposes: <ref>Unique, Rare Chromosome Disorder Support Group (2013) Fluorescence in situ hybridisation (FISH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/Other/FISH%20FTNW.pdf]</ref><br />
*'''Locus specific tags''' detect very small imbalances, and locate isolated small portions <br />
of genes within a chromosome<br />
*'''Alphoid/Centomeric Repeat probes''' are developed from the repetitive sequence located in the middle region of each chromosome, useful in determining the number of chromosomes , detecting rearrangement and when used in conjunction with locus probes to determine the absence of genetic material on a chromosome. <br />
*'''Paint Probes''' are collections of smaller probes with their own stains that bind to a different section on the chromosome - allowing the full chromosome too be labeled a unique colour, this "full colour map" can be used to know the spectral karyotype- full chromosomal mapping is useful in examining chromosomal abnormalities. <br />
<br />
{|border="1" <br />
| [[File:Fluorescent In Situ Hybridisation (FISH).jpg|thumb|right|'''FISH''' We are able to tag Specific DNA sequences using Probes which have been tagged with fluorescent Labels.This technique enables the clinical diagnosis of chromosomal abnormalities, indicated by sequential duplication, deletions and rearrangements of chromosome <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref>]]<br />
|}<br />
<br />
<br />
<br />
{|border="1" align="center"<br />
|-bgcolor="pink" <br />
| rowspan="8" |'''Advantages''' <br />
|-bgcolor="#FDE1F2" <br />
| FISH is 99% effective when used in conjunction with Competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities.<ref><pubmed>26338801</pubmed></ref><br />
|-bgcolor="#FDE1F2" <br />
| Rapid generation of results<br />
|-bgcolor="#FDE1F2" <br />
| Identifies very small translocations and aneuploidies that occur within chromosomes, that would usually be missed under microscopic analysis<br />
|-bgcolor="#FDE1F2" <br />
| Indicates whether the accessed chromosomes are normal <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|-bgcolor="#FDE1F2" <br />
| Tests for the most common chromosomal abnormalities - down syndrome chromosomes 13,16,18,21 and 22 <ref><pubmed>21749752</pubmed></ref><br />
|-bgcolor="#FDE1F2" <br />
| It may be used to compare the chromosomal gene arrangements in related species<br />
|-bgcolor="#FDE1F2" <br />
| can be used to identify and remove inheritable X-linked disease or sex chromasome anomalies such as Duchennes Muscular Dystrophy, hemophilia, ectodermal dysplasia <ref><pubmed>17876073</pubmed></ref><br />
|-bgcolor="#FEB745"<br />
| rowspan="5"|'''Disadvantages'''<br />
|-bgcolor="#FE1C5EA"<br />
| FISH destroys all cells tested <ref> O'Connor, C. (2008) Fluorescence in situ hybridization (FISH). Nature Education 1(1):171. retrieved from [http://www.nature.com/scitable/topicpage/fluorescence-in-situ-hybridization-fish-327] </ref><br />
|-bgcolor="#FE1C5EA"<br />
| It does not fully access all chromosomes (only ~ 12)<br />
|-bgcolor="#FE1C5EA"<br />
| Analysis of results is dependent upon the dot quality impacted by hybridisation efficiency or the camera sensitivity <ref><pubmed>17970921</pubmed></ref><br />
|-bgcolor="#FE1C5EA"<br />
| some studies indicate that using FISH on a day-3 embryo biopsy decreases the rate of live births <ref><pubmed>26168107</pubmed></ref><br />
|}<br />
<br />
<br />
<br />
===Array Comparative Genomic Hybridisation (aCGH)===<br />
====Description====<br />
<br />
aCGH also known as Microarray analysis efficiently scans the entire genome for chromosomal imbalances. CGH was initially developed to detect the number of changes in a solid tumor mass. It uses 2 genomes comparing the sample to the control, with each labeled in a different fluorescent dye<ref><pubmed>1876176</pubmed></ref>. Earlier CGH techniques were limited by the resolution of the imaging <ref> Lichter, P., et al. Comparative genomic hybridization: Uses and limitations. Seminars in Hematology 37, 348–357 (2000)</ref> , these initial limitations were overcome by using Microarrays in conjunction with CGh to improve the resolution of the imaging, Array Comparative Genomic Hybridisation (aCGH). This method compares sample and control microarrayed slides containing small segments of DNA (probes). <ref> Lucito, R., et al. Representational oligonucleotide microarray analysis: A high-resolution method to detect genome copy number variation. Genome Research 13, 2291–2305 (2003) </ref> the Probes used will vary according from the small (25-85 base pairs) oligonucleotides manufactured to highlight different target sequences, to the very large genomic clones (80,000- 200,00 base pairs), and as these are significantly smaller than the traditional metaphase chromosomes used for CGH, generating a higher resolution of image. <ref><pubmed>22467166</pubmed></ref>.aCGH is used as a diagnostic tool for prenatal detection f chromosomal abnormalities <ref><pubmed>19012303</pubmed></ref>.<br />
<br />
<br />
====Procedure====<br />
<ref> Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432] </ref><br />
The sample is obtained (skin, blood or fetal cells) and DNA is obtained. <br />
As a part of PGD fetal cell samples are collected from; the fertilized egg polar bodies, the blastomere (day 3 embryo) or the blastocyst/tropoectoderm stage (day 5 embryo).<br />
Sample DNA is labeled with one fluorescent dye, and the control DNA is labeled with a different colored fluorescent dye. the control DNA is used as the base point of reference. <br />
heated and denatured single DNA strands then hybridize to their complementary single strand probes, which are then combined and applied to a microarray and the results are run through a computer program and a digital imaging system is used to quantify the results( fluorescent intensities of the labeled probes). <br />
<br />
simple explanation of aCGH : [Genomics Education (2014) Genetic Testing for Health: aCGH|https://vimeo.com/84757281]<br />
<ref>Genomics Education (2014) Genetic Testing for Health: aCGH [video file] Vimeo [https://vimeo.com/84757281]</ref><br />
<br />
<br />
The fluorescent ratio and the hybridization signal at different locations on the genome of the control DNA are used to identify any variances present in the sample DNA. aCGH facilitates the clinical diagnosis of submicroscopic chromosomal duplication, deletion and rearrangements indicative of chromosomal disorders such as trisomies 1-22and specific sex linked disorders. <br />
Duplications in the DNA are displayed by the computer program as spikes/ peaks over an established threshold and deletions in DNA are displayed by the computer program as spikes/ toughs beneath this threshold <br />
-computer screening image- <br />
-drawn diagram of method-<br />
<br />
<br />
<br />
{|border="1" align="center"<br />
|-bgcolor="pink" <br />
| '''Advantages''' <br />
| '''Disadvantages'''<br />
|-<br />
| multiple applications: prenatal genetic diagnosis, cancer diagnosis, <ref><pubmed>20193845</pubmed></ref> genetic screening for developmental delay (learning disabilities) <ref><pubmed>17309648</pubmed></ref>. or congenital anomalies that are suspected to be genetic in origin <ref>NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation . retrieved from [http://www.phgfoundation.org/file/5237/]</ref><br />
| translocations and inversions of DNA are not detected<br />
|-bgcolor="pink"<br />
| trace represents all chromosomes present in the human genome chromosomes 1-22 and the X & Y chromosomes, and therefore is the most accurate method for testing whole embryo aneuploidy<br />
| limited ability diagnosing specific polyploidies such as triploidy <ref> Unique, Rare Chromosome Disorder Support Group (2013) Microarray-based Comparative Genomic Hybridiation (array CGH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/other/array%20cgh%20ftnw.pdf] </ref><br />
|-<br />
| aCGH has been extensively tested, and Validated, and is now used world wide.<br />
| will not detect mosaicism detection <20% (cultures where >1 of 5 cells are trisomy 12)<br />
|-bgcolor="pink"<br />
| detects deletions and additions and rearrangements as well as amplification, of the WHOLE genome, simultaneously.<br />
| will not detect balanced chromosomal rearrangement<br />
|-<br />
| detects submicroscopic alterations<br />
| will not detect duplications or deletions <80kb<br />
|-bgcolor="pink"<br />
| used as a diagnostic tool for prenatal detection of chromosomal abnormalities <ref><pubmed>22034057</pubmed></ref><br />
| will not detect point mutations within genes <ref>Washington department of education (CGH- FAQ for physicians. Signature Genomic LAboratories, LLC. Retrieved from [https://depts.washington.edu/dbpeds/Lab%20Tests/SignatureCGH-physician_FAQ.pdf]</ref><br />
|-<br />
| provides high resolution genomewide screening of segmental genomic copy number variations<br />
| will not detect chromosomal position of genomic gains<br />
|-bgcolor="pink"<br />
| very accurate when used in conjunction with FISH<br />
| will not detect loos of heterozygosity (LOH) or Absence of heterozygosity (AOH) <ref>WiCell Research Institute Inc. (2012) Comparative Genomic Hybridization Microarray. <br />
retrieved from [http://www.wicell.org/home/cytogenetic-services/cgh-microarray/array-comparative-genomic-hybridization-acgh.cmsx]</ref><br />
|-style="background:pink"<br />
|Alone is more reliable and in detecting chromosomal abnormalities, with a higher implantation success rate, than FISH <ref><pubmed>20494259</pubmed></ref><br />
|<br />
|-bgcolor="pink"<br />
|Allows an in depth research focus upon specific types of rearrangements within selected chromosomal regions, a recent particular area of interest is subtelomeric and pericentromeric rearrangements<br />
|<br />
|-<br />
|reduces the risk of failed implantation and miscarriage, improving the chance of a healthy baby <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|<br />
|}<br />
<br />
<br />
<br />
===Next Generation Sequencing===<br />
====Description====<br />
The development and advances within ART in the past 20 years, as well as the increasing popularity of IV, has lead to an influx of new technologies developed to screen embryos for chromosomal anomalies, which are covered by the umbrella term of Next generation Sequencing (NGS). NGS is a general term used to describe all of the new and emerging screening techniques currently being introduced and used as part of PGD for IVF . NGS screens for single gene disorders as well as conducting extensive and very comprehensive chromosome diagnosis by sequencing, counting, and accurately assembling millions of DNA reads, simultaneously. <ref><pubmed>23499002</pubmed></ref> There is a movementfor NGS to replace the other limited testing techniques and be used as the standard. <br />
====Procedure====<br />
Samples are collected from either blastomere or the blastocyst/tropoectoderm and processed for analysis by a computer system. <br />
The methodology of each process is unique to the technique being used. <br />
<br />
<br />
<br />
{|border="1" align="center"<br />
|-bgcolor="pink" <br />
| '''Advantages'''<br />
| '''Disadvantages'''<br />
|-bgcolor="white"<br />
| cheaper<br />
| there are limited information available to clinical applications of NGS <ref><pubmed>26100406</pubmed></ref><br />
|-bgcolor="pink"<br />
| opens new diagnostic possibilities<br />
|<br />
|-bgcolor="white"<br />
| accurately tests all 24 chromosomes<br />
| <br />
|-bgcolor="pink"<br />
| tests for the presence of monogenic diseases of known genetic background<br />
| <br />
|-bgcolor="white"<br />
| reduces the number of biopsies required for diagnosis<br />
| <br />
|-bgcolor="pink"<br />
| higher detection rate of small translocations<br />
| <br />
|-bgcolor="white"<br />
| highly accurate is testing for compound point mutations, chromosomal duplication, deletions and insertions <ref><pubmed>23312231</pubmed></ref><br />
| <br />
|-bgcolor="pink"<br />
| it accurately detects chromosomal aneuploidy and unbalanced rearrangement <ref><pubmed>25685330</pubmed></ref><br />
| <br />
|-bgcolor="white"<br />
| NGS single gene disorder screenings can conducted in conjunction with PCR comprehensive chromosomal screening<br />
|<br />
|-bgcolor="pink"<br />
| Reduces human error <br />
|<br />
|-bgcolor="white"<br />
| better detects the presence of mosaicism<br />
|<br />
|-bgcolor="pink"<br />
| work well in conjunction with CGH and aCGH as part of PGD, improving the chances of IVF. <ref> Morris, R. S. (2015 ) Next generation sequencing for PCG|PGS|CCS. IVF1 retrieved from [http://www.ivf1.com/next-generation-sequencing for-pgd] </ref><br />
|<br />
|}<br />
<br />
<br />
<br />
<br />
<br />
<br />
==Diagnosis==<br />
There are a large amount of diseases that PGD can apply to, below are descriptions of the diseases that PGD are more commonly used for. <br />
===Cystic Fibrosis===<br />
Cystic fibrosis is a single gene disorder. It is autosomal recessive and involves mutations in the cystic fibrosis transmembrane conductance regulator (CTFR) gene. The CTFR gene is normally responsible for the decrease in chloride and the transport of bicarbonate in epithelial cells thus playing a major physiological role. In PGD procedures, identification of the gene is assisted by microsatellite markers that have similar composition to the CTFR gene itself. Biopsy of two cells at the blastocyst stage is recommended if markers are not available. There are many variations of cystic fibrosis the most common being P.Phe508del <ref name="PMID26014425"><pubmed>26014425</pubmed></ref>.<br />
===Duchenne Muscular Dystrophy ===<br />
Duchenne Muscular Dystrophy is an X-linked recessive disease. It involves the Xp21 gene where majority of the mutations are chromosomal deletions with a smaller percentage resulting from duplications <ref name="PMID18359022"><pubmed>18359022</pubmed></ref>.<br />
===β – Thalassemia=== <br />
β – Thalassemia is known as the most common type of autosomal recessive inherited disorder among haemoglobinopathies. It involves the adult β-globin gene and is associated with the absent or decreased expression of the gene. This is commonly caused by a single nucleotide change in the gene. PGD has been used successfully worldwide to identify the β-globin gene where its application is usually performed on a single blastomere or polar body <ref name="PMID19064120">19064120</pubmed></ref>.<br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
! Applicable diseases for PGD <ref>Genoma Group (2014). Retrieved September 18th, 2015, from http://www.preimplantationgeneticdiagnosis.it/genetic-diseases-diagnosed-by-pgd.htm </ref>, <ref>Genesis Genetics (2015). Retrieved September 18th, 2015, from http://genesisgenetics.org/pgd/what-we-test-for/</ref>, <ref>Human Fertilisation & Embryology Authority (2015). Retrieved Septembr 18th, 2015, from http://guide.hfea.gov.uk/pgd/</ref><br />
|-<br />
| '''Disease'''<br />
| '''Involved Genes'''<br />
|-<br />
| 5 Alpha Reductase Deficiency (5ARD)<br />
| SRD5A2 <br />
|-<br />
| Achondroplasia<br />
|FGFR3 <br />
|-<br />
| Acute Intermittent Porphyria <br />
| ALAD, ALAS2, CPOX, FECH, HMBS, PPOX, UROD, or UROS<br />
|-<br />
| Adrenoleukodystrophy (Adrenomyeloneuropathy)<br />
| ABCD1 <br />
|-<br />
| Agammaglobulinaemia (x-linked) <br />
|BTK <br />
|-<br />
| Agammaglobulinemia Bruton Tyrosine Kinase (BTK) <br />
|BTK <br />
|-<br />
| Aicardi Goutieres Syndrome 1 (AGS1) <br />
|TREX1, RNASEH2A, RNASEH2B, RNASEH2C, SAMHD1<br />
|-<br />
| Alagille Syndrome<br />
|JAG1 or NOTCH2<br />
|- <br />
| Alpers-Huttenlocher Syndrome <br />
|POLG <br />
|-<br />
| Alpha-1-antitrypsin deficiency <br />
|SERPINA1 <br />
|-<br />
| Alpha-Mannosidosis<br />
| MAN2B1 <br />
|-<br />
| Alpha Thalassemia <br />
|HBA1 or HBA2 <br />
|-<br />
| Alports Syndrome<br />
|COL4A3, COL4A4, COL4A5<br />
|-<br />
| Alzheimer's Disease - early onset (Type 3 and 4) <br />
|APP, PSEN1, or PSEN2<br />
|-<br />
| Amyotrophic Lateral Sclerosis 1 (ALS1) <br />
|C9orf72, SOD1, TARDBP, FUS, ANG, ALS2, SETX, VAPB <br />
|-<br />
| Argininosuccinic Aciduria <br />
| ASL<br />
|-<br />
| Arrhythmogenic Right Ventricular Cardiomyopathy/ Dysplasia (ARVC/D)<br />
| DSG2; DSP; PKP2<br />
|-<br />
| Ataxia Telangiectasia<br />
| ATM<br />
|-<br />
| Bardet-Biedl Syndrome (BBS)<br />
| BBS1; BBS10<br />
|-<br />
| Barth Syndrome<br />
| TAZ<br />
|-<br />
| Beta Thalassaemia<br />
| HBB<br />
|-<br />
| Birt-Hogg-Dubé Syndrome<br />
| FLCN<br />
|-<br />
| Breast Ovarian Cancer Familial Susceptibility (BRCA2)<br />
| BRCA1; BRCA2<br />
|-<br />
| Canavan Disease <br />
| ASPA<br />
|-<br />
| Carnitine-Acylcarnitine Translocase Deficiency <br />
| SLC25A20<br />
|-<br />
| Cerebral Arteriopathy with Subcortical Infarcts & Leukoencephalopathy (CADASIL)<br />
| NOTCH3<br />
|-<br />
| Cerebral Cavernous Malformation<br />
| CCM1<br />
|-<br />
| Charcot-Marie-Tooth Disease<br />
| GJB1; MPZ; NEFL; PMP22<br />
|-<br />
| CHARGE Syndrome<br />
| CHD7<br />
|-<br />
| Cherubism<br />
| SH3BP2<br />
|-<br />
| Choroideremia<br />
| CHM<br />
|-<br />
| Chronic Granulomatous Disease<br />
| CYBB; NCF1<br />
|-<br />
| Ciliary Dyskinesia<br />
| DNAH5<br />
|-<br />
| Citrullinemia<br />
| ASS1<br />
|-<br />
| Cleidocranial Dysplasia<br />
| RUNX2<br />
|-<br />
| Cockayne Syndrome<br />
| ERCC6<br />
|-<br />
| Congenital Adrenal Hyperplasia<br />
| CYP21A2<br />
|-<br />
| Congenital Cataracts<br />
| GJA8; VSX2<br />
|-<br />
| Congenital Diarrhea, Syndromic<br />
| SPINT2<br />
|-<br />
| Congenital Disorders of Glycosylation (CDG)<br />
| ALG1; ALG6; CDG1C; DOLK; PMM2<br />
|-<br />
| Cornelia de Lange Syndrome <br />
| NIPBL<br />
|-<br />
| Craniosynostosis<br />
| TWIST1<br />
|-<br />
| Crouzon Syndrome<br />
| FGFR2<br />
|-<br />
| Cysteinyl Leukotriene Receptor 1 Deficiency <br />
| CYSLTR1<br />
|-<br />
| Cystic Fibrosis<br />
| CFTR<br />
|-<br />
| Diamond –Blackfan Anemia <br />
| RPS19<br />
|-<br />
| Duchenne Muscular Dystrophy <br />
| DMD<br />
|-<br />
| Dyskeratosis congenita (Male embryos only)<br />
| DKC1<br />
|-<br />
| Ectodermal dysplasia (Hypohidrotic)<br />
| EDA; EDA1; GJB6; IKBKG<br />
|-<br />
| Familial Adenomatous polyposis coli (FAP)<br />
| APC<br />
|-<br />
| Familial Dysautonomia<br />
| IKBKAP<br />
|-<br />
| Fanconi Anemia <br />
| FANCA; FANCC; FANCD2; FANCF; FANCG; FANCJ<br />
|-<br />
| Fragile X Syndrome (FRAX)<br />
| FMR1<br />
|-<br />
| Galactosemia <br />
| GALT<br />
|-<br />
| Gangliosidosis<br />
| GLB1<br />
|-<br />
| Glanzmann Thrombasthenia <br />
| ITGA2B<br />
|-<br />
| Glutaric Acidemia (aciduria)<br />
| GCDH <br />
|-<br />
| Glycogen Storage Disease <br />
| G6PC; GAA; SLC37A4<br />
|-<br />
| Haemophilia A<br />
| F8<br />
|-<br />
| Haemophilia B<br />
| F9<br />
|-<br />
| Hereditary Nonpolyposis Colorectal Cancer: Lynch Syndrome<br />
| MLH1; MSH2; MSH6<br />
|-<br />
| Holt Oram Syndrome<br />
| TBX5<br />
|-<br />
| Huntington Disease<br />
| HD<br />
|-<br />
| Hydrocephalus<br />
| L1CAM<br />
|-<br />
| Ichthyosis <br />
| ABCA12; STS<br />
|-<br />
| Incontinentia Pigmenti (IP)<br />
| NEMO<br />
|-<br />
| Joubert Syndrome 5<br />
| INPP5E<br />
|-<br />
| Krabbe Disease<br />
| GALC<br />
|-<br />
| Leber Congenital Amaurosis (LCA)<br />
| CEP290; GUCY2D<br />
|-<br />
| Leigh Syndrome (Infantile Subacute Necrotising Encephalopathy)<br />
| LRPPRC<br />
|-<br />
| Lesch Nyan Syndrome<br />
| HPRT1<br />
|-<br />
| Leukocyte Adhesion Deficiency (Type I)<br />
| ITGB2<br />
|-<br />
| Li-Fraumeni Syndrome<br />
| TP53<br />
|-<br />
| Macular Dystrophy Retinal <br />
| VMD2<br />
|-<br />
| Maple Syrup Urine Disorder (MSUD)<br />
| BCKDHB<br />
|-<br />
| Marfan Syndrome <br />
| FBN1<br />
|-<br />
| Menkes Syndrome<br />
| ATP7A<br />
|-<br />
| Mitochondrial DNA Depletion Syndrom <br />
| POLG; RRM2B; SUCLA2; TK2<br />
|-<br />
| Mucolipidosis type II<br />
| GNPTAB<br />
|-<br />
| Multiple Endocrine Neoplasia<br />
| MEN1; MEN2A; MEN2B<br />
|-<br />
| Multiple Exostoses<br />
| EXT1; EXT2 <br />
|-<br />
| Myotubular myopathy<br />
| MTM1 <br />
|-<br />
| Nail-Patella Syndrome<br />
| LMX1B<br />
|-<br />
| Neurofibromatosis Type 1<br />
| NF1<br />
|-<br />
| Neurofibromatosis Type 2 <br />
| NF2<br />
|-<br />
| Noonan Syndrome<br />
| KRAS, PTPN11; SOS1<br />
|-<br />
| Norrie Disease<br />
| NDP<br />
|-<br />
| Ocular Albinism <br />
| GPR143<br />
|-<br />
| Oculocutaneous Albinism <br />
| OCA2; TYR <br />
|-<br />
| Oculodentaldigital Dysplasia<br />
| GJA1<br />
|-<br />
| Optic Atrophy<br />
| OPA1<br />
|-<br />
| Ornithine Transcarbamylase Deficiency <br />
| OTC<br />
|-<br />
| Osteogenesis imperfeca <br />
| COL1A1; COL1A2<br />
|-<br />
| Osteopetrosis <br />
| CLCN7; OSTM1; TCIRG1<br />
|-<br />
| Pachyonychia Congenita <br />
| KRT16; KRT6A<br />
|-<br />
| Pancreatitis, Hereditary<br />
| PRSS1 <br />
|-<br />
| Papillorenal syndrome <br />
| PAX2<br />
|-<br />
| Phenylketonuria <br />
| PAH <br />
|-<br />
| This table does not cover the complete list of diseases that PGD can be applied to.<br />
|}<br />
<br />
==Laws & Legal status==<br />
===Australia=== <br />
PGD is currently used to detect serious genetic conditions to improve the outcome of Assisted Reproductive Technologies (ART). In very rare cases it may be used to select an embryo with compatible tissue for a sibling who has a life-threatening disease where other means of treatment is unavailable. This is with the conditions that the use of PGD will not affect the welfare and interests of the child to be born. The parents must also receive adequate counselling and have full understanding of the procedures of PGD. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"> National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art</ref><br />
The use of PGD for sex-selection is prohibited with the exception of reducing the risk of the transmission of serious sex-linked genetic conditions. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"/><br />
===Brazil=== <br />
The laws regarding PGD in Brazil are not strictly regulated. They are vague and there is limited information surround the activities of assisted reproduction in general in the country <ref name="PMID25493379"><pubmed>25493379</pubmed></ref>.<br />
===Czech Republic===<br />
The laws in the Czech Republic allow those with a “defined indication in order to exclude risk of serous genetically conditioned disease and defects with embryos before they are implanted into the cavity of the uterus”. Couples that undergo any assisted reproductive treatment including PGD have to be married. Sex-selection is illegal except in regards to serious sex-linked genetic diseases <ref name="PMID24777348"><pubmed>24777348</pubmed></ref>.<br />
===Greece=== <br />
In Greece, ART is open to those up to the age of 50 with written consent. It can only be used if a medical necessity is present such as the susceptibility of serious hereditary diseases. Sex selection is banned apart from cases of sex-linked diseases and sexually transmitted diseases <ref name="PMID24777348"/>.<br />
===Portugal=== <br />
ART is only available to those who are married or have a similar type of relationship for at least two years. The couples cannot be of the same sex and must be at least 18 years of age. Sex selection is illegal except in cases of sex-linked diseases. The use of PGD is illegal if the predictive value of genetic tests are very low <ref name="PMID24777348"/>.<br />
===Spain===<br />
PGD can be applied to “serious hereditary diseases not amenable to postnatal curative treatment” and “detection of other abnormalities which may compromise the viability of the pre-embryo”. If PGD is to be used for any other purpose authorisation must be acquired <ref name="PMID24777348"/>.<br />
===Sweden=== <br />
The use of PGD is strictly regulated and couples must achieve authorisation of the National Board of Health and Welfare. It can only be used it can only be used if the child is at risk to inheriting a serious chromosomal or monogenetic disease. It cannot be used for selection of specific characteristics <ref name="PMID24777348"/>.<br />
===United Kingdom===<br />
Those involved with carrying out the IVF treatment must have a license from the Human Fertilisation and Embryology Authority (HFEA). Only embryos that are approved by the HFEA can be implanted where the embryonic nuclear or mitochondrial DNA cannot be altered with the exception of preventing mitochondrial diseases <ref name="PMID24777348"/>. <br />
==Future/Current Research==<br />
===Noninvasive Preimplantation Genetic Testing without Embryo Biopsy===<br />
Different parameters of gametes, zygotes, embryos (“vacuoles in sperm heads, spindle position in mature oocytes, cleavage intervals of zygote, and embryo developmental dynamics”) may correlate with aneuploidy rates. This knowledge may be applied in potential noninvasive preimplantation diagnostic methods. Several methods have been proposed and are currently further researched<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Sperm Selection====<br />
Intracytoplasmic morphologically selected sperm injection (IMSI) is common procedure in IVF treatment to improve fertilization rates in patients with poor semen quality. In addition, studies have found that IMSI improves embryo development and that spermatozoa with large vacuoles in their heads correlate with increased aneuploidy rates and disturbed chromosomal structures. Thus, selecting spermatozoa based on morphological hallmarks may decrease aneuploidy rates in the fertilized embryos. As with polar body biopsies, however, this approach will solely be applicable if evidence for severe male detrimental contribution is given<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Blastocoel Fluid Extraction====<br />
In addition, a less invasive retrieval of material for diagnosis could include the extraction of the blastocoel fluid. The cavity of the blastocyst, lined by the trophectoderm, is filled with this blastocoel fluid, which contains metabolites of both trophectoderm and inner cell mass origin. The retrieval does not require a biopsy but merely a small opening to extract the fluid and, thus, causes less harm to the embryo. Multiple studies have applied this method<ref name="PMID22020776"><pubmed>22020776</pubmed></ref> <ref name="PMID23148560"><pubmed>23148560</pubmed></ref> and it may in the future become of clinical relevance.<br />
<br />
{|border="1"<br />
| [[File:Aspiration_of_the_Blastocoel_Fluid.jpeg]]<br />
|-<br />
| Aspiration of the Blastocoel Fluid using a ICSI pipette<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
|}<br />
<br />
<br />
Next to metabolites, the blastocoel fluid can contain DNA. Studies have shown that genomic DNA is present in about 90% of the blastocoel fluid samples tested. Typically the fluid is removed with an ICSI pipette from a day five blastocyst through its mural trophectoderm until the blastocyst fully collapses around the embryo. Several concerns regarding this method in a clinical setting have been raised. The collected DNA may be contaminated by the culture media that contains DNA fractions. The DNA may also be least representative of the actual embryos genome as the DNA may originate from abnormal or degenerated cells. Even though labelled noninvasive, the blastocyst still undergoes manipulation to some degree which may affect its viability. Thus, more research is required until this method can evolve from research to clinical use<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
====Proteomics====<br />
The protein secretome of blastocysts may be representative of its chromosome constitution Recent studies have found biomarkers such as lipocalin-1, interleukin-10, tumor necrosis factor, stem cell factor, and chemokine ligand 13 to be differently secreted by aneuploid blastocyst than by euploid ones. The most significant biomarker appears to be interleukin-10. Paired with novel proteomic technologies and mass spectrometry this knowledge when extended may contribute to a new invasive preimplantation genetic diagnosis method<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Embryo Morphology====<br />
Using time lapse imaging the embryo’s morphology can be closely observed and potential aneuploidy characteristics detected. Such characteristics may include the time of division to five cells, the time between the division from three to four cells, and the duration of the division from one to two and subsequently to three. In addition, the morphological quality of ICM an TE has been positively associated with aneuploidy or euploidy prognosis<ref name="PMID26246880"><pubmed>26246880</pubmed></ref>. These may give rise to an embryo quality screening prior to implantation<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
===Utilization of Diseased Cell Lines===<br />
==Ethics==<br />
==References==<br />
<br />
<references/><br />
<br />
<br />
{{StudentPage2015}}</div>Z5017878https://embryology.med.unsw.edu.au/embryology/index.php?title=2015_Group_Project_6&diff=2065652015 Group Project 62015-10-19T12:17:44Z<p>Z5017878: </p>
<hr />
<div>{{ANAT2341Project2015header}}<br />
<br />
<br />
=Prenatal Genetic Diagnosis=<br />
==Introduction==<br />
==History==<br />
Prenatal Genetic Diagnosis was historically conducted post-implantation in the first 2 trimesters <ref> Blackburn, S.L. (2003) '''Maternal, Fetal & Neonatal physiology: a Clinical perspective''' (2nd ed.). Seattle: Saudners </ref>, testing for overall fetal growth, complications of pregnancy, birth defects as well as chromosomal or genetic abnormalities<ref> Sadler T.W.(2012) '''Langman's Medical Embryology''' (12th ed.) Philadelphia: Lipincott, Wiliams & Wilkins, a Wolters Kluwer Business </ref>. Due to advancements in Artificial Reproductive Technologies ( ART) in the past 2 decades , these genetic tests are now conducted as a part of Preimplantation Genetic Diagnosis (PGD) <ref><pubmed>20638568</pubmed></ref> and art used to eliminate the rsik of passing on a genetic disorder to an offspring, before implantation, it ha now become a preventative measure. . In 1990 Preimplantation genetic testing was first used in 1990 on humans to diagnose recessive X-linked diseases in the embryos of pregnant women undergoing IVF. <ref><pubmed>2330030</pubmed></ref> PGD is offered as an alternative to prenatal diagnosis in detecting genetic disorders in high risk couples <ref><pubmed>26168107</pubmed></ref> and avoid passing an inherited disease to the offspring, by selecting genetically "normal" embryos for implantation ,to give the best chance of successful implantation , stable pregnancies and healthy children. <br />
<ref><pubmed>23499002</pubmed></ref><br />
<br />
==Preimplantation Genetic Diagnosis==<br />
[[File:Preimplantation Genetic Diagnosis Procedure.jpeg|700px|thumb|centre| Simplified steps for PGD]]<br />
<br />
<br />
Preimplantation genetic diagnosis (PGD) is used to test the genetic makeup of embryos to detect single gene disorders, chromosomal abnormalities and mitochondrial disorders. It also has applications in gender selection for diseases with unequal gender distributions <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Some diseases commonly involved with PGD include cystic fibrosis, spinal muscular atrophy and beta – thalassaemia <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press.">Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press</ref> <ref name="PMID17823145"><pubmed>17823145</pubmed></ref>. It was first used in the United Kingdom in the 1980s of arenoleucodystrophy and primarily focusing on sex- linked disorders <ref name="PMID17823145"/><ref name="PMID23150080"><pubmed>23150080</pubmed></ref>. PGD is now capable of detecting single cell defects (molecular) and chromosomal disorders resulting from the inversion, translocation or deletion of chromosomes (cytogenic) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>,<ref name="PMID11325751"><pubmed>11325751</pubmed></ref>. PGD can be applied to the embryo at different stages. That is on polar bodies, blastomeres or blastocyst <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>.<br />
Depending on the type of genetic disorder, PGD utilises different methods of genetic testing. These include Fluorescence in situ hybridisation (FISH) which is used for sex – linked disorders and detects chromosomal rearrangements <ref name="PMID11325751"/><ref name="PMID17876073"><pubmed>17876073</pubmed></ref> and Embryo halotyping which allows the identification of chromosomes causing the inherited disorder through knowledge of the pattern of closely linked markers <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. Polymerase chain reaction (PCR) is also widely used to detect molecular abnormalities <ref name="PMID11325751"/>.<br />
PGD is tightly regulated and supported by large organisations namely The American Society for Reproductive Medicine, The European Society for Human Reproduction and Embryology (ESHRE), The European Society of Human Genetics and the Preimplantation Genetic Diagnosis International Society <ref name="PMID25500181><pubmed>25500181</pubmed></ref>.<br />
===Sex-linked disorders===<br />
The determination of a disease as gender specific usually correlates with the presence or absence of specific genes such as SRY on the Y chromosome. It is known that females have two X chromosomes and males have an X and a Y chromosome where abnormalities are more prevalent on the X chromosome. PGD can be used for sex selection where only male embryos are transferred to reduce the chance of inheriting X-linked disorders. However, this does not completely eradicate the problem as male embryos remain susceptible to inheriting an affected X chromosome. Sex determination is only used when the specific mutation is unknown and has yet to be discovered <ref name="PMID24866878"><pubmed>24866878</pubmed></ref>.<br />
===Single gene defects===<br />
Single gene defects can be dominant, recessive, autosomal or X-linked. They are commonly diagnosed using PCR and although the PCR available today is complex and capable of combatting a large range of disease the development of new protocols has been proven to be difficult due to the small DNA sample available <ref name="PMID26168107"><pubmed>26168107</pubmed></ref><br />
===Mitochondrial disorders===<br />
Mitochondrial disorders also known as oxidative phosphorylation disorders arise from mutations in the nuclear DNA or mitochondrial DNA <ref name="PMID26312584"><pubmed>26312584</pubmed></ref>. They pose as a problem because they are unrecognisable until the mutations in the cell reach a detrimental level <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Mitochondrial disorders cause miscarriages and stillbirths as well as death in children and young adults. The effects can either be contained in a single organ or more commonly involve multiple organ failure where organs with high energy demands such as the brain, liver muscle and heart and heavily influenced. They are usually occur spontaneously or result from inheritance from the mother. Since mitochondria are solely inherited from the mother oocyte donations have been used as a solution to combat mitochondrial disorders. Additionally, there has been an increasing use in PGD where embryos that stay under the given threshold of 18% gene-mutations are allowed to be transferred and result in normal development. New technology in the areas of nuclear gene transfer and genome editing are also being experimented with <ref name="PMID26312584"/>. <br />
===Chromosomal disorders===<br />
Chromosomal disorders can be reciprocal, Robertsonian translocations, inversions, deletions and insertions <ref name="PMID26168107"/>. . Data from ESHRE collected between 2010 and 2011 has shown that the most common chromosomal abnormality confronted in PGD are reciprocal chromosomal abnormalities <ref name"PMID26071418"><pubmed>26071418</pubmed></ref>. PGD has also been used successfully for Robertsonian translocations (RT), a type of structural translocation. Children who carry RT are phenotypically normal, however in their later years it is found that they will suffer from infertility and repeated miscarriages due to the high frequency of abnormal embryos <ref name="PMID22081077"><pubmed>22081077</pubmed></ref>. PCR and FISH are the two main techniques used for chromosomal disorders. To be able to conduct the examinations the cells are required to be at the metaphase stage <ref name="PMID26168107"/>. <br />
==Preimplantation Genetic Screening==<br />
Prenatal Genetic Screening (PGS) involves an array of methods or ideas that aim to segregate embryos that have genetic flaws and those that are healthy <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. The occurrence of aneuploidy is high around the stages of early embryonic development and they are the most common cause if miscarriages and congenital birth defects <ref name= "PMID26085841"><pubmed>26085841</pubmed></ref>. They have little effect on the morphology of the embryo making them difficult to identify thus identification heavily relies on genetic testing <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. <br />
Genetic sampling is most commonly conducted using Microarray Comparative Genomic Hybridisation (aCGH) as well as FISH, Quantitative PCR and Single Nucleotide Polymorphism (SNP) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. These methods collectively aim to assess numeral and structural chromosomal errors <ref name= "PMID26085841"/>. Studies have also introduced Next- Generation Sequencing (NGS) <ref name= "PMID26085841"/> and Whole Genome Amplification used to screen imbalances in the complete 24-chromosomes <ref name="PMID25953353"><pubmed>25953353</pubmed></ref><br />
Statistics from ESHRE have shown that the most common indications for PGS is advanced age, followed by repeated implantation failure or recurrent miscarriage and male infertility <ref name="PMID26071418"><pubmed>26071418</pubmed></ref>.<br />
====Indications====<br />
A low percentage of structural abnormalities in chromosomes are responsible for the cause of miscarriages. Despite this, they are the most prevalent type of chromosomal abnormality accounted for in PGD <ref name="PMID20638568"/>. The presence of specific gene cycles, initiation of embryonic protein synthesis and evident physiological development are all indicative of a successful in vitro fertilisation procedure <ref name="PMID11576737"><pubmed>11576737</pubmed></ref>. To eliminate further errors from occurring during the PGD procedure it is recommended to undertake further prenatal testing such as amniocentesis in the later stages <ref name="PMID20638568"/>. <br />
=====Advanced maternal age=====<br />
Data provided by the ESHRE has shown that the mean age of women undergoing PGS is 39 years <ref name="PMID26071418"/>. Women of advanced age have been shown to have a lower rate of pregnancies reaching childbirth <ref name="PMID18583331"><pubmed>18583331</pubmed></ref>. The highlighted concern revolves around the increased occurrence of aneuploidy following maternal age. The optimal age range for the lowest aneuploidy incidence was found to be between 27 to 37 years of age (6%) then progressively higher in women aged up to 42 (33%) and most common in those 44 and above (53%) <ref name="PMID24355045"><pubmed>24355045</pubmed></ref>. <br />
=====Recurrent pregnancy loss / IVF failure=====<br />
Recurrent pregnancy loss is defined as three or more IVF failures after cumulative transfer of more than 10 good-quality embryos. These are primarily caused by two main factors, reduced endometrium receptivity or embryonic defects. Endometrium receptivity can be negatively influences by instances including uterine pathologies such as thin endometrium, altered expression of adhesive molecules and immunological factors. Additionally, embryonic defects may be due to genetic abnormalities, embryonic aneuploidy or zona hardening. Endometriosis and hydrosalpinx has been known to effect both the endometrium and embryo <ref name="PMID23260857"><pubmed>23260857</pubmed></ref>.<br />
=====Human leukocyte antigen matching=====<br />
First used in 2001, HLA matching is an option given to parents to save a child with haematological or immunological disease through conceiving another child who would potentially be able to donate cord blood or haematopoietic stem cells from the bone marrow for transplantation. The process namely PGD-HLA has shown to improve haematopoietic stem cell transplant (HSCT). PGD-HLA can only be performed when HSCT is not needed urgently due to the time needed to conceive and delivery the baby <ref name="PMID25500181"><pubmed>25500181</pubmed></ref>. It is most commonly applied to children suffering from relapsed leukaemia <ref name="PMID22524201"><pubmed>22524201</pubmed></ref>. In a case study PGD-HLA was proven to successfully cure 10 diseases including Fanconi anaemia, Diamond-Blackfan anaemia and beta thalassemia <ref name="PMID25066893><pubmed>25066893</pubmed></ref>.<br />
==Biopsy Methods==<br />
Biopsy, the removal of genetic materials, from oocytes or embryos in the preimplantation stage is the primary step in PGD. For the past two decades these biopsies have been performed at three stages, the polar body, blastomere, and blastocyst, and the methodologies optimized to ensure the embryo’s viability. The most common approach involves biopsies at the cleavage stage. However, polar body and blastocyst biopsies are increasingly more often tested and applied. Approached for opening the zona pellucida involve next to the traditional mechanical and chemical means, novel approaches such as noncontact lasers. Their application may simplify and secure the procedure significantly. The most challenging question about PGD procedures remains at what stage biopsies should be taken. Much controversy has developed around this topic, highlighting the varying disadvantages and advantages of temporal biopsies. <ref name="PMID22723007"><pubmed>22723007</pubmed></ref><br />
<br />
{|border="1" align="left"<br />
|-bgcolor="pink" <br />
|<br />
| Time of Biopsy<br />
| Advantages <br />
| Disadvantages<br />
|- <br />
| Polar Body<br />
| Day 1<br />
| No harm to oocyte<br />
| Only maternal DNA is tested, often needs to be coupled with other biopsies<br />
|-bgcolor="pink"<br />
| Blastomere<br />
| Day 3<br />
| …<br />
| … <br />
|-<br />
| Trophectoderm<br />
| Day 5 and 6 <br />
| Little harm, large amount of genetic material<br />
| Opening of blastocyst necessary, small time window for procedure<br />
|}<br />
<br />
{|border="1"<br />
| [[File:Polar_Body,_Blastomere,_and_Trophectoderm_Biopsy.jpeg]]<br />
|-<br />
| Polar body (A), blastomere (B) and trophectoderm (C) biopsies<ref name="PMID25625041"><pubmed>25625041</pubmed></ref>.<br />
|}<br />
<br />
PMID 24305177<br />
===Polar Body Analysis===<br />
Day 1<br />
====Description====<br />
Polar body (PB) biopsy, which was introduced in 1990, offers a promising alternative to biopsies performed at the blastomere stage for PGD/S indications on legal and practical grounds. <br />
Description: Consequent embryo development does not necessitate the presence of the first and second PB and their removal may not be crucial. PB biopsy requires precise timing. Keeping track of the meiotic cell cycle is necessary to perform a successful biopsy and, therefore, PB biopsy usually is applied in combination with intracytoplasmic sperm injection (ICSI). During the maturation from the germinal vesicle stage to the metaphase-II stage the first PB is formed. A cytoplasmic bridge containing spindle remnants, that are still in contact with the cellular genetic material, links this PB to the oolemma for about 90 minutes after extrusion. It is possible to visualize these remnants by polarization microscopy and it is crucial to not perform the biopsy until the first PB is no longer firmly attached to the oolemma as this indicates an immature embryo.The oocyte tolerates mechanical zona dissection best during hours four until six after ICSI as the oolemma has stabilized by that time because of the cortical granule reaction. Over time the first PB degenerates stressing a temporal biopsy and its optimal extraction time window is four to 12 hours after ICSI. The second PB forms around two to four hours after ICSI. However, its optimal time window for biopsy is set to be eight to 16 hours after ICSI. This is due to the second PB being attached to the oolemma with spindle remnants until six hours after ICSI. Biopsy at this point may cause enucleation of the oocyte. In addition, studies have shown that the amplification efficiency of second PB’s DNA is worse if the PB is extracted prior to eight hours after ICSI. <br />
Thus, it is possible to perform sequential and simultaneous biopsies for the first and second PB. If performed, sequentially the first PB may be removed four to 12 hours and the second PB eight to 16 hours after ICSI. The optimal time window for a biopsy for both the first and second PB simultaneously is eight to 12 hours after ICSI. It is highly preferred to analyze both PBs due to potential aneuploidies in either PB and crossing overs during meiosis<ref name="PMID22723007"/>. <br />
====Procedure====<br />
Chemical opening achieved with for example acidic tyrode’s solution of the zona pellucida is not tolerated by the oocyte and may have detrimental effects on the embryo’s development. Therefore, the access to the perivitelline space of the oocyte is provided by mechanical zona dissection or by laser. Both techniques work well if performed by experienced embryologist. However, laser-assisted biopsy is less time consuming when compared to manual dissection. It is critical to consider the size of the introduced opening as it will remain permanent. If it is too large the blastomere may be lost during embryo development and if it is too small it may interfere with hatching of the embryo during blastocyst stage<ref name="PMID22723007"/><br />
<br />
{|border="1"<br />
| [[File:Polar_Body_Biopsy.jpeg]]<br />
|-<br />
| The presence of a faint but clearly identifiable strand connecting PB2 to the <br />
oolemma. The biopsy was performed ∼9 h after ICSI<ref name="PMID21908464"><pubmed>21908464</pubmed></ref>.<br />
|}<br />
<br />
{|border="1"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JTaQzszVr8o</html5media><br />
|-<br />
| Laser-assisted polar body biopsy<ref>RIUK, R. (2013, June 25) Polar Body Biopsy [Video file]. Retrieved from https://www.youtube.com/watch?v=JTaQzszVr8o</ref><br />
|}<br />
<br />
====Advantages & Disadvantages====<br />
PB biopsies can only investigate the maternal contributions to the embryo as they are of maternal origin. Thus, this procedure is appropriate for PGD solely for monogenetic diseases from the maternal side. Recessive diseases may be evaluated with PB biopsies on the basis that the embryo’s outcome will be determined by the paternal contribution. (...) It may still be applied for PGS as most aneuploidies either arise during meiosis or origin from the maternal genome. However, diagnosis error has been reported due to the lack of considering paternal contributions. <br />
Because PB biopsies are performed very early it is not yet known whether the oocyte will develop into a viable embryo. Thus, PBs are commonly frozen or fixed after biopsy and depending on the state of the embryo only chosen PBs will be tested. This is primarily an economic issue as many genetic testing procedures are very cost-intensive<ref name="PMID22723007"/>.<br />
<br />
{|border="1"<br />
| [[File:Implantation_predictive_value_of_euploid_screening_results.jpeg]]<br />
|-<br />
| The sustained implantation predictive value (with 95 % confidence interval) of a euploid screening result obtained from the first polar body (PB1), PB1 and the second polar body (PB2), or a direct embryo biopsy for each stage of embryo transfer (cleavage-stage and blastocyst stage)<ref name="PMID25106935"><pubmed>25106935</pubmed></ref>.<br />
|}<br />
<br />
===Blastomere biopsy===<br />
Day 3 <br />
====Description====<br />
Blastomere biopsy has been the prevalent method for PGD and PGS in the last two decades. At least one, but up to two, blastomeres are biopsied on day three of the cleavage stage embryo. The right number of blastomeres removed is a controversial topic as two cells allow for more genetic material and more accurate results. However, removing two cells might be too invasive and damaging to the embryo. (Study)<ref name="PMID21748341"><pubmed>21748341</pubmed></ref><br />
====Procedure====<br />
Initially a hole was drilled into the zona pellucida using acid tyrodes and the blastomeres are removed via aspiration with a pipette<ref name="PMID21748341"/>.<br />
<br />
{|border="1"<br />
| [[File:Aspiration_of_a_Blastomere.jpeg]]<br />
|-<br />
| Aspiration of a Blastomere into the biopsy pipette<ref name=" PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
|}<br />
<br />
{|border="1"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=TbridWVwipI</html5media><br />
|-<br />
| Laser-assisted blastomere biopsy<ref>Sukprasert, M. (2014, March 5) Day 3 Blastomere Biopsy 1 [Video file]. Retrieved from https://www.youtube.com/watch?v=TbridWVwipI</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
===Trophectoderm biopsy===<br />
Day 5 and 6<br />
====Description====<br />
The improvement of embryo culture media allowed the in vitro development of human embryos until the blastocyst stage and opened up the possibility to take blastocyst biopsies. During day three to day five the haploid maternal and paternal genomes work together for the first time to form the genome of the embryo. The maternal epigenetic control lessens significantly while preparing for implantation with precisely arranged events happening. The first event includes a rapid increase in the number of embryonic cells which are active in mitotic divisions and apoptosis of aberrant cells. This is followed by the formation of blastocoel (cavitation) which results from the flattening of cell located on the outside of the blastomere. Now the blastocyst will expand until the embryo hatches by rupturing the zona pellucida. The cells of the blastocyst will differentiate to form two distinct cell lineages, the outer trophectoderm and the inner cell mass<ref name="PMID22723007"/>.<br />
====Procedure====<br />
Trophectoderm biopsy is usually performed in Hepes buffered biopsy medium and opening approaches include needle cutting which has been replaced by lasers in past years. Different research groups report different timings of the opening to be the most successful. Some open the blastocyst on day three or four by creating a 25 µm which causes the trophectoderm to herniate through this hole and is, thus, accessible for biopsy. Others create this hole about four hours before biopsy which allows sufficient herniation of trophectoderm cells. It is also possible to open the blastocyst immediately before biopsy. This avoids an extra step and the inner cell mass usually is easy to locate. Blastocyst biopsies involve the removal of trophectoderm cells and the ideal time for the procedure is day five. Successful biopsies on day six have been performed, while little is known about the results of biopsies on day seven. However, since the window of implantation in humans is from day eight to ten after ovulation, day seven biopsies appear to be possible<ref name="PMID22723007"/>.<br />
-collapse of trophoblasts<br />
-possible: biopsy of hatched blastocyst, holding pipette careful mild suction force to hold embryo near ICM <br />
-Cryopreservation<br />
<br />
{|border="1"<br />
| [[File:Microscopic images of human blastocysts for biopsy.jpeg]]<br />
|-<br />
| (A) Some trophectoderm cells in a blastocyst started to hatch and (B) the trophectoderm cells were biopsied with assisted laser cutting. Images in C–D show the blastocysts after vitrification and warming. Blastocysts had been cultured for 2–4 hrs after warming, showing good (ICM and trophectoderm cells) hatched (C) and hatching (D) blastocysts. The hatching blastocyst in (E) has good ICM but fair trophectoderm while the blastocyst in (F) has both fair ICM and trophectoderm. Arrows indicate ICMs and arrow heads indicate trophectoderm cells. Bar = 40 µm<ref name="PMID2190846"><pubmed>2190846</pubmed></ref>.<br />
|}<br />
<br />
<br />
{|border="1"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JI_TQ8d8tNM</html5media><br />
|-<br />
| Laser-assisted blastocyst biopsy (at 00:50 min)<ref>Coco, R. (2014, April 30) Trophectoderm biopsy in a Hatching blastocyst protruding ICM [Video file]. Retrieved from https://www.youtube.com/watch?v=JI_TQ8d8tNM</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
Blastocyst biopsies are believed to be less damaging to the embryo and appear to be unrelated to implantation rates. In addition, this biopsy method allows for a larger extraction of cells for genetic testing. However, since they are performed late in in vitro development, the time window for genetic testing is relatively small. Fast and accurate genetic testing methods are needed to ensure a successful and safe result from this biopsy. Thus, blastocyst biopsies may gain more popularity in the future whn such methods have been developed or improved<ref name="PMID22723007"/>. <br />
<br />
<br />
==Genetic Techniques==<br />
<br />
===PCR===<br />
====Description====<br />
Polymerase chain reaction (PCR) amplifies DNA specific to genetic sequence of interest . PCR was developed by Kay Mullis in the 1980s, for which he was awarded the Nobel prize for chemistry in 1993. <ref> Pubmed Docs (2015) Polymerase Chain Reaction (PCR) Pubmen. Retrieved from [http://www.ncbi.nlm.nih.gov/probe/docs/techpcr/]</ref> This technique enables clinicians to monitor and diagnose diseases using minute samples such as embryonic cells, blood & tissue. <ref>Roche (2015) PCR: How We Copy DNA. Roche Molecular Systems Inc. retrieved From [http://molecular.roche.com/pcr/Pages/Process.aspx]</ref> PCR has many important applications like DNA fingerprinting, genetic mapping, detection of viruses and bacteria as well as being used to detect genetic disorders, as a part of PGD, in conjunction with IVF. It is used to detect molecular abnormalities such as single gene disorders like Tay Sach, Cycstic fibrosis, Duchenne Muscular Dystrophy, Thalassemia, Huntington disease, Spinal muscular atrophy and many more. Molecular and Genetic analysis require a significant amount of DNA, which we would not have without PCR. It revolutionized the study of DNA, replacing all previous recombinant DNA technology. <ref> Mullins, K., Francois, F.& Gibbs R.A. (1994 ) The Polymerase Chain Reaction. p3. Springer- Science +Business Media. Birkhauser, Boston<br />
Available at [https://books.google.com.au/books?hl=en&lr=&id=gjrTBwAAQBAJ&oi=fnd&pg=PR5&dq=kary+mullis+PCR&ots=mpzAyRh5ZY&sig=PQ4goNoKJ90tb3-MkPk62zrTGbw#v=onepage&q=kary%20mullis%20PCR&f=false] </ref> <br />
<br />
====Procedure====<br />
<br />
Sample are obtained from the the blastocyst, a polar body biopsy or the blastomeres stages of the embryo. <br />
Stage 1 Denaturing: separating the target strands of DNA <br />
The obtained sample is heated to roughly 90 degrees celcius, this heat causes breaks the relatively weak bonds between nucleotides that form DNA. the double stranded DNA to split into 2 single strands of DNA that are used as templates.<br />
Stage 2 Annealing: Binding the Primers to the target DNA sequence <br />
PCR will only copy the target sequence of DNA specified by specific PCR primer. These synthesized primers Oligonucleotides are small artificial pieces of DNA. <br />
TAQ polymerase enzyme synthesize 2 new strands of DNA duplicate to the single sample DNA stand template indicated by these primers. During this stage the reaction is cooled to a temperature between 40-60 degrees Celsius. <br />
Stage 3- Extension- making copies <br />
Each of these 2 copies are then used again as templates generating 2 further replications This cycle can occur as many 30 -40 times within a couple hours leading to billions of extra copies of the original DNA segment. The optimal temperature for the further replication is roughly 72 degrees Celsius. <br />
<br />
This process mediated by a thermocycler machine that is programmed to alter the temperature of the reaction every couple of minutes, perpetuating the cycle of DNA denaturing and synthesis. <br />
This process, generates exponential exact copy of the original template DNA sequence. <br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
!PCR cycles<br />
<br />
|{|<br />
|-bgcolor="lightpink"<br />
| '''PCR Cycle'''<br />
| '''Target Copies'''<br />
|-<br />
| 1<br />
| 2<br />
|-bgcolor="pink"<br />
| 2<br />
| 4<br />
|-<br />
| 3<br />
| 8<br />
|-bgcolor="pink"<br />
| 4<br />
| 16<br />
|-"<br />
| 5 <br />
| 32<br />
|-bgcolor="pink"<br />
| 6 <br />
| 64<br />
|-<br />
| 7 <br />
| 128<br />
|-bgcolor="pink"<br />
| 8<br />
| 256<br />
|- <br />
| 9<br />
| 512 <br />
|-bgcolor="pink"<br />
| 10<br />
| 1024<br />
|-<br />
| 15<br />
| 32,768<br />
|-bgcolor="pink"<br />
| 20 <br />
| 1,048,578<br />
|-<br />
| 25<br />
| 33,554,432<br />
|-bgcolor="pink"<br />
| 30 <br />
| 1,073,741,842<br />
|-<br />
|}<br />
<br />
<br />
<br />
<br />
{|border="1" align="center"<br />
|-bgcolor="pink" <br />
| '''Advantages''' <br />
|'''Disadvantages'''<br />
|- <br />
| fast and inexpensive way of copying a target sequence of DNA<br />
| only during this exponential DNA replication phase can we determine the starting quantity sequence contained in the original sample ( template DNA strand)<br />
|-bgcolor="pink"<br />
| aids the diagnosis of single cell defects<br />
| PCR reaction is limited by the presence of inhibitors present in the sample : reagent inhibitors <br />
|-<br />
| rapid generation of results within a couple hours<br />
| self annealing due to the accumulation of the product -stopping exponential amplification for the target sequence and reach a plateau<br />
quantification of the end point of reaction of PCR products unreliable - therefore that is why we require real time quantitative RT-PCR necessary<br />
<ref> NIS (2015) Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref><br />
|-bgcolor="pink"<br />
| can start from a single molecule of DNA, therefore is more sensitive <br />
| <br />
|-<br />
| has a flexible primer design enabling<br />
| <br />
|-bgcolor="pink"<br />
| overcame previous issues associated with the limited availability of sites of end<br />
| <br />
|-<br />
| generates the DNA copies exponentially<br />
| <br />
|-bgcolor="pink"<br />
| enables DNA amplification required for molecular and genetic analysis<br />
| <br />
|-<br />
|Valid diagnostic method in selecting unaffected embryos for embryo transfer <ref> Dreesen, J., Drusedaul, M., Smeets, H., Die-Smulders, C., Coonen, E., Dumoulin, J., Gielen, M., Evers, J., Herbergers, J. & Geradets, J. (2008) Validation of preimplantation genetic diagnosis by PCR analysis: genotype comparison of the blastomere and corresponding embryo, implications for clinical practice. Mol. Hum. Reprod. 14 (10):573-579.doi: 10.1093/molehr/gan052. Retrieved from [http://molehr.oxfordjournals.org/content/14/10/573.short] </ref> <ref><pubmed>20966460</pubmed></ref><br />
|<br />
|}<br />
<br />
<br />
<br />
<br />
<br />
<br />
<br />
<br />
<br />
===Fluorescent In Situ Hybridisation (FISH)===<br />
<br />
<br />
====Description====<br />
Fluorescence in situ hybridization (FISH) the one of the most effective and rapid <ref name="PMID26338801"><pubmed>26338801</pubmed></ref> Preimplantation Genetic Diagnosis (PGD). This techniques used to locate a specific DNA sequences within a chromosome. FISH facilitates the clinical diagnosis of chromosomal abnormalities indicated by sequential duplications, deletions and rearrangements of chromosome, that are usually missed with microscopic analysis. This technique is especially relevant for female embryos with X-linked diseases,<ref><pubmed>20809319</pubmed></ref> that have no other mutation specific tests [http://www.ncbi.nlm.nih.gov/pubmed/20809319] As part of PGD, samples are collected from various stages of the embyro,and they are able to conducted tests on the blastocyst, a polar body biopsy and the blastomeres <ref><pubmed>21748341</pubmed></ref>. FISH is 99% effective when used in conjunction with competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities<ref name="PMID26338801"/>.<br />
<br />
====Procedure==== <br />
<br />
Samples are collected from either the blastocyst, a polar body biopsy or the blastomeres stages of the embryo <ref><pubmed>21748341</pubmed></ref>. <br />
DNA strands are heated and denatured causing their the individual DNA strands to break apart<br />
Probes are single complimentary stands of DNA a that have been tagged with small chemical agents that glow brightly in the presence of a specific region on a chromosome. These specific probes then hybridize and join to their complementary DNA strand. <br />
The fluorescent tags enable the researchers to correctly identify the presence or lack thereof and location of the specific chromosomes that they are testing for. <ref><pubmed>17876073</pubmed></ref><br />
Researcher analyse the results by identifying the number and the relative location of the fluorescent dots generated by the FISH images.<ref><pubmed>17970921</pubmed></ref><br />
The probe will not fully hybridise if there has been a duplication or a deletion of the DNA - indicating chromosomal and sex chromosomal anomalies like trisomies and aneuploidies. <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref><br />
<br />
<br />
Different probes are used for different purposes: <ref>Unique, Rare Chromosome Disorder Support Group (2013) Fluorescence in situ hybridisation (FISH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/Other/FISH%20FTNW.pdf]</ref><br />
*'''Locus specific tags''' detect very small imbalances, and locate isolated small portions <br />
of genes within a chromosome<br />
*'''Alphoid/Centomeric Repeat probes''' are developed from the repetitive sequence located in the middle region of each chromosome, useful in determining the number of chromosomes , detecting rearrangement and when used in conjunction with locus probes to determine the absence of genetic material on a chromosome. <br />
*'''Paint Probes''' are collections of smaller probes with their own stains that bind to a different section on the chromosome - allowing the full chromosome too be labeled a unique colour, this "full colour map" can be used to know the spectral karyotype- full chromosomal mapping is useful in examining chromosomal abnormalities. <br />
<br />
{|border="1" <br />
| [[File:Fluorescent In Situ Hybridisation (FISH).jpg|thumb|right|'''FISH''' We are able to tag Specific DNA sequences using Probes which have been tagged with fluorescent Labels.This technique enables the clinical diagnosis of chromosomal abnormalities, indicated by sequential duplication, deletions and rearrangements of chromosome <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref>]]<br />
|}<br />
<br />
<br />
<br />
{|border="1" align="center"<br />
|-bgcolor="pink" <br />
| rowspan="8" |'''Advantages''' <br />
|-bgcolor="#FDE1F2" <br />
| FISH is 99% effective when used in conjunction with Competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities.<ref><pubmed>26338801</pubmed></ref><br />
|-bgcolor="#FDE1F2" <br />
| Rapid generation of results<br />
|-bgcolor="#FDE1F2" <br />
| Identifies very small translocations and aneuploidies that occur within chromosomes, that would usually be missed under microscopic analysis<br />
|-bgcolor="#FDE1F2" <br />
| Indicates whether the accessed chromosomes are normal <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|-bgcolor="#FDE1F2" <br />
| Tests for the most common chromosomal abnormalities - down syndrome chromosomes 13,16,18,21 and 22 <ref><pubmed>21749752</pubmed></ref><br />
|-bgcolor="#FDE1F2" <br />
| It may be used to compare the chromosomal gene arrangements in related species<br />
|-bgcolor="#FDE1F2" <br />
| can be used to identify and remove inheritable X-linked disease or sex chromasome anomalies such as Duchennes Muscular Dystrophy, hemophilia, ectodermal dysplasia <ref><pubmed>17876073</pubmed></ref><br />
|-bgcolor="#C67DDC"<br />
| rowspan="5"|'''Disadvantages'''<br />
|-bgcolor="#FE1C5EA"<br />
| FISH destroys all cells tested <ref> O'Connor, C. (2008) Fluorescence in situ hybridization (FISH). Nature Education 1(1):171. retrieved from [http://www.nature.com/scitable/topicpage/fluorescence-in-situ-hybridization-fish-327] </ref><br />
|-bgcolor="#FE1C5EA"<br />
| It does not fully access all chromosomes (only ~ 12)<br />
|-bgcolor="#FE1C5EA"<br />
| Analysis of results is dependent upon the dot quality impacted by hybridisation efficiency or the camera sensitivity <ref><pubmed>17970921</pubmed></ref><br />
|-bgcolor="#FE1C5EA"<br />
| some studies indicate that using FISH on a day-3 embryo biopsy decreases the rate of live births <ref><pubmed>26168107</pubmed></ref><br />
|}<br />
<br />
<br />
<br />
===Array Comparative Genomic Hybridisation (aCGH)===<br />
====Description====<br />
<br />
aCGH also known as Microarray analysis efficiently scans the entire genome for chromosomal imbalances. CGH was initially developed to detect the number of changes in a solid tumor mass. It uses 2 genomes comparing the sample to the control, with each labeled in a different fluorescent dye<ref><pubmed>1876176</pubmed></ref>. Earlier CGH techniques were limited by the resolution of the imaging <ref> Lichter, P., et al. Comparative genomic hybridization: Uses and limitations. Seminars in Hematology 37, 348–357 (2000)</ref> , these initial limitations were overcome by using Microarrays in conjunction with CGh to improve the resolution of the imaging, Array Comparative Genomic Hybridisation (aCGH). This method compares sample and control microarrayed slides containing small segments of DNA (probes). <ref> Lucito, R., et al. Representational oligonucleotide microarray analysis: A high-resolution method to detect genome copy number variation. Genome Research 13, 2291–2305 (2003) </ref> the Probes used will vary according from the small (25-85 base pairs) oligonucleotides manufactured to highlight different target sequences, to the very large genomic clones (80,000- 200,00 base pairs), and as these are significantly smaller than the traditional metaphase chromosomes used for CGH, generating a higher resolution of image. <ref><pubmed>22467166</pubmed></ref>.aCGH is used as a diagnostic tool for prenatal detection f chromosomal abnormalities <ref><pubmed>19012303</pubmed></ref>.<br />
<br />
<br />
====Procedure====<br />
<ref> Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432] </ref><br />
The sample is obtained (skin, blood or fetal cells) and DNA is obtained. <br />
As a part of PGD fetal cell samples are collected from; the fertilized egg polar bodies, the blastomere (day 3 embryo) or the blastocyst/tropoectoderm stage (day 5 embryo).<br />
Sample DNA is labeled with one fluorescent dye, and the control DNA is labeled with a different colored fluorescent dye. the control DNA is used as the base point of reference. <br />
heated and denatured single DNA strands then hybridize to their complementary single strand probes, which are then combined and applied to a microarray and the results are run through a computer program and a digital imaging system is used to quantify the results( fluorescent intensities of the labeled probes). <br />
<br />
simple explanation of aCGH : [Genomics Education (2014) Genetic Testing for Health: aCGH|https://vimeo.com/84757281]<br />
<ref>Genomics Education (2014) Genetic Testing for Health: aCGH [video file] Vimeo [https://vimeo.com/84757281]</ref><br />
<br />
<br />
The fluorescent ratio and the hybridization signal at different locations on the genome of the control DNA are used to identify any variances present in the sample DNA. aCGH facilitates the clinical diagnosis of submicroscopic chromosomal duplication, deletion and rearrangements indicative of chromosomal disorders such as trisomies 1-22and specific sex linked disorders. <br />
Duplications in the DNA are displayed by the computer program as spikes/ peaks over an established threshold and deletions in DNA are displayed by the computer program as spikes/ toughs beneath this threshold <br />
-computer screening image- <br />
-drawn diagram of method-<br />
<br />
<br />
<br />
{|border="1" align="center"<br />
|-bgcolor="pink" <br />
| '''Advantages''' <br />
| '''Disadvantages'''<br />
|-<br />
| multiple applications: prenatal genetic diagnosis, cancer diagnosis, <ref><pubmed>20193845</pubmed></ref> genetic screening for developmental delay (learning disabilities) <ref><pubmed>17309648</pubmed></ref>. or congenital anomalies that are suspected to be genetic in origin <ref>NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation . retrieved from [http://www.phgfoundation.org/file/5237/]</ref><br />
| translocations and inversions of DNA are not detected<br />
|-bgcolor="pink"<br />
| trace represents all chromosomes present in the human genome chromosomes 1-22 and the X & Y chromosomes, and therefore is the most accurate method for testing whole embryo aneuploidy<br />
| limited ability diagnosing specific polyploidies such as triploidy <ref> Unique, Rare Chromosome Disorder Support Group (2013) Microarray-based Comparative Genomic Hybridiation (array CGH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/other/array%20cgh%20ftnw.pdf] </ref><br />
|-<br />
| aCGH has been extensively tested, and Validated, and is now used world wide.<br />
| will not detect mosaicism detection <20% (cultures where >1 of 5 cells are trisomy 12)<br />
|-bgcolor="pink"<br />
| detects deletions and additions and rearrangements as well as amplification, of the WHOLE genome, simultaneously.<br />
| will not detect balanced chromosomal rearrangement<br />
|-<br />
| detects submicroscopic alterations<br />
| will not detect duplications or deletions <80kb<br />
|-bgcolor="pink"<br />
| used as a diagnostic tool for prenatal detection of chromosomal abnormalities <ref><pubmed>22034057</pubmed></ref><br />
| will not detect point mutations within genes <ref>Washington department of education (CGH- FAQ for physicians. Signature Genomic LAboratories, LLC. Retrieved from [https://depts.washington.edu/dbpeds/Lab%20Tests/SignatureCGH-physician_FAQ.pdf]</ref><br />
|-<br />
| provides high resolution genomewide screening of segmental genomic copy number variations<br />
| will not detect chromosomal position of genomic gains<br />
|-bgcolor="pink"<br />
| very accurate when used in conjunction with FISH<br />
| will not detect loos of heterozygosity (LOH) or Absence of heterozygosity (AOH) <ref>WiCell Research Institute Inc. (2012) Comparative Genomic Hybridization Microarray. <br />
retrieved from [http://www.wicell.org/home/cytogenetic-services/cgh-microarray/array-comparative-genomic-hybridization-acgh.cmsx]</ref><br />
|-style="background:pink"<br />
|Alone is more reliable and in detecting chromosomal abnormalities, with a higher implantation success rate, than FISH <ref><pubmed>20494259</pubmed></ref><br />
|<br />
|-bgcolor="pink"<br />
|Allows an in depth research focus upon specific types of rearrangements within selected chromosomal regions, a recent particular area of interest is subtelomeric and pericentromeric rearrangements<br />
|<br />
|-<br />
|reduces the risk of failed implantation and miscarriage, improving the chance of a healthy baby <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|<br />
|}<br />
<br />
<br />
<br />
===Next Generation Sequencing===<br />
====Description====<br />
The development and advances within ART in the past 20 years, as well as the increasing popularity of IV, has lead to an influx of new technologies developed to screen embryos for chromosomal anomalies, which are covered by the umbrella term of Next generation Sequencing (NGS). NGS is a general term used to describe all of the new and emerging screening techniques currently being introduced and used as part of PGD for IVF . NGS screens for single gene disorders as well as conducting extensive and very comprehensive chromosome diagnosis by sequencing, counting, and accurately assembling millions of DNA reads, simultaneously. <ref><pubmed>23499002</pubmed></ref> There is a movementfor NGS to replace the other limited testing techniques and be used as the standard. <br />
====Procedure====<br />
Samples are collected from either blastomere or the blastocyst/tropoectoderm and processed for analysis by a computer system. <br />
The methodology of each process is unique to the technique being used. <br />
<br />
<br />
<br />
{|border="1" align="center"<br />
|-bgcolor="pink" <br />
| '''Advantages'''<br />
| '''Disadvantages'''<br />
|-bgcolor="white"<br />
| cheaper<br />
| there are limited information available to clinical applications of NGS <ref><pubmed>26100406</pubmed></ref><br />
|-bgcolor="pink"<br />
| opens new diagnostic possibilities<br />
|<br />
|-bgcolor="white"<br />
| accurately tests all 24 chromosomes<br />
| <br />
|-bgcolor="pink"<br />
| tests for the presence of monogenic diseases of known genetic background<br />
| <br />
|-bgcolor="white"<br />
| reduces the number of biopsies required for diagnosis<br />
| <br />
|-bgcolor="pink"<br />
| higher detection rate of small translocations<br />
| <br />
|-bgcolor="white"<br />
| highly accurate is testing for compound point mutations, chromosomal duplication, deletions and insertions <ref><pubmed>23312231</pubmed></ref><br />
| <br />
|-bgcolor="pink"<br />
| it accurately detects chromosomal aneuploidy and unbalanced rearrangement <ref><pubmed>25685330</pubmed></ref><br />
| <br />
|-bgcolor="white"<br />
| NGS single gene disorder screenings can conducted in conjunction with PCR comprehensive chromosomal screening<br />
|<br />
|-bgcolor="pink"<br />
| Reduces human error <br />
|<br />
|-bgcolor="white"<br />
| better detects the presence of mosaicism<br />
|<br />
|-bgcolor="pink"<br />
| work well in conjunction with CGH and aCGH as part of PGD, improving the chances of IVF. <ref> Morris, R. S. (2015 ) Next generation sequencing for PCG|PGS|CCS. IVF1 retrieved from [http://www.ivf1.com/next-generation-sequencing for-pgd] </ref><br />
|<br />
|}<br />
<br />
<br />
<br />
<br />
<br />
<br />
==Diagnosis==<br />
There are a large amount of diseases that PGD can apply to, below are descriptions of the diseases that PGD are more commonly used for. <br />
===Cystic Fibrosis===<br />
Cystic fibrosis is a single gene disorder. It is autosomal recessive and involves mutations in the cystic fibrosis transmembrane conductance regulator (CTFR) gene. The CTFR gene is normally responsible for the decrease in chloride and the transport of bicarbonate in epithelial cells thus playing a major physiological role. In PGD procedures, identification of the gene is assisted by microsatellite markers that have similar composition to the CTFR gene itself. Biopsy of two cells at the blastocyst stage is recommended if markers are not available. There are many variations of cystic fibrosis the most common being P.Phe508del <ref name="PMID26014425"><pubmed>26014425</pubmed></ref>.<br />
===Duchenne Muscular Dystrophy ===<br />
Duchenne Muscular Dystrophy is an X-linked recessive disease. It involves the Xp21 gene where majority of the mutations are chromosomal deletions with a smaller percentage resulting from duplications <ref name="PMID18359022"><pubmed>18359022</pubmed></ref>.<br />
===β – Thalassemia=== <br />
β – Thalassemia is known as the most common type of autosomal recessive inherited disorder among haemoglobinopathies. It involves the adult β-globin gene and is associated with the absent or decreased expression of the gene. This is commonly caused by a single nucleotide change in the gene. PGD has been used successfully worldwide to identify the β-globin gene where its application is usually performed on a single blastomere or polar body <ref name="PMID19064120">19064120</pubmed></ref>.<br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
! Applicable diseases for PGD <ref>Genoma Group (2014). Retrieved September 18th, 2015, from http://www.preimplantationgeneticdiagnosis.it/genetic-diseases-diagnosed-by-pgd.htm </ref>, <ref>Genesis Genetics (2015). Retrieved September 18th, 2015, from http://genesisgenetics.org/pgd/what-we-test-for/</ref>, <ref>Human Fertilisation & Embryology Authority (2015). Retrieved Septembr 18th, 2015, from http://guide.hfea.gov.uk/pgd/</ref><br />
|-<br />
| '''Disease'''<br />
| '''Involved Genes'''<br />
|-<br />
| 5 Alpha Reductase Deficiency (5ARD)<br />
| SRD5A2 <br />
|-<br />
| Achondroplasia<br />
|FGFR3 <br />
|-<br />
| Acute Intermittent Porphyria <br />
| ALAD, ALAS2, CPOX, FECH, HMBS, PPOX, UROD, or UROS<br />
|-<br />
| Adrenoleukodystrophy (Adrenomyeloneuropathy)<br />
| ABCD1 <br />
|-<br />
| Agammaglobulinaemia (x-linked) <br />
|BTK <br />
|-<br />
| Agammaglobulinemia Bruton Tyrosine Kinase (BTK) <br />
|BTK <br />
|-<br />
| Aicardi Goutieres Syndrome 1 (AGS1) <br />
|TREX1, RNASEH2A, RNASEH2B, RNASEH2C, SAMHD1<br />
|-<br />
| Alagille Syndrome<br />
|JAG1 or NOTCH2<br />
|- <br />
| Alpers-Huttenlocher Syndrome <br />
|POLG <br />
|-<br />
| Alpha-1-antitrypsin deficiency <br />
|SERPINA1 <br />
|-<br />
| Alpha-Mannosidosis<br />
| MAN2B1 <br />
|-<br />
| Alpha Thalassemia <br />
|HBA1 or HBA2 <br />
|-<br />
| Alports Syndrome<br />
|COL4A3, COL4A4, COL4A5<br />
|-<br />
| Alzheimer's Disease - early onset (Type 3 and 4) <br />
|APP, PSEN1, or PSEN2<br />
|-<br />
| Amyotrophic Lateral Sclerosis 1 (ALS1) <br />
|C9orf72, SOD1, TARDBP, FUS, ANG, ALS2, SETX, VAPB <br />
|-<br />
| Argininosuccinic Aciduria <br />
| ASL<br />
|-<br />
| Arrhythmogenic Right Ventricular Cardiomyopathy/ Dysplasia (ARVC/D)<br />
| DSG2; DSP; PKP2<br />
|-<br />
| Ataxia Telangiectasia<br />
| ATM<br />
|-<br />
| Bardet-Biedl Syndrome (BBS)<br />
| BBS1; BBS10<br />
|-<br />
| Barth Syndrome<br />
| TAZ<br />
|-<br />
| Beta Thalassaemia<br />
| HBB<br />
|-<br />
| Birt-Hogg-Dubé Syndrome<br />
| FLCN<br />
|-<br />
| Breast Ovarian Cancer Familial Susceptibility (BRCA2)<br />
| BRCA1; BRCA2<br />
|-<br />
| Canavan Disease <br />
| ASPA<br />
|-<br />
| Carnitine-Acylcarnitine Translocase Deficiency <br />
| SLC25A20<br />
|-<br />
| Cerebral Arteriopathy with Subcortical Infarcts & Leukoencephalopathy (CADASIL)<br />
| NOTCH3<br />
|-<br />
| Cerebral Cavernous Malformation<br />
| CCM1<br />
|-<br />
| Charcot-Marie-Tooth Disease<br />
| GJB1; MPZ; NEFL; PMP22<br />
|-<br />
| CHARGE Syndrome<br />
| CHD7<br />
|-<br />
| Cherubism<br />
| SH3BP2<br />
|-<br />
| Choroideremia<br />
| CHM<br />
|-<br />
| Chronic Granulomatous Disease<br />
| CYBB; NCF1<br />
|-<br />
| Ciliary Dyskinesia<br />
| DNAH5<br />
|-<br />
| Citrullinemia<br />
| ASS1<br />
|-<br />
| Cleidocranial Dysplasia<br />
| RUNX2<br />
|-<br />
| Cockayne Syndrome<br />
| ERCC6<br />
|-<br />
| Congenital Adrenal Hyperplasia<br />
| CYP21A2<br />
|-<br />
| Congenital Cataracts<br />
| GJA8; VSX2<br />
|-<br />
| Congenital Diarrhea, Syndromic<br />
| SPINT2<br />
|-<br />
| Congenital Disorders of Glycosylation (CDG)<br />
| ALG1; ALG6; CDG1C; DOLK; PMM2<br />
|-<br />
| Cornelia de Lange Syndrome <br />
| NIPBL<br />
|-<br />
| Craniosynostosis<br />
| TWIST1<br />
|-<br />
| Crouzon Syndrome<br />
| FGFR2<br />
|-<br />
| Cysteinyl Leukotriene Receptor 1 Deficiency <br />
| CYSLTR1<br />
|-<br />
| Cystic Fibrosis<br />
| CFTR<br />
|-<br />
| Diamond –Blackfan Anemia <br />
| RPS19<br />
|-<br />
| Duchenne Muscular Dystrophy <br />
| DMD<br />
|-<br />
| Dyskeratosis congenita (Male embryos only)<br />
| DKC1<br />
|-<br />
| Ectodermal dysplasia (Hypohidrotic)<br />
| EDA; EDA1; GJB6; IKBKG<br />
|-<br />
| Familial Adenomatous polyposis coli (FAP)<br />
| APC<br />
|-<br />
| Familial Dysautonomia<br />
| IKBKAP<br />
|-<br />
| Fanconi Anemia <br />
| FANCA; FANCC; FANCD2; FANCF; FANCG; FANCJ<br />
|-<br />
| Fragile X Syndrome (FRAX)<br />
| FMR1<br />
|-<br />
| Galactosemia <br />
| GALT<br />
|-<br />
| Gangliosidosis<br />
| GLB1<br />
|-<br />
| Glanzmann Thrombasthenia <br />
| ITGA2B<br />
|-<br />
| Glutaric Acidemia (aciduria)<br />
| GCDH <br />
|-<br />
| Glycogen Storage Disease <br />
| G6PC; GAA; SLC37A4<br />
|-<br />
| Haemophilia A<br />
| F8<br />
|-<br />
| Haemophilia B<br />
| F9<br />
|-<br />
| Hereditary Nonpolyposis Colorectal Cancer: Lynch Syndrome<br />
| MLH1; MSH2; MSH6<br />
|-<br />
| Holt Oram Syndrome<br />
| TBX5<br />
|-<br />
| Huntington Disease<br />
| HD<br />
|-<br />
| Hydrocephalus<br />
| L1CAM<br />
|-<br />
| Ichthyosis <br />
| ABCA12; STS<br />
|-<br />
| Incontinentia Pigmenti (IP)<br />
| NEMO<br />
|-<br />
| Joubert Syndrome 5<br />
| INPP5E<br />
|-<br />
| Krabbe Disease<br />
| GALC<br />
|-<br />
| Leber Congenital Amaurosis (LCA)<br />
| CEP290; GUCY2D<br />
|-<br />
| Leigh Syndrome (Infantile Subacute Necrotising Encephalopathy)<br />
| LRPPRC<br />
|-<br />
| Lesch Nyan Syndrome<br />
| HPRT1<br />
|-<br />
| Leukocyte Adhesion Deficiency (Type I)<br />
| ITGB2<br />
|-<br />
| Li-Fraumeni Syndrome<br />
| TP53<br />
|-<br />
| Macular Dystrophy Retinal <br />
| VMD2<br />
|-<br />
| Maple Syrup Urine Disorder (MSUD)<br />
| BCKDHB<br />
|-<br />
| Marfan Syndrome <br />
| FBN1<br />
|-<br />
| Menkes Syndrome<br />
| ATP7A<br />
|-<br />
| Mitochondrial DNA Depletion Syndrom <br />
| POLG; RRM2B; SUCLA2; TK2<br />
|-<br />
| Mucolipidosis type II<br />
| GNPTAB<br />
|-<br />
| Multiple Endocrine Neoplasia<br />
| MEN1; MEN2A; MEN2B<br />
|-<br />
| Multiple Exostoses<br />
| EXT1; EXT2 <br />
|-<br />
| Myotubular myopathy<br />
| MTM1 <br />
|-<br />
| Nail-Patella Syndrome<br />
| LMX1B<br />
|-<br />
| Neurofibromatosis Type 1<br />
| NF1<br />
|-<br />
| Neurofibromatosis Type 2 <br />
| NF2<br />
|-<br />
| Noonan Syndrome<br />
| KRAS, PTPN11; SOS1<br />
|-<br />
| Norrie Disease<br />
| NDP<br />
|-<br />
| Ocular Albinism <br />
| GPR143<br />
|-<br />
| Oculocutaneous Albinism <br />
| OCA2; TYR <br />
|-<br />
| Oculodentaldigital Dysplasia<br />
| GJA1<br />
|-<br />
| Optic Atrophy<br />
| OPA1<br />
|-<br />
| Ornithine Transcarbamylase Deficiency <br />
| OTC<br />
|-<br />
| Osteogenesis imperfeca <br />
| COL1A1; COL1A2<br />
|-<br />
| Osteopetrosis <br />
| CLCN7; OSTM1; TCIRG1<br />
|-<br />
| Pachyonychia Congenita <br />
| KRT16; KRT6A<br />
|-<br />
| Pancreatitis, Hereditary<br />
| PRSS1 <br />
|-<br />
| Papillorenal syndrome <br />
| PAX2<br />
|-<br />
| Phenylketonuria <br />
| PAH <br />
|-<br />
| This table does not cover the complete list of diseases that PGD can be applied to.<br />
|}<br />
<br />
==Laws & Legal status==<br />
===Australia=== <br />
PGD is currently used to detect serious genetic conditions to improve the outcome of Assisted Reproductive Technologies (ART). In very rare cases it may be used to select an embryo with compatible tissue for a sibling who has a life-threatening disease where other means of treatment is unavailable. This is with the conditions that the use of PGD will not affect the welfare and interests of the child to be born. The parents must also receive adequate counselling and have full understanding of the procedures of PGD. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"> National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art</ref><br />
The use of PGD for sex-selection is prohibited with the exception of reducing the risk of the transmission of serious sex-linked genetic conditions. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"/><br />
===Brazil=== <br />
The laws regarding PGD in Brazil are not strictly regulated. They are vague and there is limited information surround the activities of assisted reproduction in general in the country <ref name="PMID25493379"><pubmed>25493379</pubmed></ref>.<br />
===Czech Republic===<br />
The laws in the Czech Republic allow those with a “defined indication in order to exclude risk of serous genetically conditioned disease and defects with embryos before they are implanted into the cavity of the uterus”. Couples that undergo any assisted reproductive treatment including PGD have to be married. Sex-selection is illegal except in regards to serious sex-linked genetic diseases <ref name="PMID24777348"><pubmed>24777348</pubmed></ref>.<br />
===Greece=== <br />
In Greece, ART is open to those up to the age of 50 with written consent. It can only be used if a medical necessity is present such as the susceptibility of serious hereditary diseases. Sex selection is banned apart from cases of sex-linked diseases and sexually transmitted diseases <ref name="PMID24777348"/>.<br />
===Portugal=== <br />
ART is only available to those who are married or have a similar type of relationship for at least two years. The couples cannot be of the same sex and must be at least 18 years of age. Sex selection is illegal except in cases of sex-linked diseases. The use of PGD is illegal if the predictive value of genetic tests are very low <ref name="PMID24777348"/>.<br />
===Spain===<br />
PGD can be applied to “serious hereditary diseases not amenable to postnatal curative treatment” and “detection of other abnormalities which may compromise the viability of the pre-embryo”. If PGD is to be used for any other purpose authorisation must be acquired <ref name="PMID24777348"/>.<br />
===Sweden=== <br />
The use of PGD is strictly regulated and couples must achieve authorisation of the National Board of Health and Welfare. It can only be used it can only be used if the child is at risk to inheriting a serious chromosomal or monogenetic disease. It cannot be used for selection of specific characteristics <ref name="PMID24777348"/>.<br />
===United Kingdom===<br />
Those involved with carrying out the IVF treatment must have a license from the Human Fertilisation and Embryology Authority (HFEA). Only embryos that are approved by the HFEA can be implanted where the embryonic nuclear or mitochondrial DNA cannot be altered with the exception of preventing mitochondrial diseases <ref name="PMID24777348"/>. <br />
==Future/Current Research==<br />
===Noninvasive Preimplantation Genetic Testing without Embryo Biopsy===<br />
Different parameters of gametes, zygotes, embryos (“vacuoles in sperm heads, spindle position in mature oocytes, cleavage intervals of zygote, and embryo developmental dynamics”) may correlate with aneuploidy rates. This knowledge may be applied in potential noninvasive preimplantation diagnostic methods. Several methods have been proposed and are currently further researched<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Sperm Selection====<br />
Intracytoplasmic morphologically selected sperm injection (IMSI) is common procedure in IVF treatment to improve fertilization rates in patients with poor semen quality. In addition, studies have found that IMSI improves embryo development and that spermatozoa with large vacuoles in their heads correlate with increased aneuploidy rates and disturbed chromosomal structures. Thus, selecting spermatozoa based on morphological hallmarks may decrease aneuploidy rates in the fertilized embryos. As with polar body biopsies, however, this approach will solely be applicable if evidence for severe male detrimental contribution is given<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Blastocoel Fluid Extraction====<br />
In addition, a less invasive retrieval of material for diagnosis could include the extraction of the blastocoel fluid. The cavity of the blastocyst, lined by the trophectoderm, is filled with this blastocoel fluid, which contains metabolites of both trophectoderm and inner cell mass origin. The retrieval does not require a biopsy but merely a small opening to extract the fluid and, thus, causes less harm to the embryo. Multiple studies have applied this method<ref name="PMID22020776"><pubmed>22020776</pubmed></ref> <ref name="PMID23148560"><pubmed>23148560</pubmed></ref> and it may in the future become of clinical relevance.<br />
<br />
{|border="1"<br />
| [[File:Aspiration_of_the_Blastocoel_Fluid.jpeg]]<br />
|-<br />
| Aspiration of the Blastocoel Fluid using a ICSI pipette<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
|}<br />
<br />
<br />
Next to metabolites, the blastocoel fluid can contain DNA. Studies have shown that genomic DNA is present in about 90% of the blastocoel fluid samples tested. Typically the fluid is removed with an ICSI pipette from a day five blastocyst through its mural trophectoderm until the blastocyst fully collapses around the embryo. Several concerns regarding this method in a clinical setting have been raised. The collected DNA may be contaminated by the culture media that contains DNA fractions. The DNA may also be least representative of the actual embryos genome as the DNA may originate from abnormal or degenerated cells. Even though labelled noninvasive, the blastocyst still undergoes manipulation to some degree which may affect its viability. Thus, more research is required until this method can evolve from research to clinical use<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
====Proteomics====<br />
The protein secretome of blastocysts may be representative of its chromosome constitution Recent studies have found biomarkers such as lipocalin-1, interleukin-10, tumor necrosis factor, stem cell factor, and chemokine ligand 13 to be differently secreted by aneuploid blastocyst than by euploid ones. The most significant biomarker appears to be interleukin-10. Paired with novel proteomic technologies and mass spectrometry this knowledge when extended may contribute to a new invasive preimplantation genetic diagnosis method<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Embryo Morphology====<br />
Using time lapse imaging the embryo’s morphology can be closely observed and potential aneuploidy characteristics detected. Such characteristics may include the time of division to five cells, the time between the division from three to four cells, and the duration of the division from one to two and subsequently to three. In addition, the morphological quality of ICM an TE has been positively associated with aneuploidy or euploidy prognosis<ref name="PMID26246880"><pubmed>26246880</pubmed></ref>. These may give rise to an embryo quality screening prior to implantation<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
===Utilization of Diseased Cell Lines===<br />
==Ethics==<br />
==References==<br />
<br />
<references/><br />
<br />
<br />
{{StudentPage2015}}</div>Z5017878https://embryology.med.unsw.edu.au/embryology/index.php?title=2015_Group_Project_6&diff=2065632015 Group Project 62015-10-19T12:12:27Z<p>Z5017878: </p>
<hr />
<div>{{ANAT2341Project2015header}}<br />
<br />
<br />
=Prenatal Genetic Diagnosis=<br />
==Introduction==<br />
==History==<br />
Prenatal Genetic Diagnosis was historically conducted post-implantation in the first 2 trimesters <ref> Blackburn, S.L. (2003) '''Maternal, Fetal & Neonatal physiology: a Clinical perspective''' (2nd ed.). Seattle: Saudners </ref>, testing for overall fetal growth, complications of pregnancy, birth defects as well as chromosomal or genetic abnormalities<ref> Sadler T.W.(2012) '''Langman's Medical Embryology''' (12th ed.) Philadelphia: Lipincott, Wiliams & Wilkins, a Wolters Kluwer Business </ref>. Due to advancements in Artificial Reproductive Technologies ( ART) in the past 2 decades , these genetic tests are now conducted as a part of Preimplantation Genetic Diagnosis (PGD) <ref><pubmed>20638568</pubmed></ref> and art used to eliminate the rsik of passing on a genetic disorder to an offspring, before implantation, it ha now become a preventative measure. . In 1990 Preimplantation genetic testing was first used in 1990 on humans to diagnose recessive X-linked diseases in the embryos of pregnant women undergoing IVF. <ref><pubmed>2330030</pubmed></ref> PGD is offered as an alternative to prenatal diagnosis in detecting genetic disorders in high risk couples <ref><pubmed>26168107</pubmed></ref> and avoid passing an inherited disease to the offspring, by selecting genetically "normal" embryos for implantation ,to give the best chance of successful implantation , stable pregnancies and healthy children. <br />
<ref><pubmed>23499002</pubmed></ref><br />
<br />
==Preimplantation Genetic Diagnosis==<br />
[[File:Preimplantation Genetic Diagnosis Procedure.jpeg|700px|thumb|centre| Simplified steps for PGD]]<br />
<br />
<br />
Preimplantation genetic diagnosis (PGD) is used to test the genetic makeup of embryos to detect single gene disorders, chromosomal abnormalities and mitochondrial disorders. It also has applications in gender selection for diseases with unequal gender distributions <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Some diseases commonly involved with PGD include cystic fibrosis, spinal muscular atrophy and beta – thalassaemia <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press.">Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press</ref> <ref name="PMID17823145"><pubmed>17823145</pubmed></ref>. It was first used in the United Kingdom in the 1980s of arenoleucodystrophy and primarily focusing on sex- linked disorders <ref name="PMID17823145"/><ref name="PMID23150080"><pubmed>23150080</pubmed></ref>. PGD is now capable of detecting single cell defects (molecular) and chromosomal disorders resulting from the inversion, translocation or deletion of chromosomes (cytogenic) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>,<ref name="PMID11325751"><pubmed>11325751</pubmed></ref>. PGD can be applied to the embryo at different stages. That is on polar bodies, blastomeres or blastocyst <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>.<br />
Depending on the type of genetic disorder, PGD utilises different methods of genetic testing. These include Fluorescence in situ hybridisation (FISH) which is used for sex – linked disorders and detects chromosomal rearrangements <ref name="PMID11325751"/><ref name="PMID17876073"><pubmed>17876073</pubmed></ref> and Embryo halotyping which allows the identification of chromosomes causing the inherited disorder through knowledge of the pattern of closely linked markers <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. Polymerase chain reaction (PCR) is also widely used to detect molecular abnormalities <ref name="PMID11325751"/>.<br />
PGD is tightly regulated and supported by large organisations namely The American Society for Reproductive Medicine, The European Society for Human Reproduction and Embryology (ESHRE), The European Society of Human Genetics and the Preimplantation Genetic Diagnosis International Society <ref name="PMID25500181><pubmed>25500181</pubmed></ref>.<br />
===Sex-linked disorders===<br />
The determination of a disease as gender specific usually correlates with the presence or absence of specific genes such as SRY on the Y chromosome. It is known that females have two X chromosomes and males have an X and a Y chromosome where abnormalities are more prevalent on the X chromosome. PGD can be used for sex selection where only male embryos are transferred to reduce the chance of inheriting X-linked disorders. However, this does not completely eradicate the problem as male embryos remain susceptible to inheriting an affected X chromosome. Sex determination is only used when the specific mutation is unknown and has yet to be discovered <ref name="PMID24866878"><pubmed>24866878</pubmed></ref>.<br />
===Single gene defects===<br />
Single gene defects can be dominant, recessive, autosomal or X-linked. They are commonly diagnosed using PCR and although the PCR available today is complex and capable of combatting a large range of disease the development of new protocols has been proven to be difficult due to the small DNA sample available <ref name="PMID26168107"><pubmed>26168107</pubmed></ref><br />
===Mitochondrial disorders===<br />
Mitochondrial disorders also known as oxidative phosphorylation disorders arise from mutations in the nuclear DNA or mitochondrial DNA <ref name="PMID26312584"><pubmed>26312584</pubmed></ref>. They pose as a problem because they are unrecognisable until the mutations in the cell reach a detrimental level <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Mitochondrial disorders cause miscarriages and stillbirths as well as death in children and young adults. The effects can either be contained in a single organ or more commonly involve multiple organ failure where organs with high energy demands such as the brain, liver muscle and heart and heavily influenced. They are usually occur spontaneously or result from inheritance from the mother. Since mitochondria are solely inherited from the mother oocyte donations have been used as a solution to combat mitochondrial disorders. Additionally, there has been an increasing use in PGD where embryos that stay under the given threshold of 18% gene-mutations are allowed to be transferred and result in normal development. New technology in the areas of nuclear gene transfer and genome editing are also being experimented with <ref name="PMID26312584"/>. <br />
===Chromosomal disorders===<br />
Chromosomal disorders can be reciprocal, Robertsonian translocations, inversions, deletions and insertions <ref name="PMID26168107"/>. . Data from ESHRE collected between 2010 and 2011 has shown that the most common chromosomal abnormality confronted in PGD are reciprocal chromosomal abnormalities <ref name"PMID26071418"><pubmed>26071418</pubmed></ref>. PGD has also been used successfully for Robertsonian translocations (RT), a type of structural translocation. Children who carry RT are phenotypically normal, however in their later years it is found that they will suffer from infertility and repeated miscarriages due to the high frequency of abnormal embryos <ref name="PMID22081077"><pubmed>22081077</pubmed></ref>. PCR and FISH are the two main techniques used for chromosomal disorders. To be able to conduct the examinations the cells are required to be at the metaphase stage <ref name="PMID26168107"/>. <br />
==Preimplantation Genetic Screening==<br />
Prenatal Genetic Screening (PGS) involves an array of methods or ideas that aim to segregate embryos that have genetic flaws and those that are healthy <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. The occurrence of aneuploidy is high around the stages of early embryonic development and they are the most common cause if miscarriages and congenital birth defects <ref name= "PMID26085841"><pubmed>26085841</pubmed></ref>. They have little effect on the morphology of the embryo making them difficult to identify thus identification heavily relies on genetic testing <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. <br />
Genetic sampling is most commonly conducted using Microarray Comparative Genomic Hybridisation (aCGH) as well as FISH, Quantitative PCR and Single Nucleotide Polymorphism (SNP) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. These methods collectively aim to assess numeral and structural chromosomal errors <ref name= "PMID26085841"/>. Studies have also introduced Next- Generation Sequencing (NGS) <ref name= "PMID26085841"/> and Whole Genome Amplification used to screen imbalances in the complete 24-chromosomes <ref name="PMID25953353"><pubmed>25953353</pubmed></ref><br />
Statistics from ESHRE have shown that the most common indications for PGS is advanced age, followed by repeated implantation failure or recurrent miscarriage and male infertility <ref name="PMID26071418"><pubmed>26071418</pubmed></ref>.<br />
====Indications====<br />
A low percentage of structural abnormalities in chromosomes are responsible for the cause of miscarriages. Despite this, they are the most prevalent type of chromosomal abnormality accounted for in PGD <ref name="PMID20638568"/>. The presence of specific gene cycles, initiation of embryonic protein synthesis and evident physiological development are all indicative of a successful in vitro fertilisation procedure <ref name="PMID11576737"><pubmed>11576737</pubmed></ref>. To eliminate further errors from occurring during the PGD procedure it is recommended to undertake further prenatal testing such as amniocentesis in the later stages <ref name="PMID20638568"/>. <br />
=====Advanced maternal age=====<br />
Data provided by the ESHRE has shown that the mean age of women undergoing PGS is 39 years <ref name="PMID26071418"/>. Women of advanced age have been shown to have a lower rate of pregnancies reaching childbirth <ref name="PMID18583331"><pubmed>18583331</pubmed></ref>. The highlighted concern revolves around the increased occurrence of aneuploidy following maternal age. The optimal age range for the lowest aneuploidy incidence was found to be between 27 to 37 years of age (6%) then progressively higher in women aged up to 42 (33%) and most common in those 44 and above (53%) <ref name="PMID24355045"><pubmed>24355045</pubmed></ref>. <br />
=====Recurrent pregnancy loss / IVF failure=====<br />
Recurrent pregnancy loss is defined as three or more IVF failures after cumulative transfer of more than 10 good-quality embryos. These are primarily caused by two main factors, reduced endometrium receptivity or embryonic defects. Endometrium receptivity can be negatively influences by instances including uterine pathologies such as thin endometrium, altered expression of adhesive molecules and immunological factors. Additionally, embryonic defects may be due to genetic abnormalities, embryonic aneuploidy or zona hardening. Endometriosis and hydrosalpinx has been known to effect both the endometrium and embryo <ref name="PMID23260857"><pubmed>23260857</pubmed></ref>.<br />
=====Human leukocyte antigen matching=====<br />
First used in 2001, HLA matching is an option given to parents to save a child with haematological or immunological disease through conceiving another child who would potentially be able to donate cord blood or haematopoietic stem cells from the bone marrow for transplantation. The process namely PGD-HLA has shown to improve haematopoietic stem cell transplant (HSCT). PGD-HLA can only be performed when HSCT is not needed urgently due to the time needed to conceive and delivery the baby <ref name="PMID25500181"><pubmed>25500181</pubmed></ref>. It is most commonly applied to children suffering from relapsed leukaemia <ref name="PMID22524201"><pubmed>22524201</pubmed></ref>. In a case study PGD-HLA was proven to successfully cure 10 diseases including Fanconi anaemia, Diamond-Blackfan anaemia and beta thalassemia <ref name="PMID25066893><pubmed>25066893</pubmed></ref>.<br />
==Biopsy Methods==<br />
Biopsy, the removal of genetic materials, from oocytes or embryos in the preimplantation stage is the primary step in PGD. For the past two decades these biopsies have been performed at three stages, the polar body, blastomere, and blastocyst, and the methodologies optimized to ensure the embryo’s viability. The most common approach involves biopsies at the cleavage stage. However, polar body and blastocyst biopsies are increasingly more often tested and applied. Approached for opening the zona pellucida involve next to the traditional mechanical and chemical means, novel approaches such as noncontact lasers. Their application may simplify and secure the procedure significantly. The most challenging question about PGD procedures remains at what stage biopsies should be taken. Much controversy has developed around this topic, highlighting the varying disadvantages and advantages of temporal biopsies. <ref name="PMID22723007"><pubmed>22723007</pubmed></ref><br />
<br />
{|border="1" align="left"<br />
|-bgcolor="pink" <br />
|<br />
| Time of Biopsy<br />
| Advantages <br />
| Disadvantages<br />
|- <br />
| Polar Body<br />
| Day 1<br />
| No harm to oocyte<br />
| Only maternal DNA is tested, often needs to be coupled with other biopsies<br />
|-bgcolor="pink"<br />
| Blastomere<br />
| Day 3<br />
| …<br />
| … <br />
|-<br />
| Trophectoderm<br />
| Day 5 and 6 <br />
| Little harm, large amount of genetic material<br />
| Opening of blastocyst necessary, small time window for procedure<br />
|}<br />
<br />
{|border="1"<br />
| [[File:Polar_Body,_Blastomere,_and_Trophectoderm_Biopsy.jpeg]]<br />
|-<br />
| Polar body (A), blastomere (B) and trophectoderm (C) biopsies<ref name="PMID25625041"><pubmed>25625041</pubmed></ref>.<br />
|}<br />
<br />
PMID 24305177<br />
===Polar Body Analysis===<br />
Day 1<br />
====Description====<br />
Polar body (PB) biopsy, which was introduced in 1990, offers a promising alternative to biopsies performed at the blastomere stage for PGD/S indications on legal and practical grounds. <br />
Description: Consequent embryo development does not necessitate the presence of the first and second PB and their removal may not be crucial. PB biopsy requires precise timing. Keeping track of the meiotic cell cycle is necessary to perform a successful biopsy and, therefore, PB biopsy usually is applied in combination with intracytoplasmic sperm injection (ICSI). During the maturation from the germinal vesicle stage to the metaphase-II stage the first PB is formed. A cytoplasmic bridge containing spindle remnants, that are still in contact with the cellular genetic material, links this PB to the oolemma for about 90 minutes after extrusion. It is possible to visualize these remnants by polarization microscopy and it is crucial to not perform the biopsy until the first PB is no longer firmly attached to the oolemma as this indicates an immature embryo.The oocyte tolerates mechanical zona dissection best during hours four until six after ICSI as the oolemma has stabilized by that time because of the cortical granule reaction. Over time the first PB degenerates stressing a temporal biopsy and its optimal extraction time window is four to 12 hours after ICSI. The second PB forms around two to four hours after ICSI. However, its optimal time window for biopsy is set to be eight to 16 hours after ICSI. This is due to the second PB being attached to the oolemma with spindle remnants until six hours after ICSI. Biopsy at this point may cause enucleation of the oocyte. In addition, studies have shown that the amplification efficiency of second PB’s DNA is worse if the PB is extracted prior to eight hours after ICSI. <br />
Thus, it is possible to perform sequential and simultaneous biopsies for the first and second PB. If performed, sequentially the first PB may be removed four to 12 hours and the second PB eight to 16 hours after ICSI. The optimal time window for a biopsy for both the first and second PB simultaneously is eight to 12 hours after ICSI. It is highly preferred to analyze both PBs due to potential aneuploidies in either PB and crossing overs during meiosis<ref name="PMID22723007"/>. <br />
====Procedure====<br />
Chemical opening achieved with for example acidic tyrode’s solution of the zona pellucida is not tolerated by the oocyte and may have detrimental effects on the embryo’s development. Therefore, the access to the perivitelline space of the oocyte is provided by mechanical zona dissection or by laser. Both techniques work well if performed by experienced embryologist. However, laser-assisted biopsy is less time consuming when compared to manual dissection. It is critical to consider the size of the introduced opening as it will remain permanent. If it is too large the blastomere may be lost during embryo development and if it is too small it may interfere with hatching of the embryo during blastocyst stage<ref name="PMID22723007"/><br />
<br />
{|border="1"<br />
| [[File:Polar_Body_Biopsy.jpeg]]<br />
|-<br />
| The presence of a faint but clearly identifiable strand connecting PB2 to the <br />
oolemma. The biopsy was performed ∼9 h after ICSI<ref name="PMID21908464"><pubmed>21908464</pubmed></ref>.<br />
|}<br />
<br />
{|border="1"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JTaQzszVr8o</html5media><br />
|-<br />
| Laser-assisted polar body biopsy<ref>RIUK, R. (2013, June 25) Polar Body Biopsy [Video file]. Retrieved from https://www.youtube.com/watch?v=JTaQzszVr8o</ref><br />
|}<br />
<br />
====Advantages & Disadvantages====<br />
PB biopsies can only investigate the maternal contributions to the embryo as they are of maternal origin. Thus, this procedure is appropriate for PGD solely for monogenetic diseases from the maternal side. Recessive diseases may be evaluated with PB biopsies on the basis that the embryo’s outcome will be determined by the paternal contribution. (...) It may still be applied for PGS as most aneuploidies either arise during meiosis or origin from the maternal genome. However, diagnosis error has been reported due to the lack of considering paternal contributions. <br />
Because PB biopsies are performed very early it is not yet known whether the oocyte will develop into a viable embryo. Thus, PBs are commonly frozen or fixed after biopsy and depending on the state of the embryo only chosen PBs will be tested. This is primarily an economic issue as many genetic testing procedures are very cost-intensive<ref name="PMID22723007"/>.<br />
<br />
{|border="1"<br />
| [[File:Implantation_predictive_value_of_euploid_screening_results.jpeg]]<br />
|-<br />
| The sustained implantation predictive value (with 95 % confidence interval) of a euploid screening result obtained from the first polar body (PB1), PB1 and the second polar body (PB2), or a direct embryo biopsy for each stage of embryo transfer (cleavage-stage and blastocyst stage)<ref name="PMID25106935"><pubmed>25106935</pubmed></ref>.<br />
|}<br />
<br />
===Blastomere biopsy===<br />
Day 3 <br />
====Description====<br />
Blastomere biopsy has been the prevalent method for PGD and PGS in the last two decades. At least one, but up to two, blastomeres are biopsied on day three of the cleavage stage embryo. The right number of blastomeres removed is a controversial topic as two cells allow for more genetic material and more accurate results. However, removing two cells might be too invasive and damaging to the embryo. (Study)<ref name="PMID21748341"><pubmed>21748341</pubmed></ref><br />
====Procedure====<br />
Initially a hole was drilled into the zona pellucida using acid tyrodes and the blastomeres are removed via aspiration with a pipette<ref name="PMID21748341"/>.<br />
<br />
{|border="1"<br />
| [[File:Aspiration_of_a_Blastomere.jpeg]]<br />
|-<br />
| Aspiration of a Blastomere into the biopsy pipette<ref name=" PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
|}<br />
<br />
{|border="1"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=TbridWVwipI</html5media><br />
|-<br />
| Laser-assisted blastomere biopsy<ref>Sukprasert, M. (2014, March 5) Day 3 Blastomere Biopsy 1 [Video file]. Retrieved from https://www.youtube.com/watch?v=TbridWVwipI</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
===Trophectoderm biopsy===<br />
Day 5 and 6<br />
====Description====<br />
The improvement of embryo culture media allowed the in vitro development of human embryos until the blastocyst stage and opened up the possibility to take blastocyst biopsies. During day three to day five the haploid maternal and paternal genomes work together for the first time to form the genome of the embryo. The maternal epigenetic control lessens significantly while preparing for implantation with precisely arranged events happening. The first event includes a rapid increase in the number of embryonic cells which are active in mitotic divisions and apoptosis of aberrant cells. This is followed by the formation of blastocoel (cavitation) which results from the flattening of cell located on the outside of the blastomere. Now the blastocyst will expand until the embryo hatches by rupturing the zona pellucida. The cells of the blastocyst will differentiate to form two distinct cell lineages, the outer trophectoderm and the inner cell mass<ref name="PMID22723007"/>.<br />
====Procedure====<br />
Trophectoderm biopsy is usually performed in Hepes buffered biopsy medium and opening approaches include needle cutting which has been replaced by lasers in past years. Different research groups report different timings of the opening to be the most successful. Some open the blastocyst on day three or four by creating a 25 µm which causes the trophectoderm to herniate through this hole and is, thus, accessible for biopsy. Others create this hole about four hours before biopsy which allows sufficient herniation of trophectoderm cells. It is also possible to open the blastocyst immediately before biopsy. This avoids an extra step and the inner cell mass usually is easy to locate. Blastocyst biopsies involve the removal of trophectoderm cells and the ideal time for the procedure is day five. Successful biopsies on day six have been performed, while little is known about the results of biopsies on day seven. However, since the window of implantation in humans is from day eight to ten after ovulation, day seven biopsies appear to be possible<ref name="PMID22723007"/>.<br />
-collapse of trophoblasts<br />
-possible: biopsy of hatched blastocyst, holding pipette careful mild suction force to hold embryo near ICM <br />
-Cryopreservation<br />
<br />
{|border="1"<br />
| [[File:Microscopic images of human blastocysts for biopsy.jpeg]]<br />
|-<br />
| (A) Some trophectoderm cells in a blastocyst started to hatch and (B) the trophectoderm cells were biopsied with assisted laser cutting. Images in C–D show the blastocysts after vitrification and warming. Blastocysts had been cultured for 2–4 hrs after warming, showing good (ICM and trophectoderm cells) hatched (C) and hatching (D) blastocysts. The hatching blastocyst in (E) has good ICM but fair trophectoderm while the blastocyst in (F) has both fair ICM and trophectoderm. Arrows indicate ICMs and arrow heads indicate trophectoderm cells. Bar = 40 µm<ref name="PMID2190846"><pubmed>2190846</pubmed></ref>.<br />
|}<br />
<br />
<br />
{|border="1"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JI_TQ8d8tNM</html5media><br />
|-<br />
| Laser-assisted blastocyst biopsy (at 00:50 min)<ref>Coco, R. (2014, April 30) Trophectoderm biopsy in a Hatching blastocyst protruding ICM [Video file]. Retrieved from https://www.youtube.com/watch?v=JI_TQ8d8tNM</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
Blastocyst biopsies are believed to be less damaging to the embryo and appear to be unrelated to implantation rates. In addition, this biopsy method allows for a larger extraction of cells for genetic testing. However, since they are performed late in in vitro development, the time window for genetic testing is relatively small. Fast and accurate genetic testing methods are needed to ensure a successful and safe result from this biopsy. Thus, blastocyst biopsies may gain more popularity in the future whn such methods have been developed or improved<ref name="PMID22723007"/>. <br />
<br />
<br />
==Genetic Techniques==<br />
<br />
===PCR===<br />
====Description====<br />
Polymerase chain reaction (PCR) amplifies DNA specific to genetic sequence of interest . PCR was developed by Kay Mullis in the 1980s, for which he was awarded the Nobel prize for chemistry in 1993. <ref> Pubmed Docs (2015) Polymerase Chain Reaction (PCR) Pubmen. Retrieved from [http://www.ncbi.nlm.nih.gov/probe/docs/techpcr/]</ref> This technique enables clinicians to monitor and diagnose diseases using minute samples such as embryonic cells, blood & tissue. <ref>Roche (2015) PCR: How We Copy DNA. Roche Molecular Systems Inc. retrieved From [http://molecular.roche.com/pcr/Pages/Process.aspx]</ref> PCR has many important applications like DNA fingerprinting, genetic mapping, detection of viruses and bacteria as well as being used to detect genetic disorders, as a part of PGD, in conjunction with IVF. It is used to detect molecular abnormalities such as single gene disorders like Tay Sach, Cycstic fibrosis, Duchenne Muscular Dystrophy, Thalassemia, Huntington disease, Spinal muscular atrophy and many more. Molecular and Genetic analysis require a significant amount of DNA, which we would not have without PCR. It revolutionized the study of DNA, replacing all previous recombinant DNA technology. <ref> Mullins, K., Francois, F.& Gibbs R.A. (1994 ) The Polymerase Chain Reaction. p3. Springer- Science +Business Media. Birkhauser, Boston<br />
Available at [https://books.google.com.au/books?hl=en&lr=&id=gjrTBwAAQBAJ&oi=fnd&pg=PR5&dq=kary+mullis+PCR&ots=mpzAyRh5ZY&sig=PQ4goNoKJ90tb3-MkPk62zrTGbw#v=onepage&q=kary%20mullis%20PCR&f=false] </ref> <br />
<br />
====Procedure====<br />
<br />
Sample are obtained from the the blastocyst, a polar body biopsy or the blastomeres stages of the embryo. <br />
Stage 1 Denaturing: separating the target strands of DNA <br />
The obtained sample is heated to roughly 90 degrees celcius, this heat causes breaks the relatively weak bonds between nucleotides that form DNA. the double stranded DNA to split into 2 single strands of DNA that are used as templates.<br />
Stage 2 Annealing: Binding the Primers to the target DNA sequence <br />
PCR will only copy the target sequence of DNA specified by specific PCR primer. These synthesized primers Oligonucleotides are small artificial pieces of DNA. <br />
TAQ polymerase enzyme synthesize 2 new strands of DNA duplicate to the single sample DNA stand template indicated by these primers. During this stage the reaction is cooled to a temperature between 40-60 degrees Celsius. <br />
Stage 3- Extension- making copies <br />
Each of these 2 copies are then used again as templates generating 2 further replications This cycle can occur as many 30 -40 times within a couple hours leading to billions of extra copies of the original DNA segment. The optimal temperature for the further replication is roughly 72 degrees Celsius. <br />
<br />
This process mediated by a thermocycler machine that is programmed to alter the temperature of the reaction every couple of minutes, perpetuating the cycle of DNA denaturing and synthesis. <br />
This process, generates exponential exact copy of the original template DNA sequence. <br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
!PCR cycles<br />
<br />
|{|<br />
|-bgcolor="lightpink"<br />
| '''PCR Cycle'''<br />
| '''Target Copies'''<br />
|-<br />
| 1<br />
| 2<br />
|-bgcolor="pink"<br />
| 2<br />
| 4<br />
|-<br />
| 3<br />
| 8<br />
|-bgcolor="pink"<br />
| 4<br />
| 16<br />
|-"<br />
| 5 <br />
| 32<br />
|-bgcolor="pink"<br />
| 6 <br />
| 64<br />
|-<br />
| 7 <br />
| 128<br />
|-bgcolor="pink"<br />
| 8<br />
| 256<br />
|- <br />
| 9<br />
| 512 <br />
|-bgcolor="pink"<br />
| 10<br />
| 1024<br />
|-<br />
| 15<br />
| 32,768<br />
|-bgcolor="pink"<br />
| 20 <br />
| 1,048,578<br />
|-<br />
| 25<br />
| 33,554,432<br />
|-bgcolor="pink"<br />
| 30 <br />
| 1,073,741,842<br />
|-<br />
|}<br />
<br />
<br />
<br />
<br />
{|border="1" align="center"<br />
|-bgcolor="pink" <br />
| '''Advantages''' <br />
|'''Disadvantages'''<br />
|- <br />
| fast and inexpensive way of copying a target sequence of DNA<br />
| only during this exponential DNA replication phase can we determine the starting quantity sequence contained in the original sample ( template DNA strand)<br />
|-bgcolor="pink"<br />
| aids the diagnosis of single cell defects<br />
| PCR reaction is limited by the presence of inhibitors present in the sample : reagent inhibitors <br />
|-<br />
| rapid generation of results within a couple hours<br />
| self annealing due to the accumulation of the product -stopping exponential amplification for the target sequence and reach a plateau<br />
quantification of the end point of reaction of PCR products unreliable - therefore that is why we require real time quantitative RT-PCR necessary<br />
<ref> NIS (2015) Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref><br />
|-bgcolor="pink"<br />
| can start from a single molecule of DNA, therefore is more sensitive <br />
| <br />
|-<br />
| has a flexible primer design enabling<br />
| <br />
|-bgcolor="pink"<br />
| overcame previous issues associated with the limited availability of sites of end<br />
| <br />
|-<br />
| generates the DNA copies exponentially<br />
| <br />
|-bgcolor="pink"<br />
| enables DNA amplification required for molecular and genetic analysis<br />
| <br />
|-<br />
|Valid diagnostic method in selecting unaffected embryos for embryo transfer <ref> Dreesen, J., Drusedaul, M., Smeets, H., Die-Smulders, C., Coonen, E., Dumoulin, J., Gielen, M., Evers, J., Herbergers, J. & Geradets, J. (2008) Validation of preimplantation genetic diagnosis by PCR analysis: genotype comparison of the blastomere and corresponding embryo, implications for clinical practice. Mol. Hum. Reprod. 14 (10):573-579.doi: 10.1093/molehr/gan052. Retrieved from [http://molehr.oxfordjournals.org/content/14/10/573.short] </ref> <ref><pubmed>20966460</pubmed></ref><br />
|<br />
|}<br />
<br />
<br />
<br />
<br />
<br />
<br />
<br />
<br />
<br />
===Fluorescent In Situ Hybridisation (FISH)===<br />
<br />
<br />
====Description====<br />
Fluorescence in situ hybridization (FISH) the one of the most effective and rapid <ref name="PMID26338801"><pubmed>26338801</pubmed></ref> Preimplantation Genetic Diagnosis (PGD). This techniques used to locate a specific DNA sequences within a chromosome. FISH facilitates the clinical diagnosis of chromosomal abnormalities indicated by sequential duplications, deletions and rearrangements of chromosome, that are usually missed with microscopic analysis. This technique is especially relevant for female embryos with X-linked diseases,<ref><pubmed>20809319</pubmed></ref> that have no other mutation specific tests [http://www.ncbi.nlm.nih.gov/pubmed/20809319] As part of PGD, samples are collected from various stages of the embyro,and they are able to conducted tests on the blastocyst, a polar body biopsy and the blastomeres <ref><pubmed>21748341</pubmed></ref>. FISH is 99% effective when used in conjunction with competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities<ref name="PMID26338801"/>.<br />
<br />
====Procedure==== <br />
<br />
Samples are collected from either the blastocyst, a polar body biopsy or the blastomeres stages of the embryo <ref><pubmed>21748341</pubmed></ref>. <br />
DNA strands are heated and denatured causing their the individual DNA strands to break apart<br />
Probes are single complimentary stands of DNA a that have been tagged with small chemical agents that glow brightly in the presence of a specific region on a chromosome. These specific probes then hybridize and join to their complementary DNA strand. <br />
The fluorescent tags enable the researchers to correctly identify the presence or lack thereof and location of the specific chromosomes that they are testing for. <ref><pubmed>17876073</pubmed></ref><br />
Researcher analyse the results by identifying the number and the relative location of the fluorescent dots generated by the FISH images.<ref><pubmed>17970921</pubmed></ref><br />
The probe will not fully hybridise if there has been a duplication or a deletion of the DNA - indicating chromosomal and sex chromosomal anomalies like trisomies and aneuploidies. <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref><br />
<br />
<br />
Different probes are used for different purposes: <ref>Unique, Rare Chromosome Disorder Support Group (2013) Fluorescence in situ hybridisation (FISH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/Other/FISH%20FTNW.pdf]</ref><br />
*'''Locus specific tags''' detect very small imbalances, and locate isolated small portions <br />
of genes within a chromosome<br />
*'''Alphoid/Centomeric Repeat probes''' are developed from the repetitive sequence located in the middle region of each chromosome, useful in determining the number of chromosomes , detecting rearrangement and when used in conjunction with locus probes to determine the absence of genetic material on a chromosome. <br />
*'''Paint Probes''' are collections of smaller probes with their own stains that bind to a different section on the chromosome - allowing the full chromosome too be labeled a unique colour, this "full colour map" can be used to know the spectral karyotype- full chromosomal mapping is useful in examining chromosomal abnormalities. <br />
<br />
{|border="1" <br />
| [[File:Fluorescent In Situ Hybridisation (FISH).jpg|thumb|right|'''FISH''' We are able to tag Specific DNA sequences using Probes which have been tagged with fluorescent Labels.This technique enables the clinical diagnosis of chromosomal abnormalities, indicated by sequential duplication, deletions and rearrangements of chromosome <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref>]]<br />
|}<br />
<br />
<br />
<br />
{|border="1" align="center"<br />
|-bgcolor="pink" <br />
| rowspan="8" |'''Advantages''' <br />
|-bgcolor="#FDE1F2" <br />
| FISH is 99% effective when used in conjunction with Competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities.<ref><pubmed>26338801</pubmed></ref><br />
|-bgcolor="#FDE1F2" <br />
| Rapid generation of results<br />
|-bgcolor="#FDE1F2" <br />
| Identifies very small translocations and aneuploidies that occur within chromosomes, that would usually be missed under microscopic analysis<br />
|-bgcolor="#FDE1F2" <br />
| Indicates whether the accessed chromosomes are normal <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|-bgcolor="#FDE1F2" <br />
| Tests for the most common chromosomal abnormalities - down syndrome chromosomes 13,16,18,21 and 22 <ref><pubmed>21749752</pubmed></ref><br />
|-bgcolor="#FDE1F2" <br />
| It may be used to compare the chromosomal gene arrangements in related species<br />
|-bgcolor="#FDE1F2" <br />
| can be used to identify and remove inheritable X-linked disease or sex chromasome anomalies such as Duchennes Muscular Dystrophy, hemophilia, ectodermal dysplasia <ref><pubmed>17876073</pubmed></ref><br />
|-bgcolor="#C67DDC"<br />
| rowspan="5"|'''Disadvantages'''<br />
|-bgcolor="#E1C5EA"<br />
| FISH destroys all cells tested <ref> O'Connor, C. (2008) Fluorescence in situ hybridization (FISH). Nature Education 1(1):171. retrieved from [http://www.nature.com/scitable/topicpage/fluorescence-in-situ-hybridization-fish-327] </ref><br />
|-bgcolor="#E1C5EA"<br />
| It does not fully access all chromosomes (only ~ 12)<br />
|-bgcolor="#FE1C5EA"<br />
| Analysis of results is dependent upon the dot quality impacted by hybridisation efficiency or the camera sensitivity <ref><pubmed>17970921</pubmed></ref><br />
|-bgcolor="#E1C5EA"<br />
| some studies indicate that using FISH on a day-3 embryo biopsy decreases the rate of live births <ref><pubmed>26168107</pubmed></ref><br />
|}<br />
<br />
<br />
<br />
===Array Comparative Genomic Hybridisation (aCGH)===<br />
====Description====<br />
<br />
aCGH also known as Microarray analysis efficiently scans the entire genome for chromosomal imbalances. CGH was initially developed to detect the number of changes in a solid tumor mass. It uses 2 genomes comparing the sample to the control, with each labeled in a different fluorescent dye<ref><pubmed>1876176</pubmed></ref>. Earlier CGH techniques were limited by the resolution of the imaging <ref> Lichter, P., et al. Comparative genomic hybridization: Uses and limitations. Seminars in Hematology 37, 348–357 (2000)</ref> , these initial limitations were overcome by using Microarrays in conjunction with CGh to improve the resolution of the imaging, Array Comparative Genomic Hybridisation (aCGH). This method compares sample and control microarrayed slides containing small segments of DNA (probes). <ref> Lucito, R., et al. Representational oligonucleotide microarray analysis: A high-resolution method to detect genome copy number variation. Genome Research 13, 2291–2305 (2003) </ref> the Probes used will vary according from the small (25-85 base pairs) oligonucleotides manufactured to highlight different target sequences, to the very large genomic clones (80,000- 200,00 base pairs), and as these are significantly smaller than the traditional metaphase chromosomes used for CGH, generating a higher resolution of image. <ref><pubmed>22467166</pubmed></ref>.aCGH is used as a diagnostic tool for prenatal detection f chromosomal abnormalities <ref><pubmed>19012303</pubmed></ref>.<br />
<br />
<br />
====Procedure====<br />
<ref> Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432] </ref><br />
The sample is obtained (skin, blood or fetal cells) and DNA is obtained. <br />
As a part of PGD fetal cell samples are collected from; the fertilized egg polar bodies, the blastomere (day 3 embryo) or the blastocyst/tropoectoderm stage (day 5 embryo).<br />
Sample DNA is labeled with one fluorescent dye, and the control DNA is labeled with a different colored fluorescent dye. the control DNA is used as the base point of reference. <br />
heated and denatured single DNA strands then hybridize to their complementary single strand probes, which are then combined and applied to a microarray and the results are run through a computer program and a digital imaging system is used to quantify the results( fluorescent intensities of the labeled probes). <br />
<br />
simple explanation of aCGH : [Genomics Education (2014) Genetic Testing for Health: aCGH|https://vimeo.com/84757281]<br />
<ref>Genomics Education (2014) Genetic Testing for Health: aCGH [video file] Vimeo [https://vimeo.com/84757281]</ref><br />
<br />
<br />
The fluorescent ratio and the hybridization signal at different locations on the genome of the control DNA are used to identify any variances present in the sample DNA. aCGH facilitates the clinical diagnosis of submicroscopic chromosomal duplication, deletion and rearrangements indicative of chromosomal disorders such as trisomies 1-22and specific sex linked disorders. <br />
Duplications in the DNA are displayed by the computer program as spikes/ peaks over an established threshold and deletions in DNA are displayed by the computer program as spikes/ toughs beneath this threshold <br />
-computer screening image- <br />
-drawn diagram of method-<br />
<br />
<br />
<br />
{|border="1" align="center"<br />
|-bgcolor="pink" <br />
| '''Advantages''' <br />
| '''Disadvantages'''<br />
|-<br />
| multiple applications: prenatal genetic diagnosis, cancer diagnosis, <ref><pubmed>20193845</pubmed></ref> genetic screening for developmental delay (learning disabilities) <ref><pubmed>17309648</pubmed></ref>. or congenital anomalies that are suspected to be genetic in origin <ref>NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation . retrieved from [http://www.phgfoundation.org/file/5237/]</ref><br />
| translocations and inversions of DNA are not detected<br />
|-bgcolor="pink"<br />
| trace represents all chromosomes present in the human genome chromosomes 1-22 and the X & Y chromosomes, and therefore is the most accurate method for testing whole embryo aneuploidy<br />
| limited ability diagnosing specific polyploidies such as triploidy <ref> Unique, Rare Chromosome Disorder Support Group (2013) Microarray-based Comparative Genomic Hybridiation (array CGH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/other/array%20cgh%20ftnw.pdf] </ref><br />
|-<br />
| aCGH has been extensively tested, and Validated, and is now used world wide.<br />
| will not detect mosaicism detection <20% (cultures where >1 of 5 cells are trisomy 12)<br />
|-bgcolor="pink"<br />
| detects deletions and additions and rearrangements as well as amplification, of the WHOLE genome, simultaneously.<br />
| will not detect balanced chromosomal rearrangement<br />
|-<br />
| detects submicroscopic alterations<br />
| will not detect duplications or deletions <80kb<br />
|-bgcolor="pink"<br />
| used as a diagnostic tool for prenatal detection of chromosomal abnormalities <ref><pubmed>22034057</pubmed></ref><br />
| will not detect point mutations within genes <ref>Washington department of education (CGH- FAQ for physicians. Signature Genomic LAboratories, LLC. Retrieved from [https://depts.washington.edu/dbpeds/Lab%20Tests/SignatureCGH-physician_FAQ.pdf]</ref><br />
|-<br />
| provides high resolution genomewide screening of segmental genomic copy number variations<br />
| will not detect chromosomal position of genomic gains<br />
|-bgcolor="pink"<br />
| very accurate when used in conjunction with FISH<br />
| will not detect loos of heterozygosity (LOH) or Absence of heterozygosity (AOH) <ref>WiCell Research Institute Inc. (2012) Comparative Genomic Hybridization Microarray. <br />
retrieved from [http://www.wicell.org/home/cytogenetic-services/cgh-microarray/array-comparative-genomic-hybridization-acgh.cmsx]</ref><br />
|-style="background:pink"<br />
|Alone is more reliable and in detecting chromosomal abnormalities, with a higher implantation success rate, than FISH <ref><pubmed>20494259</pubmed></ref><br />
|<br />
|-bgcolor="pink"<br />
|Allows an in depth research focus upon specific types of rearrangements within selected chromosomal regions, a recent particular area of interest is subtelomeric and pericentromeric rearrangements<br />
|<br />
|-<br />
|reduces the risk of failed implantation and miscarriage, improving the chance of a healthy baby <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|<br />
|}<br />
<br />
<br />
<br />
===Next Generation Sequencing===<br />
====Description====<br />
The development and advances within ART in the past 20 years, as well as the increasing popularity of IV, has lead to an influx of new technologies developed to screen embryos for chromosomal anomalies, which are covered by the umbrella term of Next generation Sequencing (NGS). NGS is a general term used to describe all of the new and emerging screening techniques currently being introduced and used as part of PGD for IVF . NGS screens for single gene disorders as well as conducting extensive and very comprehensive chromosome diagnosis by sequencing, counting, and accurately assembling millions of DNA reads, simultaneously. <ref><pubmed>23499002</pubmed></ref> There is a movementfor NGS to replace the other limited testing techniques and be used as the standard. <br />
====Procedure====<br />
Samples are collected from either blastomere or the blastocyst/tropoectoderm and processed for analysis by a computer system. <br />
The methodology of each process is unique to the technique being used. <br />
<br />
<br />
<br />
{|border="1" align="center"<br />
|-bgcolor="pink" <br />
| '''Advantages'''<br />
| '''Disadvantages'''<br />
|-bgcolor="white"<br />
| cheaper<br />
| there are limited information available to clinical applications of NGS <ref><pubmed>26100406</pubmed></ref><br />
|-bgcolor="pink"<br />
| opens new diagnostic possibilities<br />
|<br />
|-bgcolor="white"<br />
| accurately tests all 24 chromosomes<br />
| <br />
|-bgcolor="pink"<br />
| tests for the presence of monogenic diseases of known genetic background<br />
| <br />
|-bgcolor="white"<br />
| reduces the number of biopsies required for diagnosis<br />
| <br />
|-bgcolor="pink"<br />
| higher detection rate of small translocations<br />
| <br />
|-bgcolor="white"<br />
| highly accurate is testing for compound point mutations, chromosomal duplication, deletions and insertions <ref><pubmed>23312231</pubmed></ref><br />
| <br />
|-bgcolor="pink"<br />
| it accurately detects chromosomal aneuploidy and unbalanced rearrangement <ref><pubmed>25685330</pubmed></ref><br />
| <br />
|-bgcolor="white"<br />
| NGS single gene disorder screenings can conducted in conjunction with PCR comprehensive chromosomal screening<br />
|<br />
|-bgcolor="pink"<br />
| Reduces human error <br />
|<br />
|-bgcolor="white"<br />
| better detects the presence of mosaicism<br />
|<br />
|-bgcolor="pink"<br />
| work well in conjunction with CGH and aCGH as part of PGD, improving the chances of IVF. <ref> Morris, R. S. (2015 ) Next generation sequencing for PCG|PGS|CCS. IVF1 retrieved from [http://www.ivf1.com/next-generation-sequencing for-pgd] </ref><br />
|<br />
|}<br />
<br />
<br />
<br />
<br />
<br />
<br />
==Diagnosis==<br />
There are a large amount of diseases that PGD can apply to, below are descriptions of the diseases that PGD are more commonly used for. <br />
===Cystic Fibrosis===<br />
Cystic fibrosis is a single gene disorder. It is autosomal recessive and involves mutations in the cystic fibrosis transmembrane conductance regulator (CTFR) gene. The CTFR gene is normally responsible for the decrease in chloride and the transport of bicarbonate in epithelial cells thus playing a major physiological role. In PGD procedures, identification of the gene is assisted by microsatellite markers that have similar composition to the CTFR gene itself. Biopsy of two cells at the blastocyst stage is recommended if markers are not available. There are many variations of cystic fibrosis the most common being P.Phe508del <ref name="PMID26014425"><pubmed>26014425</pubmed></ref>.<br />
===Duchenne Muscular Dystrophy ===<br />
Duchenne Muscular Dystrophy is an X-linked recessive disease. It involves the Xp21 gene where majority of the mutations are chromosomal deletions with a smaller percentage resulting from duplications <ref name="PMID18359022"><pubmed>18359022</pubmed></ref>.<br />
===β – Thalassemia=== <br />
β – Thalassemia is known as the most common type of autosomal recessive inherited disorder among haemoglobinopathies. It involves the adult β-globin gene and is associated with the absent or decreased expression of the gene. This is commonly caused by a single nucleotide change in the gene. PGD has been used successfully worldwide to identify the β-globin gene where its application is usually performed on a single blastomere or polar body <ref name="PMID19064120">19064120</pubmed></ref>.<br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
! Applicable diseases for PGD <ref>Genoma Group (2014). Retrieved September 18th, 2015, from http://www.preimplantationgeneticdiagnosis.it/genetic-diseases-diagnosed-by-pgd.htm </ref>, <ref>Genesis Genetics (2015). Retrieved September 18th, 2015, from http://genesisgenetics.org/pgd/what-we-test-for/</ref>, <ref>Human Fertilisation & Embryology Authority (2015). Retrieved Septembr 18th, 2015, from http://guide.hfea.gov.uk/pgd/</ref><br />
|-<br />
| '''Disease'''<br />
| '''Involved Genes'''<br />
|-<br />
| 5 Alpha Reductase Deficiency (5ARD)<br />
| SRD5A2 <br />
|-<br />
| Achondroplasia<br />
|FGFR3 <br />
|-<br />
| Acute Intermittent Porphyria <br />
| ALAD, ALAS2, CPOX, FECH, HMBS, PPOX, UROD, or UROS<br />
|-<br />
| Adrenoleukodystrophy (Adrenomyeloneuropathy)<br />
| ABCD1 <br />
|-<br />
| Agammaglobulinaemia (x-linked) <br />
|BTK <br />
|-<br />
| Agammaglobulinemia Bruton Tyrosine Kinase (BTK) <br />
|BTK <br />
|-<br />
| Aicardi Goutieres Syndrome 1 (AGS1) <br />
|TREX1, RNASEH2A, RNASEH2B, RNASEH2C, SAMHD1<br />
|-<br />
| Alagille Syndrome<br />
|JAG1 or NOTCH2<br />
|- <br />
| Alpers-Huttenlocher Syndrome <br />
|POLG <br />
|-<br />
| Alpha-1-antitrypsin deficiency <br />
|SERPINA1 <br />
|-<br />
| Alpha-Mannosidosis<br />
| MAN2B1 <br />
|-<br />
| Alpha Thalassemia <br />
|HBA1 or HBA2 <br />
|-<br />
| Alports Syndrome<br />
|COL4A3, COL4A4, COL4A5<br />
|-<br />
| Alzheimer's Disease - early onset (Type 3 and 4) <br />
|APP, PSEN1, or PSEN2<br />
|-<br />
| Amyotrophic Lateral Sclerosis 1 (ALS1) <br />
|C9orf72, SOD1, TARDBP, FUS, ANG, ALS2, SETX, VAPB <br />
|-<br />
| Argininosuccinic Aciduria <br />
| ASL<br />
|-<br />
| Arrhythmogenic Right Ventricular Cardiomyopathy/ Dysplasia (ARVC/D)<br />
| DSG2; DSP; PKP2<br />
|-<br />
| Ataxia Telangiectasia<br />
| ATM<br />
|-<br />
| Bardet-Biedl Syndrome (BBS)<br />
| BBS1; BBS10<br />
|-<br />
| Barth Syndrome<br />
| TAZ<br />
|-<br />
| Beta Thalassaemia<br />
| HBB<br />
|-<br />
| Birt-Hogg-Dubé Syndrome<br />
| FLCN<br />
|-<br />
| Breast Ovarian Cancer Familial Susceptibility (BRCA2)<br />
| BRCA1; BRCA2<br />
|-<br />
| Canavan Disease <br />
| ASPA<br />
|-<br />
| Carnitine-Acylcarnitine Translocase Deficiency <br />
| SLC25A20<br />
|-<br />
| Cerebral Arteriopathy with Subcortical Infarcts & Leukoencephalopathy (CADASIL)<br />
| NOTCH3<br />
|-<br />
| Cerebral Cavernous Malformation<br />
| CCM1<br />
|-<br />
| Charcot-Marie-Tooth Disease<br />
| GJB1; MPZ; NEFL; PMP22<br />
|-<br />
| CHARGE Syndrome<br />
| CHD7<br />
|-<br />
| Cherubism<br />
| SH3BP2<br />
|-<br />
| Choroideremia<br />
| CHM<br />
|-<br />
| Chronic Granulomatous Disease<br />
| CYBB; NCF1<br />
|-<br />
| Ciliary Dyskinesia<br />
| DNAH5<br />
|-<br />
| Citrullinemia<br />
| ASS1<br />
|-<br />
| Cleidocranial Dysplasia<br />
| RUNX2<br />
|-<br />
| Cockayne Syndrome<br />
| ERCC6<br />
|-<br />
| Congenital Adrenal Hyperplasia<br />
| CYP21A2<br />
|-<br />
| Congenital Cataracts<br />
| GJA8; VSX2<br />
|-<br />
| Congenital Diarrhea, Syndromic<br />
| SPINT2<br />
|-<br />
| Congenital Disorders of Glycosylation (CDG)<br />
| ALG1; ALG6; CDG1C; DOLK; PMM2<br />
|-<br />
| Cornelia de Lange Syndrome <br />
| NIPBL<br />
|-<br />
| Craniosynostosis<br />
| TWIST1<br />
|-<br />
| Crouzon Syndrome<br />
| FGFR2<br />
|-<br />
| Cysteinyl Leukotriene Receptor 1 Deficiency <br />
| CYSLTR1<br />
|-<br />
| Cystic Fibrosis<br />
| CFTR<br />
|-<br />
| Diamond –Blackfan Anemia <br />
| RPS19<br />
|-<br />
| Duchenne Muscular Dystrophy <br />
| DMD<br />
|-<br />
| Dyskeratosis congenita (Male embryos only)<br />
| DKC1<br />
|-<br />
| Ectodermal dysplasia (Hypohidrotic)<br />
| EDA; EDA1; GJB6; IKBKG<br />
|-<br />
| Familial Adenomatous polyposis coli (FAP)<br />
| APC<br />
|-<br />
| Familial Dysautonomia<br />
| IKBKAP<br />
|-<br />
| Fanconi Anemia <br />
| FANCA; FANCC; FANCD2; FANCF; FANCG; FANCJ<br />
|-<br />
| Fragile X Syndrome (FRAX)<br />
| FMR1<br />
|-<br />
| Galactosemia <br />
| GALT<br />
|-<br />
| Gangliosidosis<br />
| GLB1<br />
|-<br />
| Glanzmann Thrombasthenia <br />
| ITGA2B<br />
|-<br />
| Glutaric Acidemia (aciduria)<br />
| GCDH <br />
|-<br />
| Glycogen Storage Disease <br />
| G6PC; GAA; SLC37A4<br />
|-<br />
| Haemophilia A<br />
| F8<br />
|-<br />
| Haemophilia B<br />
| F9<br />
|-<br />
| Hereditary Nonpolyposis Colorectal Cancer: Lynch Syndrome<br />
| MLH1; MSH2; MSH6<br />
|-<br />
| Holt Oram Syndrome<br />
| TBX5<br />
|-<br />
| Huntington Disease<br />
| HD<br />
|-<br />
| Hydrocephalus<br />
| L1CAM<br />
|-<br />
| Ichthyosis <br />
| ABCA12; STS<br />
|-<br />
| Incontinentia Pigmenti (IP)<br />
| NEMO<br />
|-<br />
| Joubert Syndrome 5<br />
| INPP5E<br />
|-<br />
| Krabbe Disease<br />
| GALC<br />
|-<br />
| Leber Congenital Amaurosis (LCA)<br />
| CEP290; GUCY2D<br />
|-<br />
| Leigh Syndrome (Infantile Subacute Necrotising Encephalopathy)<br />
| LRPPRC<br />
|-<br />
| Lesch Nyan Syndrome<br />
| HPRT1<br />
|-<br />
| Leukocyte Adhesion Deficiency (Type I)<br />
| ITGB2<br />
|-<br />
| Li-Fraumeni Syndrome<br />
| TP53<br />
|-<br />
| Macular Dystrophy Retinal <br />
| VMD2<br />
|-<br />
| Maple Syrup Urine Disorder (MSUD)<br />
| BCKDHB<br />
|-<br />
| Marfan Syndrome <br />
| FBN1<br />
|-<br />
| Menkes Syndrome<br />
| ATP7A<br />
|-<br />
| Mitochondrial DNA Depletion Syndrom <br />
| POLG; RRM2B; SUCLA2; TK2<br />
|-<br />
| Mucolipidosis type II<br />
| GNPTAB<br />
|-<br />
| Multiple Endocrine Neoplasia<br />
| MEN1; MEN2A; MEN2B<br />
|-<br />
| Multiple Exostoses<br />
| EXT1; EXT2 <br />
|-<br />
| Myotubular myopathy<br />
| MTM1 <br />
|-<br />
| Nail-Patella Syndrome<br />
| LMX1B<br />
|-<br />
| Neurofibromatosis Type 1<br />
| NF1<br />
|-<br />
| Neurofibromatosis Type 2 <br />
| NF2<br />
|-<br />
| Noonan Syndrome<br />
| KRAS, PTPN11; SOS1<br />
|-<br />
| Norrie Disease<br />
| NDP<br />
|-<br />
| Ocular Albinism <br />
| GPR143<br />
|-<br />
| Oculocutaneous Albinism <br />
| OCA2; TYR <br />
|-<br />
| Oculodentaldigital Dysplasia<br />
| GJA1<br />
|-<br />
| Optic Atrophy<br />
| OPA1<br />
|-<br />
| Ornithine Transcarbamylase Deficiency <br />
| OTC<br />
|-<br />
| Osteogenesis imperfeca <br />
| COL1A1; COL1A2<br />
|-<br />
| Osteopetrosis <br />
| CLCN7; OSTM1; TCIRG1<br />
|-<br />
| Pachyonychia Congenita <br />
| KRT16; KRT6A<br />
|-<br />
| Pancreatitis, Hereditary<br />
| PRSS1 <br />
|-<br />
| Papillorenal syndrome <br />
| PAX2<br />
|-<br />
| Phenylketonuria <br />
| PAH <br />
|-<br />
| This table does not cover the complete list of diseases that PGD can be applied to.<br />
|}<br />
<br />
==Laws & Legal status==<br />
===Australia=== <br />
PGD is currently used to detect serious genetic conditions to improve the outcome of Assisted Reproductive Technologies (ART). In very rare cases it may be used to select an embryo with compatible tissue for a sibling who has a life-threatening disease where other means of treatment is unavailable. This is with the conditions that the use of PGD will not affect the welfare and interests of the child to be born. The parents must also receive adequate counselling and have full understanding of the procedures of PGD. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"> National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art</ref><br />
The use of PGD for sex-selection is prohibited with the exception of reducing the risk of the transmission of serious sex-linked genetic conditions. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"/><br />
===Brazil=== <br />
The laws regarding PGD in Brazil are not strictly regulated. They are vague and there is limited information surround the activities of assisted reproduction in general in the country <ref name="PMID25493379"><pubmed>25493379</pubmed></ref>.<br />
===Czech Republic===<br />
The laws in the Czech Republic allow those with a “defined indication in order to exclude risk of serous genetically conditioned disease and defects with embryos before they are implanted into the cavity of the uterus”. Couples that undergo any assisted reproductive treatment including PGD have to be married. Sex-selection is illegal except in regards to serious sex-linked genetic diseases <ref name="PMID24777348"><pubmed>24777348</pubmed></ref>.<br />
===Greece=== <br />
In Greece, ART is open to those up to the age of 50 with written consent. It can only be used if a medical necessity is present such as the susceptibility of serious hereditary diseases. Sex selection is banned apart from cases of sex-linked diseases and sexually transmitted diseases <ref name="PMID24777348"/>.<br />
===Portugal=== <br />
ART is only available to those who are married or have a similar type of relationship for at least two years. The couples cannot be of the same sex and must be at least 18 years of age. Sex selection is illegal except in cases of sex-linked diseases. The use of PGD is illegal if the predictive value of genetic tests are very low <ref name="PMID24777348"/>.<br />
===Spain===<br />
PGD can be applied to “serious hereditary diseases not amenable to postnatal curative treatment” and “detection of other abnormalities which may compromise the viability of the pre-embryo”. If PGD is to be used for any other purpose authorisation must be acquired <ref name="PMID24777348"/>.<br />
===Sweden=== <br />
The use of PGD is strictly regulated and couples must achieve authorisation of the National Board of Health and Welfare. It can only be used it can only be used if the child is at risk to inheriting a serious chromosomal or monogenetic disease. It cannot be used for selection of specific characteristics <ref name="PMID24777348"/>.<br />
===United Kingdom===<br />
Those involved with carrying out the IVF treatment must have a license from the Human Fertilisation and Embryology Authority (HFEA). Only embryos that are approved by the HFEA can be implanted where the embryonic nuclear or mitochondrial DNA cannot be altered with the exception of preventing mitochondrial diseases <ref name="PMID24777348"/>. <br />
==Future/Current Research==<br />
===Noninvasive Preimplantation Genetic Testing without Embryo Biopsy===<br />
Different parameters of gametes, zygotes, embryos (“vacuoles in sperm heads, spindle position in mature oocytes, cleavage intervals of zygote, and embryo developmental dynamics”) may correlate with aneuploidy rates. This knowledge may be applied in potential noninvasive preimplantation diagnostic methods. Several methods have been proposed and are currently further researched<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Sperm Selection====<br />
Intracytoplasmic morphologically selected sperm injection (IMSI) is common procedure in IVF treatment to improve fertilization rates in patients with poor semen quality. In addition, studies have found that IMSI improves embryo development and that spermatozoa with large vacuoles in their heads correlate with increased aneuploidy rates and disturbed chromosomal structures. Thus, selecting spermatozoa based on morphological hallmarks may decrease aneuploidy rates in the fertilized embryos. As with polar body biopsies, however, this approach will solely be applicable if evidence for severe male detrimental contribution is given<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Blastocoel Fluid Extraction====<br />
In addition, a less invasive retrieval of material for diagnosis could include the extraction of the blastocoel fluid. The cavity of the blastocyst, lined by the trophectoderm, is filled with this blastocoel fluid, which contains metabolites of both trophectoderm and inner cell mass origin. The retrieval does not require a biopsy but merely a small opening to extract the fluid and, thus, causes less harm to the embryo. Multiple studies have applied this method<ref name="PMID22020776"><pubmed>22020776</pubmed></ref> <ref name="PMID23148560"><pubmed>23148560</pubmed></ref> and it may in the future become of clinical relevance.<br />
<br />
{|border="1"<br />
| [[File:Aspiration_of_the_Blastocoel_Fluid.jpeg]]<br />
|-<br />
| Aspiration of the Blastocoel Fluid using a ICSI pipette<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
|}<br />
<br />
<br />
Next to metabolites, the blastocoel fluid can contain DNA. Studies have shown that genomic DNA is present in about 90% of the blastocoel fluid samples tested. Typically the fluid is removed with an ICSI pipette from a day five blastocyst through its mural trophectoderm until the blastocyst fully collapses around the embryo. Several concerns regarding this method in a clinical setting have been raised. The collected DNA may be contaminated by the culture media that contains DNA fractions. The DNA may also be least representative of the actual embryos genome as the DNA may originate from abnormal or degenerated cells. Even though labelled noninvasive, the blastocyst still undergoes manipulation to some degree which may affect its viability. Thus, more research is required until this method can evolve from research to clinical use<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
====Proteomics====<br />
The protein secretome of blastocysts may be representative of its chromosome constitution Recent studies have found biomarkers such as lipocalin-1, interleukin-10, tumor necrosis factor, stem cell factor, and chemokine ligand 13 to be differently secreted by aneuploid blastocyst than by euploid ones. The most significant biomarker appears to be interleukin-10. Paired with novel proteomic technologies and mass spectrometry this knowledge when extended may contribute to a new invasive preimplantation genetic diagnosis method<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Embryo Morphology====<br />
Using time lapse imaging the embryo’s morphology can be closely observed and potential aneuploidy characteristics detected. Such characteristics may include the time of division to five cells, the time between the division from three to four cells, and the duration of the division from one to two and subsequently to three. In addition, the morphological quality of ICM an TE has been positively associated with aneuploidy or euploidy prognosis<ref name="PMID26246880"><pubmed>26246880</pubmed></ref>. These may give rise to an embryo quality screening prior to implantation<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
===Utilization of Diseased Cell Lines===<br />
==Ethics==<br />
==References==<br />
<br />
<references/><br />
<br />
<br />
{{StudentPage2015}}</div>Z5017878https://embryology.med.unsw.edu.au/embryology/index.php?title=2015_Group_Project_6&diff=2065612015 Group Project 62015-10-19T12:07:52Z<p>Z5017878: </p>
<hr />
<div>{{ANAT2341Project2015header}}<br />
<br />
<br />
=Prenatal Genetic Diagnosis=<br />
==Introduction==<br />
==History==<br />
Prenatal Genetic Diagnosis was historically conducted post-implantation in the first 2 trimesters <ref> Blackburn, S.L. (2003) '''Maternal, Fetal & Neonatal physiology: a Clinical perspective''' (2nd ed.). Seattle: Saudners </ref>, testing for overall fetal growth, complications of pregnancy, birth defects as well as chromosomal or genetic abnormalities<ref> Sadler T.W.(2012) '''Langman's Medical Embryology''' (12th ed.) Philadelphia: Lipincott, Wiliams & Wilkins, a Wolters Kluwer Business </ref>. Due to advancements in Artificial Reproductive Technologies ( ART) in the past 2 decades , these genetic tests are now conducted as a part of Preimplantation Genetic Diagnosis (PGD) <ref><pubmed>20638568</pubmed></ref> and art used to eliminate the rsik of passing on a genetic disorder to an offspring, before implantation, it ha now become a preventative measure. . In 1990 Preimplantation genetic testing was first used in 1990 on humans to diagnose recessive X-linked diseases in the embryos of pregnant women undergoing IVF. <ref><pubmed>2330030</pubmed></ref> PGD is offered as an alternative to prenatal diagnosis in detecting genetic disorders in high risk couples <ref><pubmed>26168107</pubmed></ref> and avoid passing an inherited disease to the offspring, by selecting genetically "normal" embryos for implantation ,to give the best chance of successful implantation , stable pregnancies and healthy children. <br />
<ref><pubmed>23499002</pubmed></ref><br />
<br />
==Preimplantation Genetic Diagnosis==<br />
[[File:Preimplantation Genetic Diagnosis Procedure.jpeg|700px|thumb|centre| Simplified steps for PGD]]<br />
<br />
<br />
Preimplantation genetic diagnosis (PGD) is used to test the genetic makeup of embryos to detect single gene disorders, chromosomal abnormalities and mitochondrial disorders. It also has applications in gender selection for diseases with unequal gender distributions <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Some diseases commonly involved with PGD include cystic fibrosis, spinal muscular atrophy and beta – thalassaemia <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press.">Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press</ref> <ref name="PMID17823145"><pubmed>17823145</pubmed></ref>. It was first used in the United Kingdom in the 1980s of arenoleucodystrophy and primarily focusing on sex- linked disorders <ref name="PMID17823145"/><ref name="PMID23150080"><pubmed>23150080</pubmed></ref>. PGD is now capable of detecting single cell defects (molecular) and chromosomal disorders resulting from the inversion, translocation or deletion of chromosomes (cytogenic) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>,<ref name="PMID11325751"><pubmed>11325751</pubmed></ref>. PGD can be applied to the embryo at different stages. That is on polar bodies, blastomeres or blastocyst <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>.<br />
Depending on the type of genetic disorder, PGD utilises different methods of genetic testing. These include Fluorescence in situ hybridisation (FISH) which is used for sex – linked disorders and detects chromosomal rearrangements <ref name="PMID11325751"/><ref name="PMID17876073"><pubmed>17876073</pubmed></ref> and Embryo halotyping which allows the identification of chromosomes causing the inherited disorder through knowledge of the pattern of closely linked markers <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. Polymerase chain reaction (PCR) is also widely used to detect molecular abnormalities <ref name="PMID11325751"/>.<br />
PGD is tightly regulated and supported by large organisations namely The American Society for Reproductive Medicine, The European Society for Human Reproduction and Embryology (ESHRE), The European Society of Human Genetics and the Preimplantation Genetic Diagnosis International Society <ref name="PMID25500181><pubmed>25500181</pubmed></ref>.<br />
===Sex-linked disorders===<br />
The determination of a disease as gender specific usually correlates with the presence or absence of specific genes such as SRY on the Y chromosome. It is known that females have two X chromosomes and males have an X and a Y chromosome where abnormalities are more prevalent on the X chromosome. PGD can be used for sex selection where only male embryos are transferred to reduce the chance of inheriting X-linked disorders. However, this does not completely eradicate the problem as male embryos remain susceptible to inheriting an affected X chromosome. Sex determination is only used when the specific mutation is unknown and has yet to be discovered <ref name="PMID24866878"><pubmed>24866878</pubmed></ref>.<br />
===Single gene defects===<br />
Single gene defects can be dominant, recessive, autosomal or X-linked. They are commonly diagnosed using PCR and although the PCR available today is complex and capable of combatting a large range of disease the development of new protocols has been proven to be difficult due to the small DNA sample available <ref name="PMID26168107"><pubmed>26168107</pubmed></ref><br />
===Mitochondrial disorders===<br />
Mitochondrial disorders also known as oxidative phosphorylation disorders arise from mutations in the nuclear DNA or mitochondrial DNA <ref name="PMID26312584"><pubmed>26312584</pubmed></ref>. They pose as a problem because they are unrecognisable until the mutations in the cell reach a detrimental level <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Mitochondrial disorders cause miscarriages and stillbirths as well as death in children and young adults. The effects can either be contained in a single organ or more commonly involve multiple organ failure where organs with high energy demands such as the brain, liver muscle and heart and heavily influenced. They are usually occur spontaneously or result from inheritance from the mother. Since mitochondria are solely inherited from the mother oocyte donations have been used as a solution to combat mitochondrial disorders. Additionally, there has been an increasing use in PGD where embryos that stay under the given threshold of 18% gene-mutations are allowed to be transferred and result in normal development. New technology in the areas of nuclear gene transfer and genome editing are also being experimented with <ref name="PMID26312584"/>. <br />
===Chromosomal disorders===<br />
Chromosomal disorders can be reciprocal, Robertsonian translocations, inversions, deletions and insertions <ref name="PMID26168107"/>. . Data from ESHRE collected between 2010 and 2011 has shown that the most common chromosomal abnormality confronted in PGD are reciprocal chromosomal abnormalities <ref name"PMID26071418"><pubmed>26071418</pubmed></ref>. PGD has also been used successfully for Robertsonian translocations (RT), a type of structural translocation. Children who carry RT are phenotypically normal, however in their later years it is found that they will suffer from infertility and repeated miscarriages due to the high frequency of abnormal embryos <ref name="PMID22081077"><pubmed>22081077</pubmed></ref>. PCR and FISH are the two main techniques used for chromosomal disorders. To be able to conduct the examinations the cells are required to be at the metaphase stage <ref name="PMID26168107"/>. <br />
==Preimplantation Genetic Screening==<br />
Prenatal Genetic Screening (PGS) involves an array of methods or ideas that aim to segregate embryos that have genetic flaws and those that are healthy <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. The occurrence of aneuploidy is high around the stages of early embryonic development and they are the most common cause if miscarriages and congenital birth defects <ref name= "PMID26085841"><pubmed>26085841</pubmed></ref>. They have little effect on the morphology of the embryo making them difficult to identify thus identification heavily relies on genetic testing <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. <br />
Genetic sampling is most commonly conducted using Microarray Comparative Genomic Hybridisation (aCGH) as well as FISH, Quantitative PCR and Single Nucleotide Polymorphism (SNP) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. These methods collectively aim to assess numeral and structural chromosomal errors <ref name= "PMID26085841"/>. Studies have also introduced Next- Generation Sequencing (NGS) <ref name= "PMID26085841"/> and Whole Genome Amplification used to screen imbalances in the complete 24-chromosomes <ref name="PMID25953353"><pubmed>25953353</pubmed></ref><br />
Statistics from ESHRE have shown that the most common indications for PGS is advanced age, followed by repeated implantation failure or recurrent miscarriage and male infertility <ref name="PMID26071418"><pubmed>26071418</pubmed></ref>.<br />
====Indications====<br />
A low percentage of structural abnormalities in chromosomes are responsible for the cause of miscarriages. Despite this, they are the most prevalent type of chromosomal abnormality accounted for in PGD <ref name="PMID20638568"/>. The presence of specific gene cycles, initiation of embryonic protein synthesis and evident physiological development are all indicative of a successful in vitro fertilisation procedure <ref name="PMID11576737"><pubmed>11576737</pubmed></ref>. To eliminate further errors from occurring during the PGD procedure it is recommended to undertake further prenatal testing such as amniocentesis in the later stages <ref name="PMID20638568"/>. <br />
=====Advanced maternal age=====<br />
Data provided by the ESHRE has shown that the mean age of women undergoing PGS is 39 years <ref name="PMID26071418"/>. Women of advanced age have been shown to have a lower rate of pregnancies reaching childbirth <ref name="PMID18583331"><pubmed>18583331</pubmed></ref>. The highlighted concern revolves around the increased occurrence of aneuploidy following maternal age. The optimal age range for the lowest aneuploidy incidence was found to be between 27 to 37 years of age (6%) then progressively higher in women aged up to 42 (33%) and most common in those 44 and above (53%) <ref name="PMID24355045"><pubmed>24355045</pubmed></ref>. <br />
=====Recurrent pregnancy loss / IVF failure=====<br />
Recurrent pregnancy loss is defined as three or more IVF failures after cumulative transfer of more than 10 good-quality embryos. These are primarily caused by two main factors, reduced endometrium receptivity or embryonic defects. Endometrium receptivity can be negatively influences by instances including uterine pathologies such as thin endometrium, altered expression of adhesive molecules and immunological factors. Additionally, embryonic defects may be due to genetic abnormalities, embryonic aneuploidy or zona hardening. Endometriosis and hydrosalpinx has been known to effect both the endometrium and embryo <ref name="PMID23260857"><pubmed>23260857</pubmed></ref>.<br />
=====Human leukocyte antigen matching=====<br />
First used in 2001, HLA matching is an option given to parents to save a child with haematological or immunological disease through conceiving another child who would potentially be able to donate cord blood or haematopoietic stem cells from the bone marrow for transplantation. The process namely PGD-HLA has shown to improve haematopoietic stem cell transplant (HSCT). PGD-HLA can only be performed when HSCT is not needed urgently due to the time needed to conceive and delivery the baby <ref name="PMID25500181"><pubmed>25500181</pubmed></ref>. It is most commonly applied to children suffering from relapsed leukaemia <ref name="PMID22524201"><pubmed>22524201</pubmed></ref>. In a case study PGD-HLA was proven to successfully cure 10 diseases including Fanconi anaemia, Diamond-Blackfan anaemia and beta thalassemia <ref name="PMID25066893><pubmed>25066893</pubmed></ref>.<br />
==Biopsy Methods==<br />
Biopsy, the removal of genetic materials, from oocytes or embryos in the preimplantation stage is the primary step in PGD. For the past two decades these biopsies have been performed at three stages, the polar body, blastomere, and blastocyst, and the methodologies optimized to ensure the embryo’s viability. The most common approach involves biopsies at the cleavage stage. However, polar body and blastocyst biopsies are increasingly more often tested and applied. Approached for opening the zona pellucida involve next to the traditional mechanical and chemical means, novel approaches such as noncontact lasers. Their application may simplify and secure the procedure significantly. The most challenging question about PGD procedures remains at what stage biopsies should be taken. Much controversy has developed around this topic, highlighting the varying disadvantages and advantages of temporal biopsies. <ref name="PMID22723007"><pubmed>22723007</pubmed></ref><br />
<br />
{|border="1" align="left"<br />
|-bgcolor="pink" <br />
|<br />
| Time of Biopsy<br />
| Advantages <br />
| Disadvantages<br />
|- <br />
| Polar Body<br />
| Day 1<br />
| No harm to oocyte<br />
| Only maternal DNA is tested, often needs to be coupled with other biopsies<br />
|-bgcolor="pink"<br />
| Blastomere<br />
| Day 3<br />
| …<br />
| … <br />
|-<br />
| Trophectoderm<br />
| Day 5 and 6 <br />
| Little harm, large amount of genetic material<br />
| Opening of blastocyst necessary, small time window for procedure<br />
|}<br />
<br />
{|border="1"<br />
| [[File:Polar_Body,_Blastomere,_and_Trophectoderm_Biopsy.jpeg]]<br />
|-<br />
| Polar body (A), blastomere (B) and trophectoderm (C) biopsies<ref name="PMID25625041"><pubmed>25625041</pubmed></ref>.<br />
|}<br />
<br />
PMID 24305177<br />
===Polar Body Analysis===<br />
Day 1<br />
====Description====<br />
Polar body (PB) biopsy, which was introduced in 1990, offers a promising alternative to biopsies performed at the blastomere stage for PGD/S indications on legal and practical grounds. <br />
Description: Consequent embryo development does not necessitate the presence of the first and second PB and their removal may not be crucial. PB biopsy requires precise timing. Keeping track of the meiotic cell cycle is necessary to perform a successful biopsy and, therefore, PB biopsy usually is applied in combination with intracytoplasmic sperm injection (ICSI). During the maturation from the germinal vesicle stage to the metaphase-II stage the first PB is formed. A cytoplasmic bridge containing spindle remnants, that are still in contact with the cellular genetic material, links this PB to the oolemma for about 90 minutes after extrusion. It is possible to visualize these remnants by polarization microscopy and it is crucial to not perform the biopsy until the first PB is no longer firmly attached to the oolemma as this indicates an immature embryo.The oocyte tolerates mechanical zona dissection best during hours four until six after ICSI as the oolemma has stabilized by that time because of the cortical granule reaction. Over time the first PB degenerates stressing a temporal biopsy and its optimal extraction time window is four to 12 hours after ICSI. The second PB forms around two to four hours after ICSI. However, its optimal time window for biopsy is set to be eight to 16 hours after ICSI. This is due to the second PB being attached to the oolemma with spindle remnants until six hours after ICSI. Biopsy at this point may cause enucleation of the oocyte. In addition, studies have shown that the amplification efficiency of second PB’s DNA is worse if the PB is extracted prior to eight hours after ICSI. <br />
Thus, it is possible to perform sequential and simultaneous biopsies for the first and second PB. If performed, sequentially the first PB may be removed four to 12 hours and the second PB eight to 16 hours after ICSI. The optimal time window for a biopsy for both the first and second PB simultaneously is eight to 12 hours after ICSI. It is highly preferred to analyze both PBs due to potential aneuploidies in either PB and crossing overs during meiosis<ref name="PMID22723007"/>. <br />
====Procedure====<br />
Chemical opening achieved with for example acidic tyrode’s solution of the zona pellucida is not tolerated by the oocyte and may have detrimental effects on the embryo’s development. Therefore, the access to the perivitelline space of the oocyte is provided by mechanical zona dissection or by laser. Both techniques work well if performed by experienced embryologist. However, laser-assisted biopsy is less time consuming when compared to manual dissection. It is critical to consider the size of the introduced opening as it will remain permanent. If it is too large the blastomere may be lost during embryo development and if it is too small it may interfere with hatching of the embryo during blastocyst stage<ref name="PMID22723007"/><br />
<br />
{|border="1"<br />
| [[File:Polar_Body_Biopsy.jpeg]]<br />
|-<br />
| The presence of a faint but clearly identifiable strand connecting PB2 to the <br />
oolemma. The biopsy was performed ∼9 h after ICSI<ref name="PMID21908464"><pubmed>21908464</pubmed></ref>.<br />
|}<br />
<br />
{|border="1"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JTaQzszVr8o</html5media><br />
|-<br />
| Laser-assisted polar body biopsy<ref>RIUK, R. (2013, June 25) Polar Body Biopsy [Video file]. Retrieved from https://www.youtube.com/watch?v=JTaQzszVr8o</ref><br />
|}<br />
<br />
====Advantages & Disadvantages====<br />
PB biopsies can only investigate the maternal contributions to the embryo as they are of maternal origin. Thus, this procedure is appropriate for PGD solely for monogenetic diseases from the maternal side. Recessive diseases may be evaluated with PB biopsies on the basis that the embryo’s outcome will be determined by the paternal contribution. (...) It may still be applied for PGS as most aneuploidies either arise during meiosis or origin from the maternal genome. However, diagnosis error has been reported due to the lack of considering paternal contributions. <br />
Because PB biopsies are performed very early it is not yet known whether the oocyte will develop into a viable embryo. Thus, PBs are commonly frozen or fixed after biopsy and depending on the state of the embryo only chosen PBs will be tested. This is primarily an economic issue as many genetic testing procedures are very cost-intensive<ref name="PMID22723007"/>.<br />
<br />
{|border="1"<br />
| [[File:Implantation_predictive_value_of_euploid_screening_results.jpeg]]<br />
|-<br />
| The sustained implantation predictive value (with 95 % confidence interval) of a euploid screening result obtained from the first polar body (PB1), PB1 and the second polar body (PB2), or a direct embryo biopsy for each stage of embryo transfer (cleavage-stage and blastocyst stage)<ref name="PMID25106935"><pubmed>25106935</pubmed></ref>.<br />
|}<br />
<br />
===Blastomere biopsy===<br />
Day 3 <br />
====Description====<br />
Blastomere biopsy has been the prevalent method for PGD and PGS in the last two decades. At least one, but up to two, blastomeres are biopsied on day three of the cleavage stage embryo. The right number of blastomeres removed is a controversial topic as two cells allow for more genetic material and more accurate results. However, removing two cells might be too invasive and damaging to the embryo. (Study)<ref name="PMID21748341"><pubmed>21748341</pubmed></ref><br />
====Procedure====<br />
Initially a hole was drilled into the zona pellucida using acid tyrodes and the blastomeres are removed via aspiration with a pipette<ref name="PMID21748341"/>.<br />
<br />
{|border="1"<br />
| [[File:Aspiration_of_a_Blastomere.jpeg]]<br />
|-<br />
| Aspiration of a Blastomere into the biopsy pipette<ref name=" PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
|}<br />
<br />
{|border="1"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=TbridWVwipI</html5media><br />
|-<br />
| Laser-assisted blastomere biopsy<ref>Sukprasert, M. (2014, March 5) Day 3 Blastomere Biopsy 1 [Video file]. Retrieved from https://www.youtube.com/watch?v=TbridWVwipI</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
===Trophectoderm biopsy===<br />
Day 5 and 6<br />
====Description====<br />
The improvement of embryo culture media allowed the in vitro development of human embryos until the blastocyst stage and opened up the possibility to take blastocyst biopsies. During day three to day five the haploid maternal and paternal genomes work together for the first time to form the genome of the embryo. The maternal epigenetic control lessens significantly while preparing for implantation with precisely arranged events happening. The first event includes a rapid increase in the number of embryonic cells which are active in mitotic divisions and apoptosis of aberrant cells. This is followed by the formation of blastocoel (cavitation) which results from the flattening of cell located on the outside of the blastomere. Now the blastocyst will expand until the embryo hatches by rupturing the zona pellucida. The cells of the blastocyst will differentiate to form two distinct cell lineages, the outer trophectoderm and the inner cell mass<ref name="PMID22723007"/>.<br />
====Procedure====<br />
Trophectoderm biopsy is usually performed in Hepes buffered biopsy medium and opening approaches include needle cutting which has been replaced by lasers in past years. Different research groups report different timings of the opening to be the most successful. Some open the blastocyst on day three or four by creating a 25 µm which causes the trophectoderm to herniate through this hole and is, thus, accessible for biopsy. Others create this hole about four hours before biopsy which allows sufficient herniation of trophectoderm cells. It is also possible to open the blastocyst immediately before biopsy. This avoids an extra step and the inner cell mass usually is easy to locate. Blastocyst biopsies involve the removal of trophectoderm cells and the ideal time for the procedure is day five. Successful biopsies on day six have been performed, while little is known about the results of biopsies on day seven. However, since the window of implantation in humans is from day eight to ten after ovulation, day seven biopsies appear to be possible<ref name="PMID22723007"/>.<br />
-collapse of trophoblasts<br />
-possible: biopsy of hatched blastocyst, holding pipette careful mild suction force to hold embryo near ICM <br />
-Cryopreservation<br />
<br />
{|border="1"<br />
| [[File:Microscopic images of human blastocysts for biopsy.jpeg]]<br />
|-<br />
| (A) Some trophectoderm cells in a blastocyst started to hatch and (B) the trophectoderm cells were biopsied with assisted laser cutting. Images in C–D show the blastocysts after vitrification and warming. Blastocysts had been cultured for 2–4 hrs after warming, showing good (ICM and trophectoderm cells) hatched (C) and hatching (D) blastocysts. The hatching blastocyst in (E) has good ICM but fair trophectoderm while the blastocyst in (F) has both fair ICM and trophectoderm. Arrows indicate ICMs and arrow heads indicate trophectoderm cells. Bar = 40 µm<ref name="PMID2190846"><pubmed>2190846</pubmed></ref>.<br />
|}<br />
<br />
<br />
{|border="1"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JI_TQ8d8tNM</html5media><br />
|-<br />
| Laser-assisted blastocyst biopsy (at 00:50 min)<ref>Coco, R. (2014, April 30) Trophectoderm biopsy in a Hatching blastocyst protruding ICM [Video file]. Retrieved from https://www.youtube.com/watch?v=JI_TQ8d8tNM</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
Blastocyst biopsies are believed to be less damaging to the embryo and appear to be unrelated to implantation rates. In addition, this biopsy method allows for a larger extraction of cells for genetic testing. However, since they are performed late in in vitro development, the time window for genetic testing is relatively small. Fast and accurate genetic testing methods are needed to ensure a successful and safe result from this biopsy. Thus, blastocyst biopsies may gain more popularity in the future whn such methods have been developed or improved<ref name="PMID22723007"/>. <br />
<br />
<br />
==Genetic Techniques==<br />
<br />
===PCR===<br />
====Description====<br />
Polymerase chain reaction (PCR) amplifies DNA specific to genetic sequence of interest . PCR was developed by Kay Mullis in the 1980s, for which he was awarded the Nobel prize for chemistry in 1993. <ref> Pubmed Docs (2015) Polymerase Chain Reaction (PCR) Pubmen. Retrieved from [http://www.ncbi.nlm.nih.gov/probe/docs/techpcr/]</ref> This technique enables clinicians to monitor and diagnose diseases using minute samples such as embryonic cells, blood & tissue. <ref>Roche (2015) PCR: How We Copy DNA. Roche Molecular Systems Inc. retrieved From [http://molecular.roche.com/pcr/Pages/Process.aspx]</ref> PCR has many important applications like DNA fingerprinting, genetic mapping, detection of viruses and bacteria as well as being used to detect genetic disorders, as a part of PGD, in conjunction with IVF. It is used to detect molecular abnormalities such as single gene disorders like Tay Sach, Cycstic fibrosis, Duchenne Muscular Dystrophy, Thalassemia, Huntington disease, Spinal muscular atrophy and many more. Molecular and Genetic analysis require a significant amount of DNA, which we would not have without PCR. It revolutionized the study of DNA, replacing all previous recombinant DNA technology. <ref> Mullins, K., Francois, F.& Gibbs R.A. (1994 ) The Polymerase Chain Reaction. p3. Springer- Science +Business Media. Birkhauser, Boston<br />
Available at [https://books.google.com.au/books?hl=en&lr=&id=gjrTBwAAQBAJ&oi=fnd&pg=PR5&dq=kary+mullis+PCR&ots=mpzAyRh5ZY&sig=PQ4goNoKJ90tb3-MkPk62zrTGbw#v=onepage&q=kary%20mullis%20PCR&f=false] </ref> <br />
<br />
====Procedure====<br />
<br />
Sample are obtained from the the blastocyst, a polar body biopsy or the blastomeres stages of the embryo. <br />
Stage 1 Denaturing: separating the target strands of DNA <br />
The obtained sample is heated to roughly 90 degrees celcius, this heat causes breaks the relatively weak bonds between nucleotides that form DNA. the double stranded DNA to split into 2 single strands of DNA that are used as templates.<br />
Stage 2 Annealing: Binding the Primers to the target DNA sequence <br />
PCR will only copy the target sequence of DNA specified by specific PCR primer. These synthesized primers Oligonucleotides are small artificial pieces of DNA. <br />
TAQ polymerase enzyme synthesize 2 new strands of DNA duplicate to the single sample DNA stand template indicated by these primers. During this stage the reaction is cooled to a temperature between 40-60 degrees Celsius. <br />
Stage 3- Extension- making copies <br />
Each of these 2 copies are then used again as templates generating 2 further replications This cycle can occur as many 30 -40 times within a couple hours leading to billions of extra copies of the original DNA segment. The optimal temperature for the further replication is roughly 72 degrees Celsius. <br />
<br />
This process mediated by a thermocycler machine that is programmed to alter the temperature of the reaction every couple of minutes, perpetuating the cycle of DNA denaturing and synthesis. <br />
This process, generates exponential exact copy of the original template DNA sequence. <br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
!PCR cycles<br />
<br />
|{|<br />
|-bgcolor="lightpink"<br />
| '''PCR Cycle'''<br />
| '''Target Copies'''<br />
|-<br />
| 1<br />
| 2<br />
|-bgcolor="pink"<br />
| 2<br />
| 4<br />
|-<br />
| 3<br />
| 8<br />
|-bgcolor="pink"<br />
| 4<br />
| 16<br />
|-"<br />
| 5 <br />
| 32<br />
|-bgcolor="pink"<br />
| 6 <br />
| 64<br />
|-<br />
| 7 <br />
| 128<br />
|-bgcolor="pink"<br />
| 8<br />
| 256<br />
|- <br />
| 9<br />
| 512 <br />
|-bgcolor="pink"<br />
| 10<br />
| 1024<br />
|-<br />
| 15<br />
| 32,768<br />
|-bgcolor="pink"<br />
| 20 <br />
| 1,048,578<br />
|-<br />
| 25<br />
| 33,554,432<br />
|-bgcolor="pink"<br />
| 30 <br />
| 1,073,741,842<br />
|-<br />
|}<br />
<br />
<br />
<br />
<br />
{|border="1" align="center"<br />
|-bgcolor="pink" <br />
| '''Advantages''' <br />
|'''Disadvantages'''<br />
|- <br />
| fast and inexpensive way of copying a target sequence of DNA<br />
| only during this exponential DNA replication phase can we determine the starting quantity sequence contained in the original sample ( template DNA strand)<br />
|-bgcolor="pink"<br />
| aids the diagnosis of single cell defects<br />
| PCR reaction is limited by the presence of inhibitors present in the sample : reagent inhibitors <br />
|-<br />
| rapid generation of results within a couple hours<br />
| self annealing due to the accumulation of the product -stopping exponential amplification for the target sequence and reach a plateau<br />
quantification of the end point of reaction of PCR products unreliable - therefore that is why we require real time quantitative RT-PCR necessary<br />
<ref> NIS (2015) Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref><br />
|-bgcolor="pink"<br />
| can start from a single molecule of DNA, therefore is more sensitive <br />
| <br />
|-<br />
| has a flexible primer design enabling<br />
| <br />
|-bgcolor="pink"<br />
| overcame previous issues associated with the limited availability of sites of end<br />
| <br />
|-<br />
| generates the DNA copies exponentially<br />
| <br />
|-bgcolor="pink"<br />
| enables DNA amplification required for molecular and genetic analysis<br />
| <br />
|-<br />
|Valid diagnostic method in selecting unaffected embryos for embryo transfer <ref> Dreesen, J., Drusedaul, M., Smeets, H., Die-Smulders, C., Coonen, E., Dumoulin, J., Gielen, M., Evers, J., Herbergers, J. & Geradets, J. (2008) Validation of preimplantation genetic diagnosis by PCR analysis: genotype comparison of the blastomere and corresponding embryo, implications for clinical practice. Mol. Hum. Reprod. 14 (10):573-579.doi: 10.1093/molehr/gan052. Retrieved from [http://molehr.oxfordjournals.org/content/14/10/573.short] </ref> <ref><pubmed>20966460</pubmed></ref><br />
|<br />
|}<br />
<br />
<br />
<br />
<br />
<br />
<br />
<br />
<br />
<br />
===Fluorescent In Situ Hybridisation (FISH)===<br />
<br />
<br />
====Description====<br />
Fluorescence in situ hybridization (FISH) the one of the most effective and rapid <ref name="PMID26338801"><pubmed>26338801</pubmed></ref> Preimplantation Genetic Diagnosis (PGD). This techniques used to locate a specific DNA sequences within a chromosome. FISH facilitates the clinical diagnosis of chromosomal abnormalities indicated by sequential duplications, deletions and rearrangements of chromosome, that are usually missed with microscopic analysis. This technique is especially relevant for female embryos with X-linked diseases,<ref><pubmed>20809319</pubmed></ref> that have no other mutation specific tests [http://www.ncbi.nlm.nih.gov/pubmed/20809319] As part of PGD, samples are collected from various stages of the embyro,and they are able to conducted tests on the blastocyst, a polar body biopsy and the blastomeres <ref><pubmed>21748341</pubmed></ref>. FISH is 99% effective when used in conjunction with competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities<ref name="PMID26338801"/>.<br />
<br />
====Procedure==== <br />
<br />
Samples are collected from either the blastocyst, a polar body biopsy or the blastomeres stages of the embryo <ref><pubmed>21748341</pubmed></ref>. <br />
DNA strands are heated and denatured causing their the individual DNA strands to break apart<br />
Probes are single complimentary stands of DNA a that have been tagged with small chemical agents that glow brightly in the presence of a specific region on a chromosome. These specific probes then hybridize and join to their complementary DNA strand. <br />
The fluorescent tags enable the researchers to correctly identify the presence or lack thereof and location of the specific chromosomes that they are testing for. <ref><pubmed>17876073</pubmed></ref><br />
Researcher analyse the results by identifying the number and the relative location of the fluorescent dots generated by the FISH images.<ref><pubmed>17970921</pubmed></ref><br />
The probe will not fully hybridise if there has been a duplication or a deletion of the DNA - indicating chromosomal and sex chromosomal anomalies like trisomies and aneuploidies. <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref><br />
<br />
<br />
Different probes are used for different purposes: <ref>Unique, Rare Chromosome Disorder Support Group (2013) Fluorescence in situ hybridisation (FISH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/Other/FISH%20FTNW.pdf]</ref><br />
*'''Locus specific tags''' detect very small imbalances, and locate isolated small portions <br />
of genes within a chromosome<br />
*'''Alphoid/Centomeric Repeat probes''' are developed from the repetitive sequence located in the middle region of each chromosome, useful in determining the number of chromosomes , detecting rearrangement and when used in conjunction with locus probes to determine the absence of genetic material on a chromosome. <br />
*'''Paint Probes''' are collections of smaller probes with their own stains that bind to a different section on the chromosome - allowing the full chromosome too be labeled a unique colour, this "full colour map" can be used to know the spectral karyotype- full chromosomal mapping is useful in examining chromosomal abnormalities. <br />
<br />
{|border="1" <br />
| [[File:Fluorescent In Situ Hybridisation (FISH).jpg|thumb|right|'''FISH''' We are able to tag Specific DNA sequences using Probes which have been tagged with fluorescent Labels.This technique enables the clinical diagnosis of chromosomal abnormalities, indicated by sequential duplication, deletions and rearrangements of chromosome <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref>]]<br />
|}<br />
<br />
<br />
<br />
{|border="1" align="center"<br />
|-bgcolor="pink" <br />
| rowspan="7" |'''Advantages''' <br />
|-bgcolor="#FDE1F2" <br />
| FISH is 99% effective when used in conjunction with Competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities.<ref><pubmed>26338801</pubmed></ref><br />
|-bgcolor="#FDE1F2" <br />
| Rapid generation of results<br />
|-bgcolor="#FDE1F2" <br />
| Identifies very small translocations and aneuploidies that occur within chromosomes, that would usually be missed under microscopic analysis<br />
|-bgcolor="#FDE1F2" <br />
| Indicates whether the accessed chromosomes are normal <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|-bgcolor="#FDE1F2" <br />
| Tests for the most common chromosomal abnormalities - down syndrome chromosomes 13,16,18,21 and 22 <ref><pubmed>21749752</pubmed></ref><br />
|-bgcolor="#FDE1F2" <br />
| It may be used to compare the chromosomal gene arrangements in related species<br />
|-bgcolor="#FDE1F2" <br />
| can be used to identify and remove inheritable X-linked disease or sex chromasome anomalies such as Duchennes Muscular Dystrophy, hemophilia, ectodermal dysplasia <ref><pubmed>17876073</pubmed></ref><br />
|-bgcolor="pink"<br />
| rowspan="4"|'''Disadvantages'''<br />
| FISH destroys all cells tested <ref> O'Connor, C. (2008) Fluorescence in situ hybridization (FISH). Nature Education 1(1):171. retrieved from [http://www.nature.com/scitable/topicpage/fluorescence-in-situ-hybridization-fish-327] </ref><br />
|-bgcolor="#FDE1F2"<br />
| It does not fully access all chromosomes (only ~ 12)<br />
|-bgcolor="#FDE1F2"<br />
| Analysis of results is dependent upon the dot quality impacted by hybridisation efficiency or the camera sensitivity <ref><pubmed>17970921</pubmed></ref><br />
|-bgcolor="#FDE1F2"<br />
| some studies indicate that using FISH on a day-3 embryo biopsy decreases the rate of live births <ref><pubmed>26168107</pubmed></ref><br />
|}<br />
<br />
<br />
<br />
===Array Comparative Genomic Hybridisation (aCGH)===<br />
====Description====<br />
<br />
aCGH also known as Microarray analysis efficiently scans the entire genome for chromosomal imbalances. CGH was initially developed to detect the number of changes in a solid tumor mass. It uses 2 genomes comparing the sample to the control, with each labeled in a different fluorescent dye<ref><pubmed>1876176</pubmed></ref>. Earlier CGH techniques were limited by the resolution of the imaging <ref> Lichter, P., et al. Comparative genomic hybridization: Uses and limitations. Seminars in Hematology 37, 348–357 (2000)</ref> , these initial limitations were overcome by using Microarrays in conjunction with CGh to improve the resolution of the imaging, Array Comparative Genomic Hybridisation (aCGH). This method compares sample and control microarrayed slides containing small segments of DNA (probes). <ref> Lucito, R., et al. Representational oligonucleotide microarray analysis: A high-resolution method to detect genome copy number variation. Genome Research 13, 2291–2305 (2003) </ref> the Probes used will vary according from the small (25-85 base pairs) oligonucleotides manufactured to highlight different target sequences, to the very large genomic clones (80,000- 200,00 base pairs), and as these are significantly smaller than the traditional metaphase chromosomes used for CGH, generating a higher resolution of image. <ref><pubmed>22467166</pubmed></ref>.aCGH is used as a diagnostic tool for prenatal detection f chromosomal abnormalities <ref><pubmed>19012303</pubmed></ref>.<br />
<br />
<br />
====Procedure====<br />
<ref> Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432] </ref><br />
The sample is obtained (skin, blood or fetal cells) and DNA is obtained. <br />
As a part of PGD fetal cell samples are collected from; the fertilized egg polar bodies, the blastomere (day 3 embryo) or the blastocyst/tropoectoderm stage (day 5 embryo).<br />
Sample DNA is labeled with one fluorescent dye, and the control DNA is labeled with a different colored fluorescent dye. the control DNA is used as the base point of reference. <br />
heated and denatured single DNA strands then hybridize to their complementary single strand probes, which are then combined and applied to a microarray and the results are run through a computer program and a digital imaging system is used to quantify the results( fluorescent intensities of the labeled probes). <br />
<br />
simple explanation of aCGH : [Genomics Education (2014) Genetic Testing for Health: aCGH|https://vimeo.com/84757281]<br />
<ref>Genomics Education (2014) Genetic Testing for Health: aCGH [video file] Vimeo [https://vimeo.com/84757281]</ref><br />
<br />
<br />
The fluorescent ratio and the hybridization signal at different locations on the genome of the control DNA are used to identify any variances present in the sample DNA. aCGH facilitates the clinical diagnosis of submicroscopic chromosomal duplication, deletion and rearrangements indicative of chromosomal disorders such as trisomies 1-22and specific sex linked disorders. <br />
Duplications in the DNA are displayed by the computer program as spikes/ peaks over an established threshold and deletions in DNA are displayed by the computer program as spikes/ toughs beneath this threshold <br />
-computer screening image- <br />
-drawn diagram of method-<br />
<br />
<br />
<br />
{|border="1" align="center"<br />
|-bgcolor="pink" <br />
| '''Advantages''' <br />
| '''Disadvantages'''<br />
|-<br />
| multiple applications: prenatal genetic diagnosis, cancer diagnosis, <ref><pubmed>20193845</pubmed></ref> genetic screening for developmental delay (learning disabilities) <ref><pubmed>17309648</pubmed></ref>. or congenital anomalies that are suspected to be genetic in origin <ref>NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation . retrieved from [http://www.phgfoundation.org/file/5237/]</ref><br />
| translocations and inversions of DNA are not detected<br />
|-bgcolor="pink"<br />
| trace represents all chromosomes present in the human genome chromosomes 1-22 and the X & Y chromosomes, and therefore is the most accurate method for testing whole embryo aneuploidy<br />
| limited ability diagnosing specific polyploidies such as triploidy <ref> Unique, Rare Chromosome Disorder Support Group (2013) Microarray-based Comparative Genomic Hybridiation (array CGH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/other/array%20cgh%20ftnw.pdf] </ref><br />
|-<br />
| aCGH has been extensively tested, and Validated, and is now used world wide.<br />
| will not detect mosaicism detection <20% (cultures where >1 of 5 cells are trisomy 12)<br />
|-bgcolor="pink"<br />
| detects deletions and additions and rearrangements as well as amplification, of the WHOLE genome, simultaneously.<br />
| will not detect balanced chromosomal rearrangement<br />
|-<br />
| detects submicroscopic alterations<br />
| will not detect duplications or deletions <80kb<br />
|-bgcolor="pink"<br />
| used as a diagnostic tool for prenatal detection of chromosomal abnormalities <ref><pubmed>22034057</pubmed></ref><br />
| will not detect point mutations within genes <ref>Washington department of education (CGH- FAQ for physicians. Signature Genomic LAboratories, LLC. Retrieved from [https://depts.washington.edu/dbpeds/Lab%20Tests/SignatureCGH-physician_FAQ.pdf]</ref><br />
|-<br />
| provides high resolution genomewide screening of segmental genomic copy number variations<br />
| will not detect chromosomal position of genomic gains<br />
|-bgcolor="pink"<br />
| very accurate when used in conjunction with FISH<br />
| will not detect loos of heterozygosity (LOH) or Absence of heterozygosity (AOH) <ref>WiCell Research Institute Inc. (2012) Comparative Genomic Hybridization Microarray. <br />
retrieved from [http://www.wicell.org/home/cytogenetic-services/cgh-microarray/array-comparative-genomic-hybridization-acgh.cmsx]</ref><br />
|-style="background:pink"<br />
|Alone is more reliable and in detecting chromosomal abnormalities, with a higher implantation success rate, than FISH <ref><pubmed>20494259</pubmed></ref><br />
|<br />
|-bgcolor="pink"<br />
|Allows an in depth research focus upon specific types of rearrangements within selected chromosomal regions, a recent particular area of interest is subtelomeric and pericentromeric rearrangements<br />
|<br />
|-<br />
|reduces the risk of failed implantation and miscarriage, improving the chance of a healthy baby <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|<br />
|}<br />
<br />
<br />
<br />
===Next Generation Sequencing===<br />
====Description====<br />
The development and advances within ART in the past 20 years, as well as the increasing popularity of IV, has lead to an influx of new technologies developed to screen embryos for chromosomal anomalies, which are covered by the umbrella term of Next generation Sequencing (NGS). NGS is a general term used to describe all of the new and emerging screening techniques currently being introduced and used as part of PGD for IVF . NGS screens for single gene disorders as well as conducting extensive and very comprehensive chromosome diagnosis by sequencing, counting, and accurately assembling millions of DNA reads, simultaneously. <ref><pubmed>23499002</pubmed></ref> There is a movementfor NGS to replace the other limited testing techniques and be used as the standard. <br />
====Procedure====<br />
Samples are collected from either blastomere or the blastocyst/tropoectoderm and processed for analysis by a computer system. <br />
The methodology of each process is unique to the technique being used. <br />
<br />
<br />
<br />
{|border="1" align="center"<br />
|-bgcolor="pink" <br />
| '''Advantages'''<br />
| '''Disadvantages'''<br />
|-bgcolor="white"<br />
| cheaper<br />
| there are limited information available to clinical applications of NGS <ref><pubmed>26100406</pubmed></ref><br />
|-bgcolor="pink"<br />
| opens new diagnostic possibilities<br />
|<br />
|-bgcolor="white"<br />
| accurately tests all 24 chromosomes<br />
| <br />
|-bgcolor="pink"<br />
| tests for the presence of monogenic diseases of known genetic background<br />
| <br />
|-bgcolor="white"<br />
| reduces the number of biopsies required for diagnosis<br />
| <br />
|-bgcolor="pink"<br />
| higher detection rate of small translocations<br />
| <br />
|-bgcolor="white"<br />
| highly accurate is testing for compound point mutations, chromosomal duplication, deletions and insertions <ref><pubmed>23312231</pubmed></ref><br />
| <br />
|-bgcolor="pink"<br />
| it accurately detects chromosomal aneuploidy and unbalanced rearrangement <ref><pubmed>25685330</pubmed></ref><br />
| <br />
|-bgcolor="white"<br />
| NGS single gene disorder screenings can conducted in conjunction with PCR comprehensive chromosomal screening<br />
|<br />
|-bgcolor="pink"<br />
| Reduces human error <br />
|<br />
|-bgcolor="white"<br />
| better detects the presence of mosaicism<br />
|<br />
|-bgcolor="pink"<br />
| work well in conjunction with CGH and aCGH as part of PGD, improving the chances of IVF. <ref> Morris, R. S. (2015 ) Next generation sequencing for PCG|PGS|CCS. IVF1 retrieved from [http://www.ivf1.com/next-generation-sequencing for-pgd] </ref><br />
|<br />
|}<br />
<br />
<br />
<br />
<br />
<br />
<br />
==Diagnosis==<br />
There are a large amount of diseases that PGD can apply to, below are descriptions of the diseases that PGD are more commonly used for. <br />
===Cystic Fibrosis===<br />
Cystic fibrosis is a single gene disorder. It is autosomal recessive and involves mutations in the cystic fibrosis transmembrane conductance regulator (CTFR) gene. The CTFR gene is normally responsible for the decrease in chloride and the transport of bicarbonate in epithelial cells thus playing a major physiological role. In PGD procedures, identification of the gene is assisted by microsatellite markers that have similar composition to the CTFR gene itself. Biopsy of two cells at the blastocyst stage is recommended if markers are not available. There are many variations of cystic fibrosis the most common being P.Phe508del <ref name="PMID26014425"><pubmed>26014425</pubmed></ref>.<br />
===Duchenne Muscular Dystrophy ===<br />
Duchenne Muscular Dystrophy is an X-linked recessive disease. It involves the Xp21 gene where majority of the mutations are chromosomal deletions with a smaller percentage resulting from duplications <ref name="PMID18359022"><pubmed>18359022</pubmed></ref>.<br />
===β – Thalassemia=== <br />
β – Thalassemia is known as the most common type of autosomal recessive inherited disorder among haemoglobinopathies. It involves the adult β-globin gene and is associated with the absent or decreased expression of the gene. This is commonly caused by a single nucleotide change in the gene. PGD has been used successfully worldwide to identify the β-globin gene where its application is usually performed on a single blastomere or polar body <ref name="PMID19064120">19064120</pubmed></ref>.<br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
! Applicable diseases for PGD <ref>Genoma Group (2014). Retrieved September 18th, 2015, from http://www.preimplantationgeneticdiagnosis.it/genetic-diseases-diagnosed-by-pgd.htm </ref>, <ref>Genesis Genetics (2015). Retrieved September 18th, 2015, from http://genesisgenetics.org/pgd/what-we-test-for/</ref>, <ref>Human Fertilisation & Embryology Authority (2015). Retrieved Septembr 18th, 2015, from http://guide.hfea.gov.uk/pgd/</ref><br />
|-<br />
| '''Disease'''<br />
| '''Involved Genes'''<br />
|-<br />
| 5 Alpha Reductase Deficiency (5ARD)<br />
| SRD5A2 <br />
|-<br />
| Achondroplasia<br />
|FGFR3 <br />
|-<br />
| Acute Intermittent Porphyria <br />
| ALAD, ALAS2, CPOX, FECH, HMBS, PPOX, UROD, or UROS<br />
|-<br />
| Adrenoleukodystrophy (Adrenomyeloneuropathy)<br />
| ABCD1 <br />
|-<br />
| Agammaglobulinaemia (x-linked) <br />
|BTK <br />
|-<br />
| Agammaglobulinemia Bruton Tyrosine Kinase (BTK) <br />
|BTK <br />
|-<br />
| Aicardi Goutieres Syndrome 1 (AGS1) <br />
|TREX1, RNASEH2A, RNASEH2B, RNASEH2C, SAMHD1<br />
|-<br />
| Alagille Syndrome<br />
|JAG1 or NOTCH2<br />
|- <br />
| Alpers-Huttenlocher Syndrome <br />
|POLG <br />
|-<br />
| Alpha-1-antitrypsin deficiency <br />
|SERPINA1 <br />
|-<br />
| Alpha-Mannosidosis<br />
| MAN2B1 <br />
|-<br />
| Alpha Thalassemia <br />
|HBA1 or HBA2 <br />
|-<br />
| Alports Syndrome<br />
|COL4A3, COL4A4, COL4A5<br />
|-<br />
| Alzheimer's Disease - early onset (Type 3 and 4) <br />
|APP, PSEN1, or PSEN2<br />
|-<br />
| Amyotrophic Lateral Sclerosis 1 (ALS1) <br />
|C9orf72, SOD1, TARDBP, FUS, ANG, ALS2, SETX, VAPB <br />
|-<br />
| Argininosuccinic Aciduria <br />
| ASL<br />
|-<br />
| Arrhythmogenic Right Ventricular Cardiomyopathy/ Dysplasia (ARVC/D)<br />
| DSG2; DSP; PKP2<br />
|-<br />
| Ataxia Telangiectasia<br />
| ATM<br />
|-<br />
| Bardet-Biedl Syndrome (BBS)<br />
| BBS1; BBS10<br />
|-<br />
| Barth Syndrome<br />
| TAZ<br />
|-<br />
| Beta Thalassaemia<br />
| HBB<br />
|-<br />
| Birt-Hogg-Dubé Syndrome<br />
| FLCN<br />
|-<br />
| Breast Ovarian Cancer Familial Susceptibility (BRCA2)<br />
| BRCA1; BRCA2<br />
|-<br />
| Canavan Disease <br />
| ASPA<br />
|-<br />
| Carnitine-Acylcarnitine Translocase Deficiency <br />
| SLC25A20<br />
|-<br />
| Cerebral Arteriopathy with Subcortical Infarcts & Leukoencephalopathy (CADASIL)<br />
| NOTCH3<br />
|-<br />
| Cerebral Cavernous Malformation<br />
| CCM1<br />
|-<br />
| Charcot-Marie-Tooth Disease<br />
| GJB1; MPZ; NEFL; PMP22<br />
|-<br />
| CHARGE Syndrome<br />
| CHD7<br />
|-<br />
| Cherubism<br />
| SH3BP2<br />
|-<br />
| Choroideremia<br />
| CHM<br />
|-<br />
| Chronic Granulomatous Disease<br />
| CYBB; NCF1<br />
|-<br />
| Ciliary Dyskinesia<br />
| DNAH5<br />
|-<br />
| Citrullinemia<br />
| ASS1<br />
|-<br />
| Cleidocranial Dysplasia<br />
| RUNX2<br />
|-<br />
| Cockayne Syndrome<br />
| ERCC6<br />
|-<br />
| Congenital Adrenal Hyperplasia<br />
| CYP21A2<br />
|-<br />
| Congenital Cataracts<br />
| GJA8; VSX2<br />
|-<br />
| Congenital Diarrhea, Syndromic<br />
| SPINT2<br />
|-<br />
| Congenital Disorders of Glycosylation (CDG)<br />
| ALG1; ALG6; CDG1C; DOLK; PMM2<br />
|-<br />
| Cornelia de Lange Syndrome <br />
| NIPBL<br />
|-<br />
| Craniosynostosis<br />
| TWIST1<br />
|-<br />
| Crouzon Syndrome<br />
| FGFR2<br />
|-<br />
| Cysteinyl Leukotriene Receptor 1 Deficiency <br />
| CYSLTR1<br />
|-<br />
| Cystic Fibrosis<br />
| CFTR<br />
|-<br />
| Diamond –Blackfan Anemia <br />
| RPS19<br />
|-<br />
| Duchenne Muscular Dystrophy <br />
| DMD<br />
|-<br />
| Dyskeratosis congenita (Male embryos only)<br />
| DKC1<br />
|-<br />
| Ectodermal dysplasia (Hypohidrotic)<br />
| EDA; EDA1; GJB6; IKBKG<br />
|-<br />
| Familial Adenomatous polyposis coli (FAP)<br />
| APC<br />
|-<br />
| Familial Dysautonomia<br />
| IKBKAP<br />
|-<br />
| Fanconi Anemia <br />
| FANCA; FANCC; FANCD2; FANCF; FANCG; FANCJ<br />
|-<br />
| Fragile X Syndrome (FRAX)<br />
| FMR1<br />
|-<br />
| Galactosemia <br />
| GALT<br />
|-<br />
| Gangliosidosis<br />
| GLB1<br />
|-<br />
| Glanzmann Thrombasthenia <br />
| ITGA2B<br />
|-<br />
| Glutaric Acidemia (aciduria)<br />
| GCDH <br />
|-<br />
| Glycogen Storage Disease <br />
| G6PC; GAA; SLC37A4<br />
|-<br />
| Haemophilia A<br />
| F8<br />
|-<br />
| Haemophilia B<br />
| F9<br />
|-<br />
| Hereditary Nonpolyposis Colorectal Cancer: Lynch Syndrome<br />
| MLH1; MSH2; MSH6<br />
|-<br />
| Holt Oram Syndrome<br />
| TBX5<br />
|-<br />
| Huntington Disease<br />
| HD<br />
|-<br />
| Hydrocephalus<br />
| L1CAM<br />
|-<br />
| Ichthyosis <br />
| ABCA12; STS<br />
|-<br />
| Incontinentia Pigmenti (IP)<br />
| NEMO<br />
|-<br />
| Joubert Syndrome 5<br />
| INPP5E<br />
|-<br />
| Krabbe Disease<br />
| GALC<br />
|-<br />
| Leber Congenital Amaurosis (LCA)<br />
| CEP290; GUCY2D<br />
|-<br />
| Leigh Syndrome (Infantile Subacute Necrotising Encephalopathy)<br />
| LRPPRC<br />
|-<br />
| Lesch Nyan Syndrome<br />
| HPRT1<br />
|-<br />
| Leukocyte Adhesion Deficiency (Type I)<br />
| ITGB2<br />
|-<br />
| Li-Fraumeni Syndrome<br />
| TP53<br />
|-<br />
| Macular Dystrophy Retinal <br />
| VMD2<br />
|-<br />
| Maple Syrup Urine Disorder (MSUD)<br />
| BCKDHB<br />
|-<br />
| Marfan Syndrome <br />
| FBN1<br />
|-<br />
| Menkes Syndrome<br />
| ATP7A<br />
|-<br />
| Mitochondrial DNA Depletion Syndrom <br />
| POLG; RRM2B; SUCLA2; TK2<br />
|-<br />
| Mucolipidosis type II<br />
| GNPTAB<br />
|-<br />
| Multiple Endocrine Neoplasia<br />
| MEN1; MEN2A; MEN2B<br />
|-<br />
| Multiple Exostoses<br />
| EXT1; EXT2 <br />
|-<br />
| Myotubular myopathy<br />
| MTM1 <br />
|-<br />
| Nail-Patella Syndrome<br />
| LMX1B<br />
|-<br />
| Neurofibromatosis Type 1<br />
| NF1<br />
|-<br />
| Neurofibromatosis Type 2 <br />
| NF2<br />
|-<br />
| Noonan Syndrome<br />
| KRAS, PTPN11; SOS1<br />
|-<br />
| Norrie Disease<br />
| NDP<br />
|-<br />
| Ocular Albinism <br />
| GPR143<br />
|-<br />
| Oculocutaneous Albinism <br />
| OCA2; TYR <br />
|-<br />
| Oculodentaldigital Dysplasia<br />
| GJA1<br />
|-<br />
| Optic Atrophy<br />
| OPA1<br />
|-<br />
| Ornithine Transcarbamylase Deficiency <br />
| OTC<br />
|-<br />
| Osteogenesis imperfeca <br />
| COL1A1; COL1A2<br />
|-<br />
| Osteopetrosis <br />
| CLCN7; OSTM1; TCIRG1<br />
|-<br />
| Pachyonychia Congenita <br />
| KRT16; KRT6A<br />
|-<br />
| Pancreatitis, Hereditary<br />
| PRSS1 <br />
|-<br />
| Papillorenal syndrome <br />
| PAX2<br />
|-<br />
| Phenylketonuria <br />
| PAH <br />
|-<br />
| This table does not cover the complete list of diseases that PGD can be applied to.<br />
|}<br />
<br />
==Laws & Legal status==<br />
===Australia=== <br />
PGD is currently used to detect serious genetic conditions to improve the outcome of Assisted Reproductive Technologies (ART). In very rare cases it may be used to select an embryo with compatible tissue for a sibling who has a life-threatening disease where other means of treatment is unavailable. This is with the conditions that the use of PGD will not affect the welfare and interests of the child to be born. The parents must also receive adequate counselling and have full understanding of the procedures of PGD. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"> National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art</ref><br />
The use of PGD for sex-selection is prohibited with the exception of reducing the risk of the transmission of serious sex-linked genetic conditions. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"/><br />
===Brazil=== <br />
The laws regarding PGD in Brazil are not strictly regulated. They are vague and there is limited information surround the activities of assisted reproduction in general in the country <ref name="PMID25493379"><pubmed>25493379</pubmed></ref>.<br />
===Czech Republic===<br />
The laws in the Czech Republic allow those with a “defined indication in order to exclude risk of serous genetically conditioned disease and defects with embryos before they are implanted into the cavity of the uterus”. Couples that undergo any assisted reproductive treatment including PGD have to be married. Sex-selection is illegal except in regards to serious sex-linked genetic diseases <ref name="PMID24777348"><pubmed>24777348</pubmed></ref>.<br />
===Greece=== <br />
In Greece, ART is open to those up to the age of 50 with written consent. It can only be used if a medical necessity is present such as the susceptibility of serious hereditary diseases. Sex selection is banned apart from cases of sex-linked diseases and sexually transmitted diseases <ref name="PMID24777348"/>.<br />
===Portugal=== <br />
ART is only available to those who are married or have a similar type of relationship for at least two years. The couples cannot be of the same sex and must be at least 18 years of age. Sex selection is illegal except in cases of sex-linked diseases. The use of PGD is illegal if the predictive value of genetic tests are very low <ref name="PMID24777348"/>.<br />
===Spain===<br />
PGD can be applied to “serious hereditary diseases not amenable to postnatal curative treatment” and “detection of other abnormalities which may compromise the viability of the pre-embryo”. If PGD is to be used for any other purpose authorisation must be acquired <ref name="PMID24777348"/>.<br />
===Sweden=== <br />
The use of PGD is strictly regulated and couples must achieve authorisation of the National Board of Health and Welfare. It can only be used it can only be used if the child is at risk to inheriting a serious chromosomal or monogenetic disease. It cannot be used for selection of specific characteristics <ref name="PMID24777348"/>.<br />
===United Kingdom===<br />
Those involved with carrying out the IVF treatment must have a license from the Human Fertilisation and Embryology Authority (HFEA). Only embryos that are approved by the HFEA can be implanted where the embryonic nuclear or mitochondrial DNA cannot be altered with the exception of preventing mitochondrial diseases <ref name="PMID24777348"/>. <br />
==Future/Current Research==<br />
===Noninvasive Preimplantation Genetic Testing without Embryo Biopsy===<br />
Different parameters of gametes, zygotes, embryos (“vacuoles in sperm heads, spindle position in mature oocytes, cleavage intervals of zygote, and embryo developmental dynamics”) may correlate with aneuploidy rates. This knowledge may be applied in potential noninvasive preimplantation diagnostic methods. Several methods have been proposed and are currently further researched<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Sperm Selection====<br />
Intracytoplasmic morphologically selected sperm injection (IMSI) is common procedure in IVF treatment to improve fertilization rates in patients with poor semen quality. In addition, studies have found that IMSI improves embryo development and that spermatozoa with large vacuoles in their heads correlate with increased aneuploidy rates and disturbed chromosomal structures. Thus, selecting spermatozoa based on morphological hallmarks may decrease aneuploidy rates in the fertilized embryos. As with polar body biopsies, however, this approach will solely be applicable if evidence for severe male detrimental contribution is given<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Blastocoel Fluid Extraction====<br />
In addition, a less invasive retrieval of material for diagnosis could include the extraction of the blastocoel fluid. The cavity of the blastocyst, lined by the trophectoderm, is filled with this blastocoel fluid, which contains metabolites of both trophectoderm and inner cell mass origin. The retrieval does not require a biopsy but merely a small opening to extract the fluid and, thus, causes less harm to the embryo. Multiple studies have applied this method<ref name="PMID22020776"><pubmed>22020776</pubmed></ref> <ref name="PMID23148560"><pubmed>23148560</pubmed></ref> and it may in the future become of clinical relevance.<br />
<br />
{|border="1"<br />
| [[File:Aspiration_of_the_Blastocoel_Fluid.jpeg]]<br />
|-<br />
| Aspiration of the Blastocoel Fluid using a ICSI pipette<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
|}<br />
<br />
<br />
Next to metabolites, the blastocoel fluid can contain DNA. Studies have shown that genomic DNA is present in about 90% of the blastocoel fluid samples tested. Typically the fluid is removed with an ICSI pipette from a day five blastocyst through its mural trophectoderm until the blastocyst fully collapses around the embryo. Several concerns regarding this method in a clinical setting have been raised. The collected DNA may be contaminated by the culture media that contains DNA fractions. The DNA may also be least representative of the actual embryos genome as the DNA may originate from abnormal or degenerated cells. Even though labelled noninvasive, the blastocyst still undergoes manipulation to some degree which may affect its viability. Thus, more research is required until this method can evolve from research to clinical use<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
====Proteomics====<br />
The protein secretome of blastocysts may be representative of its chromosome constitution Recent studies have found biomarkers such as lipocalin-1, interleukin-10, tumor necrosis factor, stem cell factor, and chemokine ligand 13 to be differently secreted by aneuploid blastocyst than by euploid ones. The most significant biomarker appears to be interleukin-10. Paired with novel proteomic technologies and mass spectrometry this knowledge when extended may contribute to a new invasive preimplantation genetic diagnosis method<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Embryo Morphology====<br />
Using time lapse imaging the embryo’s morphology can be closely observed and potential aneuploidy characteristics detected. Such characteristics may include the time of division to five cells, the time between the division from three to four cells, and the duration of the division from one to two and subsequently to three. In addition, the morphological quality of ICM an TE has been positively associated with aneuploidy or euploidy prognosis<ref name="PMID26246880"><pubmed>26246880</pubmed></ref>. These may give rise to an embryo quality screening prior to implantation<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
===Utilization of Diseased Cell Lines===<br />
==Ethics==<br />
==References==<br />
<br />
<references/><br />
<br />
<br />
{{StudentPage2015}}</div>Z5017878https://embryology.med.unsw.edu.au/embryology/index.php?title=2015_Group_Project_6&diff=2065592015 Group Project 62015-10-19T12:04:31Z<p>Z5017878: </p>
<hr />
<div>{{ANAT2341Project2015header}}<br />
<br />
<br />
=Prenatal Genetic Diagnosis=<br />
==Introduction==<br />
==History==<br />
Prenatal Genetic Diagnosis was historically conducted post-implantation in the first 2 trimesters <ref> Blackburn, S.L. (2003) '''Maternal, Fetal & Neonatal physiology: a Clinical perspective''' (2nd ed.). Seattle: Saudners </ref>, testing for overall fetal growth, complications of pregnancy, birth defects as well as chromosomal or genetic abnormalities<ref> Sadler T.W.(2012) '''Langman's Medical Embryology''' (12th ed.) Philadelphia: Lipincott, Wiliams & Wilkins, a Wolters Kluwer Business </ref>. Due to advancements in Artificial Reproductive Technologies ( ART) in the past 2 decades , these genetic tests are now conducted as a part of Preimplantation Genetic Diagnosis (PGD) <ref><pubmed>20638568</pubmed></ref> and art used to eliminate the rsik of passing on a genetic disorder to an offspring, before implantation, it ha now become a preventative measure. . In 1990 Preimplantation genetic testing was first used in 1990 on humans to diagnose recessive X-linked diseases in the embryos of pregnant women undergoing IVF. <ref><pubmed>2330030</pubmed></ref> PGD is offered as an alternative to prenatal diagnosis in detecting genetic disorders in high risk couples <ref><pubmed>26168107</pubmed></ref> and avoid passing an inherited disease to the offspring, by selecting genetically "normal" embryos for implantation ,to give the best chance of successful implantation , stable pregnancies and healthy children. <br />
<ref><pubmed>23499002</pubmed></ref><br />
<br />
==Preimplantation Genetic Diagnosis==<br />
[[File:Preimplantation Genetic Diagnosis Procedure.jpeg|700px|thumb|centre| Simplified steps for PGD]]<br />
<br />
<br />
Preimplantation genetic diagnosis (PGD) is used to test the genetic makeup of embryos to detect single gene disorders, chromosomal abnormalities and mitochondrial disorders. It also has applications in gender selection for diseases with unequal gender distributions <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Some diseases commonly involved with PGD include cystic fibrosis, spinal muscular atrophy and beta – thalassaemia <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press.">Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press</ref> <ref name="PMID17823145"><pubmed>17823145</pubmed></ref>. It was first used in the United Kingdom in the 1980s of arenoleucodystrophy and primarily focusing on sex- linked disorders <ref name="PMID17823145"/><ref name="PMID23150080"><pubmed>23150080</pubmed></ref>. PGD is now capable of detecting single cell defects (molecular) and chromosomal disorders resulting from the inversion, translocation or deletion of chromosomes (cytogenic) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>,<ref name="PMID11325751"><pubmed>11325751</pubmed></ref>. PGD can be applied to the embryo at different stages. That is on polar bodies, blastomeres or blastocyst <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>.<br />
Depending on the type of genetic disorder, PGD utilises different methods of genetic testing. These include Fluorescence in situ hybridisation (FISH) which is used for sex – linked disorders and detects chromosomal rearrangements <ref name="PMID11325751"/><ref name="PMID17876073"><pubmed>17876073</pubmed></ref> and Embryo halotyping which allows the identification of chromosomes causing the inherited disorder through knowledge of the pattern of closely linked markers <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. Polymerase chain reaction (PCR) is also widely used to detect molecular abnormalities <ref name="PMID11325751"/>.<br />
PGD is tightly regulated and supported by large organisations namely The American Society for Reproductive Medicine, The European Society for Human Reproduction and Embryology (ESHRE), The European Society of Human Genetics and the Preimplantation Genetic Diagnosis International Society <ref name="PMID25500181><pubmed>25500181</pubmed></ref>.<br />
===Sex-linked disorders===<br />
The determination of a disease as gender specific usually correlates with the presence or absence of specific genes such as SRY on the Y chromosome. It is known that females have two X chromosomes and males have an X and a Y chromosome where abnormalities are more prevalent on the X chromosome. PGD can be used for sex selection where only male embryos are transferred to reduce the chance of inheriting X-linked disorders. However, this does not completely eradicate the problem as male embryos remain susceptible to inheriting an affected X chromosome. Sex determination is only used when the specific mutation is unknown and has yet to be discovered <ref name="PMID24866878"><pubmed>24866878</pubmed></ref>.<br />
===Single gene defects===<br />
Single gene defects can be dominant, recessive, autosomal or X-linked. They are commonly diagnosed using PCR and although the PCR available today is complex and capable of combatting a large range of disease the development of new protocols has been proven to be difficult due to the small DNA sample available <ref name="PMID26168107"><pubmed>26168107</pubmed></ref><br />
===Mitochondrial disorders===<br />
Mitochondrial disorders also known as oxidative phosphorylation disorders arise from mutations in the nuclear DNA or mitochondrial DNA <ref name="PMID26312584"><pubmed>26312584</pubmed></ref>. They pose as a problem because they are unrecognisable until the mutations in the cell reach a detrimental level <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Mitochondrial disorders cause miscarriages and stillbirths as well as death in children and young adults. The effects can either be contained in a single organ or more commonly involve multiple organ failure where organs with high energy demands such as the brain, liver muscle and heart and heavily influenced. They are usually occur spontaneously or result from inheritance from the mother. Since mitochondria are solely inherited from the mother oocyte donations have been used as a solution to combat mitochondrial disorders. Additionally, there has been an increasing use in PGD where embryos that stay under the given threshold of 18% gene-mutations are allowed to be transferred and result in normal development. New technology in the areas of nuclear gene transfer and genome editing are also being experimented with <ref name="PMID26312584"/>. <br />
===Chromosomal disorders===<br />
Chromosomal disorders can be reciprocal, Robertsonian translocations, inversions, deletions and insertions <ref name="PMID26168107"/>. . Data from ESHRE collected between 2010 and 2011 has shown that the most common chromosomal abnormality confronted in PGD are reciprocal chromosomal abnormalities <ref name"PMID26071418"><pubmed>26071418</pubmed></ref>. PGD has also been used successfully for Robertsonian translocations (RT), a type of structural translocation. Children who carry RT are phenotypically normal, however in their later years it is found that they will suffer from infertility and repeated miscarriages due to the high frequency of abnormal embryos <ref name="PMID22081077"><pubmed>22081077</pubmed></ref>. PCR and FISH are the two main techniques used for chromosomal disorders. To be able to conduct the examinations the cells are required to be at the metaphase stage <ref name="PMID26168107"/>. <br />
==Preimplantation Genetic Screening==<br />
Prenatal Genetic Screening (PGS) involves an array of methods or ideas that aim to segregate embryos that have genetic flaws and those that are healthy <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. The occurrence of aneuploidy is high around the stages of early embryonic development and they are the most common cause if miscarriages and congenital birth defects <ref name= "PMID26085841"><pubmed>26085841</pubmed></ref>. They have little effect on the morphology of the embryo making them difficult to identify thus identification heavily relies on genetic testing <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. <br />
Genetic sampling is most commonly conducted using Microarray Comparative Genomic Hybridisation (aCGH) as well as FISH, Quantitative PCR and Single Nucleotide Polymorphism (SNP) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. These methods collectively aim to assess numeral and structural chromosomal errors <ref name= "PMID26085841"/>. Studies have also introduced Next- Generation Sequencing (NGS) <ref name= "PMID26085841"/> and Whole Genome Amplification used to screen imbalances in the complete 24-chromosomes <ref name="PMID25953353"><pubmed>25953353</pubmed></ref><br />
Statistics from ESHRE have shown that the most common indications for PGS is advanced age, followed by repeated implantation failure or recurrent miscarriage and male infertility <ref name="PMID26071418"><pubmed>26071418</pubmed></ref>.<br />
====Indications====<br />
A low percentage of structural abnormalities in chromosomes are responsible for the cause of miscarriages. Despite this, they are the most prevalent type of chromosomal abnormality accounted for in PGD <ref name="PMID20638568"/>. The presence of specific gene cycles, initiation of embryonic protein synthesis and evident physiological development are all indicative of a successful in vitro fertilisation procedure <ref name="PMID11576737"><pubmed>11576737</pubmed></ref>. To eliminate further errors from occurring during the PGD procedure it is recommended to undertake further prenatal testing such as amniocentesis in the later stages <ref name="PMID20638568"/>. <br />
=====Advanced maternal age=====<br />
Data provided by the ESHRE has shown that the mean age of women undergoing PGS is 39 years <ref name="PMID26071418"/>. Women of advanced age have been shown to have a lower rate of pregnancies reaching childbirth <ref name="PMID18583331"><pubmed>18583331</pubmed></ref>. The highlighted concern revolves around the increased occurrence of aneuploidy following maternal age. The optimal age range for the lowest aneuploidy incidence was found to be between 27 to 37 years of age (6%) then progressively higher in women aged up to 42 (33%) and most common in those 44 and above (53%) <ref name="PMID24355045"><pubmed>24355045</pubmed></ref>. <br />
=====Recurrent pregnancy loss / IVF failure=====<br />
Recurrent pregnancy loss is defined as three or more IVF failures after cumulative transfer of more than 10 good-quality embryos. These are primarily caused by two main factors, reduced endometrium receptivity or embryonic defects. Endometrium receptivity can be negatively influences by instances including uterine pathologies such as thin endometrium, altered expression of adhesive molecules and immunological factors. Additionally, embryonic defects may be due to genetic abnormalities, embryonic aneuploidy or zona hardening. Endometriosis and hydrosalpinx has been known to effect both the endometrium and embryo <ref name="PMID23260857"><pubmed>23260857</pubmed></ref>.<br />
=====Human leukocyte antigen matching=====<br />
First used in 2001, HLA matching is an option given to parents to save a child with haematological or immunological disease through conceiving another child who would potentially be able to donate cord blood or haematopoietic stem cells from the bone marrow for transplantation. The process namely PGD-HLA has shown to improve haematopoietic stem cell transplant (HSCT). PGD-HLA can only be performed when HSCT is not needed urgently due to the time needed to conceive and delivery the baby <ref name="PMID25500181"><pubmed>25500181</pubmed></ref>. It is most commonly applied to children suffering from relapsed leukaemia <ref name="PMID22524201"><pubmed>22524201</pubmed></ref>. In a case study PGD-HLA was proven to successfully cure 10 diseases including Fanconi anaemia, Diamond-Blackfan anaemia and beta thalassemia <ref name="PMID25066893><pubmed>25066893</pubmed></ref>.<br />
==Biopsy Methods==<br />
Biopsy, the removal of genetic materials, from oocytes or embryos in the preimplantation stage is the primary step in PGD. For the past two decades these biopsies have been performed at three stages, the polar body, blastomere, and blastocyst, and the methodologies optimized to ensure the embryo’s viability. The most common approach involves biopsies at the cleavage stage. However, polar body and blastocyst biopsies are increasingly more often tested and applied. Approached for opening the zona pellucida involve next to the traditional mechanical and chemical means, novel approaches such as noncontact lasers. Their application may simplify and secure the procedure significantly. The most challenging question about PGD procedures remains at what stage biopsies should be taken. Much controversy has developed around this topic, highlighting the varying disadvantages and advantages of temporal biopsies. <ref name="PMID22723007"><pubmed>22723007</pubmed></ref><br />
<br />
{|border="1" align="left"<br />
|-bgcolor="pink" <br />
|<br />
| Time of Biopsy<br />
| Advantages <br />
| Disadvantages<br />
|- <br />
| Polar Body<br />
| Day 1<br />
| No harm to oocyte<br />
| Only maternal DNA is tested, often needs to be coupled with other biopsies<br />
|-bgcolor="pink"<br />
| Blastomere<br />
| Day 3<br />
| …<br />
| … <br />
|-<br />
| Trophectoderm<br />
| Day 5 and 6 <br />
| Little harm, large amount of genetic material<br />
| Opening of blastocyst necessary, small time window for procedure<br />
|}<br />
<br />
{|border="1"<br />
| [[File:Polar_Body,_Blastomere,_and_Trophectoderm_Biopsy.jpeg]]<br />
|-<br />
| Polar body (A), blastomere (B) and trophectoderm (C) biopsies<ref name="PMID25625041"><pubmed>25625041</pubmed></ref>.<br />
|}<br />
<br />
PMID 24305177<br />
===Polar Body Analysis===<br />
Day 1<br />
====Description====<br />
Polar body (PB) biopsy, which was introduced in 1990, offers a promising alternative to biopsies performed at the blastomere stage for PGD/S indications on legal and practical grounds. <br />
Description: Consequent embryo development does not necessitate the presence of the first and second PB and their removal may not be crucial. PB biopsy requires precise timing. Keeping track of the meiotic cell cycle is necessary to perform a successful biopsy and, therefore, PB biopsy usually is applied in combination with intracytoplasmic sperm injection (ICSI). During the maturation from the germinal vesicle stage to the metaphase-II stage the first PB is formed. A cytoplasmic bridge containing spindle remnants, that are still in contact with the cellular genetic material, links this PB to the oolemma for about 90 minutes after extrusion. It is possible to visualize these remnants by polarization microscopy and it is crucial to not perform the biopsy until the first PB is no longer firmly attached to the oolemma as this indicates an immature embryo.The oocyte tolerates mechanical zona dissection best during hours four until six after ICSI as the oolemma has stabilized by that time because of the cortical granule reaction. Over time the first PB degenerates stressing a temporal biopsy and its optimal extraction time window is four to 12 hours after ICSI. The second PB forms around two to four hours after ICSI. However, its optimal time window for biopsy is set to be eight to 16 hours after ICSI. This is due to the second PB being attached to the oolemma with spindle remnants until six hours after ICSI. Biopsy at this point may cause enucleation of the oocyte. In addition, studies have shown that the amplification efficiency of second PB’s DNA is worse if the PB is extracted prior to eight hours after ICSI. <br />
Thus, it is possible to perform sequential and simultaneous biopsies for the first and second PB. If performed, sequentially the first PB may be removed four to 12 hours and the second PB eight to 16 hours after ICSI. The optimal time window for a biopsy for both the first and second PB simultaneously is eight to 12 hours after ICSI. It is highly preferred to analyze both PBs due to potential aneuploidies in either PB and crossing overs during meiosis<ref name="PMID22723007"/>. <br />
====Procedure====<br />
Chemical opening achieved with for example acidic tyrode’s solution of the zona pellucida is not tolerated by the oocyte and may have detrimental effects on the embryo’s development. Therefore, the access to the perivitelline space of the oocyte is provided by mechanical zona dissection or by laser. Both techniques work well if performed by experienced embryologist. However, laser-assisted biopsy is less time consuming when compared to manual dissection. It is critical to consider the size of the introduced opening as it will remain permanent. If it is too large the blastomere may be lost during embryo development and if it is too small it may interfere with hatching of the embryo during blastocyst stage<ref name="PMID22723007"/><br />
<br />
{|border="1"<br />
| [[File:Polar_Body_Biopsy.jpeg]]<br />
|-<br />
| The presence of a faint but clearly identifiable strand connecting PB2 to the <br />
oolemma. The biopsy was performed ∼9 h after ICSI<ref name="PMID21908464"><pubmed>21908464</pubmed></ref>.<br />
|}<br />
<br />
{|border="1"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JTaQzszVr8o</html5media><br />
|-<br />
| Laser-assisted polar body biopsy<ref>RIUK, R. (2013, June 25) Polar Body Biopsy [Video file]. Retrieved from https://www.youtube.com/watch?v=JTaQzszVr8o</ref><br />
|}<br />
<br />
====Advantages & Disadvantages====<br />
PB biopsies can only investigate the maternal contributions to the embryo as they are of maternal origin. Thus, this procedure is appropriate for PGD solely for monogenetic diseases from the maternal side. Recessive diseases may be evaluated with PB biopsies on the basis that the embryo’s outcome will be determined by the paternal contribution. (...) It may still be applied for PGS as most aneuploidies either arise during meiosis or origin from the maternal genome. However, diagnosis error has been reported due to the lack of considering paternal contributions. <br />
Because PB biopsies are performed very early it is not yet known whether the oocyte will develop into a viable embryo. Thus, PBs are commonly frozen or fixed after biopsy and depending on the state of the embryo only chosen PBs will be tested. This is primarily an economic issue as many genetic testing procedures are very cost-intensive<ref name="PMID22723007"/>.<br />
<br />
{|border="1"<br />
| [[File:Implantation_predictive_value_of_euploid_screening_results.jpeg]]<br />
|-<br />
| The sustained implantation predictive value (with 95 % confidence interval) of a euploid screening result obtained from the first polar body (PB1), PB1 and the second polar body (PB2), or a direct embryo biopsy for each stage of embryo transfer (cleavage-stage and blastocyst stage)<ref name="PMID25106935"><pubmed>25106935</pubmed></ref>.<br />
|}<br />
<br />
===Blastomere biopsy===<br />
Day 3 <br />
====Description====<br />
Blastomere biopsy has been the prevalent method for PGD and PGS in the last two decades. At least one, but up to two, blastomeres are biopsied on day three of the cleavage stage embryo. The right number of blastomeres removed is a controversial topic as two cells allow for more genetic material and more accurate results. However, removing two cells might be too invasive and damaging to the embryo. (Study)<ref name="PMID21748341"><pubmed>21748341</pubmed></ref><br />
====Procedure====<br />
Initially a hole was drilled into the zona pellucida using acid tyrodes and the blastomeres are removed via aspiration with a pipette<ref name="PMID21748341"/>.<br />
<br />
{|border="1"<br />
| [[File:Aspiration_of_a_Blastomere.jpeg]]<br />
|-<br />
| Aspiration of a Blastomere into the biopsy pipette<ref name=" PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
|}<br />
<br />
{|border="1"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=TbridWVwipI</html5media><br />
|-<br />
| Laser-assisted blastomere biopsy<ref>Sukprasert, M. (2014, March 5) Day 3 Blastomere Biopsy 1 [Video file]. Retrieved from https://www.youtube.com/watch?v=TbridWVwipI</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
===Trophectoderm biopsy===<br />
Day 5 and 6<br />
====Description====<br />
The improvement of embryo culture media allowed the in vitro development of human embryos until the blastocyst stage and opened up the possibility to take blastocyst biopsies. During day three to day five the haploid maternal and paternal genomes work together for the first time to form the genome of the embryo. The maternal epigenetic control lessens significantly while preparing for implantation with precisely arranged events happening. The first event includes a rapid increase in the number of embryonic cells which are active in mitotic divisions and apoptosis of aberrant cells. This is followed by the formation of blastocoel (cavitation) which results from the flattening of cell located on the outside of the blastomere. Now the blastocyst will expand until the embryo hatches by rupturing the zona pellucida. The cells of the blastocyst will differentiate to form two distinct cell lineages, the outer trophectoderm and the inner cell mass<ref name="PMID22723007"/>.<br />
====Procedure====<br />
Trophectoderm biopsy is usually performed in Hepes buffered biopsy medium and opening approaches include needle cutting which has been replaced by lasers in past years. Different research groups report different timings of the opening to be the most successful. Some open the blastocyst on day three or four by creating a 25 µm which causes the trophectoderm to herniate through this hole and is, thus, accessible for biopsy. Others create this hole about four hours before biopsy which allows sufficient herniation of trophectoderm cells. It is also possible to open the blastocyst immediately before biopsy. This avoids an extra step and the inner cell mass usually is easy to locate. Blastocyst biopsies involve the removal of trophectoderm cells and the ideal time for the procedure is day five. Successful biopsies on day six have been performed, while little is known about the results of biopsies on day seven. However, since the window of implantation in humans is from day eight to ten after ovulation, day seven biopsies appear to be possible<ref name="PMID22723007"/>.<br />
-collapse of trophoblasts<br />
-possible: biopsy of hatched blastocyst, holding pipette careful mild suction force to hold embryo near ICM <br />
-Cryopreservation<br />
<br />
{|border="1"<br />
| [[File:Microscopic images of human blastocysts for biopsy.jpeg]]<br />
|-<br />
| (A) Some trophectoderm cells in a blastocyst started to hatch and (B) the trophectoderm cells were biopsied with assisted laser cutting. Images in C–D show the blastocysts after vitrification and warming. Blastocysts had been cultured for 2–4 hrs after warming, showing good (ICM and trophectoderm cells) hatched (C) and hatching (D) blastocysts. The hatching blastocyst in (E) has good ICM but fair trophectoderm while the blastocyst in (F) has both fair ICM and trophectoderm. Arrows indicate ICMs and arrow heads indicate trophectoderm cells. Bar = 40 µm<ref name="PMID2190846"><pubmed>2190846</pubmed></ref>.<br />
|}<br />
<br />
<br />
{|border="1"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JI_TQ8d8tNM</html5media><br />
|-<br />
| Laser-assisted blastocyst biopsy (at 00:50 min)<ref>Coco, R. (2014, April 30) Trophectoderm biopsy in a Hatching blastocyst protruding ICM [Video file]. Retrieved from https://www.youtube.com/watch?v=JI_TQ8d8tNM</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
Blastocyst biopsies are believed to be less damaging to the embryo and appear to be unrelated to implantation rates. In addition, this biopsy method allows for a larger extraction of cells for genetic testing. However, since they are performed late in in vitro development, the time window for genetic testing is relatively small. Fast and accurate genetic testing methods are needed to ensure a successful and safe result from this biopsy. Thus, blastocyst biopsies may gain more popularity in the future whn such methods have been developed or improved<ref name="PMID22723007"/>. <br />
<br />
<br />
==Genetic Techniques==<br />
<br />
===PCR===<br />
====Description====<br />
Polymerase chain reaction (PCR) amplifies DNA specific to genetic sequence of interest . PCR was developed by Kay Mullis in the 1980s, for which he was awarded the Nobel prize for chemistry in 1993. <ref> Pubmed Docs (2015) Polymerase Chain Reaction (PCR) Pubmen. Retrieved from [http://www.ncbi.nlm.nih.gov/probe/docs/techpcr/]</ref> This technique enables clinicians to monitor and diagnose diseases using minute samples such as embryonic cells, blood & tissue. <ref>Roche (2015) PCR: How We Copy DNA. Roche Molecular Systems Inc. retrieved From [http://molecular.roche.com/pcr/Pages/Process.aspx]</ref> PCR has many important applications like DNA fingerprinting, genetic mapping, detection of viruses and bacteria as well as being used to detect genetic disorders, as a part of PGD, in conjunction with IVF. It is used to detect molecular abnormalities such as single gene disorders like Tay Sach, Cycstic fibrosis, Duchenne Muscular Dystrophy, Thalassemia, Huntington disease, Spinal muscular atrophy and many more. Molecular and Genetic analysis require a significant amount of DNA, which we would not have without PCR. It revolutionized the study of DNA, replacing all previous recombinant DNA technology. <ref> Mullins, K., Francois, F.& Gibbs R.A. (1994 ) The Polymerase Chain Reaction. p3. Springer- Science +Business Media. Birkhauser, Boston<br />
Available at [https://books.google.com.au/books?hl=en&lr=&id=gjrTBwAAQBAJ&oi=fnd&pg=PR5&dq=kary+mullis+PCR&ots=mpzAyRh5ZY&sig=PQ4goNoKJ90tb3-MkPk62zrTGbw#v=onepage&q=kary%20mullis%20PCR&f=false] </ref> <br />
<br />
====Procedure====<br />
<br />
Sample are obtained from the the blastocyst, a polar body biopsy or the blastomeres stages of the embryo. <br />
Stage 1 Denaturing: separating the target strands of DNA <br />
The obtained sample is heated to roughly 90 degrees celcius, this heat causes breaks the relatively weak bonds between nucleotides that form DNA. the double stranded DNA to split into 2 single strands of DNA that are used as templates.<br />
Stage 2 Annealing: Binding the Primers to the target DNA sequence <br />
PCR will only copy the target sequence of DNA specified by specific PCR primer. These synthesized primers Oligonucleotides are small artificial pieces of DNA. <br />
TAQ polymerase enzyme synthesize 2 new strands of DNA duplicate to the single sample DNA stand template indicated by these primers. During this stage the reaction is cooled to a temperature between 40-60 degrees Celsius. <br />
Stage 3- Extension- making copies <br />
Each of these 2 copies are then used again as templates generating 2 further replications This cycle can occur as many 30 -40 times within a couple hours leading to billions of extra copies of the original DNA segment. The optimal temperature for the further replication is roughly 72 degrees Celsius. <br />
<br />
This process mediated by a thermocycler machine that is programmed to alter the temperature of the reaction every couple of minutes, perpetuating the cycle of DNA denaturing and synthesis. <br />
This process, generates exponential exact copy of the original template DNA sequence. <br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
!PCR cycles<br />
<br />
|{|<br />
|-bgcolor="lightpink"<br />
| '''PCR Cycle'''<br />
| '''Target Copies'''<br />
|-<br />
| 1<br />
| 2<br />
|-bgcolor="pink"<br />
| 2<br />
| 4<br />
|-<br />
| 3<br />
| 8<br />
|-bgcolor="pink"<br />
| 4<br />
| 16<br />
|-"<br />
| 5 <br />
| 32<br />
|-bgcolor="pink"<br />
| 6 <br />
| 64<br />
|-<br />
| 7 <br />
| 128<br />
|-bgcolor="pink"<br />
| 8<br />
| 256<br />
|- <br />
| 9<br />
| 512 <br />
|-bgcolor="pink"<br />
| 10<br />
| 1024<br />
|-<br />
| 15<br />
| 32,768<br />
|-bgcolor="pink"<br />
| 20 <br />
| 1,048,578<br />
|-<br />
| 25<br />
| 33,554,432<br />
|-bgcolor="pink"<br />
| 30 <br />
| 1,073,741,842<br />
|-<br />
|}<br />
<br />
<br />
<br />
<br />
{|border="1" align="center"<br />
|-bgcolor="pink" <br />
| '''Advantages''' <br />
|'''Disadvantages'''<br />
|- <br />
| fast and inexpensive way of copying a target sequence of DNA<br />
| only during this exponential DNA replication phase can we determine the starting quantity sequence contained in the original sample ( template DNA strand)<br />
|-bgcolor="pink"<br />
| aids the diagnosis of single cell defects<br />
| PCR reaction is limited by the presence of inhibitors present in the sample : reagent inhibitors <br />
|-<br />
| rapid generation of results within a couple hours<br />
| self annealing due to the accumulation of the product -stopping exponential amplification for the target sequence and reach a plateau<br />
quantification of the end point of reaction of PCR products unreliable - therefore that is why we require real time quantitative RT-PCR necessary<br />
<ref> NIS (2015) Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref><br />
|-bgcolor="pink"<br />
| can start from a single molecule of DNA, therefore is more sensitive <br />
| <br />
|-<br />
| has a flexible primer design enabling<br />
| <br />
|-bgcolor="pink"<br />
| overcame previous issues associated with the limited availability of sites of end<br />
| <br />
|-<br />
| generates the DNA copies exponentially<br />
| <br />
|-bgcolor="pink"<br />
| enables DNA amplification required for molecular and genetic analysis<br />
| <br />
|-<br />
|Valid diagnostic method in selecting unaffected embryos for embryo transfer <ref> Dreesen, J., Drusedaul, M., Smeets, H., Die-Smulders, C., Coonen, E., Dumoulin, J., Gielen, M., Evers, J., Herbergers, J. & Geradets, J. (2008) Validation of preimplantation genetic diagnosis by PCR analysis: genotype comparison of the blastomere and corresponding embryo, implications for clinical practice. Mol. Hum. Reprod. 14 (10):573-579.doi: 10.1093/molehr/gan052. Retrieved from [http://molehr.oxfordjournals.org/content/14/10/573.short] </ref> <ref><pubmed>20966460</pubmed></ref><br />
|<br />
|}<br />
<br />
<br />
<br />
<br />
<br />
<br />
<br />
<br />
<br />
===Fluorescent In Situ Hybridisation (FISH)===<br />
<br />
<br />
====Description====<br />
Fluorescence in situ hybridization (FISH) the one of the most effective and rapid <ref name="PMID26338801"><pubmed>26338801</pubmed></ref> Preimplantation Genetic Diagnosis (PGD). This techniques used to locate a specific DNA sequences within a chromosome. FISH facilitates the clinical diagnosis of chromosomal abnormalities indicated by sequential duplications, deletions and rearrangements of chromosome, that are usually missed with microscopic analysis. This technique is especially relevant for female embryos with X-linked diseases,<ref><pubmed>20809319</pubmed></ref> that have no other mutation specific tests [http://www.ncbi.nlm.nih.gov/pubmed/20809319] As part of PGD, samples are collected from various stages of the embyro,and they are able to conducted tests on the blastocyst, a polar body biopsy and the blastomeres <ref><pubmed>21748341</pubmed></ref>. FISH is 99% effective when used in conjunction with competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities<ref name="PMID26338801"/>.<br />
<br />
====Procedure==== <br />
<br />
Samples are collected from either the blastocyst, a polar body biopsy or the blastomeres stages of the embryo <ref><pubmed>21748341</pubmed></ref>. <br />
DNA strands are heated and denatured causing their the individual DNA strands to break apart<br />
Probes are single complimentary stands of DNA a that have been tagged with small chemical agents that glow brightly in the presence of a specific region on a chromosome. These specific probes then hybridize and join to their complementary DNA strand. <br />
The fluorescent tags enable the researchers to correctly identify the presence or lack thereof and location of the specific chromosomes that they are testing for. <ref><pubmed>17876073</pubmed></ref><br />
Researcher analyse the results by identifying the number and the relative location of the fluorescent dots generated by the FISH images.<ref><pubmed>17970921</pubmed></ref><br />
The probe will not fully hybridise if there has been a duplication or a deletion of the DNA - indicating chromosomal and sex chromosomal anomalies like trisomies and aneuploidies. <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref><br />
<br />
<br />
Different probes are used for different purposes: <ref>Unique, Rare Chromosome Disorder Support Group (2013) Fluorescence in situ hybridisation (FISH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/Other/FISH%20FTNW.pdf]</ref><br />
*'''Locus specific tags''' detect very small imbalances, and locate isolated small portions <br />
of genes within a chromosome<br />
*'''Alphoid/Centomeric Repeat probes''' are developed from the repetitive sequence located in the middle region of each chromosome, useful in determining the number of chromosomes , detecting rearrangement and when used in conjunction with locus probes to determine the absence of genetic material on a chromosome. <br />
*'''Paint Probes''' are collections of smaller probes with their own stains that bind to a different section on the chromosome - allowing the full chromosome too be labeled a unique colour, this "full colour map" can be used to know the spectral karyotype- full chromosomal mapping is useful in examining chromosomal abnormalities. <br />
<br />
{|border="1" <br />
| [[File:Fluorescent In Situ Hybridisation (FISH).jpg|thumb|right|'''FISH''' We are able to tag Specific DNA sequences using Probes which have been tagged with fluorescent Labels.This technique enables the clinical diagnosis of chromosomal abnormalities, indicated by sequential duplication, deletions and rearrangements of chromosome <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref>]]<br />
|}<br />
<br />
<br />
<br />
{|border="1" align="center"<br />
|-bgcolor="pink" <br />
| rowspan="7" |'''Advantages''' <br />
| FISH is 99% effective when used in conjunction with Competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities.<ref><pubmed>26338801</pubmed></ref><br />
|-bgcolor="#FBC7E7" <br />
| Rapid generation of results<br />
|-bgcolor="#FBC7E7" <br />
| Identifies very small translocations and aneuploidies that occur within chromosomes, that would usually be missed under microscopic analysis<br />
|-bgcolor="#FBC7E7" <br />
| Indicates whether the accessed chromosomes are normal <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|-bgcolor="#FBC7E7" <br />
| Tests for the most common chromosomal abnormalities - down syndrome chromosomes 13,16,18,21 and 22 <ref><pubmed>21749752</pubmed></ref><br />
|-bgcolor="#FBC7E7" <br />
| It may be used to compare the chromosomal gene arrangements in related species<br />
|-bgcolor="#FBC7E7" <br />
| can be used to identify and remove inheritable X-linked disease or sex chromasome anomalies such as Duchennes Muscular Dystrophy, hemophilia, ectodermal dysplasia <ref><pubmed>17876073</pubmed></ref><br />
|-bgcolor="pink"<br />
| rowspan="4"|'''Disadvantages'''<br />
| FISH destroys all cells tested <ref> O'Connor, C. (2008) Fluorescence in situ hybridization (FISH). Nature Education 1(1):171. retrieved from [http://www.nature.com/scitable/topicpage/fluorescence-in-situ-hybridization-fish-327] </ref><br />
|-bgcolor="#FBC7E7"<br />
| It does not fully access all chromosomes (only ~ 12)<br />
|-bgcolor="#FBC7E7"<br />
| Analysis of results is dependent upon the dot quality impacted by hybridisation efficiency or the camera sensitivity <ref><pubmed>17970921</pubmed></ref><br />
|-bgcolor="#FBC7E7"<br />
| some studies indicate that using FISH on a day-3 embryo biopsy decreases the rate of live births <ref><pubmed>26168107</pubmed></ref><br />
|}<br />
<br />
<br />
<br />
===Array Comparative Genomic Hybridisation (aCGH)===<br />
====Description====<br />
<br />
aCGH also known as Microarray analysis efficiently scans the entire genome for chromosomal imbalances. CGH was initially developed to detect the number of changes in a solid tumor mass. It uses 2 genomes comparing the sample to the control, with each labeled in a different fluorescent dye<ref><pubmed>1876176</pubmed></ref>. Earlier CGH techniques were limited by the resolution of the imaging <ref> Lichter, P., et al. Comparative genomic hybridization: Uses and limitations. Seminars in Hematology 37, 348–357 (2000)</ref> , these initial limitations were overcome by using Microarrays in conjunction with CGh to improve the resolution of the imaging, Array Comparative Genomic Hybridisation (aCGH). This method compares sample and control microarrayed slides containing small segments of DNA (probes). <ref> Lucito, R., et al. Representational oligonucleotide microarray analysis: A high-resolution method to detect genome copy number variation. Genome Research 13, 2291–2305 (2003) </ref> the Probes used will vary according from the small (25-85 base pairs) oligonucleotides manufactured to highlight different target sequences, to the very large genomic clones (80,000- 200,00 base pairs), and as these are significantly smaller than the traditional metaphase chromosomes used for CGH, generating a higher resolution of image. <ref><pubmed>22467166</pubmed></ref>.aCGH is used as a diagnostic tool for prenatal detection f chromosomal abnormalities <ref><pubmed>19012303</pubmed></ref>.<br />
<br />
<br />
====Procedure====<br />
<ref> Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432] </ref><br />
The sample is obtained (skin, blood or fetal cells) and DNA is obtained. <br />
As a part of PGD fetal cell samples are collected from; the fertilized egg polar bodies, the blastomere (day 3 embryo) or the blastocyst/tropoectoderm stage (day 5 embryo).<br />
Sample DNA is labeled with one fluorescent dye, and the control DNA is labeled with a different colored fluorescent dye. the control DNA is used as the base point of reference. <br />
heated and denatured single DNA strands then hybridize to their complementary single strand probes, which are then combined and applied to a microarray and the results are run through a computer program and a digital imaging system is used to quantify the results( fluorescent intensities of the labeled probes). <br />
<br />
simple explanation of aCGH : [Genomics Education (2014) Genetic Testing for Health: aCGH|https://vimeo.com/84757281]<br />
<ref>Genomics Education (2014) Genetic Testing for Health: aCGH [video file] Vimeo [https://vimeo.com/84757281]</ref><br />
<br />
<br />
The fluorescent ratio and the hybridization signal at different locations on the genome of the control DNA are used to identify any variances present in the sample DNA. aCGH facilitates the clinical diagnosis of submicroscopic chromosomal duplication, deletion and rearrangements indicative of chromosomal disorders such as trisomies 1-22and specific sex linked disorders. <br />
Duplications in the DNA are displayed by the computer program as spikes/ peaks over an established threshold and deletions in DNA are displayed by the computer program as spikes/ toughs beneath this threshold <br />
-computer screening image- <br />
-drawn diagram of method-<br />
<br />
<br />
<br />
{|border="1" align="center"<br />
|-bgcolor="pink" <br />
| '''Advantages''' <br />
| '''Disadvantages'''<br />
|-<br />
| multiple applications: prenatal genetic diagnosis, cancer diagnosis, <ref><pubmed>20193845</pubmed></ref> genetic screening for developmental delay (learning disabilities) <ref><pubmed>17309648</pubmed></ref>. or congenital anomalies that are suspected to be genetic in origin <ref>NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation . retrieved from [http://www.phgfoundation.org/file/5237/]</ref><br />
| translocations and inversions of DNA are not detected<br />
|-bgcolor="pink"<br />
| trace represents all chromosomes present in the human genome chromosomes 1-22 and the X & Y chromosomes, and therefore is the most accurate method for testing whole embryo aneuploidy<br />
| limited ability diagnosing specific polyploidies such as triploidy <ref> Unique, Rare Chromosome Disorder Support Group (2013) Microarray-based Comparative Genomic Hybridiation (array CGH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/other/array%20cgh%20ftnw.pdf] </ref><br />
|-<br />
| aCGH has been extensively tested, and Validated, and is now used world wide.<br />
| will not detect mosaicism detection <20% (cultures where >1 of 5 cells are trisomy 12)<br />
|-bgcolor="pink"<br />
| detects deletions and additions and rearrangements as well as amplification, of the WHOLE genome, simultaneously.<br />
| will not detect balanced chromosomal rearrangement<br />
|-<br />
| detects submicroscopic alterations<br />
| will not detect duplications or deletions <80kb<br />
|-bgcolor="pink"<br />
| used as a diagnostic tool for prenatal detection of chromosomal abnormalities <ref><pubmed>22034057</pubmed></ref><br />
| will not detect point mutations within genes <ref>Washington department of education (CGH- FAQ for physicians. Signature Genomic LAboratories, LLC. Retrieved from [https://depts.washington.edu/dbpeds/Lab%20Tests/SignatureCGH-physician_FAQ.pdf]</ref><br />
|-<br />
| provides high resolution genomewide screening of segmental genomic copy number variations<br />
| will not detect chromosomal position of genomic gains<br />
|-bgcolor="pink"<br />
| very accurate when used in conjunction with FISH<br />
| will not detect loos of heterozygosity (LOH) or Absence of heterozygosity (AOH) <ref>WiCell Research Institute Inc. (2012) Comparative Genomic Hybridization Microarray. <br />
retrieved from [http://www.wicell.org/home/cytogenetic-services/cgh-microarray/array-comparative-genomic-hybridization-acgh.cmsx]</ref><br />
|-style="background:pink"<br />
|Alone is more reliable and in detecting chromosomal abnormalities, with a higher implantation success rate, than FISH <ref><pubmed>20494259</pubmed></ref><br />
|<br />
|-bgcolor="pink"<br />
|Allows an in depth research focus upon specific types of rearrangements within selected chromosomal regions, a recent particular area of interest is subtelomeric and pericentromeric rearrangements<br />
|<br />
|-<br />
|reduces the risk of failed implantation and miscarriage, improving the chance of a healthy baby <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|<br />
|}<br />
<br />
<br />
<br />
===Next Generation Sequencing===<br />
====Description====<br />
The development and advances within ART in the past 20 years, as well as the increasing popularity of IV, has lead to an influx of new technologies developed to screen embryos for chromosomal anomalies, which are covered by the umbrella term of Next generation Sequencing (NGS). NGS is a general term used to describe all of the new and emerging screening techniques currently being introduced and used as part of PGD for IVF . NGS screens for single gene disorders as well as conducting extensive and very comprehensive chromosome diagnosis by sequencing, counting, and accurately assembling millions of DNA reads, simultaneously. <ref><pubmed>23499002</pubmed></ref> There is a movementfor NGS to replace the other limited testing techniques and be used as the standard. <br />
====Procedure====<br />
Samples are collected from either blastomere or the blastocyst/tropoectoderm and processed for analysis by a computer system. <br />
The methodology of each process is unique to the technique being used. <br />
<br />
<br />
<br />
{|border="1" align="center"<br />
|-bgcolor="pink" <br />
| '''Advantages'''<br />
| '''Disadvantages'''<br />
|-bgcolor="white"<br />
| cheaper<br />
| there are limited information available to clinical applications of NGS <ref><pubmed>26100406</pubmed></ref><br />
|-bgcolor="pink"<br />
| opens new diagnostic possibilities<br />
|<br />
|-bgcolor="white"<br />
| accurately tests all 24 chromosomes<br />
| <br />
|-bgcolor="pink"<br />
| tests for the presence of monogenic diseases of known genetic background<br />
| <br />
|-bgcolor="white"<br />
| reduces the number of biopsies required for diagnosis<br />
| <br />
|-bgcolor="pink"<br />
| higher detection rate of small translocations<br />
| <br />
|-bgcolor="white"<br />
| highly accurate is testing for compound point mutations, chromosomal duplication, deletions and insertions <ref><pubmed>23312231</pubmed></ref><br />
| <br />
|-bgcolor="pink"<br />
| it accurately detects chromosomal aneuploidy and unbalanced rearrangement <ref><pubmed>25685330</pubmed></ref><br />
| <br />
|-bgcolor="white"<br />
| NGS single gene disorder screenings can conducted in conjunction with PCR comprehensive chromosomal screening<br />
|<br />
|-bgcolor="pink"<br />
| Reduces human error <br />
|<br />
|-bgcolor="white"<br />
| better detects the presence of mosaicism<br />
|<br />
|-bgcolor="pink"<br />
| work well in conjunction with CGH and aCGH as part of PGD, improving the chances of IVF. <ref> Morris, R. S. (2015 ) Next generation sequencing for PCG|PGS|CCS. IVF1 retrieved from [http://www.ivf1.com/next-generation-sequencing for-pgd] </ref><br />
|<br />
|}<br />
<br />
<br />
<br />
<br />
<br />
<br />
==Diagnosis==<br />
There are a large amount of diseases that PGD can apply to, below are descriptions of the diseases that PGD are more commonly used for. <br />
===Cystic Fibrosis===<br />
Cystic fibrosis is a single gene disorder. It is autosomal recessive and involves mutations in the cystic fibrosis transmembrane conductance regulator (CTFR) gene. The CTFR gene is normally responsible for the decrease in chloride and the transport of bicarbonate in epithelial cells thus playing a major physiological role. In PGD procedures, identification of the gene is assisted by microsatellite markers that have similar composition to the CTFR gene itself. Biopsy of two cells at the blastocyst stage is recommended if markers are not available. There are many variations of cystic fibrosis the most common being P.Phe508del <ref name="PMID26014425"><pubmed>26014425</pubmed></ref>.<br />
===Duchenne Muscular Dystrophy ===<br />
Duchenne Muscular Dystrophy is an X-linked recessive disease. It involves the Xp21 gene where majority of the mutations are chromosomal deletions with a smaller percentage resulting from duplications <ref name="PMID18359022"><pubmed>18359022</pubmed></ref>.<br />
===β – Thalassemia=== <br />
β – Thalassemia is known as the most common type of autosomal recessive inherited disorder among haemoglobinopathies. It involves the adult β-globin gene and is associated with the absent or decreased expression of the gene. This is commonly caused by a single nucleotide change in the gene. PGD has been used successfully worldwide to identify the β-globin gene where its application is usually performed on a single blastomere or polar body <ref name="PMID19064120">19064120</pubmed></ref>.<br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
! Applicable diseases for PGD <ref>Genoma Group (2014). Retrieved September 18th, 2015, from http://www.preimplantationgeneticdiagnosis.it/genetic-diseases-diagnosed-by-pgd.htm </ref>, <ref>Genesis Genetics (2015). Retrieved September 18th, 2015, from http://genesisgenetics.org/pgd/what-we-test-for/</ref>, <ref>Human Fertilisation & Embryology Authority (2015). Retrieved Septembr 18th, 2015, from http://guide.hfea.gov.uk/pgd/</ref><br />
|-<br />
| '''Disease'''<br />
| '''Involved Genes'''<br />
|-<br />
| 5 Alpha Reductase Deficiency (5ARD)<br />
| SRD5A2 <br />
|-<br />
| Achondroplasia<br />
|FGFR3 <br />
|-<br />
| Acute Intermittent Porphyria <br />
| ALAD, ALAS2, CPOX, FECH, HMBS, PPOX, UROD, or UROS<br />
|-<br />
| Adrenoleukodystrophy (Adrenomyeloneuropathy)<br />
| ABCD1 <br />
|-<br />
| Agammaglobulinaemia (x-linked) <br />
|BTK <br />
|-<br />
| Agammaglobulinemia Bruton Tyrosine Kinase (BTK) <br />
|BTK <br />
|-<br />
| Aicardi Goutieres Syndrome 1 (AGS1) <br />
|TREX1, RNASEH2A, RNASEH2B, RNASEH2C, SAMHD1<br />
|-<br />
| Alagille Syndrome<br />
|JAG1 or NOTCH2<br />
|- <br />
| Alpers-Huttenlocher Syndrome <br />
|POLG <br />
|-<br />
| Alpha-1-antitrypsin deficiency <br />
|SERPINA1 <br />
|-<br />
| Alpha-Mannosidosis<br />
| MAN2B1 <br />
|-<br />
| Alpha Thalassemia <br />
|HBA1 or HBA2 <br />
|-<br />
| Alports Syndrome<br />
|COL4A3, COL4A4, COL4A5<br />
|-<br />
| Alzheimer's Disease - early onset (Type 3 and 4) <br />
|APP, PSEN1, or PSEN2<br />
|-<br />
| Amyotrophic Lateral Sclerosis 1 (ALS1) <br />
|C9orf72, SOD1, TARDBP, FUS, ANG, ALS2, SETX, VAPB <br />
|-<br />
| Argininosuccinic Aciduria <br />
| ASL<br />
|-<br />
| Arrhythmogenic Right Ventricular Cardiomyopathy/ Dysplasia (ARVC/D)<br />
| DSG2; DSP; PKP2<br />
|-<br />
| Ataxia Telangiectasia<br />
| ATM<br />
|-<br />
| Bardet-Biedl Syndrome (BBS)<br />
| BBS1; BBS10<br />
|-<br />
| Barth Syndrome<br />
| TAZ<br />
|-<br />
| Beta Thalassaemia<br />
| HBB<br />
|-<br />
| Birt-Hogg-Dubé Syndrome<br />
| FLCN<br />
|-<br />
| Breast Ovarian Cancer Familial Susceptibility (BRCA2)<br />
| BRCA1; BRCA2<br />
|-<br />
| Canavan Disease <br />
| ASPA<br />
|-<br />
| Carnitine-Acylcarnitine Translocase Deficiency <br />
| SLC25A20<br />
|-<br />
| Cerebral Arteriopathy with Subcortical Infarcts & Leukoencephalopathy (CADASIL)<br />
| NOTCH3<br />
|-<br />
| Cerebral Cavernous Malformation<br />
| CCM1<br />
|-<br />
| Charcot-Marie-Tooth Disease<br />
| GJB1; MPZ; NEFL; PMP22<br />
|-<br />
| CHARGE Syndrome<br />
| CHD7<br />
|-<br />
| Cherubism<br />
| SH3BP2<br />
|-<br />
| Choroideremia<br />
| CHM<br />
|-<br />
| Chronic Granulomatous Disease<br />
| CYBB; NCF1<br />
|-<br />
| Ciliary Dyskinesia<br />
| DNAH5<br />
|-<br />
| Citrullinemia<br />
| ASS1<br />
|-<br />
| Cleidocranial Dysplasia<br />
| RUNX2<br />
|-<br />
| Cockayne Syndrome<br />
| ERCC6<br />
|-<br />
| Congenital Adrenal Hyperplasia<br />
| CYP21A2<br />
|-<br />
| Congenital Cataracts<br />
| GJA8; VSX2<br />
|-<br />
| Congenital Diarrhea, Syndromic<br />
| SPINT2<br />
|-<br />
| Congenital Disorders of Glycosylation (CDG)<br />
| ALG1; ALG6; CDG1C; DOLK; PMM2<br />
|-<br />
| Cornelia de Lange Syndrome <br />
| NIPBL<br />
|-<br />
| Craniosynostosis<br />
| TWIST1<br />
|-<br />
| Crouzon Syndrome<br />
| FGFR2<br />
|-<br />
| Cysteinyl Leukotriene Receptor 1 Deficiency <br />
| CYSLTR1<br />
|-<br />
| Cystic Fibrosis<br />
| CFTR<br />
|-<br />
| Diamond –Blackfan Anemia <br />
| RPS19<br />
|-<br />
| Duchenne Muscular Dystrophy <br />
| DMD<br />
|-<br />
| Dyskeratosis congenita (Male embryos only)<br />
| DKC1<br />
|-<br />
| Ectodermal dysplasia (Hypohidrotic)<br />
| EDA; EDA1; GJB6; IKBKG<br />
|-<br />
| Familial Adenomatous polyposis coli (FAP)<br />
| APC<br />
|-<br />
| Familial Dysautonomia<br />
| IKBKAP<br />
|-<br />
| Fanconi Anemia <br />
| FANCA; FANCC; FANCD2; FANCF; FANCG; FANCJ<br />
|-<br />
| Fragile X Syndrome (FRAX)<br />
| FMR1<br />
|-<br />
| Galactosemia <br />
| GALT<br />
|-<br />
| Gangliosidosis<br />
| GLB1<br />
|-<br />
| Glanzmann Thrombasthenia <br />
| ITGA2B<br />
|-<br />
| Glutaric Acidemia (aciduria)<br />
| GCDH <br />
|-<br />
| Glycogen Storage Disease <br />
| G6PC; GAA; SLC37A4<br />
|-<br />
| Haemophilia A<br />
| F8<br />
|-<br />
| Haemophilia B<br />
| F9<br />
|-<br />
| Hereditary Nonpolyposis Colorectal Cancer: Lynch Syndrome<br />
| MLH1; MSH2; MSH6<br />
|-<br />
| Holt Oram Syndrome<br />
| TBX5<br />
|-<br />
| Huntington Disease<br />
| HD<br />
|-<br />
| Hydrocephalus<br />
| L1CAM<br />
|-<br />
| Ichthyosis <br />
| ABCA12; STS<br />
|-<br />
| Incontinentia Pigmenti (IP)<br />
| NEMO<br />
|-<br />
| Joubert Syndrome 5<br />
| INPP5E<br />
|-<br />
| Krabbe Disease<br />
| GALC<br />
|-<br />
| Leber Congenital Amaurosis (LCA)<br />
| CEP290; GUCY2D<br />
|-<br />
| Leigh Syndrome (Infantile Subacute Necrotising Encephalopathy)<br />
| LRPPRC<br />
|-<br />
| Lesch Nyan Syndrome<br />
| HPRT1<br />
|-<br />
| Leukocyte Adhesion Deficiency (Type I)<br />
| ITGB2<br />
|-<br />
| Li-Fraumeni Syndrome<br />
| TP53<br />
|-<br />
| Macular Dystrophy Retinal <br />
| VMD2<br />
|-<br />
| Maple Syrup Urine Disorder (MSUD)<br />
| BCKDHB<br />
|-<br />
| Marfan Syndrome <br />
| FBN1<br />
|-<br />
| Menkes Syndrome<br />
| ATP7A<br />
|-<br />
| Mitochondrial DNA Depletion Syndrom <br />
| POLG; RRM2B; SUCLA2; TK2<br />
|-<br />
| Mucolipidosis type II<br />
| GNPTAB<br />
|-<br />
| Multiple Endocrine Neoplasia<br />
| MEN1; MEN2A; MEN2B<br />
|-<br />
| Multiple Exostoses<br />
| EXT1; EXT2 <br />
|-<br />
| Myotubular myopathy<br />
| MTM1 <br />
|-<br />
| Nail-Patella Syndrome<br />
| LMX1B<br />
|-<br />
| Neurofibromatosis Type 1<br />
| NF1<br />
|-<br />
| Neurofibromatosis Type 2 <br />
| NF2<br />
|-<br />
| Noonan Syndrome<br />
| KRAS, PTPN11; SOS1<br />
|-<br />
| Norrie Disease<br />
| NDP<br />
|-<br />
| Ocular Albinism <br />
| GPR143<br />
|-<br />
| Oculocutaneous Albinism <br />
| OCA2; TYR <br />
|-<br />
| Oculodentaldigital Dysplasia<br />
| GJA1<br />
|-<br />
| Optic Atrophy<br />
| OPA1<br />
|-<br />
| Ornithine Transcarbamylase Deficiency <br />
| OTC<br />
|-<br />
| Osteogenesis imperfeca <br />
| COL1A1; COL1A2<br />
|-<br />
| Osteopetrosis <br />
| CLCN7; OSTM1; TCIRG1<br />
|-<br />
| Pachyonychia Congenita <br />
| KRT16; KRT6A<br />
|-<br />
| Pancreatitis, Hereditary<br />
| PRSS1 <br />
|-<br />
| Papillorenal syndrome <br />
| PAX2<br />
|-<br />
| Phenylketonuria <br />
| PAH <br />
|-<br />
| This table does not cover the complete list of diseases that PGD can be applied to.<br />
|}<br />
<br />
==Laws & Legal status==<br />
===Australia=== <br />
PGD is currently used to detect serious genetic conditions to improve the outcome of Assisted Reproductive Technologies (ART). In very rare cases it may be used to select an embryo with compatible tissue for a sibling who has a life-threatening disease where other means of treatment is unavailable. This is with the conditions that the use of PGD will not affect the welfare and interests of the child to be born. The parents must also receive adequate counselling and have full understanding of the procedures of PGD. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"> National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art</ref><br />
The use of PGD for sex-selection is prohibited with the exception of reducing the risk of the transmission of serious sex-linked genetic conditions. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"/><br />
===Brazil=== <br />
The laws regarding PGD in Brazil are not strictly regulated. They are vague and there is limited information surround the activities of assisted reproduction in general in the country <ref name="PMID25493379"><pubmed>25493379</pubmed></ref>.<br />
===Czech Republic===<br />
The laws in the Czech Republic allow those with a “defined indication in order to exclude risk of serous genetically conditioned disease and defects with embryos before they are implanted into the cavity of the uterus”. Couples that undergo any assisted reproductive treatment including PGD have to be married. Sex-selection is illegal except in regards to serious sex-linked genetic diseases <ref name="PMID24777348"><pubmed>24777348</pubmed></ref>.<br />
===Greece=== <br />
In Greece, ART is open to those up to the age of 50 with written consent. It can only be used if a medical necessity is present such as the susceptibility of serious hereditary diseases. Sex selection is banned apart from cases of sex-linked diseases and sexually transmitted diseases <ref name="PMID24777348"/>.<br />
===Portugal=== <br />
ART is only available to those who are married or have a similar type of relationship for at least two years. The couples cannot be of the same sex and must be at least 18 years of age. Sex selection is illegal except in cases of sex-linked diseases. The use of PGD is illegal if the predictive value of genetic tests are very low <ref name="PMID24777348"/>.<br />
===Spain===<br />
PGD can be applied to “serious hereditary diseases not amenable to postnatal curative treatment” and “detection of other abnormalities which may compromise the viability of the pre-embryo”. If PGD is to be used for any other purpose authorisation must be acquired <ref name="PMID24777348"/>.<br />
===Sweden=== <br />
The use of PGD is strictly regulated and couples must achieve authorisation of the National Board of Health and Welfare. It can only be used it can only be used if the child is at risk to inheriting a serious chromosomal or monogenetic disease. It cannot be used for selection of specific characteristics <ref name="PMID24777348"/>.<br />
===United Kingdom===<br />
Those involved with carrying out the IVF treatment must have a license from the Human Fertilisation and Embryology Authority (HFEA). Only embryos that are approved by the HFEA can be implanted where the embryonic nuclear or mitochondrial DNA cannot be altered with the exception of preventing mitochondrial diseases <ref name="PMID24777348"/>. <br />
==Future/Current Research==<br />
===Noninvasive Preimplantation Genetic Testing without Embryo Biopsy===<br />
Different parameters of gametes, zygotes, embryos (“vacuoles in sperm heads, spindle position in mature oocytes, cleavage intervals of zygote, and embryo developmental dynamics”) may correlate with aneuploidy rates. This knowledge may be applied in potential noninvasive preimplantation diagnostic methods. Several methods have been proposed and are currently further researched<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Sperm Selection====<br />
Intracytoplasmic morphologically selected sperm injection (IMSI) is common procedure in IVF treatment to improve fertilization rates in patients with poor semen quality. In addition, studies have found that IMSI improves embryo development and that spermatozoa with large vacuoles in their heads correlate with increased aneuploidy rates and disturbed chromosomal structures. Thus, selecting spermatozoa based on morphological hallmarks may decrease aneuploidy rates in the fertilized embryos. As with polar body biopsies, however, this approach will solely be applicable if evidence for severe male detrimental contribution is given<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Blastocoel Fluid Extraction====<br />
In addition, a less invasive retrieval of material for diagnosis could include the extraction of the blastocoel fluid. The cavity of the blastocyst, lined by the trophectoderm, is filled with this blastocoel fluid, which contains metabolites of both trophectoderm and inner cell mass origin. The retrieval does not require a biopsy but merely a small opening to extract the fluid and, thus, causes less harm to the embryo. Multiple studies have applied this method<ref name="PMID22020776"><pubmed>22020776</pubmed></ref> <ref name="PMID23148560"><pubmed>23148560</pubmed></ref> and it may in the future become of clinical relevance.<br />
<br />
{|border="1"<br />
| [[File:Aspiration_of_the_Blastocoel_Fluid.jpeg]]<br />
|-<br />
| Aspiration of the Blastocoel Fluid using a ICSI pipette<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
|}<br />
<br />
<br />
Next to metabolites, the blastocoel fluid can contain DNA. Studies have shown that genomic DNA is present in about 90% of the blastocoel fluid samples tested. Typically the fluid is removed with an ICSI pipette from a day five blastocyst through its mural trophectoderm until the blastocyst fully collapses around the embryo. Several concerns regarding this method in a clinical setting have been raised. The collected DNA may be contaminated by the culture media that contains DNA fractions. The DNA may also be least representative of the actual embryos genome as the DNA may originate from abnormal or degenerated cells. Even though labelled noninvasive, the blastocyst still undergoes manipulation to some degree which may affect its viability. Thus, more research is required until this method can evolve from research to clinical use<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
====Proteomics====<br />
The protein secretome of blastocysts may be representative of its chromosome constitution Recent studies have found biomarkers such as lipocalin-1, interleukin-10, tumor necrosis factor, stem cell factor, and chemokine ligand 13 to be differently secreted by aneuploid blastocyst than by euploid ones. The most significant biomarker appears to be interleukin-10. Paired with novel proteomic technologies and mass spectrometry this knowledge when extended may contribute to a new invasive preimplantation genetic diagnosis method<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Embryo Morphology====<br />
Using time lapse imaging the embryo’s morphology can be closely observed and potential aneuploidy characteristics detected. Such characteristics may include the time of division to five cells, the time between the division from three to four cells, and the duration of the division from one to two and subsequently to three. In addition, the morphological quality of ICM an TE has been positively associated with aneuploidy or euploidy prognosis<ref name="PMID26246880"><pubmed>26246880</pubmed></ref>. These may give rise to an embryo quality screening prior to implantation<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
===Utilization of Diseased Cell Lines===<br />
==Ethics==<br />
==References==<br />
<br />
<references/><br />
<br />
<br />
{{StudentPage2015}}</div>Z5017878https://embryology.med.unsw.edu.au/embryology/index.php?title=2015_Group_Project_6&diff=2065552015 Group Project 62015-10-19T11:59:23Z<p>Z5017878: </p>
<hr />
<div>{{ANAT2341Project2015header}}<br />
<br />
<br />
=Prenatal Genetic Diagnosis=<br />
==Introduction==<br />
==History==<br />
Prenatal Genetic Diagnosis was historically conducted post-implantation in the first 2 trimesters <ref> Blackburn, S.L. (2003) '''Maternal, Fetal & Neonatal physiology: a Clinical perspective''' (2nd ed.). Seattle: Saudners </ref>, testing for overall fetal growth, complications of pregnancy, birth defects as well as chromosomal or genetic abnormalities<ref> Sadler T.W.(2012) '''Langman's Medical Embryology''' (12th ed.) Philadelphia: Lipincott, Wiliams & Wilkins, a Wolters Kluwer Business </ref>. Due to advancements in Artificial Reproductive Technologies ( ART) in the past 2 decades , these genetic tests are now conducted as a part of Preimplantation Genetic Diagnosis (PGD) <ref><pubmed>20638568</pubmed></ref> and art used to eliminate the rsik of passing on a genetic disorder to an offspring, before implantation, it ha now become a preventative measure. . In 1990 Preimplantation genetic testing was first used in 1990 on humans to diagnose recessive X-linked diseases in the embryos of pregnant women undergoing IVF. <ref><pubmed>2330030</pubmed></ref> PGD is offered as an alternative to prenatal diagnosis in detecting genetic disorders in high risk couples <ref><pubmed>26168107</pubmed></ref> and avoid passing an inherited disease to the offspring, by selecting genetically "normal" embryos for implantation ,to give the best chance of successful implantation , stable pregnancies and healthy children. <br />
<ref><pubmed>23499002</pubmed></ref><br />
<br />
==Preimplantation Genetic Diagnosis==<br />
[[File:Preimplantation Genetic Diagnosis Procedure.jpeg|700px|thumb|centre| Simplified steps for PGD]]<br />
<br />
<br />
Preimplantation genetic diagnosis (PGD) is used to test the genetic makeup of embryos to detect single gene disorders, chromosomal abnormalities and mitochondrial disorders. It also has applications in gender selection for diseases with unequal gender distributions <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Some diseases commonly involved with PGD include cystic fibrosis, spinal muscular atrophy and beta – thalassaemia <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press.">Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press</ref> <ref name="PMID17823145"><pubmed>17823145</pubmed></ref>. It was first used in the United Kingdom in the 1980s of arenoleucodystrophy and primarily focusing on sex- linked disorders <ref name="PMID17823145"/><ref name="PMID23150080"><pubmed>23150080</pubmed></ref>. PGD is now capable of detecting single cell defects (molecular) and chromosomal disorders resulting from the inversion, translocation or deletion of chromosomes (cytogenic) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>,<ref name="PMID11325751"><pubmed>11325751</pubmed></ref>. PGD can be applied to the embryo at different stages. That is on polar bodies, blastomeres or blastocyst <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>.<br />
Depending on the type of genetic disorder, PGD utilises different methods of genetic testing. These include Fluorescence in situ hybridisation (FISH) which is used for sex – linked disorders and detects chromosomal rearrangements <ref name="PMID11325751"/><ref name="PMID17876073"><pubmed>17876073</pubmed></ref> and Embryo halotyping which allows the identification of chromosomes causing the inherited disorder through knowledge of the pattern of closely linked markers <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. Polymerase chain reaction (PCR) is also widely used to detect molecular abnormalities <ref name="PMID11325751"/>.<br />
PGD is tightly regulated and supported by large organisations namely The American Society for Reproductive Medicine, The European Society for Human Reproduction and Embryology (ESHRE), The European Society of Human Genetics and the Preimplantation Genetic Diagnosis International Society <ref name="PMID25500181><pubmed>25500181</pubmed></ref>.<br />
===Sex-linked disorders===<br />
The determination of a disease as gender specific usually correlates with the presence or absence of specific genes such as SRY on the Y chromosome. It is known that females have two X chromosomes and males have an X and a Y chromosome where abnormalities are more prevalent on the X chromosome. PGD can be used for sex selection where only male embryos are transferred to reduce the chance of inheriting X-linked disorders. However, this does not completely eradicate the problem as male embryos remain susceptible to inheriting an affected X chromosome. Sex determination is only used when the specific mutation is unknown and has yet to be discovered <ref name="PMID24866878"><pubmed>24866878</pubmed></ref>.<br />
===Single gene defects===<br />
Single gene defects can be dominant, recessive, autosomal or X-linked. They are commonly diagnosed using PCR and although the PCR available today is complex and capable of combatting a large range of disease the development of new protocols has been proven to be difficult due to the small DNA sample available <ref name="PMID26168107"><pubmed>26168107</pubmed></ref><br />
===Mitochondrial disorders===<br />
Mitochondrial disorders also known as oxidative phosphorylation disorders arise from mutations in the nuclear DNA or mitochondrial DNA <ref name="PMID26312584"><pubmed>26312584</pubmed></ref>. They pose as a problem because they are unrecognisable until the mutations in the cell reach a detrimental level <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Mitochondrial disorders cause miscarriages and stillbirths as well as death in children and young adults. The effects can either be contained in a single organ or more commonly involve multiple organ failure where organs with high energy demands such as the brain, liver muscle and heart and heavily influenced. They are usually occur spontaneously or result from inheritance from the mother. Since mitochondria are solely inherited from the mother oocyte donations have been used as a solution to combat mitochondrial disorders. Additionally, there has been an increasing use in PGD where embryos that stay under the given threshold of 18% gene-mutations are allowed to be transferred and result in normal development. New technology in the areas of nuclear gene transfer and genome editing are also being experimented with <ref name="PMID26312584"/>. <br />
===Chromosomal disorders===<br />
Chromosomal disorders can be reciprocal, Robertsonian translocations, inversions, deletions and insertions <ref name="PMID26168107"/>. . Data from ESHRE collected between 2010 and 2011 has shown that the most common chromosomal abnormality confronted in PGD are reciprocal chromosomal abnormalities <ref name"PMID26071418"><pubmed>26071418</pubmed></ref>. PGD has also been used successfully for Robertsonian translocations (RT), a type of structural translocation. Children who carry RT are phenotypically normal, however in their later years it is found that they will suffer from infertility and repeated miscarriages due to the high frequency of abnormal embryos <ref name="PMID22081077"><pubmed>22081077</pubmed></ref>. PCR and FISH are the two main techniques used for chromosomal disorders. To be able to conduct the examinations the cells are required to be at the metaphase stage <ref name="PMID26168107"/>. <br />
==Preimplantation Genetic Screening==<br />
Prenatal Genetic Screening (PGS) involves an array of methods or ideas that aim to segregate embryos that have genetic flaws and those that are healthy <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. The occurrence of aneuploidy is high around the stages of early embryonic development and they are the most common cause if miscarriages and congenital birth defects <ref name= "PMID26085841"><pubmed>26085841</pubmed></ref>. They have little effect on the morphology of the embryo making them difficult to identify thus identification heavily relies on genetic testing <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. <br />
Genetic sampling is most commonly conducted using Microarray Comparative Genomic Hybridisation (aCGH) as well as FISH, Quantitative PCR and Single Nucleotide Polymorphism (SNP) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. These methods collectively aim to assess numeral and structural chromosomal errors <ref name= "PMID26085841"/>. Studies have also introduced Next- Generation Sequencing (NGS) <ref name= "PMID26085841"/> and Whole Genome Amplification used to screen imbalances in the complete 24-chromosomes <ref name="PMID25953353"><pubmed>25953353</pubmed></ref><br />
Statistics from ESHRE have shown that the most common indications for PGS is advanced age, followed by repeated implantation failure or recurrent miscarriage and male infertility <ref name="PMID26071418"><pubmed>26071418</pubmed></ref>.<br />
====Indications====<br />
A low percentage of structural abnormalities in chromosomes are responsible for the cause of miscarriages. Despite this, they are the most prevalent type of chromosomal abnormality accounted for in PGD <ref name="PMID20638568"/>. The presence of specific gene cycles, initiation of embryonic protein synthesis and evident physiological development are all indicative of a successful in vitro fertilisation procedure <ref name="PMID11576737"><pubmed>11576737</pubmed></ref>. To eliminate further errors from occurring during the PGD procedure it is recommended to undertake further prenatal testing such as amniocentesis in the later stages <ref name="PMID20638568"/>. <br />
=====Advanced maternal age=====<br />
Data provided by the ESHRE has shown that the mean age of women undergoing PGS is 39 years <ref name="PMID26071418"/>. Women of advanced age have been shown to have a lower rate of pregnancies reaching childbirth <ref name="PMID18583331"><pubmed>18583331</pubmed></ref>. The highlighted concern revolves around the increased occurrence of aneuploidy following maternal age. The optimal age range for the lowest aneuploidy incidence was found to be between 27 to 37 years of age (6%) then progressively higher in women aged up to 42 (33%) and most common in those 44 and above (53%) <ref name="PMID24355045"><pubmed>24355045</pubmed></ref>. <br />
=====Recurrent pregnancy loss / IVF failure=====<br />
Recurrent pregnancy loss is defined as three or more IVF failures after cumulative transfer of more than 10 good-quality embryos. These are primarily caused by two main factors, reduced endometrium receptivity or embryonic defects. Endometrium receptivity can be negatively influences by instances including uterine pathologies such as thin endometrium, altered expression of adhesive molecules and immunological factors. Additionally, embryonic defects may be due to genetic abnormalities, embryonic aneuploidy or zona hardening. Endometriosis and hydrosalpinx has been known to effect both the endometrium and embryo <ref name="PMID23260857"><pubmed>23260857</pubmed></ref>.<br />
=====Human leukocyte antigen matching=====<br />
First used in 2001, HLA matching is an option given to parents to save a child with haematological or immunological disease through conceiving another child who would potentially be able to donate cord blood or haematopoietic stem cells from the bone marrow for transplantation. The process namely PGD-HLA has shown to improve haematopoietic stem cell transplant (HSCT). PGD-HLA can only be performed when HSCT is not needed urgently due to the time needed to conceive and delivery the baby <ref name="PMID25500181"><pubmed>25500181</pubmed></ref>. It is most commonly applied to children suffering from relapsed leukaemia <ref name="PMID22524201"><pubmed>22524201</pubmed></ref>. In a case study PGD-HLA was proven to successfully cure 10 diseases including Fanconi anaemia, Diamond-Blackfan anaemia and beta thalassemia <ref name="PMID25066893><pubmed>25066893</pubmed></ref>.<br />
==Biopsy Methods==<br />
Biopsy, the removal of genetic materials, from oocytes or embryos in the preimplantation stage is the primary step in PGD. For the past two decades these biopsies have been performed at three stages, the polar body, blastomere, and blastocyst, and the methodologies optimized to ensure the embryo’s viability. The most common approach involves biopsies at the cleavage stage. However, polar body and blastocyst biopsies are increasingly more often tested and applied. Approached for opening the zona pellucida involve next to the traditional mechanical and chemical means, novel approaches such as noncontact lasers. Their application may simplify and secure the procedure significantly. The most challenging question about PGD procedures remains at what stage biopsies should be taken. Much controversy has developed around this topic, highlighting the varying disadvantages and advantages of temporal biopsies. <ref name="PMID22723007"><pubmed>22723007</pubmed></ref><br />
<br />
{|border="1" align="left"<br />
|-bgcolor="pink" <br />
|<br />
| Time of Biopsy<br />
| Advantages <br />
| Disadvantages<br />
|- <br />
| Polar Body<br />
| Day 1<br />
| No harm to oocyte<br />
| Only maternal DNA is tested, often needs to be coupled with other biopsies<br />
|-bgcolor="pink"<br />
| Blastomere<br />
| Day 3<br />
| …<br />
| … <br />
|-<br />
| Trophectoderm<br />
| Day 5 and 6 <br />
| Little harm, large amount of genetic material<br />
| Opening of blastocyst necessary, small time window for procedure<br />
|}<br />
<br />
{|border="1"<br />
| [[File:Polar_Body,_Blastomere,_and_Trophectoderm_Biopsy.jpeg]]<br />
|-<br />
| Polar body (A), blastomere (B) and trophectoderm (C) biopsies<ref name="PMID25625041"><pubmed>25625041</pubmed></ref>.<br />
|}<br />
<br />
PMID 24305177<br />
===Polar Body Analysis===<br />
Day 1<br />
====Description====<br />
Polar body (PB) biopsy, which was introduced in 1990, offers a promising alternative to biopsies performed at the blastomere stage for PGD/S indications on legal and practical grounds. <br />
Description: Consequent embryo development does not necessitate the presence of the first and second PB and their removal may not be crucial. PB biopsy requires precise timing. Keeping track of the meiotic cell cycle is necessary to perform a successful biopsy and, therefore, PB biopsy usually is applied in combination with intracytoplasmic sperm injection (ICSI). During the maturation from the germinal vesicle stage to the metaphase-II stage the first PB is formed. A cytoplasmic bridge containing spindle remnants, that are still in contact with the cellular genetic material, links this PB to the oolemma for about 90 minutes after extrusion. It is possible to visualize these remnants by polarization microscopy and it is crucial to not perform the biopsy until the first PB is no longer firmly attached to the oolemma as this indicates an immature embryo.The oocyte tolerates mechanical zona dissection best during hours four until six after ICSI as the oolemma has stabilized by that time because of the cortical granule reaction. Over time the first PB degenerates stressing a temporal biopsy and its optimal extraction time window is four to 12 hours after ICSI. The second PB forms around two to four hours after ICSI. However, its optimal time window for biopsy is set to be eight to 16 hours after ICSI. This is due to the second PB being attached to the oolemma with spindle remnants until six hours after ICSI. Biopsy at this point may cause enucleation of the oocyte. In addition, studies have shown that the amplification efficiency of second PB’s DNA is worse if the PB is extracted prior to eight hours after ICSI. <br />
Thus, it is possible to perform sequential and simultaneous biopsies for the first and second PB. If performed, sequentially the first PB may be removed four to 12 hours and the second PB eight to 16 hours after ICSI. The optimal time window for a biopsy for both the first and second PB simultaneously is eight to 12 hours after ICSI. It is highly preferred to analyze both PBs due to potential aneuploidies in either PB and crossing overs during meiosis<ref name="PMID22723007"/>. <br />
====Procedure====<br />
Chemical opening achieved with for example acidic tyrode’s solution of the zona pellucida is not tolerated by the oocyte and may have detrimental effects on the embryo’s development. Therefore, the access to the perivitelline space of the oocyte is provided by mechanical zona dissection or by laser. Both techniques work well if performed by experienced embryologist. However, laser-assisted biopsy is less time consuming when compared to manual dissection. It is critical to consider the size of the introduced opening as it will remain permanent. If it is too large the blastomere may be lost during embryo development and if it is too small it may interfere with hatching of the embryo during blastocyst stage<ref name="PMID22723007"/><br />
<br />
{|border="1"<br />
| [[File:Polar_Body_Biopsy.jpeg]]<br />
|-<br />
| The presence of a faint but clearly identifiable strand connecting PB2 to the <br />
oolemma. The biopsy was performed ∼9 h after ICSI<ref name="PMID21908464"><pubmed>21908464</pubmed></ref>.<br />
|}<br />
<br />
{|border="1"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JTaQzszVr8o</html5media><br />
|-<br />
| Laser-assisted polar body biopsy<ref>RIUK, R. (2013, June 25) Polar Body Biopsy [Video file]. Retrieved from https://www.youtube.com/watch?v=JTaQzszVr8o</ref><br />
|}<br />
<br />
====Advantages & Disadvantages====<br />
PB biopsies can only investigate the maternal contributions to the embryo as they are of maternal origin. Thus, this procedure is appropriate for PGD solely for monogenetic diseases from the maternal side. Recessive diseases may be evaluated with PB biopsies on the basis that the embryo’s outcome will be determined by the paternal contribution. (...) It may still be applied for PGS as most aneuploidies either arise during meiosis or origin from the maternal genome. However, diagnosis error has been reported due to the lack of considering paternal contributions. <br />
Because PB biopsies are performed very early it is not yet known whether the oocyte will develop into a viable embryo. Thus, PBs are commonly frozen or fixed after biopsy and depending on the state of the embryo only chosen PBs will be tested. This is primarily an economic issue as many genetic testing procedures are very cost-intensive<ref name="PMID22723007"/>.<br />
<br />
{|border="1"<br />
| [[File:Implantation_predictive_value_of_euploid_screening_results.jpeg]]<br />
|-<br />
| The sustained implantation predictive value (with 95 % confidence interval) of a euploid screening result obtained from the first polar body (PB1), PB1 and the second polar body (PB2), or a direct embryo biopsy for each stage of embryo transfer (cleavage-stage and blastocyst stage)<ref name="PMID25106935"><pubmed>25106935</pubmed></ref>.<br />
|}<br />
<br />
===Blastomere biopsy===<br />
Day 3 <br />
====Description====<br />
Blastomere biopsy has been the prevalent method for PGD and PGS in the last two decades. At least one, but up to two, blastomeres are biopsied on day three of the cleavage stage embryo. The right number of blastomeres removed is a controversial topic as two cells allow for more genetic material and more accurate results. However, removing two cells might be too invasive and damaging to the embryo. (Study)<ref name="PMID21748341"><pubmed>21748341</pubmed></ref><br />
====Procedure====<br />
Initially a hole was drilled into the zona pellucida using acid tyrodes and the blastomeres are removed via aspiration with a pipette<ref name="PMID21748341"/>.<br />
<br />
{|border="1"<br />
| [[File:Aspiration_of_a_Blastomere.jpeg]]<br />
|-<br />
| Aspiration of a Blastomere into the biopsy pipette<ref name=" PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
|}<br />
<br />
{|border="1"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=TbridWVwipI</html5media><br />
|-<br />
| Laser-assisted blastomere biopsy<ref>Sukprasert, M. (2014, March 5) Day 3 Blastomere Biopsy 1 [Video file]. Retrieved from https://www.youtube.com/watch?v=TbridWVwipI</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
===Trophectoderm biopsy===<br />
Day 5 and 6<br />
====Description====<br />
The improvement of embryo culture media allowed the in vitro development of human embryos until the blastocyst stage and opened up the possibility to take blastocyst biopsies. During day three to day five the haploid maternal and paternal genomes work together for the first time to form the genome of the embryo. The maternal epigenetic control lessens significantly while preparing for implantation with precisely arranged events happening. The first event includes a rapid increase in the number of embryonic cells which are active in mitotic divisions and apoptosis of aberrant cells. This is followed by the formation of blastocoel (cavitation) which results from the flattening of cell located on the outside of the blastomere. Now the blastocyst will expand until the embryo hatches by rupturing the zona pellucida. The cells of the blastocyst will differentiate to form two distinct cell lineages, the outer trophectoderm and the inner cell mass<ref name="PMID22723007"/>.<br />
====Procedure====<br />
Trophectoderm biopsy is usually performed in Hepes buffered biopsy medium and opening approaches include needle cutting which has been replaced by lasers in past years. Different research groups report different timings of the opening to be the most successful. Some open the blastocyst on day three or four by creating a 25 µm which causes the trophectoderm to herniate through this hole and is, thus, accessible for biopsy. Others create this hole about four hours before biopsy which allows sufficient herniation of trophectoderm cells. It is also possible to open the blastocyst immediately before biopsy. This avoids an extra step and the inner cell mass usually is easy to locate. Blastocyst biopsies involve the removal of trophectoderm cells and the ideal time for the procedure is day five. Successful biopsies on day six have been performed, while little is known about the results of biopsies on day seven. However, since the window of implantation in humans is from day eight to ten after ovulation, day seven biopsies appear to be possible<ref name="PMID22723007"/>.<br />
-collapse of trophoblasts<br />
-possible: biopsy of hatched blastocyst, holding pipette careful mild suction force to hold embryo near ICM <br />
-Cryopreservation<br />
<br />
{|border="1"<br />
| [[File:Microscopic images of human blastocysts for biopsy.jpeg]]<br />
|-<br />
| (A) Some trophectoderm cells in a blastocyst started to hatch and (B) the trophectoderm cells were biopsied with assisted laser cutting. Images in C–D show the blastocysts after vitrification and warming. Blastocysts had been cultured for 2–4 hrs after warming, showing good (ICM and trophectoderm cells) hatched (C) and hatching (D) blastocysts. The hatching blastocyst in (E) has good ICM but fair trophectoderm while the blastocyst in (F) has both fair ICM and trophectoderm. Arrows indicate ICMs and arrow heads indicate trophectoderm cells. Bar = 40 µm<ref name="PMID2190846"><pubmed>2190846</pubmed></ref>.<br />
|}<br />
<br />
<br />
{|border="1"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JI_TQ8d8tNM</html5media><br />
|-<br />
| Laser-assisted blastocyst biopsy (at 00:50 min)<ref>Coco, R. (2014, April 30) Trophectoderm biopsy in a Hatching blastocyst protruding ICM [Video file]. Retrieved from https://www.youtube.com/watch?v=JI_TQ8d8tNM</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
Blastocyst biopsies are believed to be less damaging to the embryo and appear to be unrelated to implantation rates. In addition, this biopsy method allows for a larger extraction of cells for genetic testing. However, since they are performed late in in vitro development, the time window for genetic testing is relatively small. Fast and accurate genetic testing methods are needed to ensure a successful and safe result from this biopsy. Thus, blastocyst biopsies may gain more popularity in the future whn such methods have been developed or improved<ref name="PMID22723007"/>. <br />
<br />
<br />
==Genetic Techniques==<br />
<br />
===PCR===<br />
====Description====<br />
Polymerase chain reaction (PCR) amplifies DNA specific to genetic sequence of interest . PCR was developed by Kay Mullis in the 1980s, for which he was awarded the Nobel prize for chemistry in 1993. <ref> Pubmed Docs (2015) Polymerase Chain Reaction (PCR) Pubmen. Retrieved from [http://www.ncbi.nlm.nih.gov/probe/docs/techpcr/]</ref> This technique enables clinicians to monitor and diagnose diseases using minute samples such as embryonic cells, blood & tissue. <ref>Roche (2015) PCR: How We Copy DNA. Roche Molecular Systems Inc. retrieved From [http://molecular.roche.com/pcr/Pages/Process.aspx]</ref> PCR has many important applications like DNA fingerprinting, genetic mapping, detection of viruses and bacteria as well as being used to detect genetic disorders, as a part of PGD, in conjunction with IVF. It is used to detect molecular abnormalities such as single gene disorders like Tay Sach, Cycstic fibrosis, Duchenne Muscular Dystrophy, Thalassemia, Huntington disease, Spinal muscular atrophy and many more. Molecular and Genetic analysis require a significant amount of DNA, which we would not have without PCR. It revolutionized the study of DNA, replacing all previous recombinant DNA technology. <ref> Mullins, K., Francois, F.& Gibbs R.A. (1994 ) The Polymerase Chain Reaction. p3. Springer- Science +Business Media. Birkhauser, Boston<br />
Available at [https://books.google.com.au/books?hl=en&lr=&id=gjrTBwAAQBAJ&oi=fnd&pg=PR5&dq=kary+mullis+PCR&ots=mpzAyRh5ZY&sig=PQ4goNoKJ90tb3-MkPk62zrTGbw#v=onepage&q=kary%20mullis%20PCR&f=false] </ref> <br />
<br />
====Procedure====<br />
<br />
Sample are obtained from the the blastocyst, a polar body biopsy or the blastomeres stages of the embryo. <br />
Stage 1 Denaturing: separating the target strands of DNA <br />
The obtained sample is heated to roughly 90 degrees celcius, this heat causes breaks the relatively weak bonds between nucleotides that form DNA. the double stranded DNA to split into 2 single strands of DNA that are used as templates.<br />
Stage 2 Annealing: Binding the Primers to the target DNA sequence <br />
PCR will only copy the target sequence of DNA specified by specific PCR primer. These synthesized primers Oligonucleotides are small artificial pieces of DNA. <br />
TAQ polymerase enzyme synthesize 2 new strands of DNA duplicate to the single sample DNA stand template indicated by these primers. During this stage the reaction is cooled to a temperature between 40-60 degrees Celsius. <br />
Stage 3- Extension- making copies <br />
Each of these 2 copies are then used again as templates generating 2 further replications This cycle can occur as many 30 -40 times within a couple hours leading to billions of extra copies of the original DNA segment. The optimal temperature for the further replication is roughly 72 degrees Celsius. <br />
<br />
This process mediated by a thermocycler machine that is programmed to alter the temperature of the reaction every couple of minutes, perpetuating the cycle of DNA denaturing and synthesis. <br />
This process, generates exponential exact copy of the original template DNA sequence. <br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
!PCR cycles<br />
<br />
|{|<br />
|-bgcolor="lightpink"<br />
| '''PCR Cycle'''<br />
| '''Target Copies'''<br />
|-<br />
| 1<br />
| 2<br />
|-bgcolor="pink"<br />
| 2<br />
| 4<br />
|-<br />
| 3<br />
| 8<br />
|-bgcolor="pink"<br />
| 4<br />
| 16<br />
|-"<br />
| 5 <br />
| 32<br />
|-bgcolor="pink"<br />
| 6 <br />
| 64<br />
|-<br />
| 7 <br />
| 128<br />
|-bgcolor="pink"<br />
| 8<br />
| 256<br />
|- <br />
| 9<br />
| 512 <br />
|-bgcolor="pink"<br />
| 10<br />
| 1024<br />
|-<br />
| 15<br />
| 32,768<br />
|-bgcolor="pink"<br />
| 20 <br />
| 1,048,578<br />
|-<br />
| 25<br />
| 33,554,432<br />
|-bgcolor="pink"<br />
| 30 <br />
| 1,073,741,842<br />
|-<br />
|}<br />
<br />
<br />
<br />
<br />
{|border="1" align="center"<br />
|-bgcolor="pink" <br />
| '''Advantages''' <br />
|'''Disadvantages'''<br />
|- <br />
| fast and inexpensive way of copying a target sequence of DNA<br />
| only during this exponential DNA replication phase can we determine the starting quantity sequence contained in the original sample ( template DNA strand)<br />
|-bgcolor="pink"<br />
| aids the diagnosis of single cell defects<br />
| PCR reaction is limited by the presence of inhibitors present in the sample : reagent inhibitors <br />
|-<br />
| rapid generation of results within a couple hours<br />
| self annealing due to the accumulation of the product -stopping exponential amplification for the target sequence and reach a plateau<br />
quantification of the end point of reaction of PCR products unreliable - therefore that is why we require real time quantitative RT-PCR necessary<br />
<ref> NIS (2015) Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref><br />
|-bgcolor="pink"<br />
| can start from a single molecule of DNA, therefore is more sensitive <br />
| <br />
|-<br />
| has a flexible primer design enabling<br />
| <br />
|-bgcolor="pink"<br />
| overcame previous issues associated with the limited availability of sites of end<br />
| <br />
|-<br />
| generates the DNA copies exponentially<br />
| <br />
|-bgcolor="pink"<br />
| enables DNA amplification required for molecular and genetic analysis<br />
| <br />
|-<br />
|Valid diagnostic method in selecting unaffected embryos for embryo transfer <ref> Dreesen, J., Drusedaul, M., Smeets, H., Die-Smulders, C., Coonen, E., Dumoulin, J., Gielen, M., Evers, J., Herbergers, J. & Geradets, J. (2008) Validation of preimplantation genetic diagnosis by PCR analysis: genotype comparison of the blastomere and corresponding embryo, implications for clinical practice. Mol. Hum. Reprod. 14 (10):573-579.doi: 10.1093/molehr/gan052. Retrieved from [http://molehr.oxfordjournals.org/content/14/10/573.short] </ref> <ref><pubmed>20966460</pubmed></ref><br />
|<br />
|}<br />
<br />
<br />
<br />
<br />
<br />
<br />
<br />
<br />
<br />
===Fluorescent In Situ Hybridisation (FISH)===<br />
<br />
<br />
====Description====<br />
Fluorescence in situ hybridization (FISH) the one of the most effective and rapid <ref name="PMID26338801"><pubmed>26338801</pubmed></ref> Preimplantation Genetic Diagnosis (PGD). This techniques used to locate a specific DNA sequences within a chromosome. FISH facilitates the clinical diagnosis of chromosomal abnormalities indicated by sequential duplications, deletions and rearrangements of chromosome, that are usually missed with microscopic analysis. This technique is especially relevant for female embryos with X-linked diseases,<ref><pubmed>20809319</pubmed></ref> that have no other mutation specific tests [http://www.ncbi.nlm.nih.gov/pubmed/20809319] As part of PGD, samples are collected from various stages of the embyro,and they are able to conducted tests on the blastocyst, a polar body biopsy and the blastomeres <ref><pubmed>21748341</pubmed></ref>. FISH is 99% effective when used in conjunction with competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities<ref name="PMID26338801"/>.<br />
<br />
====Procedure==== <br />
<br />
Samples are collected from either the blastocyst, a polar body biopsy or the blastomeres stages of the embryo <ref><pubmed>21748341</pubmed></ref>. <br />
DNA strands are heated and denatured causing their the individual DNA strands to break apart<br />
Probes are single complimentary stands of DNA a that have been tagged with small chemical agents that glow brightly in the presence of a specific region on a chromosome. These specific probes then hybridize and join to their complementary DNA strand. <br />
The fluorescent tags enable the researchers to correctly identify the presence or lack thereof and location of the specific chromosomes that they are testing for. <ref><pubmed>17876073</pubmed></ref><br />
Researcher analyse the results by identifying the number and the relative location of the fluorescent dots generated by the FISH images.<ref><pubmed>17970921</pubmed></ref><br />
The probe will not fully hybridise if there has been a duplication or a deletion of the DNA - indicating chromosomal and sex chromosomal anomalies like trisomies and aneuploidies. <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref><br />
<br />
<br />
Different probes are used for different purposes: <ref>Unique, Rare Chromosome Disorder Support Group (2013) Fluorescence in situ hybridisation (FISH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/Other/FISH%20FTNW.pdf]</ref><br />
*'''Locus specific tags''' detect very small imbalances, and locate isolated small portions <br />
of genes within a chromosome<br />
*'''Alphoid/Centomeric Repeat probes''' are developed from the repetitive sequence located in the middle region of each chromosome, useful in determining the number of chromosomes , detecting rearrangement and when used in conjunction with locus probes to determine the absence of genetic material on a chromosome. <br />
*'''Paint Probes''' are collections of smaller probes with their own stains that bind to a different section on the chromosome - allowing the full chromosome too be labeled a unique colour, this "full colour map" can be used to know the spectral karyotype- full chromosomal mapping is useful in examining chromosomal abnormalities. <br />
<br />
{|border="1" <br />
| [[File:Fluorescent In Situ Hybridisation (FISH).jpg|thumb|right|'''FISH''' We are able to tag Specific DNA sequences using Probes which have been tagged with fluorescent Labels.This technique enables the clinical diagnosis of chromosomal abnormalities, indicated by sequential duplication, deletions and rearrangements of chromosome <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref>]]<br />
|}<br />
<br />
<br />
<br />
{|border="1" align="center"<br />
|-bgcolor="pink" <br />
| rowspan="7" |'''Advantages''' <br />
| FISH is 99% effective when used in conjunction with Competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities.<ref><pubmed>26338801</pubmed></ref><br />
|-bgcolor="pink" <br />
| Rapid generation of results<br />
|-bgcolor="pink" <br />
| Identifies very small translocations and aneuploidies that occur within chromosomes, that would usually be missed under microscopic analysis<br />
|-bgcolor="pink" <br />
| Indicates whether the accessed chromosomes are normal <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|-bgcolor="pink" <br />
| Tests for the most common chromosomal abnormalities - down syndrome chromosomes 13,16,18,21 and 22 <ref><pubmed>21749752</pubmed></ref><br />
|-bgcolor="pink" <br />
| It may be used to compare the chromosomal gene arrangements in related species<br />
|-bgcolor="pink" <br />
| can be used to identify and remove inheritable X-linked disease or sex chromasome anomalies such as Duchennes Muscular Dystrophy, hemophilia, ectodermal dysplasia <ref><pubmed>17876073</pubmed></ref><br />
|-bgcolor="white"<br />
| rowspan="4"|'''Disadvantages'''<br />
| FISH destroys all cells tested <ref> O'Connor, C. (2008) Fluorescence in situ hybridization (FISH). Nature Education 1(1):171. retrieved from [http://www.nature.com/scitable/topicpage/fluorescence-in-situ-hybridization-fish-327] </ref><br />
|-<br />
| It does not fully access all chromosomes (only ~ 12)<br />
|-<br />
| Analysis of results is dependent upon the dot quality impacted by hybridisation efficiency or the camera sensitivity <ref><pubmed>17970921</pubmed></ref><br />
|-<br />
| some studies indicate that using FISH on a day-3 embryo biopsy decreases the rate of live births <ref><pubmed>26168107</pubmed></ref><br />
|}<br />
<br />
<br />
<br />
===Array Comparative Genomic Hybridisation (aCGH)===<br />
====Description====<br />
<br />
aCGH also known as Microarray analysis efficiently scans the entire genome for chromosomal imbalances. CGH was initially developed to detect the number of changes in a solid tumor mass. It uses 2 genomes comparing the sample to the control, with each labeled in a different fluorescent dye<ref><pubmed>1876176</pubmed></ref>. Earlier CGH techniques were limited by the resolution of the imaging <ref> Lichter, P., et al. Comparative genomic hybridization: Uses and limitations. Seminars in Hematology 37, 348–357 (2000)</ref> , these initial limitations were overcome by using Microarrays in conjunction with CGh to improve the resolution of the imaging, Array Comparative Genomic Hybridisation (aCGH). This method compares sample and control microarrayed slides containing small segments of DNA (probes). <ref> Lucito, R., et al. Representational oligonucleotide microarray analysis: A high-resolution method to detect genome copy number variation. Genome Research 13, 2291–2305 (2003) </ref> the Probes used will vary according from the small (25-85 base pairs) oligonucleotides manufactured to highlight different target sequences, to the very large genomic clones (80,000- 200,00 base pairs), and as these are significantly smaller than the traditional metaphase chromosomes used for CGH, generating a higher resolution of image. <ref><pubmed>22467166</pubmed></ref>.aCGH is used as a diagnostic tool for prenatal detection f chromosomal abnormalities <ref><pubmed>19012303</pubmed></ref>.<br />
<br />
<br />
====Procedure====<br />
<ref> Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432] </ref><br />
The sample is obtained (skin, blood or fetal cells) and DNA is obtained. <br />
As a part of PGD fetal cell samples are collected from; the fertilized egg polar bodies, the blastomere (day 3 embryo) or the blastocyst/tropoectoderm stage (day 5 embryo).<br />
Sample DNA is labeled with one fluorescent dye, and the control DNA is labeled with a different colored fluorescent dye. the control DNA is used as the base point of reference. <br />
heated and denatured single DNA strands then hybridize to their complementary single strand probes, which are then combined and applied to a microarray and the results are run through a computer program and a digital imaging system is used to quantify the results( fluorescent intensities of the labeled probes). <br />
<br />
simple explanation of aCGH : [Genomics Education (2014) Genetic Testing for Health: aCGH|https://vimeo.com/84757281]<br />
<ref>Genomics Education (2014) Genetic Testing for Health: aCGH [video file] Vimeo [https://vimeo.com/84757281]</ref><br />
<br />
<br />
The fluorescent ratio and the hybridization signal at different locations on the genome of the control DNA are used to identify any variances present in the sample DNA. aCGH facilitates the clinical diagnosis of submicroscopic chromosomal duplication, deletion and rearrangements indicative of chromosomal disorders such as trisomies 1-22and specific sex linked disorders. <br />
Duplications in the DNA are displayed by the computer program as spikes/ peaks over an established threshold and deletions in DNA are displayed by the computer program as spikes/ toughs beneath this threshold <br />
-computer screening image- <br />
-drawn diagram of method-<br />
<br />
<br />
<br />
{|border="1" align="center"<br />
|-bgcolor="pink" <br />
| '''Advantages''' <br />
| '''Disadvantages'''<br />
|-<br />
| multiple applications: prenatal genetic diagnosis, cancer diagnosis, <ref><pubmed>20193845</pubmed></ref> genetic screening for developmental delay (learning disabilities) <ref><pubmed>17309648</pubmed></ref>. or congenital anomalies that are suspected to be genetic in origin <ref>NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation . retrieved from [http://www.phgfoundation.org/file/5237/]</ref><br />
| translocations and inversions of DNA are not detected<br />
|-bgcolor="pink"<br />
| trace represents all chromosomes present in the human genome chromosomes 1-22 and the X & Y chromosomes, and therefore is the most accurate method for testing whole embryo aneuploidy<br />
| limited ability diagnosing specific polyploidies such as triploidy <ref> Unique, Rare Chromosome Disorder Support Group (2013) Microarray-based Comparative Genomic Hybridiation (array CGH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/other/array%20cgh%20ftnw.pdf] </ref><br />
|-<br />
| aCGH has been extensively tested, and Validated, and is now used world wide.<br />
| will not detect mosaicism detection <20% (cultures where >1 of 5 cells are trisomy 12)<br />
|-bgcolor="pink"<br />
| detects deletions and additions and rearrangements as well as amplification, of the WHOLE genome, simultaneously.<br />
| will not detect balanced chromosomal rearrangement<br />
|-<br />
| detects submicroscopic alterations<br />
| will not detect duplications or deletions <80kb<br />
|-bgcolor="pink"<br />
| used as a diagnostic tool for prenatal detection of chromosomal abnormalities <ref><pubmed>22034057</pubmed></ref><br />
| will not detect point mutations within genes <ref>Washington department of education (CGH- FAQ for physicians. Signature Genomic LAboratories, LLC. Retrieved from [https://depts.washington.edu/dbpeds/Lab%20Tests/SignatureCGH-physician_FAQ.pdf]</ref><br />
|-<br />
| provides high resolution genomewide screening of segmental genomic copy number variations<br />
| will not detect chromosomal position of genomic gains<br />
|-bgcolor="pink"<br />
| very accurate when used in conjunction with FISH<br />
| will not detect loos of heterozygosity (LOH) or Absence of heterozygosity (AOH) <ref>WiCell Research Institute Inc. (2012) Comparative Genomic Hybridization Microarray. <br />
retrieved from [http://www.wicell.org/home/cytogenetic-services/cgh-microarray/array-comparative-genomic-hybridization-acgh.cmsx]</ref><br />
|-style="background:pink"<br />
|Alone is more reliable and in detecting chromosomal abnormalities, with a higher implantation success rate, than FISH <ref><pubmed>20494259</pubmed></ref><br />
|<br />
|-bgcolor="pink"<br />
|Allows an in depth research focus upon specific types of rearrangements within selected chromosomal regions, a recent particular area of interest is subtelomeric and pericentromeric rearrangements<br />
|<br />
|-<br />
|reduces the risk of failed implantation and miscarriage, improving the chance of a healthy baby <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|<br />
|}<br />
<br />
<br />
<br />
===Next Generation Sequencing===<br />
====Description====<br />
The development and advances within ART in the past 20 years, as well as the increasing popularity of IV, has lead to an influx of new technologies developed to screen embryos for chromosomal anomalies, which are covered by the umbrella term of Next generation Sequencing (NGS). NGS is a general term used to describe all of the new and emerging screening techniques currently being introduced and used as part of PGD for IVF . NGS screens for single gene disorders as well as conducting extensive and very comprehensive chromosome diagnosis by sequencing, counting, and accurately assembling millions of DNA reads, simultaneously. <ref><pubmed>23499002</pubmed></ref> There is a movementfor NGS to replace the other limited testing techniques and be used as the standard. <br />
====Procedure====<br />
Samples are collected from either blastomere or the blastocyst/tropoectoderm and processed for analysis by a computer system. <br />
The methodology of each process is unique to the technique being used. <br />
<br />
<br />
<br />
{|border="1" align="center"<br />
|-bgcolor="pink" <br />
| '''Advantages'''<br />
| '''Disadvantages'''<br />
|-bgcolor="white"<br />
| cheaper<br />
| there are limited information available to clinical applications of NGS <ref><pubmed>26100406</pubmed></ref><br />
|-bgcolor="pink"<br />
| opens new diagnostic possibilities<br />
|<br />
|-bgcolor="white"<br />
| accurately tests all 24 chromosomes<br />
| <br />
|-bgcolor="pink"<br />
| tests for the presence of monogenic diseases of known genetic background<br />
| <br />
|-bgcolor="white"<br />
| reduces the number of biopsies required for diagnosis<br />
| <br />
|-bgcolor="pink"<br />
| higher detection rate of small translocations<br />
| <br />
|-bgcolor="white"<br />
| highly accurate is testing for compound point mutations, chromosomal duplication, deletions and insertions <ref><pubmed>23312231</pubmed></ref><br />
| <br />
|-bgcolor="pink"<br />
| it accurately detects chromosomal aneuploidy and unbalanced rearrangement <ref><pubmed>25685330</pubmed></ref><br />
| <br />
|-bgcolor="white"<br />
| NGS single gene disorder screenings can conducted in conjunction with PCR comprehensive chromosomal screening<br />
|<br />
|-bgcolor="pink"<br />
| Reduces human error <br />
|<br />
|-bgcolor="white"<br />
| better detects the presence of mosaicism<br />
|<br />
|-bgcolor="pink"<br />
| work well in conjunction with CGH and aCGH as part of PGD, improving the chances of IVF. <ref> Morris, R. S. (2015 ) Next generation sequencing for PCG|PGS|CCS. IVF1 retrieved from [http://www.ivf1.com/next-generation-sequencing for-pgd] </ref><br />
|<br />
|}<br />
<br />
<br />
<br />
<br />
<br />
<br />
==Diagnosis==<br />
There are a large amount of diseases that PGD can apply to, below are descriptions of the diseases that PGD are more commonly used for. <br />
===Cystic Fibrosis===<br />
Cystic fibrosis is a single gene disorder. It is autosomal recessive and involves mutations in the cystic fibrosis transmembrane conductance regulator (CTFR) gene. The CTFR gene is normally responsible for the decrease in chloride and the transport of bicarbonate in epithelial cells thus playing a major physiological role. In PGD procedures, identification of the gene is assisted by microsatellite markers that have similar composition to the CTFR gene itself. Biopsy of two cells at the blastocyst stage is recommended if markers are not available. There are many variations of cystic fibrosis the most common being P.Phe508del <ref name="PMID26014425"><pubmed>26014425</pubmed></ref>.<br />
===Duchenne Muscular Dystrophy ===<br />
Duchenne Muscular Dystrophy is an X-linked recessive disease. It involves the Xp21 gene where majority of the mutations are chromosomal deletions with a smaller percentage resulting from duplications <ref name="PMID18359022"><pubmed>18359022</pubmed></ref>.<br />
===β – Thalassemia=== <br />
β – Thalassemia is known as the most common type of autosomal recessive inherited disorder among haemoglobinopathies. It involves the adult β-globin gene and is associated with the absent or decreased expression of the gene. This is commonly caused by a single nucleotide change in the gene. PGD has been used successfully worldwide to identify the β-globin gene where its application is usually performed on a single blastomere or polar body <ref name="PMID19064120">19064120</pubmed></ref>.<br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
! Applicable diseases for PGD <ref>Genoma Group (2014). Retrieved September 18th, 2015, from http://www.preimplantationgeneticdiagnosis.it/genetic-diseases-diagnosed-by-pgd.htm </ref>, <ref>Genesis Genetics (2015). Retrieved September 18th, 2015, from http://genesisgenetics.org/pgd/what-we-test-for/</ref>, <ref>Human Fertilisation & Embryology Authority (2015). Retrieved Septembr 18th, 2015, from http://guide.hfea.gov.uk/pgd/</ref><br />
|-<br />
| '''Disease'''<br />
| '''Involved Genes'''<br />
|-<br />
| 5 Alpha Reductase Deficiency (5ARD)<br />
| SRD5A2 <br />
|-<br />
| Achondroplasia<br />
|FGFR3 <br />
|-<br />
| Acute Intermittent Porphyria <br />
| ALAD, ALAS2, CPOX, FECH, HMBS, PPOX, UROD, or UROS<br />
|-<br />
| Adrenoleukodystrophy (Adrenomyeloneuropathy)<br />
| ABCD1 <br />
|-<br />
| Agammaglobulinaemia (x-linked) <br />
|BTK <br />
|-<br />
| Agammaglobulinemia Bruton Tyrosine Kinase (BTK) <br />
|BTK <br />
|-<br />
| Aicardi Goutieres Syndrome 1 (AGS1) <br />
|TREX1, RNASEH2A, RNASEH2B, RNASEH2C, SAMHD1<br />
|-<br />
| Alagille Syndrome<br />
|JAG1 or NOTCH2<br />
|- <br />
| Alpers-Huttenlocher Syndrome <br />
|POLG <br />
|-<br />
| Alpha-1-antitrypsin deficiency <br />
|SERPINA1 <br />
|-<br />
| Alpha-Mannosidosis<br />
| MAN2B1 <br />
|-<br />
| Alpha Thalassemia <br />
|HBA1 or HBA2 <br />
|-<br />
| Alports Syndrome<br />
|COL4A3, COL4A4, COL4A5<br />
|-<br />
| Alzheimer's Disease - early onset (Type 3 and 4) <br />
|APP, PSEN1, or PSEN2<br />
|-<br />
| Amyotrophic Lateral Sclerosis 1 (ALS1) <br />
|C9orf72, SOD1, TARDBP, FUS, ANG, ALS2, SETX, VAPB <br />
|-<br />
| Argininosuccinic Aciduria <br />
| ASL<br />
|-<br />
| Arrhythmogenic Right Ventricular Cardiomyopathy/ Dysplasia (ARVC/D)<br />
| DSG2; DSP; PKP2<br />
|-<br />
| Ataxia Telangiectasia<br />
| ATM<br />
|-<br />
| Bardet-Biedl Syndrome (BBS)<br />
| BBS1; BBS10<br />
|-<br />
| Barth Syndrome<br />
| TAZ<br />
|-<br />
| Beta Thalassaemia<br />
| HBB<br />
|-<br />
| Birt-Hogg-Dubé Syndrome<br />
| FLCN<br />
|-<br />
| Breast Ovarian Cancer Familial Susceptibility (BRCA2)<br />
| BRCA1; BRCA2<br />
|-<br />
| Canavan Disease <br />
| ASPA<br />
|-<br />
| Carnitine-Acylcarnitine Translocase Deficiency <br />
| SLC25A20<br />
|-<br />
| Cerebral Arteriopathy with Subcortical Infarcts & Leukoencephalopathy (CADASIL)<br />
| NOTCH3<br />
|-<br />
| Cerebral Cavernous Malformation<br />
| CCM1<br />
|-<br />
| Charcot-Marie-Tooth Disease<br />
| GJB1; MPZ; NEFL; PMP22<br />
|-<br />
| CHARGE Syndrome<br />
| CHD7<br />
|-<br />
| Cherubism<br />
| SH3BP2<br />
|-<br />
| Choroideremia<br />
| CHM<br />
|-<br />
| Chronic Granulomatous Disease<br />
| CYBB; NCF1<br />
|-<br />
| Ciliary Dyskinesia<br />
| DNAH5<br />
|-<br />
| Citrullinemia<br />
| ASS1<br />
|-<br />
| Cleidocranial Dysplasia<br />
| RUNX2<br />
|-<br />
| Cockayne Syndrome<br />
| ERCC6<br />
|-<br />
| Congenital Adrenal Hyperplasia<br />
| CYP21A2<br />
|-<br />
| Congenital Cataracts<br />
| GJA8; VSX2<br />
|-<br />
| Congenital Diarrhea, Syndromic<br />
| SPINT2<br />
|-<br />
| Congenital Disorders of Glycosylation (CDG)<br />
| ALG1; ALG6; CDG1C; DOLK; PMM2<br />
|-<br />
| Cornelia de Lange Syndrome <br />
| NIPBL<br />
|-<br />
| Craniosynostosis<br />
| TWIST1<br />
|-<br />
| Crouzon Syndrome<br />
| FGFR2<br />
|-<br />
| Cysteinyl Leukotriene Receptor 1 Deficiency <br />
| CYSLTR1<br />
|-<br />
| Cystic Fibrosis<br />
| CFTR<br />
|-<br />
| Diamond –Blackfan Anemia <br />
| RPS19<br />
|-<br />
| Duchenne Muscular Dystrophy <br />
| DMD<br />
|-<br />
| Dyskeratosis congenita (Male embryos only)<br />
| DKC1<br />
|-<br />
| Ectodermal dysplasia (Hypohidrotic)<br />
| EDA; EDA1; GJB6; IKBKG<br />
|-<br />
| Familial Adenomatous polyposis coli (FAP)<br />
| APC<br />
|-<br />
| Familial Dysautonomia<br />
| IKBKAP<br />
|-<br />
| Fanconi Anemia <br />
| FANCA; FANCC; FANCD2; FANCF; FANCG; FANCJ<br />
|-<br />
| Fragile X Syndrome (FRAX)<br />
| FMR1<br />
|-<br />
| Galactosemia <br />
| GALT<br />
|-<br />
| Gangliosidosis<br />
| GLB1<br />
|-<br />
| Glanzmann Thrombasthenia <br />
| ITGA2B<br />
|-<br />
| Glutaric Acidemia (aciduria)<br />
| GCDH <br />
|-<br />
| Glycogen Storage Disease <br />
| G6PC; GAA; SLC37A4<br />
|-<br />
| Haemophilia A<br />
| F8<br />
|-<br />
| Haemophilia B<br />
| F9<br />
|-<br />
| Hereditary Nonpolyposis Colorectal Cancer: Lynch Syndrome<br />
| MLH1; MSH2; MSH6<br />
|-<br />
| Holt Oram Syndrome<br />
| TBX5<br />
|-<br />
| Huntington Disease<br />
| HD<br />
|-<br />
| Hydrocephalus<br />
| L1CAM<br />
|-<br />
| Ichthyosis <br />
| ABCA12; STS<br />
|-<br />
| Incontinentia Pigmenti (IP)<br />
| NEMO<br />
|-<br />
| Joubert Syndrome 5<br />
| INPP5E<br />
|-<br />
| Krabbe Disease<br />
| GALC<br />
|-<br />
| Leber Congenital Amaurosis (LCA)<br />
| CEP290; GUCY2D<br />
|-<br />
| Leigh Syndrome (Infantile Subacute Necrotising Encephalopathy)<br />
| LRPPRC<br />
|-<br />
| Lesch Nyan Syndrome<br />
| HPRT1<br />
|-<br />
| Leukocyte Adhesion Deficiency (Type I)<br />
| ITGB2<br />
|-<br />
| Li-Fraumeni Syndrome<br />
| TP53<br />
|-<br />
| Macular Dystrophy Retinal <br />
| VMD2<br />
|-<br />
| Maple Syrup Urine Disorder (MSUD)<br />
| BCKDHB<br />
|-<br />
| Marfan Syndrome <br />
| FBN1<br />
|-<br />
| Menkes Syndrome<br />
| ATP7A<br />
|-<br />
| Mitochondrial DNA Depletion Syndrom <br />
| POLG; RRM2B; SUCLA2; TK2<br />
|-<br />
| Mucolipidosis type II<br />
| GNPTAB<br />
|-<br />
| Multiple Endocrine Neoplasia<br />
| MEN1; MEN2A; MEN2B<br />
|-<br />
| Multiple Exostoses<br />
| EXT1; EXT2 <br />
|-<br />
| Myotubular myopathy<br />
| MTM1 <br />
|-<br />
| Nail-Patella Syndrome<br />
| LMX1B<br />
|-<br />
| Neurofibromatosis Type 1<br />
| NF1<br />
|-<br />
| Neurofibromatosis Type 2 <br />
| NF2<br />
|-<br />
| Noonan Syndrome<br />
| KRAS, PTPN11; SOS1<br />
|-<br />
| Norrie Disease<br />
| NDP<br />
|-<br />
| Ocular Albinism <br />
| GPR143<br />
|-<br />
| Oculocutaneous Albinism <br />
| OCA2; TYR <br />
|-<br />
| Oculodentaldigital Dysplasia<br />
| GJA1<br />
|-<br />
| Optic Atrophy<br />
| OPA1<br />
|-<br />
| Ornithine Transcarbamylase Deficiency <br />
| OTC<br />
|-<br />
| Osteogenesis imperfeca <br />
| COL1A1; COL1A2<br />
|-<br />
| Osteopetrosis <br />
| CLCN7; OSTM1; TCIRG1<br />
|-<br />
| Pachyonychia Congenita <br />
| KRT16; KRT6A<br />
|-<br />
| Pancreatitis, Hereditary<br />
| PRSS1 <br />
|-<br />
| Papillorenal syndrome <br />
| PAX2<br />
|-<br />
| Phenylketonuria <br />
| PAH <br />
|-<br />
| This table does not cover the complete list of diseases that PGD can be applied to.<br />
|}<br />
<br />
==Laws & Legal status==<br />
===Australia=== <br />
PGD is currently used to detect serious genetic conditions to improve the outcome of Assisted Reproductive Technologies (ART). In very rare cases it may be used to select an embryo with compatible tissue for a sibling who has a life-threatening disease where other means of treatment is unavailable. This is with the conditions that the use of PGD will not affect the welfare and interests of the child to be born. The parents must also receive adequate counselling and have full understanding of the procedures of PGD. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"> National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art</ref><br />
The use of PGD for sex-selection is prohibited with the exception of reducing the risk of the transmission of serious sex-linked genetic conditions. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"/><br />
===Brazil=== <br />
The laws regarding PGD in Brazil are not strictly regulated. They are vague and there is limited information surround the activities of assisted reproduction in general in the country <ref name="PMID25493379"><pubmed>25493379</pubmed></ref>.<br />
===Czech Republic===<br />
The laws in the Czech Republic allow those with a “defined indication in order to exclude risk of serous genetically conditioned disease and defects with embryos before they are implanted into the cavity of the uterus”. Couples that undergo any assisted reproductive treatment including PGD have to be married. Sex-selection is illegal except in regards to serious sex-linked genetic diseases <ref name="PMID24777348"><pubmed>24777348</pubmed></ref>.<br />
===Greece=== <br />
In Greece, ART is open to those up to the age of 50 with written consent. It can only be used if a medical necessity is present such as the susceptibility of serious hereditary diseases. Sex selection is banned apart from cases of sex-linked diseases and sexually transmitted diseases <ref name="PMID24777348"/>.<br />
===Portugal=== <br />
ART is only available to those who are married or have a similar type of relationship for at least two years. The couples cannot be of the same sex and must be at least 18 years of age. Sex selection is illegal except in cases of sex-linked diseases. The use of PGD is illegal if the predictive value of genetic tests are very low <ref name="PMID24777348"/>.<br />
===Spain===<br />
PGD can be applied to “serious hereditary diseases not amenable to postnatal curative treatment” and “detection of other abnormalities which may compromise the viability of the pre-embryo”. If PGD is to be used for any other purpose authorisation must be acquired <ref name="PMID24777348"/>.<br />
===Sweden=== <br />
The use of PGD is strictly regulated and couples must achieve authorisation of the National Board of Health and Welfare. It can only be used it can only be used if the child is at risk to inheriting a serious chromosomal or monogenetic disease. It cannot be used for selection of specific characteristics <ref name="PMID24777348"/>.<br />
===United Kingdom===<br />
Those involved with carrying out the IVF treatment must have a license from the Human Fertilisation and Embryology Authority (HFEA). Only embryos that are approved by the HFEA can be implanted where the embryonic nuclear or mitochondrial DNA cannot be altered with the exception of preventing mitochondrial diseases <ref name="PMID24777348"/>. <br />
==Future/Current Research==<br />
===Noninvasive Preimplantation Genetic Testing without Embryo Biopsy===<br />
Different parameters of gametes, zygotes, embryos (“vacuoles in sperm heads, spindle position in mature oocytes, cleavage intervals of zygote, and embryo developmental dynamics”) may correlate with aneuploidy rates. This knowledge may be applied in potential noninvasive preimplantation diagnostic methods. Several methods have been proposed and are currently further researched<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Sperm Selection====<br />
Intracytoplasmic morphologically selected sperm injection (IMSI) is common procedure in IVF treatment to improve fertilization rates in patients with poor semen quality. In addition, studies have found that IMSI improves embryo development and that spermatozoa with large vacuoles in their heads correlate with increased aneuploidy rates and disturbed chromosomal structures. Thus, selecting spermatozoa based on morphological hallmarks may decrease aneuploidy rates in the fertilized embryos. As with polar body biopsies, however, this approach will solely be applicable if evidence for severe male detrimental contribution is given<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Blastocoel Fluid Extraction====<br />
In addition, a less invasive retrieval of material for diagnosis could include the extraction of the blastocoel fluid. The cavity of the blastocyst, lined by the trophectoderm, is filled with this blastocoel fluid, which contains metabolites of both trophectoderm and inner cell mass origin. The retrieval does not require a biopsy but merely a small opening to extract the fluid and, thus, causes less harm to the embryo. Multiple studies have applied this method<ref name="PMID22020776"><pubmed>22020776</pubmed></ref> <ref name="PMID23148560"><pubmed>23148560</pubmed></ref> and it may in the future become of clinical relevance.<br />
<br />
{|border="1"<br />
| [[File:Aspiration_of_the_Blastocoel_Fluid.jpeg]]<br />
|-<br />
| Aspiration of the Blastocoel Fluid using a ICSI pipette<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
|}<br />
<br />
<br />
Next to metabolites, the blastocoel fluid can contain DNA. Studies have shown that genomic DNA is present in about 90% of the blastocoel fluid samples tested. Typically the fluid is removed with an ICSI pipette from a day five blastocyst through its mural trophectoderm until the blastocyst fully collapses around the embryo. Several concerns regarding this method in a clinical setting have been raised. The collected DNA may be contaminated by the culture media that contains DNA fractions. The DNA may also be least representative of the actual embryos genome as the DNA may originate from abnormal or degenerated cells. Even though labelled noninvasive, the blastocyst still undergoes manipulation to some degree which may affect its viability. Thus, more research is required until this method can evolve from research to clinical use<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
====Proteomics====<br />
The protein secretome of blastocysts may be representative of its chromosome constitution Recent studies have found biomarkers such as lipocalin-1, interleukin-10, tumor necrosis factor, stem cell factor, and chemokine ligand 13 to be differently secreted by aneuploid blastocyst than by euploid ones. The most significant biomarker appears to be interleukin-10. Paired with novel proteomic technologies and mass spectrometry this knowledge when extended may contribute to a new invasive preimplantation genetic diagnosis method<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Embryo Morphology====<br />
Using time lapse imaging the embryo’s morphology can be closely observed and potential aneuploidy characteristics detected. Such characteristics may include the time of division to five cells, the time between the division from three to four cells, and the duration of the division from one to two and subsequently to three. In addition, the morphological quality of ICM an TE has been positively associated with aneuploidy or euploidy prognosis<ref name="PMID26246880"><pubmed>26246880</pubmed></ref>. These may give rise to an embryo quality screening prior to implantation<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
===Utilization of Diseased Cell Lines===<br />
==Ethics==<br />
==References==<br />
<br />
<references/><br />
<br />
<br />
{{StudentPage2015}}</div>Z5017878https://embryology.med.unsw.edu.au/embryology/index.php?title=2015_Group_Project_6&diff=2065532015 Group Project 62015-10-19T11:56:34Z<p>Z5017878: </p>
<hr />
<div>{{ANAT2341Project2015header}}<br />
<br />
<br />
=Prenatal Genetic Diagnosis=<br />
==Introduction==<br />
==History==<br />
Prenatal Genetic Diagnosis was historically conducted post-implantation in the first 2 trimesters <ref> Blackburn, S.L. (2003) '''Maternal, Fetal & Neonatal physiology: a Clinical perspective''' (2nd ed.). Seattle: Saudners </ref>, testing for overall fetal growth, complications of pregnancy, birth defects as well as chromosomal or genetic abnormalities<ref> Sadler T.W.(2012) '''Langman's Medical Embryology''' (12th ed.) Philadelphia: Lipincott, Wiliams & Wilkins, a Wolters Kluwer Business </ref>. Due to advancements in Artificial Reproductive Technologies ( ART) in the past 2 decades , these genetic tests are now conducted as a part of Preimplantation Genetic Diagnosis (PGD) <ref><pubmed>20638568</pubmed></ref> and art used to eliminate the rsik of passing on a genetic disorder to an offspring, before implantation, it ha now become a preventative measure. . In 1990 Preimplantation genetic testing was first used in 1990 on humans to diagnose recessive X-linked diseases in the embryos of pregnant women undergoing IVF. <ref><pubmed>2330030</pubmed></ref> PGD is offered as an alternative to prenatal diagnosis in detecting genetic disorders in high risk couples <ref><pubmed>26168107</pubmed></ref> and avoid passing an inherited disease to the offspring, by selecting genetically "normal" embryos for implantation ,to give the best chance of successful implantation , stable pregnancies and healthy children. <br />
<ref><pubmed>23499002</pubmed></ref><br />
<br />
==Preimplantation Genetic Diagnosis==<br />
[[File:Preimplantation Genetic Diagnosis Procedure.jpeg|700px|thumb|centre| Simplified steps for PGD]]<br />
<br />
<br />
Preimplantation genetic diagnosis (PGD) is used to test the genetic makeup of embryos to detect single gene disorders, chromosomal abnormalities and mitochondrial disorders. It also has applications in gender selection for diseases with unequal gender distributions <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Some diseases commonly involved with PGD include cystic fibrosis, spinal muscular atrophy and beta – thalassaemia <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press.">Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press</ref> <ref name="PMID17823145"><pubmed>17823145</pubmed></ref>. It was first used in the United Kingdom in the 1980s of arenoleucodystrophy and primarily focusing on sex- linked disorders <ref name="PMID17823145"/><ref name="PMID23150080"><pubmed>23150080</pubmed></ref>. PGD is now capable of detecting single cell defects (molecular) and chromosomal disorders resulting from the inversion, translocation or deletion of chromosomes (cytogenic) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>,<ref name="PMID11325751"><pubmed>11325751</pubmed></ref>. PGD can be applied to the embryo at different stages. That is on polar bodies, blastomeres or blastocyst <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>.<br />
Depending on the type of genetic disorder, PGD utilises different methods of genetic testing. These include Fluorescence in situ hybridisation (FISH) which is used for sex – linked disorders and detects chromosomal rearrangements <ref name="PMID11325751"/><ref name="PMID17876073"><pubmed>17876073</pubmed></ref> and Embryo halotyping which allows the identification of chromosomes causing the inherited disorder through knowledge of the pattern of closely linked markers <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. Polymerase chain reaction (PCR) is also widely used to detect molecular abnormalities <ref name="PMID11325751"/>.<br />
PGD is tightly regulated and supported by large organisations namely The American Society for Reproductive Medicine, The European Society for Human Reproduction and Embryology (ESHRE), The European Society of Human Genetics and the Preimplantation Genetic Diagnosis International Society <ref name="PMID25500181><pubmed>25500181</pubmed></ref>.<br />
===Sex-linked disorders===<br />
The determination of a disease as gender specific usually correlates with the presence or absence of specific genes such as SRY on the Y chromosome. It is known that females have two X chromosomes and males have an X and a Y chromosome where abnormalities are more prevalent on the X chromosome. PGD can be used for sex selection where only male embryos are transferred to reduce the chance of inheriting X-linked disorders. However, this does not completely eradicate the problem as male embryos remain susceptible to inheriting an affected X chromosome. Sex determination is only used when the specific mutation is unknown and has yet to be discovered <ref name="PMID24866878"><pubmed>24866878</pubmed></ref>.<br />
===Single gene defects===<br />
Single gene defects can be dominant, recessive, autosomal or X-linked. They are commonly diagnosed using PCR and although the PCR available today is complex and capable of combatting a large range of disease the development of new protocols has been proven to be difficult due to the small DNA sample available <ref name="PMID26168107"><pubmed>26168107</pubmed></ref><br />
===Mitochondrial disorders===<br />
Mitochondrial disorders also known as oxidative phosphorylation disorders arise from mutations in the nuclear DNA or mitochondrial DNA <ref name="PMID26312584"><pubmed>26312584</pubmed></ref>. They pose as a problem because they are unrecognisable until the mutations in the cell reach a detrimental level <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Mitochondrial disorders cause miscarriages and stillbirths as well as death in children and young adults. The effects can either be contained in a single organ or more commonly involve multiple organ failure where organs with high energy demands such as the brain, liver muscle and heart and heavily influenced. They are usually occur spontaneously or result from inheritance from the mother. Since mitochondria are solely inherited from the mother oocyte donations have been used as a solution to combat mitochondrial disorders. Additionally, there has been an increasing use in PGD where embryos that stay under the given threshold of 18% gene-mutations are allowed to be transferred and result in normal development. New technology in the areas of nuclear gene transfer and genome editing are also being experimented with <ref name="PMID26312584"/>. <br />
===Chromosomal disorders===<br />
Chromosomal disorders can be reciprocal, Robertsonian translocations, inversions, deletions and insertions <ref name="PMID26168107"/>. . Data from ESHRE collected between 2010 and 2011 has shown that the most common chromosomal abnormality confronted in PGD are reciprocal chromosomal abnormalities <ref name"PMID26071418"><pubmed>26071418</pubmed></ref>. PGD has also been used successfully for Robertsonian translocations (RT), a type of structural translocation. Children who carry RT are phenotypically normal, however in their later years it is found that they will suffer from infertility and repeated miscarriages due to the high frequency of abnormal embryos <ref name="PMID22081077"><pubmed>22081077</pubmed></ref>. PCR and FISH are the two main techniques used for chromosomal disorders. To be able to conduct the examinations the cells are required to be at the metaphase stage <ref name="PMID26168107"/>. <br />
==Preimplantation Genetic Screening==<br />
Prenatal Genetic Screening (PGS) involves an array of methods or ideas that aim to segregate embryos that have genetic flaws and those that are healthy <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. The occurrence of aneuploidy is high around the stages of early embryonic development and they are the most common cause if miscarriages and congenital birth defects <ref name= "PMID26085841"><pubmed>26085841</pubmed></ref>. They have little effect on the morphology of the embryo making them difficult to identify thus identification heavily relies on genetic testing <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. <br />
Genetic sampling is most commonly conducted using Microarray Comparative Genomic Hybridisation (aCGH) as well as FISH, Quantitative PCR and Single Nucleotide Polymorphism (SNP) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. These methods collectively aim to assess numeral and structural chromosomal errors <ref name= "PMID26085841"/>. Studies have also introduced Next- Generation Sequencing (NGS) <ref name= "PMID26085841"/> and Whole Genome Amplification used to screen imbalances in the complete 24-chromosomes <ref name="PMID25953353"><pubmed>25953353</pubmed></ref><br />
Statistics from ESHRE have shown that the most common indications for PGS is advanced age, followed by repeated implantation failure or recurrent miscarriage and male infertility <ref name="PMID26071418"><pubmed>26071418</pubmed></ref>.<br />
====Indications====<br />
A low percentage of structural abnormalities in chromosomes are responsible for the cause of miscarriages. Despite this, they are the most prevalent type of chromosomal abnormality accounted for in PGD <ref name="PMID20638568"/>. The presence of specific gene cycles, initiation of embryonic protein synthesis and evident physiological development are all indicative of a successful in vitro fertilisation procedure <ref name="PMID11576737"><pubmed>11576737</pubmed></ref>. To eliminate further errors from occurring during the PGD procedure it is recommended to undertake further prenatal testing such as amniocentesis in the later stages <ref name="PMID20638568"/>. <br />
=====Advanced maternal age=====<br />
Data provided by the ESHRE has shown that the mean age of women undergoing PGS is 39 years <ref name="PMID26071418"/>. Women of advanced age have been shown to have a lower rate of pregnancies reaching childbirth <ref name="PMID18583331"><pubmed>18583331</pubmed></ref>. The highlighted concern revolves around the increased occurrence of aneuploidy following maternal age. The optimal age range for the lowest aneuploidy incidence was found to be between 27 to 37 years of age (6%) then progressively higher in women aged up to 42 (33%) and most common in those 44 and above (53%) <ref name="PMID24355045"><pubmed>24355045</pubmed></ref>. <br />
=====Recurrent pregnancy loss / IVF failure=====<br />
Recurrent pregnancy loss is defined as three or more IVF failures after cumulative transfer of more than 10 good-quality embryos. These are primarily caused by two main factors, reduced endometrium receptivity or embryonic defects. Endometrium receptivity can be negatively influences by instances including uterine pathologies such as thin endometrium, altered expression of adhesive molecules and immunological factors. Additionally, embryonic defects may be due to genetic abnormalities, embryonic aneuploidy or zona hardening. Endometriosis and hydrosalpinx has been known to effect both the endometrium and embryo <ref name="PMID23260857"><pubmed>23260857</pubmed></ref>.<br />
=====Human leukocyte antigen matching=====<br />
First used in 2001, HLA matching is an option given to parents to save a child with haematological or immunological disease through conceiving another child who would potentially be able to donate cord blood or haematopoietic stem cells from the bone marrow for transplantation. The process namely PGD-HLA has shown to improve haematopoietic stem cell transplant (HSCT). PGD-HLA can only be performed when HSCT is not needed urgently due to the time needed to conceive and delivery the baby <ref name="PMID25500181"><pubmed>25500181</pubmed></ref>. It is most commonly applied to children suffering from relapsed leukaemia <ref name="PMID22524201"><pubmed>22524201</pubmed></ref>. In a case study PGD-HLA was proven to successfully cure 10 diseases including Fanconi anaemia, Diamond-Blackfan anaemia and beta thalassemia <ref name="PMID25066893><pubmed>25066893</pubmed></ref>.<br />
==Biopsy Methods==<br />
Biopsy, the removal of genetic materials, from oocytes or embryos in the preimplantation stage is the primary step in PGD. For the past two decades these biopsies have been performed at three stages, the polar body, blastomere, and blastocyst, and the methodologies optimized to ensure the embryo’s viability. The most common approach involves biopsies at the cleavage stage. However, polar body and blastocyst biopsies are increasingly more often tested and applied. Approached for opening the zona pellucida involve next to the traditional mechanical and chemical means, novel approaches such as noncontact lasers. Their application may simplify and secure the procedure significantly. The most challenging question about PGD procedures remains at what stage biopsies should be taken. Much controversy has developed around this topic, highlighting the varying disadvantages and advantages of temporal biopsies. <ref name="PMID22723007"><pubmed>22723007</pubmed></ref><br />
<br />
{|border="1" align="left"<br />
|-bgcolor="pink" <br />
|<br />
| Time of Biopsy<br />
| Advantages <br />
| Disadvantages<br />
|- <br />
| Polar Body<br />
| Day 1<br />
| No harm to oocyte<br />
| Only maternal DNA is tested, often needs to be coupled with other biopsies<br />
|-bgcolor="pink"<br />
| Blastomere<br />
| Day 3<br />
| …<br />
| … <br />
|-<br />
| Trophectoderm<br />
| Day 5 and 6 <br />
| Little harm, large amount of genetic material<br />
| Opening of blastocyst necessary, small time window for procedure<br />
|}<br />
<br />
{|border="1"<br />
| [[File:Polar_Body,_Blastomere,_and_Trophectoderm_Biopsy.jpeg]]<br />
|-<br />
| Polar body (A), blastomere (B) and trophectoderm (C) biopsies<ref name="PMID25625041"><pubmed>25625041</pubmed></ref>.<br />
|}<br />
<br />
PMID 24305177<br />
===Polar Body Analysis===<br />
Day 1<br />
====Description====<br />
Polar body (PB) biopsy, which was introduced in 1990, offers a promising alternative to biopsies performed at the blastomere stage for PGD/S indications on legal and practical grounds. <br />
Description: Consequent embryo development does not necessitate the presence of the first and second PB and their removal may not be crucial. PB biopsy requires precise timing. Keeping track of the meiotic cell cycle is necessary to perform a successful biopsy and, therefore, PB biopsy usually is applied in combination with intracytoplasmic sperm injection (ICSI). During the maturation from the germinal vesicle stage to the metaphase-II stage the first PB is formed. A cytoplasmic bridge containing spindle remnants, that are still in contact with the cellular genetic material, links this PB to the oolemma for about 90 minutes after extrusion. It is possible to visualize these remnants by polarization microscopy and it is crucial to not perform the biopsy until the first PB is no longer firmly attached to the oolemma as this indicates an immature embryo.The oocyte tolerates mechanical zona dissection best during hours four until six after ICSI as the oolemma has stabilized by that time because of the cortical granule reaction. Over time the first PB degenerates stressing a temporal biopsy and its optimal extraction time window is four to 12 hours after ICSI. The second PB forms around two to four hours after ICSI. However, its optimal time window for biopsy is set to be eight to 16 hours after ICSI. This is due to the second PB being attached to the oolemma with spindle remnants until six hours after ICSI. Biopsy at this point may cause enucleation of the oocyte. In addition, studies have shown that the amplification efficiency of second PB’s DNA is worse if the PB is extracted prior to eight hours after ICSI. <br />
Thus, it is possible to perform sequential and simultaneous biopsies for the first and second PB. If performed, sequentially the first PB may be removed four to 12 hours and the second PB eight to 16 hours after ICSI. The optimal time window for a biopsy for both the first and second PB simultaneously is eight to 12 hours after ICSI. It is highly preferred to analyze both PBs due to potential aneuploidies in either PB and crossing overs during meiosis<ref name="PMID22723007"/>. <br />
====Procedure====<br />
Chemical opening achieved with for example acidic tyrode’s solution of the zona pellucida is not tolerated by the oocyte and may have detrimental effects on the embryo’s development. Therefore, the access to the perivitelline space of the oocyte is provided by mechanical zona dissection or by laser. Both techniques work well if performed by experienced embryologist. However, laser-assisted biopsy is less time consuming when compared to manual dissection. It is critical to consider the size of the introduced opening as it will remain permanent. If it is too large the blastomere may be lost during embryo development and if it is too small it may interfere with hatching of the embryo during blastocyst stage<ref name="PMID22723007"/><br />
<br />
{|border="1"<br />
| [[File:Polar_Body_Biopsy.jpeg]]<br />
|-<br />
| The presence of a faint but clearly identifiable strand connecting PB2 to the <br />
oolemma. The biopsy was performed ∼9 h after ICSI<ref name="PMID21908464"><pubmed>21908464</pubmed></ref>.<br />
|}<br />
<br />
{|border="1"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JTaQzszVr8o</html5media><br />
|-<br />
| Laser-assisted polar body biopsy<ref>RIUK, R. (2013, June 25) Polar Body Biopsy [Video file]. Retrieved from https://www.youtube.com/watch?v=JTaQzszVr8o</ref><br />
|}<br />
<br />
====Advantages & Disadvantages====<br />
PB biopsies can only investigate the maternal contributions to the embryo as they are of maternal origin. Thus, this procedure is appropriate for PGD solely for monogenetic diseases from the maternal side. Recessive diseases may be evaluated with PB biopsies on the basis that the embryo’s outcome will be determined by the paternal contribution. (...) It may still be applied for PGS as most aneuploidies either arise during meiosis or origin from the maternal genome. However, diagnosis error has been reported due to the lack of considering paternal contributions. <br />
Because PB biopsies are performed very early it is not yet known whether the oocyte will develop into a viable embryo. Thus, PBs are commonly frozen or fixed after biopsy and depending on the state of the embryo only chosen PBs will be tested. This is primarily an economic issue as many genetic testing procedures are very cost-intensive<ref name="PMID22723007"/>.<br />
<br />
{|border="1"<br />
| [[File:Implantation_predictive_value_of_euploid_screening_results.jpeg]]<br />
|-<br />
| The sustained implantation predictive value (with 95 % confidence interval) of a euploid screening result obtained from the first polar body (PB1), PB1 and the second polar body (PB2), or a direct embryo biopsy for each stage of embryo transfer (cleavage-stage and blastocyst stage)<ref name="PMID25106935"><pubmed>25106935</pubmed></ref>.<br />
|}<br />
<br />
===Blastomere biopsy===<br />
Day 3 <br />
====Description====<br />
Blastomere biopsy has been the prevalent method for PGD and PGS in the last two decades. At least one, but up to two, blastomeres are biopsied on day three of the cleavage stage embryo. The right number of blastomeres removed is a controversial topic as two cells allow for more genetic material and more accurate results. However, removing two cells might be too invasive and damaging to the embryo. (Study)<ref name="PMID21748341"><pubmed>21748341</pubmed></ref><br />
====Procedure====<br />
Initially a hole was drilled into the zona pellucida using acid tyrodes and the blastomeres are removed via aspiration with a pipette<ref name="PMID21748341"/>.<br />
<br />
{|border="1"<br />
| [[File:Aspiration_of_a_Blastomere.jpeg]]<br />
|-<br />
| Aspiration of a Blastomere into the biopsy pipette<ref name=" PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
|}<br />
<br />
{|border="1"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=TbridWVwipI</html5media><br />
|-<br />
| Laser-assisted blastomere biopsy<ref>Sukprasert, M. (2014, March 5) Day 3 Blastomere Biopsy 1 [Video file]. Retrieved from https://www.youtube.com/watch?v=TbridWVwipI</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
===Trophectoderm biopsy===<br />
Day 5 and 6<br />
====Description====<br />
The improvement of embryo culture media allowed the in vitro development of human embryos until the blastocyst stage and opened up the possibility to take blastocyst biopsies. During day three to day five the haploid maternal and paternal genomes work together for the first time to form the genome of the embryo. The maternal epigenetic control lessens significantly while preparing for implantation with precisely arranged events happening. The first event includes a rapid increase in the number of embryonic cells which are active in mitotic divisions and apoptosis of aberrant cells. This is followed by the formation of blastocoel (cavitation) which results from the flattening of cell located on the outside of the blastomere. Now the blastocyst will expand until the embryo hatches by rupturing the zona pellucida. The cells of the blastocyst will differentiate to form two distinct cell lineages, the outer trophectoderm and the inner cell mass<ref name="PMID22723007"/>.<br />
====Procedure====<br />
Trophectoderm biopsy is usually performed in Hepes buffered biopsy medium and opening approaches include needle cutting which has been replaced by lasers in past years. Different research groups report different timings of the opening to be the most successful. Some open the blastocyst on day three or four by creating a 25 µm which causes the trophectoderm to herniate through this hole and is, thus, accessible for biopsy. Others create this hole about four hours before biopsy which allows sufficient herniation of trophectoderm cells. It is also possible to open the blastocyst immediately before biopsy. This avoids an extra step and the inner cell mass usually is easy to locate. Blastocyst biopsies involve the removal of trophectoderm cells and the ideal time for the procedure is day five. Successful biopsies on day six have been performed, while little is known about the results of biopsies on day seven. However, since the window of implantation in humans is from day eight to ten after ovulation, day seven biopsies appear to be possible<ref name="PMID22723007"/>.<br />
-collapse of trophoblasts<br />
-possible: biopsy of hatched blastocyst, holding pipette careful mild suction force to hold embryo near ICM <br />
-Cryopreservation<br />
<br />
{|border="1"<br />
| [[File:Microscopic images of human blastocysts for biopsy.jpeg]]<br />
|-<br />
| (A) Some trophectoderm cells in a blastocyst started to hatch and (B) the trophectoderm cells were biopsied with assisted laser cutting. Images in C–D show the blastocysts after vitrification and warming. Blastocysts had been cultured for 2–4 hrs after warming, showing good (ICM and trophectoderm cells) hatched (C) and hatching (D) blastocysts. The hatching blastocyst in (E) has good ICM but fair trophectoderm while the blastocyst in (F) has both fair ICM and trophectoderm. Arrows indicate ICMs and arrow heads indicate trophectoderm cells. Bar = 40 µm<ref name="PMID2190846"><pubmed>2190846</pubmed></ref>.<br />
|}<br />
<br />
<br />
{|border="1"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JI_TQ8d8tNM</html5media><br />
|-<br />
| Laser-assisted blastocyst biopsy (at 00:50 min)<ref>Coco, R. (2014, April 30) Trophectoderm biopsy in a Hatching blastocyst protruding ICM [Video file]. Retrieved from https://www.youtube.com/watch?v=JI_TQ8d8tNM</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
Blastocyst biopsies are believed to be less damaging to the embryo and appear to be unrelated to implantation rates. In addition, this biopsy method allows for a larger extraction of cells for genetic testing. However, since they are performed late in in vitro development, the time window for genetic testing is relatively small. Fast and accurate genetic testing methods are needed to ensure a successful and safe result from this biopsy. Thus, blastocyst biopsies may gain more popularity in the future whn such methods have been developed or improved<ref name="PMID22723007"/>. <br />
<br />
<br />
==Genetic Techniques==<br />
<br />
===PCR===<br />
====Description====<br />
Polymerase chain reaction (PCR) amplifies DNA specific to genetic sequence of interest . PCR was developed by Kay Mullis in the 1980s, for which he was awarded the Nobel prize for chemistry in 1993. <ref> Pubmed Docs (2015) Polymerase Chain Reaction (PCR) Pubmen. Retrieved from [http://www.ncbi.nlm.nih.gov/probe/docs/techpcr/]</ref> This technique enables clinicians to monitor and diagnose diseases using minute samples such as embryonic cells, blood & tissue. <ref>Roche (2015) PCR: How We Copy DNA. Roche Molecular Systems Inc. retrieved From [http://molecular.roche.com/pcr/Pages/Process.aspx]</ref> PCR has many important applications like DNA fingerprinting, genetic mapping, detection of viruses and bacteria as well as being used to detect genetic disorders, as a part of PGD, in conjunction with IVF. It is used to detect molecular abnormalities such as single gene disorders like Tay Sach, Cycstic fibrosis, Duchenne Muscular Dystrophy, Thalassemia, Huntington disease, Spinal muscular atrophy and many more. Molecular and Genetic analysis require a significant amount of DNA, which we would not have without PCR. It revolutionized the study of DNA, replacing all previous recombinant DNA technology. <ref> Mullins, K., Francois, F.& Gibbs R.A. (1994 ) The Polymerase Chain Reaction. p3. Springer- Science +Business Media. Birkhauser, Boston<br />
Available at [https://books.google.com.au/books?hl=en&lr=&id=gjrTBwAAQBAJ&oi=fnd&pg=PR5&dq=kary+mullis+PCR&ots=mpzAyRh5ZY&sig=PQ4goNoKJ90tb3-MkPk62zrTGbw#v=onepage&q=kary%20mullis%20PCR&f=false] </ref> <br />
<br />
====Procedure====<br />
<br />
Sample are obtained from the the blastocyst, a polar body biopsy or the blastomeres stages of the embryo. <br />
Stage 1 Denaturing: separating the target strands of DNA <br />
The obtained sample is heated to roughly 90 degrees celcius, this heat causes breaks the relatively weak bonds between nucleotides that form DNA. the double stranded DNA to split into 2 single strands of DNA that are used as templates.<br />
Stage 2 Annealing: Binding the Primers to the target DNA sequence <br />
PCR will only copy the target sequence of DNA specified by specific PCR primer. These synthesized primers Oligonucleotides are small artificial pieces of DNA. <br />
TAQ polymerase enzyme synthesize 2 new strands of DNA duplicate to the single sample DNA stand template indicated by these primers. During this stage the reaction is cooled to a temperature between 40-60 degrees Celsius. <br />
Stage 3- Extension- making copies <br />
Each of these 2 copies are then used again as templates generating 2 further replications This cycle can occur as many 30 -40 times within a couple hours leading to billions of extra copies of the original DNA segment. The optimal temperature for the further replication is roughly 72 degrees Celsius. <br />
<br />
This process mediated by a thermocycler machine that is programmed to alter the temperature of the reaction every couple of minutes, perpetuating the cycle of DNA denaturing and synthesis. <br />
This process, generates exponential exact copy of the original template DNA sequence. <br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
!PCR cycles<br />
<br />
|{|<br />
|-bgcolor="lightpink"<br />
| '''PCR Cycle'''<br />
| '''Target Copies'''<br />
|-<br />
| 1<br />
| 2<br />
|-bgcolor="pink"<br />
| 2<br />
| 4<br />
|-<br />
| 3<br />
| 8<br />
|-bgcolor="pink"<br />
| 4<br />
| 16<br />
|-"<br />
| 5 <br />
| 32<br />
|-bgcolor="pink"<br />
| 6 <br />
| 64<br />
|-<br />
| 7 <br />
| 128<br />
|-bgcolor="pink"<br />
| 8<br />
| 256<br />
|- <br />
| 9<br />
| 512 <br />
|-bgcolor="pink"<br />
| 10<br />
| 1024<br />
|-<br />
| 15<br />
| 32,768<br />
|-bgcolor="pink"<br />
| 20 <br />
| 1,048,578<br />
|-<br />
| 25<br />
| 33,554,432<br />
|-bgcolor="pink"<br />
| 30 <br />
| 1,073,741,842<br />
|-<br />
|}<br />
<br />
<br />
<br />
<br />
{|border="1" align="center"<br />
|-bgcolor="pink" <br />
| '''Advantages''' <br />
|'''Disadvantages'''<br />
|- <br />
| fast and inexpensive way of copying a target sequence of DNA<br />
| only during this exponential DNA replication phase can we determine the starting quantity sequence contained in the original sample ( template DNA strand)<br />
|-bgcolor="pink"<br />
| aids the diagnosis of single cell defects<br />
| PCR reaction is limited by the presence of inhibitors present in the sample : reagent inhibitors <br />
|-<br />
| rapid generation of results within a couple hours<br />
| self annealing due to the accumulation of the product -stopping exponential amplification for the target sequence and reach a plateau<br />
quantification of the end point of reaction of PCR products unreliable - therefore that is why we require real time quantitative RT-PCR necessary<br />
<ref> NIS (2015) Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref><br />
|-bgcolor="pink"<br />
| can start from a single molecule of DNA, therefore is more sensitive <br />
| <br />
|-<br />
| has a flexible primer design enabling<br />
| <br />
|-bgcolor="pink"<br />
| overcame previous issues associated with the limited availability of sites of end<br />
| <br />
|-<br />
| generates the DNA copies exponentially<br />
| <br />
|-bgcolor="pink"<br />
| enables DNA amplification required for molecular and genetic analysis<br />
| <br />
|-<br />
|Valid diagnostic method in selecting unaffected embryos for embryo transfer <ref> Dreesen, J., Drusedaul, M., Smeets, H., Die-Smulders, C., Coonen, E., Dumoulin, J., Gielen, M., Evers, J., Herbergers, J. & Geradets, J. (2008) Validation of preimplantation genetic diagnosis by PCR analysis: genotype comparison of the blastomere and corresponding embryo, implications for clinical practice. Mol. Hum. Reprod. 14 (10):573-579.doi: 10.1093/molehr/gan052. Retrieved from [http://molehr.oxfordjournals.org/content/14/10/573.short] </ref> <ref><pubmed>20966460</pubmed></ref><br />
|<br />
|}<br />
<br />
<br />
<br />
<br />
<br />
<br />
<br />
<br />
<br />
===Fluorescent In Situ Hybridisation (FISH)===<br />
<br />
<br />
====Description====<br />
Fluorescence in situ hybridization (FISH) the one of the most effective and rapid <ref name="PMID26338801"><pubmed>26338801</pubmed></ref> Preimplantation Genetic Diagnosis (PGD). This techniques used to locate a specific DNA sequences within a chromosome. FISH facilitates the clinical diagnosis of chromosomal abnormalities indicated by sequential duplications, deletions and rearrangements of chromosome, that are usually missed with microscopic analysis. This technique is especially relevant for female embryos with X-linked diseases,<ref><pubmed>20809319</pubmed></ref> that have no other mutation specific tests [http://www.ncbi.nlm.nih.gov/pubmed/20809319] As part of PGD, samples are collected from various stages of the embyro,and they are able to conducted tests on the blastocyst, a polar body biopsy and the blastomeres <ref><pubmed>21748341</pubmed></ref>. FISH is 99% effective when used in conjunction with competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities<ref name="PMID26338801"/>.<br />
<br />
====Procedure==== <br />
<br />
Samples are collected from either the blastocyst, a polar body biopsy or the blastomeres stages of the embryo <ref><pubmed>21748341</pubmed></ref>. <br />
DNA strands are heated and denatured causing their the individual DNA strands to break apart<br />
Probes are single complimentary stands of DNA a that have been tagged with small chemical agents that glow brightly in the presence of a specific region on a chromosome. These specific probes then hybridize and join to their complementary DNA strand. <br />
The fluorescent tags enable the researchers to correctly identify the presence or lack thereof and location of the specific chromosomes that they are testing for. <ref><pubmed>17876073</pubmed></ref><br />
Researcher analyse the results by identifying the number and the relative location of the fluorescent dots generated by the FISH images.<ref><pubmed>17970921</pubmed></ref><br />
The probe will not fully hybridise if there has been a duplication or a deletion of the DNA - indicating chromosomal and sex chromosomal anomalies like trisomies and aneuploidies. <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref><br />
<br />
<br />
Different probes are used for different purposes: <ref>Unique, Rare Chromosome Disorder Support Group (2013) Fluorescence in situ hybridisation (FISH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/Other/FISH%20FTNW.pdf]</ref><br />
*'''Locus specific tags''' detect very small imbalances, and locate isolated small portions <br />
of genes within a chromosome<br />
*'''Alphoid/Centomeric Repeat probes''' are developed from the repetitive sequence located in the middle region of each chromosome, useful in determining the number of chromosomes , detecting rearrangement and when used in conjunction with locus probes to determine the absence of genetic material on a chromosome. <br />
*'''Paint Probes''' are collections of smaller probes with their own stains that bind to a different section on the chromosome - allowing the full chromosome too be labeled a unique colour, this "full colour map" can be used to know the spectral karyotype- full chromosomal mapping is useful in examining chromosomal abnormalities. <br />
<br />
{|border="1" <br />
| [[File:Fluorescent In Situ Hybridisation (FISH).jpg|thumb|right|'''FISH''' We are able to tag Specific DNA sequences using Probes which have been tagged with fluorescent Labels.This technique enables the clinical diagnosis of chromosomal abnormalities, indicated by sequential duplication, deletions and rearrangements of chromosome <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref>]]<br />
|}<br />
<br />
<br />
<br />
{|border="1" align="center"<br />
|-bgcolor="pink" <br />
| rowspan="7" |'''Advantages''' <br />
| FISH is 99% effective when used in conjunction with Competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities.<ref><pubmed>26338801</pubmed></ref><br />
|-bgcolor="pink" <br />
| Rapid generation of results<br />
|-bgcolor="pink" <br />
| Identifies very small translocations and aneuploidies that occur within chromosomes, that would usually be missed under microscopic analysis<br />
|-bgcolor="pink" <br />
| Indicates whether the accessed chromosomes are normal <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|-bgcolor="pink" <br />
| Tests for the most common chromosomal abnormalities - down syndrome chromosomes 13,16,18,21 and 22 <ref><pubmed>21749752</pubmed></ref><br />
|-bgcolor="pink" <br />
| It may be used to compare the chromosomal gene arrangements in related species<br />
|-bgcolor="pink" <br />
| can be used to identify and remove inheritable X-linked disease or sex chromasome anomalies such as Duchennes Muscular Dystrophy, hemophilia, ectodermal dysplasia <ref><pubmed>17876073</pubmed></ref><br />
|-bgcolor="white"<br />
| rowspan="4"|'''Disadvantages'''<br />
| FISH destroys all cells tested <ref> O'Connor, C. (2008) Fluorescence in situ hybridization (FISH). Nature Education 1(1):171. retrieved from [http://www.nature.com/scitable/topicpage/fluorescence-in-situ-hybridization-fish-327] </ref><br />
|-<br />
| It does not fully access all chromosomes (only ~ 12)<br />
|-<br />
| Analysis of results is dependent upon the dot quality impacted by hybridisation efficiency or the camera sensitivity <ref><pubmed>17970921</pubmed></ref><br />
|-<br />
| some studies indicate that using FISH on a day-3 embryo biopsy decreases the rate of live births <ref><pubmed>26168107</pubmed></ref><br />
|}<br />
<br />
<br />
<br />
===Array Comparative Genomic Hybridisation (aCGH)===<br />
====Description====<br />
<br />
aCGH also known as Microarray analysis efficiently scans the entire genome for chromosomal imbalances. CGH was initially developed to detect the number of changes in a solid tumor mass. It uses 2 genomes comparing the sample to the control, with each labeled in a different fluorescent dye<ref><pubmed>1876176</pubmed></ref>. Earlier CGH techniques were limited by the resolution of the imaging <ref> Lichter, P., et al. Comparative genomic hybridization: Uses and limitations. Seminars in Hematology 37, 348–357 (2000)</ref> , these initial limitations were overcome by using Microarrays in conjunction with CGh to improve the resolution of the imaging, Array Comparative Genomic Hybridisation (aCGH). This method compares sample and control microarrayed slides containing small segments of DNA (probes). <ref> Lucito, R., et al. Representational oligonucleotide microarray analysis: A high-resolution method to detect genome copy number variation. Genome Research 13, 2291–2305 (2003) </ref> the Probes used will vary according from the small (25-85 base pairs) oligonucleotides manufactured to highlight different target sequences, to the very large genomic clones (80,000- 200,00 base pairs), and as these are significantly smaller than the traditional metaphase chromosomes used for CGH, generating a higher resolution of image. <ref><pubmed>22467166</pubmed></ref>.aCGH is used as a diagnostic tool for prenatal detection f chromosomal abnormalities <ref><pubmed>19012303</pubmed></ref>.<br />
<br />
<br />
====Procedure====<br />
<ref> Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432] </ref><br />
The sample is obtained (skin, blood or fetal cells) and DNA is obtained. <br />
As a part of PGD fetal cell samples are collected from; the fertilized egg polar bodies, the blastomere (day 3 embryo) or the blastocyst/tropoectoderm stage (day 5 embryo).<br />
Sample DNA is labeled with one fluorescent dye, and the control DNA is labeled with a different colored fluorescent dye. the control DNA is used as the base point of reference. <br />
heated and denatured single DNA strands then hybridize to their complementary single strand probes, which are then combined and applied to a microarray and the results are run through a computer program and a digital imaging system is used to quantify the results( fluorescent intensities of the labeled probes). <br />
<br />
simple explanation of aCGH : [Genomics Education (2014) Genetic Testing for Health: aCGH|https://vimeo.com/84757281]<br />
<ref>Genomics Education (2014) Genetic Testing for Health: aCGH [video file] Vimeo [https://vimeo.com/84757281]</ref><br />
<br />
<br />
The fluorescent ratio and the hybridization signal at different locations on the genome of the control DNA are used to identify any variances present in the sample DNA. aCGH facilitates the clinical diagnosis of submicroscopic chromosomal duplication, deletion and rearrangements indicative of chromosomal disorders such as trisomies 1-22and specific sex linked disorders. <br />
Duplications in the DNA are displayed by the computer program as spikes/ peaks over an established threshold and deletions in DNA are displayed by the computer program as spikes/ toughs beneath this threshold <br />
-computer screening image- <br />
-drawn diagram of method-<br />
<br />
<br />
<br />
{|border="1" align="center"<br />
|-bgcolor="pink" <br />
| '''Advantages''' <br />
| '''Disadvantages'''<br />
|-<br />
| multiple applications: prenatal genetic diagnosis, cancer diagnosis, <ref><pubmed>20193845</pubmed></ref> genetic screening for developmental delay (learning disabilities) <ref><pubmed>17309648</pubmed></ref>. or congenital anomalies that are suspected to be genetic in origin <ref>NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation . retrieved from [http://www.phgfoundation.org/file/5237/]</ref><br />
| translocations and inversions of DNA are not detected<br />
|-bgcolor="pink"<br />
| trace represents all chromosomes present in the human genome chromosomes 1-22 and the X & Y chromosomes, and therefore is the most accurate method for testing whole embryo aneuploidy<br />
| limited ability diagnosing specific polyploidies such as triploidy <ref> Unique, Rare Chromosome Disorder Support Group (2013) Microarray-based Comparative Genomic Hybridiation (array CGH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/other/array%20cgh%20ftnw.pdf] </ref><br />
|-<br />
| aCGH has been extensively tested, and Validated, and is now used world wide.<br />
| will not detect mosaicism detection <20% (cultures where >1 of 5 cells are trisomy 12)<br />
|-bgcolor="pink"<br />
| detects deletions and additions and rearrangements as well as amplification, of the WHOLE genome, simultaneously.<br />
| will not detect balanced chromosomal rearrangement<br />
|-<br />
| detects submicroscopic alterations<br />
| will not detect duplications or deletions <80kb<br />
|-bgcolor="pink"<br />
| used as a diagnostic tool for prenatal detection of chromosomal abnormalities <ref><pubmed>22034057</pubmed></ref><br />
| will not detect point mutations within genes <ref>Washington department of education (CGH- FAQ for physicians. Signature Genomic LAboratories, LLC. Retrieved from [https://depts.washington.edu/dbpeds/Lab%20Tests/SignatureCGH-physician_FAQ.pdf]</ref><br />
|-<br />
| provides high resolution genomewide screening of segmental genomic copy number variations<br />
| will not detect chromosomal position of genomic gains<br />
|-bgcolor="pink"<br />
| very accurate when used in conjunction with FISH<br />
| will not detect loos of heterozygosity (LOH) or Absence of heterozygosity (AOH) <ref>WiCell Research Institute Inc. (2012) Comparative Genomic Hybridization Microarray. <br />
retrieved from [http://www.wicell.org/home/cytogenetic-services/cgh-microarray/array-comparative-genomic-hybridization-acgh.cmsx]</ref><br />
|-style="background:pink"<br />
|Alone is more reliable and in detecting chromosomal abnormalities, with a higher implantation success rate, than FISH <ref><pubmed>20494259</pubmed></ref><br />
|<br />
|-bgcolor="pink"<br />
|Allows an in depth research focus upon specific types of rearrangements within selected chromosomal regions, a recent particular area of interest is subtelomeric and pericentromeric rearrangements<br />
|<br />
|-<br />
|reduces the risk of failed implantation and miscarriage, improving the chance of a healthy baby <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|<br />
|}<br />
<br />
<br />
<br />
===Next Generation Sequencing===<br />
====Description====<br />
The development and advances within ART in the past 20 years, as well as the increasing popularity of IV, has lead to an influx of new technologies developed to screen embryos for chromosomal anomalies, which are covered by the umbrella term of Next generation Sequencing (NGS). NGS is a general term used to describe all of the new and emerging screening techniques currently being introduced and used as part of PGD for IVF . NGS screens for single gene disorders as well as conducting extensive and very comprehensive chromosome diagnosis by sequencing, counting, and accurately assembling millions of DNA reads, simultaneously. <ref><pubmed>23499002</pubmed></ref> There is a movementfor NGS to replace the other limited testing techniques and be used as the standard. <br />
====Procedure====<br />
Samples are collected from either blastomere or the blastocyst/tropoectoderm and processed for analysis by a computer system. <br />
The methodology of each process is unique to the technique being used. <br />
<br />
<br />
<br />
{|border="1" align="center"<br />
|-bgcolor="pink" <br />
| '''Advantages'''<br />
| '''Disadvantages'''<br />
|-bgcolor="white"<br />
| cheaper<br />
| there are limited information available to clinical applications of NGS <ref><pubmed>26100406</pubmed></ref><br />
|-bgcolor="pink"<br />
| opens new diagnostic possibilities<br />
|<br />
|-bgcolor="white"<br />
| accurately tests all 24 chromosomes<br />
| <br />
|-bgcolor="pink"<br />
| tests for the presence of monogenic diseases of known genetic background<br />
| <br />
|-bgcolor="white"<br />
| reduces the number of biopsies required for diagnosis<br />
| <br />
|-bgcolor="pink"<br />
| higher detection rate of small translocations<br />
| <br />
|-bgcolor="white"<br />
| highly accurate is testing for compound point mutations, chromosomal duplication, deletions and insertions <ref><pubmed>23312231</pubmed></ref><br />
| <br />
|-bgcolor="pink"<br />
| it accurately detects chromosomal aneuploidy and unbalanced rearrangement <ref><pubmed>25685330</pubmed></ref><br />
| <br />
|-bgcolor="white"<br />
| NGS single gene disorder screenings can conducted in conjunction with PCR comprehensive chromosomal screening<br />
|<br />
|-bgcolor="pink"<br />
| Reduces human error <br />
|<br />
|-bgcolor="white"<br />
| better detects the presence of mosaicism<br />
|<br />
|-bgcolor="pink"<br />
| work well in conjunction with CGH and aCGH as part of PGD, improving the chances of IVF. <ref> Morris, R. S. (2015 ) Next generation sequencing for PCG|PGS|CCS. IVF1 retrieved from [http://www.ivf1.com/next-generation-sequencing for-pgd] </ref><br />
|<br />
|}<br />
<br />
<br />
<br />
<br />
<br />
<br />
==Diagnosis==<br />
There are a large amount of diseases that PGD can apply to, below are descriptions of the diseases that PGD are more commonly used for. <br />
===Cystic Fibrosis===<br />
Cystic fibrosis is a single gene disorder. It is autosomal recessive and involves mutations in the cystic fibrosis transmembrane conductance regulator (CTFR) gene. The CTFR gene is normally responsible for the decrease in chloride and the transport of bicarbonate in epithelial cells thus playing a major physiological role. In PGD procedures, identification of the gene is assisted by microsatellite markers that have similar composition to the CTFR gene itself. Biopsy of two cells at the blastocyst stage is recommended if markers are not available. There are many variations of cystic fibrosis the most common being P.Phe508del <ref name="PMID26014425"><pubmed>26014425</pubmed></ref>.<br />
===Duchenne Muscular Dystrophy ===<br />
Duchenne Muscular Dystrophy is an X-linked recessive disease. It involves the Xp21 gene where majority of the mutations are chromosomal deletions with a smaller percentage resulting from duplications <ref name="PMID18359022"><pubmed>18359022</pubmed></ref>.<br />
===β – Thalassemia=== <br />
β – Thalassemia is known as the most common type of autosomal recessive inherited disorder among haemoglobinopathies. It involves the adult β-globin gene and is associated with the absent or decreased expression of the gene. This is commonly caused by a single nucleotide change in the gene. PGD has been used successfully worldwide to identify the β-globin gene where its application is usually performed on a single blastomere or polar body <ref name="PMID19064120">19064120</pubmed></ref>.<br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
! Applicable diseases for PGD <ref>Genoma Group (2014). Retrieved September 18th, 2015, from http://www.preimplantationgeneticdiagnosis.it/genetic-diseases-diagnosed-by-pgd.htm </ref>, <ref>Genesis Genetics (2015). Retrieved September 18th, 2015, from http://genesisgenetics.org/pgd/what-we-test-for/</ref>, <ref>Human Fertilisation & Embryology Authority (2015). Retrieved Septembr 18th, 2015, from http://guide.hfea.gov.uk/pgd/</ref><br />
| '''Disease'''<br />
| '''Involved Genes'''<br />
|-<br />
| 5 Alpha Reductase Deficiency (5ARD)<br />
| SRD5A2 <br />
|-<br />
| Achondroplasia<br />
|FGFR3 <br />
|-<br />
| Acute Intermittent Porphyria <br />
| ALAD, ALAS2, CPOX, FECH, HMBS, PPOX, UROD, or UROS<br />
|-<br />
| Adrenoleukodystrophy (Adrenomyeloneuropathy)<br />
| ABCD1 <br />
|-<br />
| Agammaglobulinaemia (x-linked) <br />
|BTK <br />
|-<br />
| Agammaglobulinemia Bruton Tyrosine Kinase (BTK) <br />
|BTK <br />
|-<br />
| Aicardi Goutieres Syndrome 1 (AGS1) <br />
|TREX1, RNASEH2A, RNASEH2B, RNASEH2C, SAMHD1<br />
|-<br />
| Alagille Syndrome<br />
|JAG1 or NOTCH2<br />
|- <br />
| Alpers-Huttenlocher Syndrome <br />
|POLG <br />
|-<br />
| Alpha-1-antitrypsin deficiency <br />
|SERPINA1 <br />
|-<br />
| Alpha-Mannosidosis<br />
| MAN2B1 <br />
|-<br />
| Alpha Thalassemia <br />
|HBA1 or HBA2 <br />
|-<br />
| Alports Syndrome<br />
|COL4A3, COL4A4, COL4A5<br />
|-<br />
| Alzheimer's Disease - early onset (Type 3 and 4) <br />
|APP, PSEN1, or PSEN2<br />
|-<br />
| Amyotrophic Lateral Sclerosis 1 (ALS1) <br />
|C9orf72, SOD1, TARDBP, FUS, ANG, ALS2, SETX, VAPB <br />
|-<br />
| Argininosuccinic Aciduria <br />
| ASL<br />
|-<br />
| Arrhythmogenic Right Ventricular Cardiomyopathy/ Dysplasia (ARVC/D)<br />
| DSG2; DSP; PKP2<br />
|-<br />
| Ataxia Telangiectasia<br />
| ATM<br />
|-<br />
| Bardet-Biedl Syndrome (BBS)<br />
| BBS1; BBS10<br />
|-<br />
| Barth Syndrome<br />
| TAZ<br />
|-<br />
| Beta Thalassaemia<br />
| HBB<br />
|-<br />
| Birt-Hogg-Dubé Syndrome<br />
| FLCN<br />
|-<br />
| Breast Ovarian Cancer Familial Susceptibility (BRCA2)<br />
| BRCA1; BRCA2<br />
|-<br />
| Canavan Disease <br />
| ASPA<br />
|-<br />
| Carnitine-Acylcarnitine Translocase Deficiency <br />
| SLC25A20<br />
|-<br />
| Cerebral Arteriopathy with Subcortical Infarcts & Leukoencephalopathy (CADASIL)<br />
| NOTCH3<br />
|-<br />
| Cerebral Cavernous Malformation<br />
| CCM1<br />
|-<br />
| Charcot-Marie-Tooth Disease<br />
| GJB1; MPZ; NEFL; PMP22<br />
|-<br />
| CHARGE Syndrome<br />
| CHD7<br />
|-<br />
| Cherubism<br />
| SH3BP2<br />
|-<br />
| Choroideremia<br />
| CHM<br />
|-<br />
| Chronic Granulomatous Disease<br />
| CYBB; NCF1<br />
|-<br />
| Ciliary Dyskinesia<br />
| DNAH5<br />
|-<br />
| Citrullinemia<br />
| ASS1<br />
|-<br />
| Cleidocranial Dysplasia<br />
| RUNX2<br />
|-<br />
| Cockayne Syndrome<br />
| ERCC6<br />
|-<br />
| Congenital Adrenal Hyperplasia<br />
| CYP21A2<br />
|-<br />
| Congenital Cataracts<br />
| GJA8; VSX2<br />
|-<br />
| Congenital Diarrhea, Syndromic<br />
| SPINT2<br />
|-<br />
| Congenital Disorders of Glycosylation (CDG)<br />
| ALG1; ALG6; CDG1C; DOLK; PMM2<br />
|-<br />
| Cornelia de Lange Syndrome <br />
| NIPBL<br />
|-<br />
| Craniosynostosis<br />
| TWIST1<br />
|-<br />
| Crouzon Syndrome<br />
| FGFR2<br />
|-<br />
| Cysteinyl Leukotriene Receptor 1 Deficiency <br />
| CYSLTR1<br />
|-<br />
| Cystic Fibrosis<br />
| CFTR<br />
|-<br />
| Diamond –Blackfan Anemia <br />
| RPS19<br />
|-<br />
| Duchenne Muscular Dystrophy <br />
| DMD<br />
|-<br />
| Dyskeratosis congenita (Male embryos only)<br />
| DKC1<br />
|-<br />
| Ectodermal dysplasia (Hypohidrotic)<br />
| EDA; EDA1; GJB6; IKBKG<br />
|-<br />
| Familial Adenomatous polyposis coli (FAP)<br />
| APC<br />
|-<br />
| Familial Dysautonomia<br />
| IKBKAP<br />
|-<br />
| Fanconi Anemia <br />
| FANCA; FANCC; FANCD2; FANCF; FANCG; FANCJ<br />
|-<br />
| Fragile X Syndrome (FRAX)<br />
| FMR1<br />
|-<br />
| Galactosemia <br />
| GALT<br />
|-<br />
| Gangliosidosis<br />
| GLB1<br />
|-<br />
| Glanzmann Thrombasthenia <br />
| ITGA2B<br />
|-<br />
| Glutaric Acidemia (aciduria)<br />
| GCDH <br />
|-<br />
| Glycogen Storage Disease <br />
| G6PC; GAA; SLC37A4<br />
|-<br />
| Haemophilia A<br />
| F8<br />
|-<br />
| Haemophilia B<br />
| F9<br />
|-<br />
| Hereditary Nonpolyposis Colorectal Cancer: Lynch Syndrome<br />
| MLH1; MSH2; MSH6<br />
|-<br />
| Holt Oram Syndrome<br />
| TBX5<br />
|-<br />
| Huntington Disease<br />
| HD<br />
|-<br />
| Hydrocephalus<br />
| L1CAM<br />
|-<br />
| Ichthyosis <br />
| ABCA12; STS<br />
|-<br />
| Incontinentia Pigmenti (IP)<br />
| NEMO<br />
|-<br />
| Joubert Syndrome 5<br />
| INPP5E<br />
|-<br />
| Krabbe Disease<br />
| GALC<br />
|-<br />
| Leber Congenital Amaurosis (LCA)<br />
| CEP290; GUCY2D<br />
|-<br />
| Leigh Syndrome (Infantile Subacute Necrotising Encephalopathy)<br />
| LRPPRC<br />
|-<br />
| Lesch Nyan Syndrome<br />
| HPRT1<br />
|-<br />
| Leukocyte Adhesion Deficiency (Type I)<br />
| ITGB2<br />
|-<br />
| Li-Fraumeni Syndrome<br />
| TP53<br />
|-<br />
| Macular Dystrophy Retinal <br />
| VMD2<br />
|-<br />
| Maple Syrup Urine Disorder (MSUD)<br />
| BCKDHB<br />
|-<br />
| Marfan Syndrome <br />
| FBN1<br />
|-<br />
| Menkes Syndrome<br />
| ATP7A<br />
|-<br />
| Mitochondrial DNA Depletion Syndrom <br />
| POLG; RRM2B; SUCLA2; TK2<br />
|-<br />
| Mucolipidosis type II<br />
| GNPTAB<br />
|-<br />
| Multiple Endocrine Neoplasia<br />
| MEN1; MEN2A; MEN2B<br />
|-<br />
| Multiple Exostoses<br />
| EXT1; EXT2 <br />
|-<br />
| Myotubular myopathy<br />
| MTM1 <br />
|-<br />
| Nail-Patella Syndrome<br />
| LMX1B<br />
|-<br />
| Neurofibromatosis Type 1<br />
| NF1<br />
|-<br />
| Neurofibromatosis Type 2 <br />
| NF2<br />
|-<br />
| Noonan Syndrome<br />
| KRAS, PTPN11; SOS1<br />
|-<br />
| Norrie Disease<br />
| NDP<br />
|-<br />
| Ocular Albinism <br />
| GPR143<br />
|-<br />
| Oculocutaneous Albinism <br />
| OCA2; TYR <br />
|-<br />
| Oculodentaldigital Dysplasia<br />
| GJA1<br />
|-<br />
| Optic Atrophy<br />
| OPA1<br />
|-<br />
| Ornithine Transcarbamylase Deficiency <br />
| OTC<br />
|-<br />
| Osteogenesis imperfeca <br />
| COL1A1; COL1A2<br />
|-<br />
| Osteopetrosis <br />
| CLCN7; OSTM1; TCIRG1<br />
|-<br />
| Pachyonychia Congenita <br />
| KRT16; KRT6A<br />
|-<br />
| Pancreatitis, Hereditary<br />
| PRSS1 <br />
|-<br />
| Papillorenal syndrome <br />
| PAX2<br />
|-<br />
| Phenylketonuria <br />
| PAH <br />
|-<br />
| This table does not cover the complete list of diseases that PGD can be applied to.<br />
|}<br />
<br />
==Laws & Legal status==<br />
===Australia=== <br />
PGD is currently used to detect serious genetic conditions to improve the outcome of Assisted Reproductive Technologies (ART). In very rare cases it may be used to select an embryo with compatible tissue for a sibling who has a life-threatening disease where other means of treatment is unavailable. This is with the conditions that the use of PGD will not affect the welfare and interests of the child to be born. The parents must also receive adequate counselling and have full understanding of the procedures of PGD. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"> National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art</ref><br />
The use of PGD for sex-selection is prohibited with the exception of reducing the risk of the transmission of serious sex-linked genetic conditions. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"/><br />
===Brazil=== <br />
The laws regarding PGD in Brazil are not strictly regulated. They are vague and there is limited information surround the activities of assisted reproduction in general in the country <ref name="PMID25493379"><pubmed>25493379</pubmed></ref>.<br />
===Czech Republic===<br />
The laws in the Czech Republic allow those with a “defined indication in order to exclude risk of serous genetically conditioned disease and defects with embryos before they are implanted into the cavity of the uterus”. Couples that undergo any assisted reproductive treatment including PGD have to be married. Sex-selection is illegal except in regards to serious sex-linked genetic diseases <ref name="PMID24777348"><pubmed>24777348</pubmed></ref>.<br />
===Greece=== <br />
In Greece, ART is open to those up to the age of 50 with written consent. It can only be used if a medical necessity is present such as the susceptibility of serious hereditary diseases. Sex selection is banned apart from cases of sex-linked diseases and sexually transmitted diseases <ref name="PMID24777348"/>.<br />
===Portugal=== <br />
ART is only available to those who are married or have a similar type of relationship for at least two years. The couples cannot be of the same sex and must be at least 18 years of age. Sex selection is illegal except in cases of sex-linked diseases. The use of PGD is illegal if the predictive value of genetic tests are very low <ref name="PMID24777348"/>.<br />
===Spain===<br />
PGD can be applied to “serious hereditary diseases not amenable to postnatal curative treatment” and “detection of other abnormalities which may compromise the viability of the pre-embryo”. If PGD is to be used for any other purpose authorisation must be acquired <ref name="PMID24777348"/>.<br />
===Sweden=== <br />
The use of PGD is strictly regulated and couples must achieve authorisation of the National Board of Health and Welfare. It can only be used it can only be used if the child is at risk to inheriting a serious chromosomal or monogenetic disease. It cannot be used for selection of specific characteristics <ref name="PMID24777348"/>.<br />
===United Kingdom===<br />
Those involved with carrying out the IVF treatment must have a license from the Human Fertilisation and Embryology Authority (HFEA). Only embryos that are approved by the HFEA can be implanted where the embryonic nuclear or mitochondrial DNA cannot be altered with the exception of preventing mitochondrial diseases <ref name="PMID24777348"/>. <br />
==Future/Current Research==<br />
===Noninvasive Preimplantation Genetic Testing without Embryo Biopsy===<br />
Different parameters of gametes, zygotes, embryos (“vacuoles in sperm heads, spindle position in mature oocytes, cleavage intervals of zygote, and embryo developmental dynamics”) may correlate with aneuploidy rates. This knowledge may be applied in potential noninvasive preimplantation diagnostic methods. Several methods have been proposed and are currently further researched<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Sperm Selection====<br />
Intracytoplasmic morphologically selected sperm injection (IMSI) is common procedure in IVF treatment to improve fertilization rates in patients with poor semen quality. In addition, studies have found that IMSI improves embryo development and that spermatozoa with large vacuoles in their heads correlate with increased aneuploidy rates and disturbed chromosomal structures. Thus, selecting spermatozoa based on morphological hallmarks may decrease aneuploidy rates in the fertilized embryos. As with polar body biopsies, however, this approach will solely be applicable if evidence for severe male detrimental contribution is given<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Blastocoel Fluid Extraction====<br />
In addition, a less invasive retrieval of material for diagnosis could include the extraction of the blastocoel fluid. The cavity of the blastocyst, lined by the trophectoderm, is filled with this blastocoel fluid, which contains metabolites of both trophectoderm and inner cell mass origin. The retrieval does not require a biopsy but merely a small opening to extract the fluid and, thus, causes less harm to the embryo. Multiple studies have applied this method<ref name="PMID22020776"><pubmed>22020776</pubmed></ref> <ref name="PMID23148560"><pubmed>23148560</pubmed></ref> and it may in the future become of clinical relevance.<br />
<br />
{|border="1"<br />
| [[File:Aspiration_of_the_Blastocoel_Fluid.jpeg]]<br />
|-<br />
| Aspiration of the Blastocoel Fluid using a ICSI pipette<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
|}<br />
<br />
<br />
Next to metabolites, the blastocoel fluid can contain DNA. Studies have shown that genomic DNA is present in about 90% of the blastocoel fluid samples tested. Typically the fluid is removed with an ICSI pipette from a day five blastocyst through its mural trophectoderm until the blastocyst fully collapses around the embryo. Several concerns regarding this method in a clinical setting have been raised. The collected DNA may be contaminated by the culture media that contains DNA fractions. The DNA may also be least representative of the actual embryos genome as the DNA may originate from abnormal or degenerated cells. Even though labelled noninvasive, the blastocyst still undergoes manipulation to some degree which may affect its viability. Thus, more research is required until this method can evolve from research to clinical use<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
====Proteomics====<br />
The protein secretome of blastocysts may be representative of its chromosome constitution Recent studies have found biomarkers such as lipocalin-1, interleukin-10, tumor necrosis factor, stem cell factor, and chemokine ligand 13 to be differently secreted by aneuploid blastocyst than by euploid ones. The most significant biomarker appears to be interleukin-10. Paired with novel proteomic technologies and mass spectrometry this knowledge when extended may contribute to a new invasive preimplantation genetic diagnosis method<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Embryo Morphology====<br />
Using time lapse imaging the embryo’s morphology can be closely observed and potential aneuploidy characteristics detected. Such characteristics may include the time of division to five cells, the time between the division from three to four cells, and the duration of the division from one to two and subsequently to three. In addition, the morphological quality of ICM an TE has been positively associated with aneuploidy or euploidy prognosis<ref name="PMID26246880"><pubmed>26246880</pubmed></ref>. These may give rise to an embryo quality screening prior to implantation<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
===Utilization of Diseased Cell Lines===<br />
==Ethics==<br />
==References==<br />
<br />
<references/><br />
<br />
<br />
{{StudentPage2015}}</div>Z5017878https://embryology.med.unsw.edu.au/embryology/index.php?title=2015_Group_Project_6&diff=2065512015 Group Project 62015-10-19T11:50:52Z<p>Z5017878: </p>
<hr />
<div>{{ANAT2341Project2015header}}<br />
<br />
<br />
=Prenatal Genetic Diagnosis=<br />
==Introduction==<br />
==History==<br />
Prenatal Genetic Diagnosis was historically conducted post-implantation in the first 2 trimesters <ref> Blackburn, S.L. (2003) '''Maternal, Fetal & Neonatal physiology: a Clinical perspective''' (2nd ed.). Seattle: Saudners </ref>, testing for overall fetal growth, complications of pregnancy, birth defects as well as chromosomal or genetic abnormalities<ref> Sadler T.W.(2012) '''Langman's Medical Embryology''' (12th ed.) Philadelphia: Lipincott, Wiliams & Wilkins, a Wolters Kluwer Business </ref>. Due to advancements in Artificial Reproductive Technologies ( ART) in the past 2 decades , these genetic tests are now conducted as a part of Preimplantation Genetic Diagnosis (PGD) <ref><pubmed>20638568</pubmed></ref> and art used to eliminate the rsik of passing on a genetic disorder to an offspring, before implantation, it ha now become a preventative measure. . In 1990 Preimplantation genetic testing was first used in 1990 on humans to diagnose recessive X-linked diseases in the embryos of pregnant women undergoing IVF. <ref><pubmed>2330030</pubmed></ref> PGD is offered as an alternative to prenatal diagnosis in detecting genetic disorders in high risk couples <ref><pubmed>26168107</pubmed></ref> and avoid passing an inherited disease to the offspring, by selecting genetically "normal" embryos for implantation ,to give the best chance of successful implantation , stable pregnancies and healthy children. <br />
<ref><pubmed>23499002</pubmed></ref><br />
<br />
==Preimplantation Genetic Diagnosis==<br />
[[File:Preimplantation Genetic Diagnosis Procedure.jpeg|700px|thumb|centre| Simplified steps for PGD]]<br />
<br />
<br />
Preimplantation genetic diagnosis (PGD) is used to test the genetic makeup of embryos to detect single gene disorders, chromosomal abnormalities and mitochondrial disorders. It also has applications in gender selection for diseases with unequal gender distributions <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Some diseases commonly involved with PGD include cystic fibrosis, spinal muscular atrophy and beta – thalassaemia <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press.">Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press</ref> <ref name="PMID17823145"><pubmed>17823145</pubmed></ref>. It was first used in the United Kingdom in the 1980s of arenoleucodystrophy and primarily focusing on sex- linked disorders <ref name="PMID17823145"/><ref name="PMID23150080"><pubmed>23150080</pubmed></ref>. PGD is now capable of detecting single cell defects (molecular) and chromosomal disorders resulting from the inversion, translocation or deletion of chromosomes (cytogenic) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>,<ref name="PMID11325751"><pubmed>11325751</pubmed></ref>. PGD can be applied to the embryo at different stages. That is on polar bodies, blastomeres or blastocyst <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>.<br />
Depending on the type of genetic disorder, PGD utilises different methods of genetic testing. These include Fluorescence in situ hybridisation (FISH) which is used for sex – linked disorders and detects chromosomal rearrangements <ref name="PMID11325751"/><ref name="PMID17876073"><pubmed>17876073</pubmed></ref> and Embryo halotyping which allows the identification of chromosomes causing the inherited disorder through knowledge of the pattern of closely linked markers <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. Polymerase chain reaction (PCR) is also widely used to detect molecular abnormalities <ref name="PMID11325751"/>.<br />
PGD is tightly regulated and supported by large organisations namely The American Society for Reproductive Medicine, The European Society for Human Reproduction and Embryology (ESHRE), The European Society of Human Genetics and the Preimplantation Genetic Diagnosis International Society <ref name="PMID25500181><pubmed>25500181</pubmed></ref>.<br />
===Sex-linked disorders===<br />
The determination of a disease as gender specific usually correlates with the presence or absence of specific genes such as SRY on the Y chromosome. It is known that females have two X chromosomes and males have an X and a Y chromosome where abnormalities are more prevalent on the X chromosome. PGD can be used for sex selection where only male embryos are transferred to reduce the chance of inheriting X-linked disorders. However, this does not completely eradicate the problem as male embryos remain susceptible to inheriting an affected X chromosome. Sex determination is only used when the specific mutation is unknown and has yet to be discovered <ref name="PMID24866878"><pubmed>24866878</pubmed></ref>.<br />
===Single gene defects===<br />
Single gene defects can be dominant, recessive, autosomal or X-linked. They are commonly diagnosed using PCR and although the PCR available today is complex and capable of combatting a large range of disease the development of new protocols has been proven to be difficult due to the small DNA sample available <ref name="PMID26168107"><pubmed>26168107</pubmed></ref><br />
===Mitochondrial disorders===<br />
Mitochondrial disorders also known as oxidative phosphorylation disorders arise from mutations in the nuclear DNA or mitochondrial DNA <ref name="PMID26312584"><pubmed>26312584</pubmed></ref>. They pose as a problem because they are unrecognisable until the mutations in the cell reach a detrimental level <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Mitochondrial disorders cause miscarriages and stillbirths as well as death in children and young adults. The effects can either be contained in a single organ or more commonly involve multiple organ failure where organs with high energy demands such as the brain, liver muscle and heart and heavily influenced. They are usually occur spontaneously or result from inheritance from the mother. Since mitochondria are solely inherited from the mother oocyte donations have been used as a solution to combat mitochondrial disorders. Additionally, there has been an increasing use in PGD where embryos that stay under the given threshold of 18% gene-mutations are allowed to be transferred and result in normal development. New technology in the areas of nuclear gene transfer and genome editing are also being experimented with <ref name="PMID26312584"/>. <br />
===Chromosomal disorders===<br />
Chromosomal disorders can be reciprocal, Robertsonian translocations, inversions, deletions and insertions <ref name="PMID26168107"/>. . Data from ESHRE collected between 2010 and 2011 has shown that the most common chromosomal abnormality confronted in PGD are reciprocal chromosomal abnormalities <ref name"PMID26071418"><pubmed>26071418</pubmed></ref>. PGD has also been used successfully for Robertsonian translocations (RT), a type of structural translocation. Children who carry RT are phenotypically normal, however in their later years it is found that they will suffer from infertility and repeated miscarriages due to the high frequency of abnormal embryos <ref name="PMID22081077"><pubmed>22081077</pubmed></ref>. PCR and FISH are the two main techniques used for chromosomal disorders. To be able to conduct the examinations the cells are required to be at the metaphase stage <ref name="PMID26168107"/>. <br />
==Preimplantation Genetic Screening==<br />
Prenatal Genetic Screening (PGS) involves an array of methods or ideas that aim to segregate embryos that have genetic flaws and those that are healthy <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. The occurrence of aneuploidy is high around the stages of early embryonic development and they are the most common cause if miscarriages and congenital birth defects <ref name= "PMID26085841"><pubmed>26085841</pubmed></ref>. They have little effect on the morphology of the embryo making them difficult to identify thus identification heavily relies on genetic testing <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. <br />
Genetic sampling is most commonly conducted using Microarray Comparative Genomic Hybridisation (aCGH) as well as FISH, Quantitative PCR and Single Nucleotide Polymorphism (SNP) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. These methods collectively aim to assess numeral and structural chromosomal errors <ref name= "PMID26085841"/>. Studies have also introduced Next- Generation Sequencing (NGS) <ref name= "PMID26085841"/> and Whole Genome Amplification used to screen imbalances in the complete 24-chromosomes <ref name="PMID25953353"><pubmed>25953353</pubmed></ref><br />
Statistics from ESHRE have shown that the most common indications for PGS is advanced age, followed by repeated implantation failure or recurrent miscarriage and male infertility <ref name="PMID26071418"><pubmed>26071418</pubmed></ref>.<br />
====Indications====<br />
A low percentage of structural abnormalities in chromosomes are responsible for the cause of miscarriages. Despite this, they are the most prevalent type of chromosomal abnormality accounted for in PGD <ref name="PMID20638568"/>. The presence of specific gene cycles, initiation of embryonic protein synthesis and evident physiological development are all indicative of a successful in vitro fertilisation procedure <ref name="PMID11576737"><pubmed>11576737</pubmed></ref>. To eliminate further errors from occurring during the PGD procedure it is recommended to undertake further prenatal testing such as amniocentesis in the later stages <ref name="PMID20638568"/>. <br />
=====Advanced maternal age=====<br />
Data provided by the ESHRE has shown that the mean age of women undergoing PGS is 39 years <ref name="PMID26071418"/>. Women of advanced age have been shown to have a lower rate of pregnancies reaching childbirth <ref name="PMID18583331"><pubmed>18583331</pubmed></ref>. The highlighted concern revolves around the increased occurrence of aneuploidy following maternal age. The optimal age range for the lowest aneuploidy incidence was found to be between 27 to 37 years of age (6%) then progressively higher in women aged up to 42 (33%) and most common in those 44 and above (53%) <ref name="PMID24355045"><pubmed>24355045</pubmed></ref>. <br />
=====Recurrent pregnancy loss / IVF failure=====<br />
Recurrent pregnancy loss is defined as three or more IVF failures after cumulative transfer of more than 10 good-quality embryos. These are primarily caused by two main factors, reduced endometrium receptivity or embryonic defects. Endometrium receptivity can be negatively influences by instances including uterine pathologies such as thin endometrium, altered expression of adhesive molecules and immunological factors. Additionally, embryonic defects may be due to genetic abnormalities, embryonic aneuploidy or zona hardening. Endometriosis and hydrosalpinx has been known to effect both the endometrium and embryo <ref name="PMID23260857"><pubmed>23260857</pubmed></ref>.<br />
=====Human leukocyte antigen matching=====<br />
First used in 2001, HLA matching is an option given to parents to save a child with haematological or immunological disease through conceiving another child who would potentially be able to donate cord blood or haematopoietic stem cells from the bone marrow for transplantation. The process namely PGD-HLA has shown to improve haematopoietic stem cell transplant (HSCT). PGD-HLA can only be performed when HSCT is not needed urgently due to the time needed to conceive and delivery the baby <ref name="PMID25500181"><pubmed>25500181</pubmed></ref>. It is most commonly applied to children suffering from relapsed leukaemia <ref name="PMID22524201"><pubmed>22524201</pubmed></ref>. In a case study PGD-HLA was proven to successfully cure 10 diseases including Fanconi anaemia, Diamond-Blackfan anaemia and beta thalassemia <ref name="PMID25066893><pubmed>25066893</pubmed></ref>.<br />
==Biopsy Methods==<br />
Biopsy, the removal of genetic materials, from oocytes or embryos in the preimplantation stage is the primary step in PGD. For the past two decades these biopsies have been performed at three stages, the polar body, blastomere, and blastocyst, and the methodologies optimized to ensure the embryo’s viability. The most common approach involves biopsies at the cleavage stage. However, polar body and blastocyst biopsies are increasingly more often tested and applied. Approached for opening the zona pellucida involve next to the traditional mechanical and chemical means, novel approaches such as noncontact lasers. Their application may simplify and secure the procedure significantly. The most challenging question about PGD procedures remains at what stage biopsies should be taken. Much controversy has developed around this topic, highlighting the varying disadvantages and advantages of temporal biopsies. <ref name="PMID22723007"><pubmed>22723007</pubmed></ref><br />
<br />
{|border="1" align="left"<br />
|-bgcolor="pink" <br />
|<br />
| Time of Biopsy<br />
| Advantages <br />
| Disadvantages<br />
|- <br />
| Polar Body<br />
| Day 1<br />
| No harm to oocyte<br />
| Only maternal DNA is tested, often needs to be coupled with other biopsies<br />
|-bgcolor="pink"<br />
| Blastomere<br />
| Day 3<br />
| …<br />
| … <br />
|-<br />
| Trophectoderm<br />
| Day 5 and 6 <br />
| Little harm, large amount of genetic material<br />
| Opening of blastocyst necessary, small time window for procedure<br />
|}<br />
<br />
{|border="1"<br />
| [[File:Polar_Body,_Blastomere,_and_Trophectoderm_Biopsy.jpeg]]<br />
|-<br />
| Polar body (A), blastomere (B) and trophectoderm (C) biopsies<ref name="PMID25625041"><pubmed>25625041</pubmed></ref>.<br />
|}<br />
<br />
PMID 24305177<br />
===Polar Body Analysis===<br />
Day 1<br />
====Description====<br />
Polar body (PB) biopsy, which was introduced in 1990, offers a promising alternative to biopsies performed at the blastomere stage for PGD/S indications on legal and practical grounds. <br />
Description: Consequent embryo development does not necessitate the presence of the first and second PB and their removal may not be crucial. PB biopsy requires precise timing. Keeping track of the meiotic cell cycle is necessary to perform a successful biopsy and, therefore, PB biopsy usually is applied in combination with intracytoplasmic sperm injection (ICSI). During the maturation from the germinal vesicle stage to the metaphase-II stage the first PB is formed. A cytoplasmic bridge containing spindle remnants, that are still in contact with the cellular genetic material, links this PB to the oolemma for about 90 minutes after extrusion. It is possible to visualize these remnants by polarization microscopy and it is crucial to not perform the biopsy until the first PB is no longer firmly attached to the oolemma as this indicates an immature embryo.The oocyte tolerates mechanical zona dissection best during hours four until six after ICSI as the oolemma has stabilized by that time because of the cortical granule reaction. Over time the first PB degenerates stressing a temporal biopsy and its optimal extraction time window is four to 12 hours after ICSI. The second PB forms around two to four hours after ICSI. However, its optimal time window for biopsy is set to be eight to 16 hours after ICSI. This is due to the second PB being attached to the oolemma with spindle remnants until six hours after ICSI. Biopsy at this point may cause enucleation of the oocyte. In addition, studies have shown that the amplification efficiency of second PB’s DNA is worse if the PB is extracted prior to eight hours after ICSI. <br />
Thus, it is possible to perform sequential and simultaneous biopsies for the first and second PB. If performed, sequentially the first PB may be removed four to 12 hours and the second PB eight to 16 hours after ICSI. The optimal time window for a biopsy for both the first and second PB simultaneously is eight to 12 hours after ICSI. It is highly preferred to analyze both PBs due to potential aneuploidies in either PB and crossing overs during meiosis<ref name="PMID22723007"/>. <br />
====Procedure====<br />
Chemical opening achieved with for example acidic tyrode’s solution of the zona pellucida is not tolerated by the oocyte and may have detrimental effects on the embryo’s development. Therefore, the access to the perivitelline space of the oocyte is provided by mechanical zona dissection or by laser. Both techniques work well if performed by experienced embryologist. However, laser-assisted biopsy is less time consuming when compared to manual dissection. It is critical to consider the size of the introduced opening as it will remain permanent. If it is too large the blastomere may be lost during embryo development and if it is too small it may interfere with hatching of the embryo during blastocyst stage<ref name="PMID22723007"/><br />
<br />
{|border="1"<br />
| [[File:Polar_Body_Biopsy.jpeg]]<br />
|-<br />
| The presence of a faint but clearly identifiable strand connecting PB2 to the <br />
oolemma. The biopsy was performed ∼9 h after ICSI<ref name="PMID21908464"><pubmed>21908464</pubmed></ref>.<br />
|}<br />
<br />
{|border="1"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JTaQzszVr8o</html5media><br />
|-<br />
| Laser-assisted polar body biopsy<ref>RIUK, R. (2013, June 25) Polar Body Biopsy [Video file]. Retrieved from https://www.youtube.com/watch?v=JTaQzszVr8o</ref><br />
|}<br />
<br />
====Advantages & Disadvantages====<br />
PB biopsies can only investigate the maternal contributions to the embryo as they are of maternal origin. Thus, this procedure is appropriate for PGD solely for monogenetic diseases from the maternal side. Recessive diseases may be evaluated with PB biopsies on the basis that the embryo’s outcome will be determined by the paternal contribution. (...) It may still be applied for PGS as most aneuploidies either arise during meiosis or origin from the maternal genome. However, diagnosis error has been reported due to the lack of considering paternal contributions. <br />
Because PB biopsies are performed very early it is not yet known whether the oocyte will develop into a viable embryo. Thus, PBs are commonly frozen or fixed after biopsy and depending on the state of the embryo only chosen PBs will be tested. This is primarily an economic issue as many genetic testing procedures are very cost-intensive<ref name="PMID22723007"/>.<br />
<br />
{|border="1"<br />
| [[File:Implantation_predictive_value_of_euploid_screening_results.jpeg]]<br />
|-<br />
| The sustained implantation predictive value (with 95 % confidence interval) of a euploid screening result obtained from the first polar body (PB1), PB1 and the second polar body (PB2), or a direct embryo biopsy for each stage of embryo transfer (cleavage-stage and blastocyst stage)<ref name="PMID25106935"><pubmed>25106935</pubmed></ref>.<br />
|}<br />
<br />
===Blastomere biopsy===<br />
Day 3 <br />
====Description====<br />
Blastomere biopsy has been the prevalent method for PGD and PGS in the last two decades. At least one, but up to two, blastomeres are biopsied on day three of the cleavage stage embryo. The right number of blastomeres removed is a controversial topic as two cells allow for more genetic material and more accurate results. However, removing two cells might be too invasive and damaging to the embryo. (Study)<ref name="PMID21748341"><pubmed>21748341</pubmed></ref><br />
====Procedure====<br />
Initially a hole was drilled into the zona pellucida using acid tyrodes and the blastomeres are removed via aspiration with a pipette<ref name="PMID21748341"/>.<br />
<br />
{|border="1"<br />
| [[File:Aspiration_of_a_Blastomere.jpeg]]<br />
|-<br />
| Aspiration of a Blastomere into the biopsy pipette<ref name=" PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
|}<br />
<br />
{|border="1"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=TbridWVwipI</html5media><br />
|-<br />
| Laser-assisted blastomere biopsy<ref>Sukprasert, M. (2014, March 5) Day 3 Blastomere Biopsy 1 [Video file]. Retrieved from https://www.youtube.com/watch?v=TbridWVwipI</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
===Trophectoderm biopsy===<br />
Day 5 and 6<br />
====Description====<br />
The improvement of embryo culture media allowed the in vitro development of human embryos until the blastocyst stage and opened up the possibility to take blastocyst biopsies. During day three to day five the haploid maternal and paternal genomes work together for the first time to form the genome of the embryo. The maternal epigenetic control lessens significantly while preparing for implantation with precisely arranged events happening. The first event includes a rapid increase in the number of embryonic cells which are active in mitotic divisions and apoptosis of aberrant cells. This is followed by the formation of blastocoel (cavitation) which results from the flattening of cell located on the outside of the blastomere. Now the blastocyst will expand until the embryo hatches by rupturing the zona pellucida. The cells of the blastocyst will differentiate to form two distinct cell lineages, the outer trophectoderm and the inner cell mass<ref name="PMID22723007"/>.<br />
====Procedure====<br />
Trophectoderm biopsy is usually performed in Hepes buffered biopsy medium and opening approaches include needle cutting which has been replaced by lasers in past years. Different research groups report different timings of the opening to be the most successful. Some open the blastocyst on day three or four by creating a 25 µm which causes the trophectoderm to herniate through this hole and is, thus, accessible for biopsy. Others create this hole about four hours before biopsy which allows sufficient herniation of trophectoderm cells. It is also possible to open the blastocyst immediately before biopsy. This avoids an extra step and the inner cell mass usually is easy to locate. Blastocyst biopsies involve the removal of trophectoderm cells and the ideal time for the procedure is day five. Successful biopsies on day six have been performed, while little is known about the results of biopsies on day seven. However, since the window of implantation in humans is from day eight to ten after ovulation, day seven biopsies appear to be possible<ref name="PMID22723007"/>.<br />
-collapse of trophoblasts<br />
-possible: biopsy of hatched blastocyst, holding pipette careful mild suction force to hold embryo near ICM <br />
-Cryopreservation<br />
<br />
{|border="1"<br />
| [[File:Microscopic images of human blastocysts for biopsy.jpeg]]<br />
|-<br />
| (A) Some trophectoderm cells in a blastocyst started to hatch and (B) the trophectoderm cells were biopsied with assisted laser cutting. Images in C–D show the blastocysts after vitrification and warming. Blastocysts had been cultured for 2–4 hrs after warming, showing good (ICM and trophectoderm cells) hatched (C) and hatching (D) blastocysts. The hatching blastocyst in (E) has good ICM but fair trophectoderm while the blastocyst in (F) has both fair ICM and trophectoderm. Arrows indicate ICMs and arrow heads indicate trophectoderm cells. Bar = 40 µm<ref name="PMID2190846"><pubmed>2190846</pubmed></ref>.<br />
|}<br />
<br />
<br />
{|border="1"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JI_TQ8d8tNM</html5media><br />
|-<br />
| Laser-assisted blastocyst biopsy (at 00:50 min)<ref>Coco, R. (2014, April 30) Trophectoderm biopsy in a Hatching blastocyst protruding ICM [Video file]. Retrieved from https://www.youtube.com/watch?v=JI_TQ8d8tNM</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
Blastocyst biopsies are believed to be less damaging to the embryo and appear to be unrelated to implantation rates. In addition, this biopsy method allows for a larger extraction of cells for genetic testing. However, since they are performed late in in vitro development, the time window for genetic testing is relatively small. Fast and accurate genetic testing methods are needed to ensure a successful and safe result from this biopsy. Thus, blastocyst biopsies may gain more popularity in the future whn such methods have been developed or improved<ref name="PMID22723007"/>. <br />
<br />
<br />
==Genetic Techniques==<br />
<br />
===PCR===<br />
====Description====<br />
Polymerase chain reaction (PCR) amplifies DNA specific to genetic sequence of interest . PCR was developed by Kay Mullis in the 1980s, for which he was awarded the Nobel prize for chemistry in 1993. <ref> Pubmed Docs (2015) Polymerase Chain Reaction (PCR) Pubmen. Retrieved from [http://www.ncbi.nlm.nih.gov/probe/docs/techpcr/]</ref> This technique enables clinicians to monitor and diagnose diseases using minute samples such as embryonic cells, blood & tissue. <ref>Roche (2015) PCR: How We Copy DNA. Roche Molecular Systems Inc. retrieved From [http://molecular.roche.com/pcr/Pages/Process.aspx]</ref> PCR has many important applications like DNA fingerprinting, genetic mapping, detection of viruses and bacteria as well as being used to detect genetic disorders, as a part of PGD, in conjunction with IVF. It is used to detect molecular abnormalities such as single gene disorders like Tay Sach, Cycstic fibrosis, Duchenne Muscular Dystrophy, Thalassemia, Huntington disease, Spinal muscular atrophy and many more. Molecular and Genetic analysis require a significant amount of DNA, which we would not have without PCR. It revolutionized the study of DNA, replacing all previous recombinant DNA technology. <ref> Mullins, K., Francois, F.& Gibbs R.A. (1994 ) The Polymerase Chain Reaction. p3. Springer- Science +Business Media. Birkhauser, Boston<br />
Available at [https://books.google.com.au/books?hl=en&lr=&id=gjrTBwAAQBAJ&oi=fnd&pg=PR5&dq=kary+mullis+PCR&ots=mpzAyRh5ZY&sig=PQ4goNoKJ90tb3-MkPk62zrTGbw#v=onepage&q=kary%20mullis%20PCR&f=false] </ref> <br />
<br />
====Procedure====<br />
<br />
Sample are obtained from the the blastocyst, a polar body biopsy or the blastomeres stages of the embryo. <br />
Stage 1 Denaturing: separating the target strands of DNA <br />
The obtained sample is heated to roughly 90 degrees celcius, this heat causes breaks the relatively weak bonds between nucleotides that form DNA. the double stranded DNA to split into 2 single strands of DNA that are used as templates.<br />
Stage 2 Annealing: Binding the Primers to the target DNA sequence <br />
PCR will only copy the target sequence of DNA specified by specific PCR primer. These synthesized primers Oligonucleotides are small artificial pieces of DNA. <br />
TAQ polymerase enzyme synthesize 2 new strands of DNA duplicate to the single sample DNA stand template indicated by these primers. During this stage the reaction is cooled to a temperature between 40-60 degrees Celsius. <br />
Stage 3- Extension- making copies <br />
Each of these 2 copies are then used again as templates generating 2 further replications This cycle can occur as many 30 -40 times within a couple hours leading to billions of extra copies of the original DNA segment. The optimal temperature for the further replication is roughly 72 degrees Celsius. <br />
<br />
This process mediated by a thermocycler machine that is programmed to alter the temperature of the reaction every couple of minutes, perpetuating the cycle of DNA denaturing and synthesis. <br />
This process, generates exponential exact copy of the original template DNA sequence. <br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
!PCR cycles<br />
<br />
|{|<br />
|-bgcolor="lightpink"<br />
| '''PCR Cycle'''<br />
| '''Target Copies'''<br />
|-<br />
| 1<br />
| 2<br />
|-bgcolor="pink"<br />
| 2<br />
| 4<br />
|-<br />
| 3<br />
| 8<br />
|-bgcolor="pink"<br />
| 4<br />
| 16<br />
|-"<br />
| 5 <br />
| 32<br />
|-bgcolor="pink"<br />
| 6 <br />
| 64<br />
|-<br />
| 7 <br />
| 128<br />
|-bgcolor="pink"<br />
| 8<br />
| 256<br />
|- <br />
| 9<br />
| 512 <br />
|-bgcolor="pink"<br />
| 10<br />
| 1024<br />
|-<br />
| 15<br />
| 32,768<br />
|-bgcolor="pink"<br />
| 20 <br />
| 1,048,578<br />
|-<br />
| 25<br />
| 33,554,432<br />
|-bgcolor="pink"<br />
| 30 <br />
| 1,073,741,842<br />
|-<br />
|}<br />
<br />
<br />
<br />
<br />
{|border="1" align="center"<br />
|-bgcolor="pink" <br />
| '''Advantages''' <br />
|'''Disadvantages'''<br />
|- <br />
| fast and inexpensive way of copying a target sequence of DNA<br />
| only during this exponential DNA replication phase can we determine the starting quantity sequence contained in the original sample ( template DNA strand)<br />
|-bgcolor="pink"<br />
| aids the diagnosis of single cell defects<br />
| PCR reaction is limited by the presence of inhibitors present in the sample : reagent inhibitors <br />
|-<br />
| rapid generation of results within a couple hours<br />
| self annealing due to the accumulation of the product -stopping exponential amplification for the target sequence and reach a plateau<br />
quantification of the end point of reaction of PCR products unreliable - therefore that is why we require real time quantitative RT-PCR necessary<br />
<ref> NIS (2015) Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref><br />
|-bgcolor="pink"<br />
| can start from a single molecule of DNA, therefore is more sensitive <br />
| <br />
|-<br />
| has a flexible primer design enabling<br />
| <br />
|-bgcolor="pink"<br />
| overcame previous issues associated with the limited availability of sites of end<br />
| <br />
|-<br />
| generates the DNA copies exponentially<br />
| <br />
|-bgcolor="pink"<br />
| enables DNA amplification required for molecular and genetic analysis<br />
| <br />
|-<br />
|Valid diagnostic method in selecting unaffected embryos for embryo transfer <ref> Dreesen, J., Drusedaul, M., Smeets, H., Die-Smulders, C., Coonen, E., Dumoulin, J., Gielen, M., Evers, J., Herbergers, J. & Geradets, J. (2008) Validation of preimplantation genetic diagnosis by PCR analysis: genotype comparison of the blastomere and corresponding embryo, implications for clinical practice. Mol. Hum. Reprod. 14 (10):573-579.doi: 10.1093/molehr/gan052. Retrieved from [http://molehr.oxfordjournals.org/content/14/10/573.short] </ref> <ref><pubmed>20966460</pubmed></ref><br />
|<br />
|}<br />
<br />
<br />
<br />
<br />
<br />
<br />
<br />
<br />
<br />
===Fluorescent In Situ Hybridisation (FISH)===<br />
<br />
<br />
====Description====<br />
Fluorescence in situ hybridization (FISH) the one of the most effective and rapid <ref name="PMID26338801"><pubmed>26338801</pubmed></ref> Preimplantation Genetic Diagnosis (PGD). This techniques used to locate a specific DNA sequences within a chromosome. FISH facilitates the clinical diagnosis of chromosomal abnormalities indicated by sequential duplications, deletions and rearrangements of chromosome, that are usually missed with microscopic analysis. This technique is especially relevant for female embryos with X-linked diseases,<ref><pubmed>20809319</pubmed></ref> that have no other mutation specific tests [http://www.ncbi.nlm.nih.gov/pubmed/20809319] As part of PGD, samples are collected from various stages of the embyro,and they are able to conducted tests on the blastocyst, a polar body biopsy and the blastomeres <ref><pubmed>21748341</pubmed></ref>. FISH is 99% effective when used in conjunction with competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities<ref name="PMID26338801"/>.<br />
<br />
====Procedure==== <br />
<br />
Samples are collected from either the blastocyst, a polar body biopsy or the blastomeres stages of the embryo <ref><pubmed>21748341</pubmed></ref>. <br />
DNA strands are heated and denatured causing their the individual DNA strands to break apart<br />
Probes are single complimentary stands of DNA a that have been tagged with small chemical agents that glow brightly in the presence of a specific region on a chromosome. These specific probes then hybridize and join to their complementary DNA strand. <br />
The fluorescent tags enable the researchers to correctly identify the presence or lack thereof and location of the specific chromosomes that they are testing for. <ref><pubmed>17876073</pubmed></ref><br />
Researcher analyse the results by identifying the number and the relative location of the fluorescent dots generated by the FISH images.<ref><pubmed>17970921</pubmed></ref><br />
The probe will not fully hybridise if there has been a duplication or a deletion of the DNA - indicating chromosomal and sex chromosomal anomalies like trisomies and aneuploidies. <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref><br />
<br />
<br />
Different probes are used for different purposes: <ref>Unique, Rare Chromosome Disorder Support Group (2013) Fluorescence in situ hybridisation (FISH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/Other/FISH%20FTNW.pdf]</ref><br />
*'''Locus specific tags''' detect very small imbalances, and locate isolated small portions <br />
of genes within a chromosome<br />
*'''Alphoid/Centomeric Repeat probes''' are developed from the repetitive sequence located in the middle region of each chromosome, useful in determining the number of chromosomes , detecting rearrangement and when used in conjunction with locus probes to determine the absence of genetic material on a chromosome. <br />
*'''Paint Probes''' are collections of smaller probes with their own stains that bind to a different section on the chromosome - allowing the full chromosome too be labeled a unique colour, this "full colour map" can be used to know the spectral karyotype- full chromosomal mapping is useful in examining chromosomal abnormalities. <br />
<br />
{|border="1" <br />
| [[File:Fluorescent In Situ Hybridisation (FISH).jpg|thumb|right|'''FISH''' We are able to tag Specific DNA sequences using Probes which have been tagged with fluorescent Labels.This technique enables the clinical diagnosis of chromosomal abnormalities, indicated by sequential duplication, deletions and rearrangements of chromosome <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref>]]<br />
|}<br />
<br />
<br />
<br />
{|border="1" align="center"<br />
|-bgcolor="pink" <br />
| rowspan="7" |'''Advantages''' <br />
| FISH is 99% effective when used in conjunction with Competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities.<ref><pubmed>26338801</pubmed></ref><br />
|-bgcolor="pink" <br />
| Rapid generation of results<br />
|-bgcolor="pink" <br />
| Identifies very small translocations and aneuploidies that occur within chromosomes, that would usually be missed under microscopic analysis<br />
|-bgcolor="pink" <br />
| Indicates whether the accessed chromosomes are normal <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|-bgcolor="pink" <br />
| Tests for the most common chromosomal abnormalities - down syndrome chromosomes 13,16,18,21 and 22 <ref><pubmed>21749752</pubmed></ref><br />
|-bgcolor="pink" <br />
| It may be used to compare the chromosomal gene arrangements in related species<br />
|-bgcolor="pink" <br />
| can be used to identify and remove inheritable X-linked disease or sex chromasome anomalies such as Duchennes Muscular Dystrophy, hemophilia, ectodermal dysplasia <ref><pubmed>17876073</pubmed></ref><br />
|-bgcolor="white"<br />
| rowspan="4"|'''Disadvantages'''<br />
| FISH destroys all cells tested <ref> O'Connor, C. (2008) Fluorescence in situ hybridization (FISH). Nature Education 1(1):171. retrieved from [http://www.nature.com/scitable/topicpage/fluorescence-in-situ-hybridization-fish-327] </ref><br />
|-<br />
| It does not fully access all chromosomes (only ~ 12)<br />
|-<br />
| Analysis of results is dependent upon the dot quality impacted by hybridisation efficiency or the camera sensitivity <ref><pubmed>17970921</pubmed></ref><br />
|-<br />
| some studies indicate that using FISH on a day-3 embryo biopsy decreases the rate of live births <ref><pubmed>26168107</pubmed></ref><br />
|}<br />
<br />
<br />
<br />
===Array Comparative Genomic Hybridisation (aCGH)===<br />
====Description====<br />
<br />
aCGH also known as Microarray analysis efficiently scans the entire genome for chromosomal imbalances. CGH was initially developed to detect the number of changes in a solid tumor mass. It uses 2 genomes comparing the sample to the control, with each labeled in a different fluorescent dye<ref><pubmed>1876176</pubmed></ref>. Earlier CGH techniques were limited by the resolution of the imaging <ref> Lichter, P., et al. Comparative genomic hybridization: Uses and limitations. Seminars in Hematology 37, 348–357 (2000)</ref> , these initial limitations were overcome by using Microarrays in conjunction with CGh to improve the resolution of the imaging, Array Comparative Genomic Hybridisation (aCGH). This method compares sample and control microarrayed slides containing small segments of DNA (probes). <ref> Lucito, R., et al. Representational oligonucleotide microarray analysis: A high-resolution method to detect genome copy number variation. Genome Research 13, 2291–2305 (2003) </ref> the Probes used will vary according from the small (25-85 base pairs) oligonucleotides manufactured to highlight different target sequences, to the very large genomic clones (80,000- 200,00 base pairs), and as these are significantly smaller than the traditional metaphase chromosomes used for CGH, generating a higher resolution of image. <ref><pubmed>22467166</pubmed></ref>.aCGH is used as a diagnostic tool for prenatal detection f chromosomal abnormalities <ref><pubmed>19012303</pubmed></ref>.<br />
<br />
<br />
====Procedure====<br />
<ref> Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432] </ref><br />
The sample is obtained (skin, blood or fetal cells) and DNA is obtained. <br />
As a part of PGD fetal cell samples are collected from; the fertilized egg polar bodies, the blastomere (day 3 embryo) or the blastocyst/tropoectoderm stage (day 5 embryo).<br />
Sample DNA is labeled with one fluorescent dye, and the control DNA is labeled with a different colored fluorescent dye. the control DNA is used as the base point of reference. <br />
heated and denatured single DNA strands then hybridize to their complementary single strand probes, which are then combined and applied to a microarray and the results are run through a computer program and a digital imaging system is used to quantify the results( fluorescent intensities of the labeled probes). <br />
<br />
simple explanation of aCGH : [Genomics Education (2014) Genetic Testing for Health: aCGH|https://vimeo.com/84757281]<br />
<ref>Genomics Education (2014) Genetic Testing for Health: aCGH [video file] Vimeo [https://vimeo.com/84757281]</ref><br />
<br />
<br />
The fluorescent ratio and the hybridization signal at different locations on the genome of the control DNA are used to identify any variances present in the sample DNA. aCGH facilitates the clinical diagnosis of submicroscopic chromosomal duplication, deletion and rearrangements indicative of chromosomal disorders such as trisomies 1-22and specific sex linked disorders. <br />
Duplications in the DNA are displayed by the computer program as spikes/ peaks over an established threshold and deletions in DNA are displayed by the computer program as spikes/ toughs beneath this threshold <br />
-computer screening image- <br />
-drawn diagram of method-<br />
<br />
<br />
<br />
{|border="1" align="center"<br />
|-bgcolor="pink" <br />
| '''Advantages''' <br />
| '''Disadvantages'''<br />
|-<br />
| multiple applications: prenatal genetic diagnosis, cancer diagnosis, <ref><pubmed>20193845</pubmed></ref> genetic screening for developmental delay (learning disabilities) <ref><pubmed>17309648</pubmed></ref>. or congenital anomalies that are suspected to be genetic in origin <ref>NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation . retrieved from [http://www.phgfoundation.org/file/5237/]</ref><br />
| translocations and inversions of DNA are not detected<br />
|-bgcolor="pink"<br />
| trace represents all chromosomes present in the human genome chromosomes 1-22 and the X & Y chromosomes, and therefore is the most accurate method for testing whole embryo aneuploidy<br />
| limited ability diagnosing specific polyploidies such as triploidy <ref> Unique, Rare Chromosome Disorder Support Group (2013) Microarray-based Comparative Genomic Hybridiation (array CGH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/other/array%20cgh%20ftnw.pdf] </ref><br />
|-<br />
| aCGH has been extensively tested, and Validated, and is now used world wide.<br />
| will not detect mosaicism detection <20% (cultures where >1 of 5 cells are trisomy 12)<br />
|-bgcolor="pink"<br />
| detects deletions and additions and rearrangements as well as amplification, of the WHOLE genome, simultaneously.<br />
| will not detect balanced chromosomal rearrangement<br />
|-<br />
| detects submicroscopic alterations<br />
| will not detect duplications or deletions <80kb<br />
|-bgcolor="pink"<br />
| used as a diagnostic tool for prenatal detection of chromosomal abnormalities <ref><pubmed>22034057</pubmed></ref><br />
| will not detect point mutations within genes <ref>Washington department of education (CGH- FAQ for physicians. Signature Genomic LAboratories, LLC. Retrieved from [https://depts.washington.edu/dbpeds/Lab%20Tests/SignatureCGH-physician_FAQ.pdf]</ref><br />
|-<br />
| provides high resolution genomewide screening of segmental genomic copy number variations<br />
| will not detect chromosomal position of genomic gains<br />
|-bgcolor="pink"<br />
| very accurate when used in conjunction with FISH<br />
| will not detect loos of heterozygosity (LOH) or Absence of heterozygosity (AOH) <ref>WiCell Research Institute Inc. (2012) Comparative Genomic Hybridization Microarray. <br />
retrieved from [http://www.wicell.org/home/cytogenetic-services/cgh-microarray/array-comparative-genomic-hybridization-acgh.cmsx]</ref><br />
|-style="background:pink"<br />
|Alone is more reliable and in detecting chromosomal abnormalities, with a higher implantation success rate, than FISH <ref><pubmed>20494259</pubmed></ref><br />
|<br />
|-bgcolor="pink"<br />
|Allows an in depth research focus upon specific types of rearrangements within selected chromosomal regions, a recent particular area of interest is subtelomeric and pericentromeric rearrangements<br />
|<br />
|-<br />
|reduces the risk of failed implantation and miscarriage, improving the chance of a healthy baby <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|<br />
|}<br />
<br />
<br />
<br />
===Next Generation Sequencing===<br />
====Description====<br />
The development and advances within ART in the past 20 years, as well as the increasing popularity of IV, has lead to an influx of new technologies developed to screen embryos for chromosomal anomalies, which are covered by the umbrella term of Next generation Sequencing (NGS). NGS is a general term used to describe all of the new and emerging screening techniques currently being introduced and used as part of PGD for IVF . NGS screens for single gene disorders as well as conducting extensive and very comprehensive chromosome diagnosis by sequencing, counting, and accurately assembling millions of DNA reads, simultaneously. <ref><pubmed>23499002</pubmed></ref> There is a movementfor NGS to replace the other limited testing techniques and be used as the standard. <br />
====Procedure====<br />
Samples are collected from either blastomere or the blastocyst/tropoectoderm and processed for analysis by a computer system. <br />
The methodology of each process is unique to the technique being used. <br />
<br />
<br />
<br />
{|border="1" align="center"<br />
|-bgcolor="pink" <br />
| '''Advantages'''<br />
| '''Disadvantages'''<br />
|-bgcolor="white"<br />
| cheaper<br />
| there are limited information available to clinical applications of NGS <ref><pubmed>26100406</pubmed></ref><br />
|-bgcolor="pink"<br />
| opens new diagnostic possibilities<br />
|<br />
|-bgcolor="white"<br />
| accurately tests all 24 chromosomes<br />
| <br />
|-bgcolor="pink"<br />
| tests for the presence of monogenic diseases of known genetic background<br />
| <br />
|-bgcolor="white"<br />
| reduces the number of biopsies required for diagnosis<br />
| <br />
|-bgcolor="pink"<br />
| higher detection rate of small translocations<br />
| <br />
|-bgcolor="white"<br />
| highly accurate is testing for compound point mutations, chromosomal duplication, deletions and insertions <ref><pubmed>23312231</pubmed></ref><br />
| <br />
|-bgcolor="pink"<br />
| it accurately detects chromosomal aneuploidy and unbalanced rearrangement <ref><pubmed>25685330</pubmed></ref><br />
| <br />
|-bgcolor="white"<br />
| NGS single gene disorder screenings can conducted in conjunction with PCR comprehensive chromosomal screening<br />
|<br />
|-bgcolor="pink"<br />
| Reduces human error <br />
|<br />
|-bgcolor="white"<br />
| better detects the presence of mosaicism<br />
|<br />
|-bgcolor="pink"<br />
| work well in conjunction with CGH and aCGH as part of PGD, improving the chances of IVF. <ref> Morris, R. S. (2015 ) Next generation sequencing for PCG|PGS|CCS. IVF1 retrieved from [http://www.ivf1.com/next-generation-sequencing for-pgd] </ref><br />
|<br />
|}<br />
<br />
<br />
<br />
<br />
<br />
<br />
==Diagnosis==<br />
There are a large amount of diseases that PGD can apply to, below are descriptions of the diseases that PGD are more commonly used for. <br />
===Cystic Fibrosis===<br />
Cystic fibrosis is a single gene disorder. It is autosomal recessive and involves mutations in the cystic fibrosis transmembrane conductance regulator (CTFR) gene. The CTFR gene is normally responsible for the decrease in chloride and the transport of bicarbonate in epithelial cells thus playing a major physiological role. In PGD procedures, identification of the gene is assisted by microsatellite markers that have similar composition to the CTFR gene itself. Biopsy of two cells at the blastocyst stage is recommended if markers are not available. There are many variations of cystic fibrosis the most common being P.Phe508del <ref name="PMID26014425"><pubmed>26014425</pubmed></ref>.<br />
===Duchenne Muscular Dystrophy ===<br />
Duchenne Muscular Dystrophy is an X-linked recessive disease. It involves the Xp21 gene where majority of the mutations are chromosomal deletions with a smaller percentage resulting from duplications <ref name="PMID18359022"><pubmed>18359022</pubmed></ref>.<br />
===β – Thalassemia=== <br />
β – Thalassemia is known as the most common type of autosomal recessive inherited disorder among haemoglobinopathies. It involves the adult β-globin gene and is associated with the absent or decreased expression of the gene. This is commonly caused by a single nucleotide change in the gene. PGD has been used successfully worldwide to identify the β-globin gene where its application is usually performed on a single blastomere or polar body <ref name="PMID19064120">19064120</pubmed></ref>.<br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
! Applicable diseases for PGD <ref>Genoma Group (2014). Retrieved September 18th, 2015, from http://www.preimplantationgeneticdiagnosis.it/genetic-diseases-diagnosed-by-pgd.htm </ref>, <ref>Genesis Genetics (2015). Retrieved September 18th, 2015, from http://genesisgenetics.org/pgd/what-we-test-for/</ref>, <ref>Human Fertilisation & Embryology Authority (2015). Retrieved Septembr 18th, 2015, from http://guide.hfea.gov.uk/pgd/</ref><br />
<br />
|{<br />
| '''Disease'''<br />
| '''Involved Genes'''<br />
|-<br />
| 5 Alpha Reductase Deficiency (5ARD)<br />
| SRD5A2 <br />
|-<br />
| Achondroplasia<br />
|FGFR3 <br />
|-<br />
| Acute Intermittent Porphyria <br />
| ALAD, ALAS2, CPOX, FECH, HMBS, PPOX, UROD, or UROS<br />
|-<br />
| Adrenoleukodystrophy (Adrenomyeloneuropathy)<br />
| ABCD1 <br />
|-<br />
| Agammaglobulinaemia (x-linked) <br />
|BTK <br />
|-<br />
| Agammaglobulinemia Bruton Tyrosine Kinase (BTK) <br />
|BTK <br />
|-<br />
| Aicardi Goutieres Syndrome 1 (AGS1) <br />
|TREX1, RNASEH2A, RNASEH2B, RNASEH2C, SAMHD1<br />
|-<br />
| Alagille Syndrome<br />
|JAG1 or NOTCH2<br />
|- <br />
| Alpers-Huttenlocher Syndrome <br />
|POLG <br />
|-<br />
| Alpha-1-antitrypsin deficiency <br />
|SERPINA1 <br />
|-<br />
| Alpha-Mannosidosis<br />
| MAN2B1 <br />
|-<br />
| Alpha Thalassemia <br />
|HBA1 or HBA2 <br />
|-<br />
| Alports Syndrome<br />
|COL4A3, COL4A4, COL4A5<br />
|-<br />
| Alzheimer's Disease - early onset (Type 3 and 4) <br />
|APP, PSEN1, or PSEN2<br />
|-<br />
| Amyotrophic Lateral Sclerosis 1 (ALS1) <br />
|C9orf72, SOD1, TARDBP, FUS, ANG, ALS2, SETX, VAPB <br />
|-<br />
| Argininosuccinic Aciduria <br />
| ASL<br />
|-<br />
| Arrhythmogenic Right Ventricular Cardiomyopathy/ Dysplasia (ARVC/D)<br />
| DSG2; DSP; PKP2<br />
|-<br />
| Ataxia Telangiectasia<br />
| ATM<br />
|-<br />
| Bardet-Biedl Syndrome (BBS)<br />
| BBS1; BBS10<br />
|-<br />
| Barth Syndrome<br />
| TAZ<br />
|-<br />
| Beta Thalassaemia<br />
| HBB<br />
|-<br />
| Birt-Hogg-Dubé Syndrome<br />
| FLCN<br />
|-<br />
| Breast Ovarian Cancer Familial Susceptibility (BRCA2)<br />
| BRCA1; BRCA2<br />
|-<br />
| Canavan Disease <br />
| ASPA<br />
|-<br />
| Carnitine-Acylcarnitine Translocase Deficiency <br />
| SLC25A20<br />
|-<br />
| Cerebral Arteriopathy with Subcortical Infarcts & Leukoencephalopathy (CADASIL)<br />
| NOTCH3<br />
|-<br />
| Cerebral Cavernous Malformation<br />
| CCM1<br />
|-<br />
| Charcot-Marie-Tooth Disease<br />
| GJB1; MPZ; NEFL; PMP22<br />
|-<br />
| CHARGE Syndrome<br />
| CHD7<br />
|-<br />
| Cherubism<br />
| SH3BP2<br />
|-<br />
| Choroideremia<br />
| CHM<br />
|-<br />
| Chronic Granulomatous Disease<br />
| CYBB; NCF1<br />
|-<br />
| Ciliary Dyskinesia<br />
| DNAH5<br />
|-<br />
| Citrullinemia<br />
| ASS1<br />
|-<br />
| Cleidocranial Dysplasia<br />
| RUNX2<br />
|-<br />
| Cockayne Syndrome<br />
| ERCC6<br />
|-<br />
| Congenital Adrenal Hyperplasia<br />
| CYP21A2<br />
|-<br />
| Congenital Cataracts<br />
| GJA8; VSX2<br />
|-<br />
| Congenital Diarrhea, Syndromic<br />
| SPINT2<br />
|-<br />
| Congenital Disorders of Glycosylation (CDG)<br />
| ALG1; ALG6; CDG1C; DOLK; PMM2<br />
|-<br />
| Cornelia de Lange Syndrome <br />
| NIPBL<br />
|-<br />
| Craniosynostosis<br />
| TWIST1<br />
|-<br />
| Crouzon Syndrome<br />
| FGFR2<br />
|-<br />
| Cysteinyl Leukotriene Receptor 1 Deficiency <br />
| CYSLTR1<br />
|-<br />
| Cystic Fibrosis<br />
| CFTR<br />
|-<br />
| Diamond –Blackfan Anemia <br />
| RPS19<br />
|-<br />
| Duchenne Muscular Dystrophy <br />
| DMD<br />
|-<br />
| Dyskeratosis congenita (Male embryos only)<br />
| DKC1<br />
|-<br />
| Ectodermal dysplasia (Hypohidrotic)<br />
| EDA; EDA1; GJB6; IKBKG<br />
|-<br />
| Familial Adenomatous polyposis coli (FAP)<br />
| APC<br />
|-<br />
| Familial Dysautonomia<br />
| IKBKAP<br />
|-<br />
| Fanconi Anemia <br />
| FANCA; FANCC; FANCD2; FANCF; FANCG; FANCJ<br />
|-<br />
| Fragile X Syndrome (FRAX)<br />
| FMR1<br />
|-<br />
| Galactosemia <br />
| GALT<br />
|-<br />
| Gangliosidosis<br />
| GLB1<br />
|-<br />
| Glanzmann Thrombasthenia <br />
| ITGA2B<br />
|-<br />
| Glutaric Acidemia (aciduria)<br />
| GCDH <br />
|-<br />
| Glycogen Storage Disease <br />
| G6PC; GAA; SLC37A4<br />
|-<br />
| Haemophilia A<br />
| F8<br />
|-<br />
| Haemophilia B<br />
| F9<br />
|-<br />
| Hereditary Nonpolyposis Colorectal Cancer: Lynch Syndrome<br />
| MLH1; MSH2; MSH6<br />
|-<br />
| Holt Oram Syndrome<br />
| TBX5<br />
|-<br />
| Huntington Disease<br />
| HD<br />
|-<br />
| Hydrocephalus<br />
| L1CAM<br />
|-<br />
| Ichthyosis <br />
| ABCA12; STS<br />
|-<br />
| Incontinentia Pigmenti (IP)<br />
| NEMO<br />
|-<br />
| Joubert Syndrome 5<br />
| INPP5E<br />
|-<br />
| Krabbe Disease<br />
| GALC<br />
|-<br />
| Leber Congenital Amaurosis (LCA)<br />
| CEP290; GUCY2D<br />
|-<br />
| Leigh Syndrome (Infantile Subacute Necrotising Encephalopathy)<br />
| LRPPRC<br />
|-<br />
| Lesch Nyan Syndrome<br />
| HPRT1<br />
|-<br />
| Leukocyte Adhesion Deficiency (Type I)<br />
| ITGB2<br />
|-<br />
| Li-Fraumeni Syndrome<br />
| TP53<br />
|-<br />
| Macular Dystrophy Retinal <br />
| VMD2<br />
|-<br />
| Maple Syrup Urine Disorder (MSUD)<br />
| BCKDHB<br />
|-<br />
| Marfan Syndrome <br />
| FBN1<br />
|-<br />
| Menkes Syndrome<br />
| ATP7A<br />
|-<br />
| Mitochondrial DNA Depletion Syndrom <br />
| POLG; RRM2B; SUCLA2; TK2<br />
|-<br />
| Mucolipidosis type II<br />
| GNPTAB<br />
|-<br />
| Multiple Endocrine Neoplasia<br />
| MEN1; MEN2A; MEN2B<br />
|-<br />
| Multiple Exostoses<br />
| EXT1; EXT2 <br />
|-<br />
| Myotubular myopathy<br />
| MTM1 <br />
|-<br />
| Nail-Patella Syndrome<br />
| LMX1B<br />
|-<br />
| Neurofibromatosis Type 1<br />
| NF1<br />
|-<br />
| Neurofibromatosis Type 2 <br />
| NF2<br />
|-<br />
| Noonan Syndrome<br />
| KRAS, PTPN11; SOS1<br />
|-<br />
| Norrie Disease<br />
| NDP<br />
|-<br />
| Ocular Albinism <br />
| GPR143<br />
|-<br />
| Oculocutaneous Albinism <br />
| OCA2; TYR <br />
|-<br />
| Oculodentaldigital Dysplasia<br />
| GJA1<br />
|-<br />
| Optic Atrophy<br />
| OPA1<br />
|-<br />
| Ornithine Transcarbamylase Deficiency <br />
| OTC<br />
|-<br />
| Osteogenesis imperfeca <br />
| COL1A1; COL1A2<br />
|-<br />
| Osteopetrosis <br />
| CLCN7; OSTM1; TCIRG1<br />
|-<br />
| Pachyonychia Congenita <br />
| KRT16; KRT6A<br />
|-<br />
| Pancreatitis, Hereditary<br />
| PRSS1 <br />
|-<br />
| Papillorenal syndrome <br />
| PAX2<br />
|-<br />
| Phenylketonuria <br />
| PAH <br />
|-<br />
| This table does not cover the complete list of diseases that PGD can be applied to.<br />
|}<br />
<br />
==Laws & Legal status==<br />
===Australia=== <br />
PGD is currently used to detect serious genetic conditions to improve the outcome of Assisted Reproductive Technologies (ART). In very rare cases it may be used to select an embryo with compatible tissue for a sibling who has a life-threatening disease where other means of treatment is unavailable. This is with the conditions that the use of PGD will not affect the welfare and interests of the child to be born. The parents must also receive adequate counselling and have full understanding of the procedures of PGD. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"> National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art</ref><br />
The use of PGD for sex-selection is prohibited with the exception of reducing the risk of the transmission of serious sex-linked genetic conditions. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"/><br />
===Brazil=== <br />
The laws regarding PGD in Brazil are not strictly regulated. They are vague and there is limited information surround the activities of assisted reproduction in general in the country <ref name="PMID25493379"><pubmed>25493379</pubmed></ref>.<br />
===Czech Republic===<br />
The laws in the Czech Republic allow those with a “defined indication in order to exclude risk of serous genetically conditioned disease and defects with embryos before they are implanted into the cavity of the uterus”. Couples that undergo any assisted reproductive treatment including PGD have to be married. Sex-selection is illegal except in regards to serious sex-linked genetic diseases <ref name="PMID24777348"><pubmed>24777348</pubmed></ref>.<br />
===Greece=== <br />
In Greece, ART is open to those up to the age of 50 with written consent. It can only be used if a medical necessity is present such as the susceptibility of serious hereditary diseases. Sex selection is banned apart from cases of sex-linked diseases and sexually transmitted diseases <ref name="PMID24777348"/>.<br />
===Portugal=== <br />
ART is only available to those who are married or have a similar type of relationship for at least two years. The couples cannot be of the same sex and must be at least 18 years of age. Sex selection is illegal except in cases of sex-linked diseases. The use of PGD is illegal if the predictive value of genetic tests are very low <ref name="PMID24777348"/>.<br />
===Spain===<br />
PGD can be applied to “serious hereditary diseases not amenable to postnatal curative treatment” and “detection of other abnormalities which may compromise the viability of the pre-embryo”. If PGD is to be used for any other purpose authorisation must be acquired <ref name="PMID24777348"/>.<br />
===Sweden=== <br />
The use of PGD is strictly regulated and couples must achieve authorisation of the National Board of Health and Welfare. It can only be used it can only be used if the child is at risk to inheriting a serious chromosomal or monogenetic disease. It cannot be used for selection of specific characteristics <ref name="PMID24777348"/>.<br />
===United Kingdom===<br />
Those involved with carrying out the IVF treatment must have a license from the Human Fertilisation and Embryology Authority (HFEA). Only embryos that are approved by the HFEA can be implanted where the embryonic nuclear or mitochondrial DNA cannot be altered with the exception of preventing mitochondrial diseases <ref name="PMID24777348"/>. <br />
==Future/Current Research==<br />
===Noninvasive Preimplantation Genetic Testing without Embryo Biopsy===<br />
Different parameters of gametes, zygotes, embryos (“vacuoles in sperm heads, spindle position in mature oocytes, cleavage intervals of zygote, and embryo developmental dynamics”) may correlate with aneuploidy rates. This knowledge may be applied in potential noninvasive preimplantation diagnostic methods. Several methods have been proposed and are currently further researched<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Sperm Selection====<br />
Intracytoplasmic morphologically selected sperm injection (IMSI) is common procedure in IVF treatment to improve fertilization rates in patients with poor semen quality. In addition, studies have found that IMSI improves embryo development and that spermatozoa with large vacuoles in their heads correlate with increased aneuploidy rates and disturbed chromosomal structures. Thus, selecting spermatozoa based on morphological hallmarks may decrease aneuploidy rates in the fertilized embryos. As with polar body biopsies, however, this approach will solely be applicable if evidence for severe male detrimental contribution is given<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Blastocoel Fluid Extraction====<br />
In addition, a less invasive retrieval of material for diagnosis could include the extraction of the blastocoel fluid. The cavity of the blastocyst, lined by the trophectoderm, is filled with this blastocoel fluid, which contains metabolites of both trophectoderm and inner cell mass origin. The retrieval does not require a biopsy but merely a small opening to extract the fluid and, thus, causes less harm to the embryo. Multiple studies have applied this method<ref name="PMID22020776"><pubmed>22020776</pubmed></ref> <ref name="PMID23148560"><pubmed>23148560</pubmed></ref> and it may in the future become of clinical relevance.<br />
<br />
{|border="1"<br />
| [[File:Aspiration_of_the_Blastocoel_Fluid.jpeg]]<br />
|-<br />
| Aspiration of the Blastocoel Fluid using a ICSI pipette<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
|}<br />
<br />
<br />
Next to metabolites, the blastocoel fluid can contain DNA. Studies have shown that genomic DNA is present in about 90% of the blastocoel fluid samples tested. Typically the fluid is removed with an ICSI pipette from a day five blastocyst through its mural trophectoderm until the blastocyst fully collapses around the embryo. Several concerns regarding this method in a clinical setting have been raised. The collected DNA may be contaminated by the culture media that contains DNA fractions. The DNA may also be least representative of the actual embryos genome as the DNA may originate from abnormal or degenerated cells. Even though labelled noninvasive, the blastocyst still undergoes manipulation to some degree which may affect its viability. Thus, more research is required until this method can evolve from research to clinical use<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
====Proteomics====<br />
The protein secretome of blastocysts may be representative of its chromosome constitution Recent studies have found biomarkers such as lipocalin-1, interleukin-10, tumor necrosis factor, stem cell factor, and chemokine ligand 13 to be differently secreted by aneuploid blastocyst than by euploid ones. The most significant biomarker appears to be interleukin-10. Paired with novel proteomic technologies and mass spectrometry this knowledge when extended may contribute to a new invasive preimplantation genetic diagnosis method<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Embryo Morphology====<br />
Using time lapse imaging the embryo’s morphology can be closely observed and potential aneuploidy characteristics detected. Such characteristics may include the time of division to five cells, the time between the division from three to four cells, and the duration of the division from one to two and subsequently to three. In addition, the morphological quality of ICM an TE has been positively associated with aneuploidy or euploidy prognosis<ref name="PMID26246880"><pubmed>26246880</pubmed></ref>. These may give rise to an embryo quality screening prior to implantation<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
===Utilization of Diseased Cell Lines===<br />
==Ethics==<br />
==References==<br />
<br />
<references/><br />
<br />
<br />
{{StudentPage2015}}</div>Z5017878https://embryology.med.unsw.edu.au/embryology/index.php?title=2015_Group_Project_6&diff=2065492015 Group Project 62015-10-19T11:47:30Z<p>Z5017878: </p>
<hr />
<div>{{ANAT2341Project2015header}}<br />
<br />
<br />
=Prenatal Genetic Diagnosis=<br />
==Introduction==<br />
==History==<br />
Prenatal Genetic Diagnosis was historically conducted post-implantation in the first 2 trimesters <ref> Blackburn, S.L. (2003) '''Maternal, Fetal & Neonatal physiology: a Clinical perspective''' (2nd ed.). Seattle: Saudners </ref>, testing for overall fetal growth, complications of pregnancy, birth defects as well as chromosomal or genetic abnormalities<ref> Sadler T.W.(2012) '''Langman's Medical Embryology''' (12th ed.) Philadelphia: Lipincott, Wiliams & Wilkins, a Wolters Kluwer Business </ref>. Due to advancements in Artificial Reproductive Technologies ( ART) in the past 2 decades , these genetic tests are now conducted as a part of Preimplantation Genetic Diagnosis (PGD) <ref><pubmed>20638568</pubmed></ref> and art used to eliminate the rsik of passing on a genetic disorder to an offspring, before implantation, it ha now become a preventative measure. . In 1990 Preimplantation genetic testing was first used in 1990 on humans to diagnose recessive X-linked diseases in the embryos of pregnant women undergoing IVF. <ref><pubmed>2330030</pubmed></ref> PGD is offered as an alternative to prenatal diagnosis in detecting genetic disorders in high risk couples <ref><pubmed>26168107</pubmed></ref> and avoid passing an inherited disease to the offspring, by selecting genetically "normal" embryos for implantation ,to give the best chance of successful implantation , stable pregnancies and healthy children. <br />
<ref><pubmed>23499002</pubmed></ref><br />
<br />
==Preimplantation Genetic Diagnosis==<br />
[[File:Preimplantation Genetic Diagnosis Procedure.jpeg|700px|thumb|centre| Simplified steps for PGD]]<br />
<br />
<br />
Preimplantation genetic diagnosis (PGD) is used to test the genetic makeup of embryos to detect single gene disorders, chromosomal abnormalities and mitochondrial disorders. It also has applications in gender selection for diseases with unequal gender distributions <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Some diseases commonly involved with PGD include cystic fibrosis, spinal muscular atrophy and beta – thalassaemia <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press.">Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press</ref> <ref name="PMID17823145"><pubmed>17823145</pubmed></ref>. It was first used in the United Kingdom in the 1980s of arenoleucodystrophy and primarily focusing on sex- linked disorders <ref name="PMID17823145"/><ref name="PMID23150080"><pubmed>23150080</pubmed></ref>. PGD is now capable of detecting single cell defects (molecular) and chromosomal disorders resulting from the inversion, translocation or deletion of chromosomes (cytogenic) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>,<ref name="PMID11325751"><pubmed>11325751</pubmed></ref>. PGD can be applied to the embryo at different stages. That is on polar bodies, blastomeres or blastocyst <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>.<br />
Depending on the type of genetic disorder, PGD utilises different methods of genetic testing. These include Fluorescence in situ hybridisation (FISH) which is used for sex – linked disorders and detects chromosomal rearrangements <ref name="PMID11325751"/><ref name="PMID17876073"><pubmed>17876073</pubmed></ref> and Embryo halotyping which allows the identification of chromosomes causing the inherited disorder through knowledge of the pattern of closely linked markers <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. Polymerase chain reaction (PCR) is also widely used to detect molecular abnormalities <ref name="PMID11325751"/>.<br />
PGD is tightly regulated and supported by large organisations namely The American Society for Reproductive Medicine, The European Society for Human Reproduction and Embryology (ESHRE), The European Society of Human Genetics and the Preimplantation Genetic Diagnosis International Society <ref name="PMID25500181><pubmed>25500181</pubmed></ref>.<br />
===Sex-linked disorders===<br />
The determination of a disease as gender specific usually correlates with the presence or absence of specific genes such as SRY on the Y chromosome. It is known that females have two X chromosomes and males have an X and a Y chromosome where abnormalities are more prevalent on the X chromosome. PGD can be used for sex selection where only male embryos are transferred to reduce the chance of inheriting X-linked disorders. However, this does not completely eradicate the problem as male embryos remain susceptible to inheriting an affected X chromosome. Sex determination is only used when the specific mutation is unknown and has yet to be discovered <ref name="PMID24866878"><pubmed>24866878</pubmed></ref>.<br />
===Single gene defects===<br />
Single gene defects can be dominant, recessive, autosomal or X-linked. They are commonly diagnosed using PCR and although the PCR available today is complex and capable of combatting a large range of disease the development of new protocols has been proven to be difficult due to the small DNA sample available <ref name="PMID26168107"><pubmed>26168107</pubmed></ref><br />
===Mitochondrial disorders===<br />
Mitochondrial disorders also known as oxidative phosphorylation disorders arise from mutations in the nuclear DNA or mitochondrial DNA <ref name="PMID26312584"><pubmed>26312584</pubmed></ref>. They pose as a problem because they are unrecognisable until the mutations in the cell reach a detrimental level <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Mitochondrial disorders cause miscarriages and stillbirths as well as death in children and young adults. The effects can either be contained in a single organ or more commonly involve multiple organ failure where organs with high energy demands such as the brain, liver muscle and heart and heavily influenced. They are usually occur spontaneously or result from inheritance from the mother. Since mitochondria are solely inherited from the mother oocyte donations have been used as a solution to combat mitochondrial disorders. Additionally, there has been an increasing use in PGD where embryos that stay under the given threshold of 18% gene-mutations are allowed to be transferred and result in normal development. New technology in the areas of nuclear gene transfer and genome editing are also being experimented with <ref name="PMID26312584"/>. <br />
===Chromosomal disorders===<br />
Chromosomal disorders can be reciprocal, Robertsonian translocations, inversions, deletions and insertions <ref name="PMID26168107"/>. . Data from ESHRE collected between 2010 and 2011 has shown that the most common chromosomal abnormality confronted in PGD are reciprocal chromosomal abnormalities <ref name"PMID26071418"><pubmed>26071418</pubmed></ref>. PGD has also been used successfully for Robertsonian translocations (RT), a type of structural translocation. Children who carry RT are phenotypically normal, however in their later years it is found that they will suffer from infertility and repeated miscarriages due to the high frequency of abnormal embryos <ref name="PMID22081077"><pubmed>22081077</pubmed></ref>. PCR and FISH are the two main techniques used for chromosomal disorders. To be able to conduct the examinations the cells are required to be at the metaphase stage <ref name="PMID26168107"/>. <br />
==Preimplantation Genetic Screening==<br />
Prenatal Genetic Screening (PGS) involves an array of methods or ideas that aim to segregate embryos that have genetic flaws and those that are healthy <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. The occurrence of aneuploidy is high around the stages of early embryonic development and they are the most common cause if miscarriages and congenital birth defects <ref name= "PMID26085841"><pubmed>26085841</pubmed></ref>. They have little effect on the morphology of the embryo making them difficult to identify thus identification heavily relies on genetic testing <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. <br />
Genetic sampling is most commonly conducted using Microarray Comparative Genomic Hybridisation (aCGH) as well as FISH, Quantitative PCR and Single Nucleotide Polymorphism (SNP) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. These methods collectively aim to assess numeral and structural chromosomal errors <ref name= "PMID26085841"/>. Studies have also introduced Next- Generation Sequencing (NGS) <ref name= "PMID26085841"/> and Whole Genome Amplification used to screen imbalances in the complete 24-chromosomes <ref name="PMID25953353"><pubmed>25953353</pubmed></ref><br />
Statistics from ESHRE have shown that the most common indications for PGS is advanced age, followed by repeated implantation failure or recurrent miscarriage and male infertility <ref name="PMID26071418"><pubmed>26071418</pubmed></ref>.<br />
====Indications====<br />
A low percentage of structural abnormalities in chromosomes are responsible for the cause of miscarriages. Despite this, they are the most prevalent type of chromosomal abnormality accounted for in PGD <ref name="PMID20638568"/>. The presence of specific gene cycles, initiation of embryonic protein synthesis and evident physiological development are all indicative of a successful in vitro fertilisation procedure <ref name="PMID11576737"><pubmed>11576737</pubmed></ref>. To eliminate further errors from occurring during the PGD procedure it is recommended to undertake further prenatal testing such as amniocentesis in the later stages <ref name="PMID20638568"/>. <br />
=====Advanced maternal age=====<br />
Data provided by the ESHRE has shown that the mean age of women undergoing PGS is 39 years <ref name="PMID26071418"/>. Women of advanced age have been shown to have a lower rate of pregnancies reaching childbirth <ref name="PMID18583331"><pubmed>18583331</pubmed></ref>. The highlighted concern revolves around the increased occurrence of aneuploidy following maternal age. The optimal age range for the lowest aneuploidy incidence was found to be between 27 to 37 years of age (6%) then progressively higher in women aged up to 42 (33%) and most common in those 44 and above (53%) <ref name="PMID24355045"><pubmed>24355045</pubmed></ref>. <br />
=====Recurrent pregnancy loss / IVF failure=====<br />
Recurrent pregnancy loss is defined as three or more IVF failures after cumulative transfer of more than 10 good-quality embryos. These are primarily caused by two main factors, reduced endometrium receptivity or embryonic defects. Endometrium receptivity can be negatively influences by instances including uterine pathologies such as thin endometrium, altered expression of adhesive molecules and immunological factors. Additionally, embryonic defects may be due to genetic abnormalities, embryonic aneuploidy or zona hardening. Endometriosis and hydrosalpinx has been known to effect both the endometrium and embryo <ref name="PMID23260857"><pubmed>23260857</pubmed></ref>.<br />
=====Human leukocyte antigen matching=====<br />
First used in 2001, HLA matching is an option given to parents to save a child with haematological or immunological disease through conceiving another child who would potentially be able to donate cord blood or haematopoietic stem cells from the bone marrow for transplantation. The process namely PGD-HLA has shown to improve haematopoietic stem cell transplant (HSCT). PGD-HLA can only be performed when HSCT is not needed urgently due to the time needed to conceive and delivery the baby <ref name="PMID25500181"><pubmed>25500181</pubmed></ref>. It is most commonly applied to children suffering from relapsed leukaemia <ref name="PMID22524201"><pubmed>22524201</pubmed></ref>. In a case study PGD-HLA was proven to successfully cure 10 diseases including Fanconi anaemia, Diamond-Blackfan anaemia and beta thalassemia <ref name="PMID25066893><pubmed>25066893</pubmed></ref>.<br />
==Biopsy Methods==<br />
Biopsy, the removal of genetic materials, from oocytes or embryos in the preimplantation stage is the primary step in PGD. For the past two decades these biopsies have been performed at three stages, the polar body, blastomere, and blastocyst, and the methodologies optimized to ensure the embryo’s viability. The most common approach involves biopsies at the cleavage stage. However, polar body and blastocyst biopsies are increasingly more often tested and applied. Approached for opening the zona pellucida involve next to the traditional mechanical and chemical means, novel approaches such as noncontact lasers. Their application may simplify and secure the procedure significantly. The most challenging question about PGD procedures remains at what stage biopsies should be taken. Much controversy has developed around this topic, highlighting the varying disadvantages and advantages of temporal biopsies. <ref name="PMID22723007"><pubmed>22723007</pubmed></ref><br />
<br />
{|border="1" align="left"<br />
|-bgcolor="pink" <br />
|<br />
| Time of Biopsy<br />
| Advantages <br />
| Disadvantages<br />
|- <br />
| Polar Body<br />
| Day 1<br />
| No harm to oocyte<br />
| Only maternal DNA is tested, often needs to be coupled with other biopsies<br />
|-bgcolor="pink"<br />
| Blastomere<br />
| Day 3<br />
| …<br />
| … <br />
|-<br />
| Trophectoderm<br />
| Day 5 and 6 <br />
| Little harm, large amount of genetic material<br />
| Opening of blastocyst necessary, small time window for procedure<br />
|}<br />
<br />
{|border="1"<br />
| [[File:Polar_Body,_Blastomere,_and_Trophectoderm_Biopsy.jpeg]]<br />
|-<br />
| Polar body (A), blastomere (B) and trophectoderm (C) biopsies<ref name="PMID25625041"><pubmed>25625041</pubmed></ref>.<br />
|}<br />
<br />
PMID 24305177<br />
===Polar Body Analysis===<br />
Day 1<br />
====Description====<br />
Polar body (PB) biopsy, which was introduced in 1990, offers a promising alternative to biopsies performed at the blastomere stage for PGD/S indications on legal and practical grounds. <br />
Description: Consequent embryo development does not necessitate the presence of the first and second PB and their removal may not be crucial. PB biopsy requires precise timing. Keeping track of the meiotic cell cycle is necessary to perform a successful biopsy and, therefore, PB biopsy usually is applied in combination with intracytoplasmic sperm injection (ICSI). During the maturation from the germinal vesicle stage to the metaphase-II stage the first PB is formed. A cytoplasmic bridge containing spindle remnants, that are still in contact with the cellular genetic material, links this PB to the oolemma for about 90 minutes after extrusion. It is possible to visualize these remnants by polarization microscopy and it is crucial to not perform the biopsy until the first PB is no longer firmly attached to the oolemma as this indicates an immature embryo.The oocyte tolerates mechanical zona dissection best during hours four until six after ICSI as the oolemma has stabilized by that time because of the cortical granule reaction. Over time the first PB degenerates stressing a temporal biopsy and its optimal extraction time window is four to 12 hours after ICSI. The second PB forms around two to four hours after ICSI. However, its optimal time window for biopsy is set to be eight to 16 hours after ICSI. This is due to the second PB being attached to the oolemma with spindle remnants until six hours after ICSI. Biopsy at this point may cause enucleation of the oocyte. In addition, studies have shown that the amplification efficiency of second PB’s DNA is worse if the PB is extracted prior to eight hours after ICSI. <br />
Thus, it is possible to perform sequential and simultaneous biopsies for the first and second PB. If performed, sequentially the first PB may be removed four to 12 hours and the second PB eight to 16 hours after ICSI. The optimal time window for a biopsy for both the first and second PB simultaneously is eight to 12 hours after ICSI. It is highly preferred to analyze both PBs due to potential aneuploidies in either PB and crossing overs during meiosis<ref name="PMID22723007"/>. <br />
====Procedure====<br />
Chemical opening achieved with for example acidic tyrode’s solution of the zona pellucida is not tolerated by the oocyte and may have detrimental effects on the embryo’s development. Therefore, the access to the perivitelline space of the oocyte is provided by mechanical zona dissection or by laser. Both techniques work well if performed by experienced embryologist. However, laser-assisted biopsy is less time consuming when compared to manual dissection. It is critical to consider the size of the introduced opening as it will remain permanent. If it is too large the blastomere may be lost during embryo development and if it is too small it may interfere with hatching of the embryo during blastocyst stage<ref name="PMID22723007"/><br />
<br />
{|border="1"<br />
| [[File:Polar_Body_Biopsy.jpeg]]<br />
|-<br />
| The presence of a faint but clearly identifiable strand connecting PB2 to the <br />
oolemma. The biopsy was performed ∼9 h after ICSI<ref name="PMID21908464"><pubmed>21908464</pubmed></ref>.<br />
|}<br />
<br />
{|border="1"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JTaQzszVr8o</html5media><br />
|-<br />
| Laser-assisted polar body biopsy<ref>RIUK, R. (2013, June 25) Polar Body Biopsy [Video file]. Retrieved from https://www.youtube.com/watch?v=JTaQzszVr8o</ref><br />
|}<br />
<br />
====Advantages & Disadvantages====<br />
PB biopsies can only investigate the maternal contributions to the embryo as they are of maternal origin. Thus, this procedure is appropriate for PGD solely for monogenetic diseases from the maternal side. Recessive diseases may be evaluated with PB biopsies on the basis that the embryo’s outcome will be determined by the paternal contribution. (...) It may still be applied for PGS as most aneuploidies either arise during meiosis or origin from the maternal genome. However, diagnosis error has been reported due to the lack of considering paternal contributions. <br />
Because PB biopsies are performed very early it is not yet known whether the oocyte will develop into a viable embryo. Thus, PBs are commonly frozen or fixed after biopsy and depending on the state of the embryo only chosen PBs will be tested. This is primarily an economic issue as many genetic testing procedures are very cost-intensive<ref name="PMID22723007"/>.<br />
<br />
{|border="1"<br />
| [[File:Implantation_predictive_value_of_euploid_screening_results.jpeg]]<br />
|-<br />
| The sustained implantation predictive value (with 95 % confidence interval) of a euploid screening result obtained from the first polar body (PB1), PB1 and the second polar body (PB2), or a direct embryo biopsy for each stage of embryo transfer (cleavage-stage and blastocyst stage)<ref name="PMID25106935"><pubmed>25106935</pubmed></ref>.<br />
|}<br />
<br />
===Blastomere biopsy===<br />
Day 3 <br />
====Description====<br />
Blastomere biopsy has been the prevalent method for PGD and PGS in the last two decades. At least one, but up to two, blastomeres are biopsied on day three of the cleavage stage embryo. The right number of blastomeres removed is a controversial topic as two cells allow for more genetic material and more accurate results. However, removing two cells might be too invasive and damaging to the embryo. (Study)<ref name="PMID21748341"><pubmed>21748341</pubmed></ref><br />
====Procedure====<br />
Initially a hole was drilled into the zona pellucida using acid tyrodes and the blastomeres are removed via aspiration with a pipette<ref name="PMID21748341"/>.<br />
<br />
{|border="1"<br />
| [[File:Aspiration_of_a_Blastomere.jpeg]]<br />
|-<br />
| Aspiration of a Blastomere into the biopsy pipette<ref name=" PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
|}<br />
<br />
{|border="1"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=TbridWVwipI</html5media><br />
|-<br />
| Laser-assisted blastomere biopsy<ref>Sukprasert, M. (2014, March 5) Day 3 Blastomere Biopsy 1 [Video file]. Retrieved from https://www.youtube.com/watch?v=TbridWVwipI</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
===Trophectoderm biopsy===<br />
Day 5 and 6<br />
====Description====<br />
The improvement of embryo culture media allowed the in vitro development of human embryos until the blastocyst stage and opened up the possibility to take blastocyst biopsies. During day three to day five the haploid maternal and paternal genomes work together for the first time to form the genome of the embryo. The maternal epigenetic control lessens significantly while preparing for implantation with precisely arranged events happening. The first event includes a rapid increase in the number of embryonic cells which are active in mitotic divisions and apoptosis of aberrant cells. This is followed by the formation of blastocoel (cavitation) which results from the flattening of cell located on the outside of the blastomere. Now the blastocyst will expand until the embryo hatches by rupturing the zona pellucida. The cells of the blastocyst will differentiate to form two distinct cell lineages, the outer trophectoderm and the inner cell mass<ref name="PMID22723007"/>.<br />
====Procedure====<br />
Trophectoderm biopsy is usually performed in Hepes buffered biopsy medium and opening approaches include needle cutting which has been replaced by lasers in past years. Different research groups report different timings of the opening to be the most successful. Some open the blastocyst on day three or four by creating a 25 µm which causes the trophectoderm to herniate through this hole and is, thus, accessible for biopsy. Others create this hole about four hours before biopsy which allows sufficient herniation of trophectoderm cells. It is also possible to open the blastocyst immediately before biopsy. This avoids an extra step and the inner cell mass usually is easy to locate. Blastocyst biopsies involve the removal of trophectoderm cells and the ideal time for the procedure is day five. Successful biopsies on day six have been performed, while little is known about the results of biopsies on day seven. However, since the window of implantation in humans is from day eight to ten after ovulation, day seven biopsies appear to be possible<ref name="PMID22723007"/>.<br />
-collapse of trophoblasts<br />
-possible: biopsy of hatched blastocyst, holding pipette careful mild suction force to hold embryo near ICM <br />
-Cryopreservation<br />
<br />
{|border="1"<br />
| [[File:Microscopic images of human blastocysts for biopsy.jpeg]]<br />
|-<br />
| (A) Some trophectoderm cells in a blastocyst started to hatch and (B) the trophectoderm cells were biopsied with assisted laser cutting. Images in C–D show the blastocysts after vitrification and warming. Blastocysts had been cultured for 2–4 hrs after warming, showing good (ICM and trophectoderm cells) hatched (C) and hatching (D) blastocysts. The hatching blastocyst in (E) has good ICM but fair trophectoderm while the blastocyst in (F) has both fair ICM and trophectoderm. Arrows indicate ICMs and arrow heads indicate trophectoderm cells. Bar = 40 µm<ref name="PMID2190846"><pubmed>2190846</pubmed></ref>.<br />
|}<br />
<br />
<br />
{|border="1"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JI_TQ8d8tNM</html5media><br />
|-<br />
| Laser-assisted blastocyst biopsy (at 00:50 min)<ref>Coco, R. (2014, April 30) Trophectoderm biopsy in a Hatching blastocyst protruding ICM [Video file]. Retrieved from https://www.youtube.com/watch?v=JI_TQ8d8tNM</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
Blastocyst biopsies are believed to be less damaging to the embryo and appear to be unrelated to implantation rates. In addition, this biopsy method allows for a larger extraction of cells for genetic testing. However, since they are performed late in in vitro development, the time window for genetic testing is relatively small. Fast and accurate genetic testing methods are needed to ensure a successful and safe result from this biopsy. Thus, blastocyst biopsies may gain more popularity in the future whn such methods have been developed or improved<ref name="PMID22723007"/>. <br />
<br />
<br />
==Genetic Techniques==<br />
<br />
===PCR===<br />
====Description====<br />
Polymerase chain reaction (PCR) amplifies DNA specific to genetic sequence of interest . PCR was developed by Kay Mullis in the 1980s, for which he was awarded the Nobel prize for chemistry in 1993. <ref> Pubmed Docs (2015) Polymerase Chain Reaction (PCR) Pubmen. Retrieved from [http://www.ncbi.nlm.nih.gov/probe/docs/techpcr/]</ref> This technique enables clinicians to monitor and diagnose diseases using minute samples such as embryonic cells, blood & tissue. <ref>Roche (2015) PCR: How We Copy DNA. Roche Molecular Systems Inc. retrieved From [http://molecular.roche.com/pcr/Pages/Process.aspx]</ref> PCR has many important applications like DNA fingerprinting, genetic mapping, detection of viruses and bacteria as well as being used to detect genetic disorders, as a part of PGD, in conjunction with IVF. It is used to detect molecular abnormalities such as single gene disorders like Tay Sach, Cycstic fibrosis, Duchenne Muscular Dystrophy, Thalassemia, Huntington disease, Spinal muscular atrophy and many more. Molecular and Genetic analysis require a significant amount of DNA, which we would not have without PCR. It revolutionized the study of DNA, replacing all previous recombinant DNA technology. <ref> Mullins, K., Francois, F.& Gibbs R.A. (1994 ) The Polymerase Chain Reaction. p3. Springer- Science +Business Media. Birkhauser, Boston<br />
Available at [https://books.google.com.au/books?hl=en&lr=&id=gjrTBwAAQBAJ&oi=fnd&pg=PR5&dq=kary+mullis+PCR&ots=mpzAyRh5ZY&sig=PQ4goNoKJ90tb3-MkPk62zrTGbw#v=onepage&q=kary%20mullis%20PCR&f=false] </ref> <br />
<br />
====Procedure====<br />
<br />
Sample are obtained from the the blastocyst, a polar body biopsy or the blastomeres stages of the embryo. <br />
Stage 1 Denaturing: separating the target strands of DNA <br />
The obtained sample is heated to roughly 90 degrees celcius, this heat causes breaks the relatively weak bonds between nucleotides that form DNA. the double stranded DNA to split into 2 single strands of DNA that are used as templates.<br />
Stage 2 Annealing: Binding the Primers to the target DNA sequence <br />
PCR will only copy the target sequence of DNA specified by specific PCR primer. These synthesized primers Oligonucleotides are small artificial pieces of DNA. <br />
TAQ polymerase enzyme synthesize 2 new strands of DNA duplicate to the single sample DNA stand template indicated by these primers. During this stage the reaction is cooled to a temperature between 40-60 degrees Celsius. <br />
Stage 3- Extension- making copies <br />
Each of these 2 copies are then used again as templates generating 2 further replications This cycle can occur as many 30 -40 times within a couple hours leading to billions of extra copies of the original DNA segment. The optimal temperature for the further replication is roughly 72 degrees Celsius. <br />
<br />
This process mediated by a thermocycler machine that is programmed to alter the temperature of the reaction every couple of minutes, perpetuating the cycle of DNA denaturing and synthesis. <br />
This process, generates exponential exact copy of the original template DNA sequence. <br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
!PCR cycles<br />
<br />
|{|<br />
|-bgcolor="lightpink"<br />
| '''PCR Cycle'''<br />
| '''Target Copies'''<br />
|-<br />
| 1<br />
| 2<br />
|-bgcolor="pink"<br />
| 2<br />
| 4<br />
|-<br />
| 3<br />
| 8<br />
|-bgcolor="pink"<br />
| 4<br />
| 16<br />
|-"<br />
| 5 <br />
| 32<br />
|-bgcolor="pink"<br />
| 6 <br />
| 64<br />
|-<br />
| 7 <br />
| 128<br />
|-bgcolor="pink"<br />
| 8<br />
| 256<br />
|- <br />
| 9<br />
| 512 <br />
|-bgcolor="pink"<br />
| 10<br />
| 1024<br />
|-<br />
| 15<br />
| 32,768<br />
|-bgcolor="pink"<br />
| 20 <br />
| 1,048,578<br />
|-<br />
| 25<br />
| 33,554,432<br />
|-bgcolor="pink"<br />
| 30 <br />
| 1,073,741,842<br />
|-<br />
|}<br />
<br />
<br />
<br />
<br />
{|border="1" align="right"<br />
|-bgcolor="pink" <br />
| '''Advantages''' <br />
|'''Disadvantages'''<br />
|- <br />
| fast and inexpensive way of copying a target sequence of DNA<br />
| only during this exponential DNA replication phase can we determine the starting quantity sequence contained in the original sample ( template DNA strand)<br />
|-bgcolor="pink"<br />
| aids the diagnosis of single cell defects<br />
| PCR reaction is limited by the presence of inhibitors present in the sample : reagent inhibitors <br />
|-<br />
| rapid generation of results within a couple hours<br />
| self annealing due to the accumulation of the product -stopping exponential amplification for the target sequence and reach a plateau<br />
quantification of the end point of reaction of PCR products unreliable - therefore that is why we require real time quantitative RT-PCR necessary<br />
<ref> NIS (2015) Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref><br />
|-bgcolor="pink"<br />
| can start from a single molecule of DNA, therefore is more sensitive <br />
| <br />
|-<br />
| has a flexible primer design enabling<br />
| <br />
|-bgcolor="pink"<br />
| overcame previous issues associated with the limited availability of sites of end<br />
| <br />
|-<br />
| generates the DNA copies exponentially<br />
| <br />
|-bgcolor="pink"<br />
| enables DNA amplification required for molecular and genetic analysis<br />
| <br />
|-<br />
|Valid diagnostic method in selecting unaffected embryos for embryo transfer <ref> Dreesen, J., Drusedaul, M., Smeets, H., Die-Smulders, C., Coonen, E., Dumoulin, J., Gielen, M., Evers, J., Herbergers, J. & Geradets, J. (2008) Validation of preimplantation genetic diagnosis by PCR analysis: genotype comparison of the blastomere and corresponding embryo, implications for clinical practice. Mol. Hum. Reprod. 14 (10):573-579.doi: 10.1093/molehr/gan052. Retrieved from [http://molehr.oxfordjournals.org/content/14/10/573.short] </ref> <ref><pubmed>20966460</pubmed></ref><br />
|<br />
|}<br />
<br />
<br />
<br />
<br />
<br />
<br />
<br />
<br />
<br />
===Fluorescent In Situ Hybridisation (FISH)===<br />
<br />
<br />
====Description====<br />
Fluorescence in situ hybridization (FISH) the one of the most effective and rapid <ref name="PMID26338801"><pubmed>26338801</pubmed></ref> Preimplantation Genetic Diagnosis (PGD). This techniques used to locate a specific DNA sequences within a chromosome. FISH facilitates the clinical diagnosis of chromosomal abnormalities indicated by sequential duplications, deletions and rearrangements of chromosome, that are usually missed with microscopic analysis. This technique is especially relevant for female embryos with X-linked diseases,<ref><pubmed>20809319</pubmed></ref> that have no other mutation specific tests [http://www.ncbi.nlm.nih.gov/pubmed/20809319] As part of PGD, samples are collected from various stages of the embyro,and they are able to conducted tests on the blastocyst, a polar body biopsy and the blastomeres <ref><pubmed>21748341</pubmed></ref>. FISH is 99% effective when used in conjunction with competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities<ref name="PMID26338801"/>.<br />
<br />
====Procedure==== <br />
<br />
Samples are collected from either the blastocyst, a polar body biopsy or the blastomeres stages of the embryo <ref><pubmed>21748341</pubmed></ref>. <br />
DNA strands are heated and denatured causing their the individual DNA strands to break apart<br />
Probes are single complimentary stands of DNA a that have been tagged with small chemical agents that glow brightly in the presence of a specific region on a chromosome. These specific probes then hybridize and join to their complementary DNA strand. <br />
The fluorescent tags enable the researchers to correctly identify the presence or lack thereof and location of the specific chromosomes that they are testing for. <ref><pubmed>17876073</pubmed></ref><br />
Researcher analyse the results by identifying the number and the relative location of the fluorescent dots generated by the FISH images.<ref><pubmed>17970921</pubmed></ref><br />
The probe will not fully hybridise if there has been a duplication or a deletion of the DNA - indicating chromosomal and sex chromosomal anomalies like trisomies and aneuploidies. <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref><br />
<br />
<br />
Different probes are used for different purposes: <ref>Unique, Rare Chromosome Disorder Support Group (2013) Fluorescence in situ hybridisation (FISH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/Other/FISH%20FTNW.pdf]</ref><br />
*'''Locus specific tags''' detect very small imbalances, and locate isolated small portions <br />
of genes within a chromosome<br />
*'''Alphoid/Centomeric Repeat probes''' are developed from the repetitive sequence located in the middle region of each chromosome, useful in determining the number of chromosomes , detecting rearrangement and when used in conjunction with locus probes to determine the absence of genetic material on a chromosome. <br />
*'''Paint Probes''' are collections of smaller probes with their own stains that bind to a different section on the chromosome - allowing the full chromosome too be labeled a unique colour, this "full colour map" can be used to know the spectral karyotype- full chromosomal mapping is useful in examining chromosomal abnormalities. <br />
<br />
{|border="1"<br />
| [[File:Fluorescent In Situ Hybridisation (FISH).jpg|thumb|right|'''FISH''' We are able to tag Specific DNA sequences using Probes which have been tagged with fluorescent Labels.This technique enables the clinical diagnosis of chromosomal abnormalities, indicated by sequential duplication, deletions and rearrangements of chromosome <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref>]]<br />
|}<br />
<br />
<br />
<br />
{|border="1" <br />
|-bgcolor="pink" <br />
| rowspan="7" |'''Advantages''' <br />
| FISH is 99% effective when used in conjunction with Competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities.<ref><pubmed>26338801</pubmed></ref><br />
|-bgcolor="pink" <br />
| Rapid generation of results<br />
|-bgcolor="pink" <br />
| Identifies very small translocations and aneuploidies that occur within chromosomes, that would usually be missed under microscopic analysis<br />
|-bgcolor="pink" <br />
| Indicates whether the accessed chromosomes are normal <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|-bgcolor="pink" <br />
| Tests for the most common chromosomal abnormalities - down syndrome chromosomes 13,16,18,21 and 22 <ref><pubmed>21749752</pubmed></ref><br />
|-bgcolor="pink" <br />
| It may be used to compare the chromosomal gene arrangements in related species<br />
|-bgcolor="pink" <br />
| can be used to identify and remove inheritable X-linked disease or sex chromasome anomalies such as Duchennes Muscular Dystrophy, hemophilia, ectodermal dysplasia <ref><pubmed>17876073</pubmed></ref><br />
|-bgcolor="white"<br />
| rowspan="4"|'''Disadvantages'''<br />
| FISH destroys all cells tested <ref> O'Connor, C. (2008) Fluorescence in situ hybridization (FISH). Nature Education 1(1):171. retrieved from [http://www.nature.com/scitable/topicpage/fluorescence-in-situ-hybridization-fish-327] </ref><br />
|-<br />
| It does not fully access all chromosomes (only ~ 12)<br />
|-<br />
| Analysis of results is dependent upon the dot quality impacted by hybridisation efficiency or the camera sensitivity <ref><pubmed>17970921</pubmed></ref><br />
|-<br />
| some studies indicate that using FISH on a day-3 embryo biopsy decreases the rate of live births <ref><pubmed>26168107</pubmed></ref><br />
|}<br />
<br />
<br />
<br />
===Array Comparative Genomic Hybridisation (aCGH)===<br />
====Description====<br />
<br />
aCGH also known as Microarray analysis efficiently scans the entire genome for chromosomal imbalances. CGH was initially developed to detect the number of changes in a solid tumor mass. It uses 2 genomes comparing the sample to the control, with each labeled in a different fluorescent dye<ref><pubmed>1876176</pubmed></ref>. Earlier CGH techniques were limited by the resolution of the imaging <ref> Lichter, P., et al. Comparative genomic hybridization: Uses and limitations. Seminars in Hematology 37, 348–357 (2000)</ref> , these initial limitations were overcome by using Microarrays in conjunction with CGh to improve the resolution of the imaging, Array Comparative Genomic Hybridisation (aCGH). This method compares sample and control microarrayed slides containing small segments of DNA (probes). <ref> Lucito, R., et al. Representational oligonucleotide microarray analysis: A high-resolution method to detect genome copy number variation. Genome Research 13, 2291–2305 (2003) </ref> the Probes used will vary according from the small (25-85 base pairs) oligonucleotides manufactured to highlight different target sequences, to the very large genomic clones (80,000- 200,00 base pairs), and as these are significantly smaller than the traditional metaphase chromosomes used for CGH, generating a higher resolution of image. <ref><pubmed>22467166</pubmed></ref>.aCGH is used as a diagnostic tool for prenatal detection f chromosomal abnormalities <ref><pubmed>19012303</pubmed></ref>.<br />
<br />
<br />
====Procedure====<br />
<ref> Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432] </ref><br />
The sample is obtained (skin, blood or fetal cells) and DNA is obtained. <br />
As a part of PGD fetal cell samples are collected from; the fertilized egg polar bodies, the blastomere (day 3 embryo) or the blastocyst/tropoectoderm stage (day 5 embryo).<br />
Sample DNA is labeled with one fluorescent dye, and the control DNA is labeled with a different colored fluorescent dye. the control DNA is used as the base point of reference. <br />
heated and denatured single DNA strands then hybridize to their complementary single strand probes, which are then combined and applied to a microarray and the results are run through a computer program and a digital imaging system is used to quantify the results( fluorescent intensities of the labeled probes). <br />
<br />
simple explanation of aCGH : [Genomics Education (2014) Genetic Testing for Health: aCGH|https://vimeo.com/84757281]<br />
<ref>Genomics Education (2014) Genetic Testing for Health: aCGH [video file] Vimeo [https://vimeo.com/84757281]</ref><br />
<br />
<br />
The fluorescent ratio and the hybridization signal at different locations on the genome of the control DNA are used to identify any variances present in the sample DNA. aCGH facilitates the clinical diagnosis of submicroscopic chromosomal duplication, deletion and rearrangements indicative of chromosomal disorders such as trisomies 1-22and specific sex linked disorders. <br />
Duplications in the DNA are displayed by the computer program as spikes/ peaks over an established threshold and deletions in DNA are displayed by the computer program as spikes/ toughs beneath this threshold <br />
-computer screening image- <br />
-drawn diagram of method-<br />
<br />
<br />
<br />
{|border="1" <br />
|-bgcolor="pink" <br />
| '''Advantages''' <br />
| '''Disadvantages'''<br />
|-<br />
| multiple applications: prenatal genetic diagnosis, cancer diagnosis, <ref><pubmed>20193845</pubmed></ref> genetic screening for developmental delay (learning disabilities) <ref><pubmed>17309648</pubmed></ref>. or congenital anomalies that are suspected to be genetic in origin <ref>NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation . retrieved from [http://www.phgfoundation.org/file/5237/]</ref><br />
| translocations and inversions of DNA are not detected<br />
|-bgcolor="pink"<br />
| trace represents all chromosomes present in the human genome chromosomes 1-22 and the X & Y chromosomes, and therefore is the most accurate method for testing whole embryo aneuploidy<br />
| limited ability diagnosing specific polyploidies such as triploidy <ref> Unique, Rare Chromosome Disorder Support Group (2013) Microarray-based Comparative Genomic Hybridiation (array CGH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/other/array%20cgh%20ftnw.pdf] </ref><br />
|-<br />
| aCGH has been extensively tested, and Validated, and is now used world wide.<br />
| will not detect mosaicism detection <20% (cultures where >1 of 5 cells are trisomy 12)<br />
|-bgcolor="pink"<br />
| detects deletions and additions and rearrangements as well as amplification, of the WHOLE genome, simultaneously.<br />
| will not detect balanced chromosomal rearrangement<br />
|-<br />
| detects submicroscopic alterations<br />
| will not detect duplications or deletions <80kb<br />
|-bgcolor="pink"<br />
| used as a diagnostic tool for prenatal detection of chromosomal abnormalities <ref><pubmed>22034057</pubmed></ref><br />
| will not detect point mutations within genes <ref>Washington department of education (CGH- FAQ for physicians. Signature Genomic LAboratories, LLC. Retrieved from [https://depts.washington.edu/dbpeds/Lab%20Tests/SignatureCGH-physician_FAQ.pdf]</ref><br />
|-<br />
| provides high resolution genomewide screening of segmental genomic copy number variations<br />
| will not detect chromosomal position of genomic gains<br />
|-bgcolor="pink"<br />
| very accurate when used in conjunction with FISH<br />
| will not detect loos of heterozygosity (LOH) or Absence of heterozygosity (AOH) <ref>WiCell Research Institute Inc. (2012) Comparative Genomic Hybridization Microarray. <br />
retrieved from [http://www.wicell.org/home/cytogenetic-services/cgh-microarray/array-comparative-genomic-hybridization-acgh.cmsx]</ref><br />
|-style="background:pink"<br />
|Alone is more reliable and in detecting chromosomal abnormalities, with a higher implantation success rate, than FISH <ref><pubmed>20494259</pubmed></ref><br />
|<br />
|-bgcolor="pink"<br />
|Allows an in depth research focus upon specific types of rearrangements within selected chromosomal regions, a recent particular area of interest is subtelomeric and pericentromeric rearrangements<br />
|<br />
|-<br />
|reduces the risk of failed implantation and miscarriage, improving the chance of a healthy baby <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|<br />
|}<br />
<br />
<br />
<br />
===Next Generation Sequencing===<br />
====Description====<br />
The development and advances within ART in the past 20 years, as well as the increasing popularity of IV, has lead to an influx of new technologies developed to screen embryos for chromosomal anomalies, which are covered by the umbrella term of Next generation Sequencing (NGS). NGS is a general term used to describe all of the new and emerging screening techniques currently being introduced and used as part of PGD for IVF . NGS screens for single gene disorders as well as conducting extensive and very comprehensive chromosome diagnosis by sequencing, counting, and accurately assembling millions of DNA reads, simultaneously. <ref><pubmed>23499002</pubmed></ref> There is a movementfor NGS to replace the other limited testing techniques and be used as the standard. <br />
====Procedure====<br />
Samples are collected from either blastomere or the blastocyst/tropoectoderm and processed for analysis by a computer system. <br />
The methodology of each process is unique to the technique being used. <br />
<br />
<br />
<br />
{|border="1" align="center"<br />
|-bgcolor="pink" <br />
| '''Advantages'''<br />
| '''Disadvantages'''<br />
|-bgcolor="white"<br />
| cheaper<br />
| there are limited information available to clinical applications of NGS <ref><pubmed>26100406</pubmed></ref><br />
|-bgcolor="pink"<br />
| opens new diagnostic possibilities<br />
|<br />
|-bgcolor="white"<br />
| accurately tests all 24 chromosomes<br />
| <br />
|-bgcolor="pink"<br />
| tests for the presence of monogenic diseases of known genetic background<br />
| <br />
|-bgcolor="white"<br />
| reduces the number of biopsies required for diagnosis<br />
| <br />
|-bgcolor="pink"<br />
| higher detection rate of small translocations<br />
| <br />
|-bgcolor="white"<br />
| highly accurate is testing for compound point mutations, chromosomal duplication, deletions and insertions <ref><pubmed>23312231</pubmed></ref><br />
| <br />
|-bgcolor="pink"<br />
| it accurately detects chromosomal aneuploidy and unbalanced rearrangement <ref><pubmed>25685330</pubmed></ref><br />
| <br />
|-bgcolor="white"<br />
| NGS single gene disorder screenings can conducted in conjunction with PCR comprehensive chromosomal screening<br />
|<br />
|-bgcolor="pink"<br />
| Reduces human error <br />
|<br />
|-bgcolor="white"<br />
| better detects the presence of mosaicism<br />
|<br />
|-bgcolor="pink"<br />
| work well in conjunction with CGH and aCGH as part of PGD, improving the chances of IVF. <ref> Morris, R. S. (2015 ) Next generation sequencing for PCG|PGS|CCS. IVF1 retrieved from [http://www.ivf1.com/next-generation-sequencing for-pgd] </ref><br />
|<br />
|}<br />
<br />
<br />
<br />
<br />
<br />
<br />
==Diagnosis==<br />
There are a large amount of diseases that PGD can apply to, below are descriptions of the diseases that PGD are more commonly used for. <br />
===Cystic Fibrosis===<br />
Cystic fibrosis is a single gene disorder. It is autosomal recessive and involves mutations in the cystic fibrosis transmembrane conductance regulator (CTFR) gene. The CTFR gene is normally responsible for the decrease in chloride and the transport of bicarbonate in epithelial cells thus playing a major physiological role. In PGD procedures, identification of the gene is assisted by microsatellite markers that have similar composition to the CTFR gene itself. Biopsy of two cells at the blastocyst stage is recommended if markers are not available. There are many variations of cystic fibrosis the most common being P.Phe508del <ref name="PMID26014425"><pubmed>26014425</pubmed></ref>.<br />
===Duchenne Muscular Dystrophy ===<br />
Duchenne Muscular Dystrophy is an X-linked recessive disease. It involves the Xp21 gene where majority of the mutations are chromosomal deletions with a smaller percentage resulting from duplications <ref name="PMID18359022"><pubmed>18359022</pubmed></ref>.<br />
===β – Thalassemia=== <br />
β – Thalassemia is known as the most common type of autosomal recessive inherited disorder among haemoglobinopathies. It involves the adult β-globin gene and is associated with the absent or decreased expression of the gene. This is commonly caused by a single nucleotide change in the gene. PGD has been used successfully worldwide to identify the β-globin gene where its application is usually performed on a single blastomere or polar body <ref name="PMID19064120">19064120</pubmed></ref>.<br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
! Applicable diseases for PGD <ref>Genoma Group (2014). Retrieved September 18th, 2015, from http://www.preimplantationgeneticdiagnosis.it/genetic-diseases-diagnosed-by-pgd.htm </ref>, <ref>Genesis Genetics (2015). Retrieved September 18th, 2015, from http://genesisgenetics.org/pgd/what-we-test-for/</ref>, <ref>Human Fertilisation & Embryology Authority (2015). Retrieved Septembr 18th, 2015, from http://guide.hfea.gov.uk/pgd/</ref><br />
<br />
|{<br />
| '''Disease'''<br />
| '''Involved Genes'''<br />
|-<br />
| 5 Alpha Reductase Deficiency (5ARD)<br />
| SRD5A2 <br />
|-<br />
| Achondroplasia<br />
|FGFR3 <br />
|-<br />
| Acute Intermittent Porphyria <br />
| ALAD, ALAS2, CPOX, FECH, HMBS, PPOX, UROD, or UROS<br />
|-<br />
| Adrenoleukodystrophy (Adrenomyeloneuropathy)<br />
| ABCD1 <br />
|-<br />
| Agammaglobulinaemia (x-linked) <br />
|BTK <br />
|-<br />
| Agammaglobulinemia Bruton Tyrosine Kinase (BTK) <br />
|BTK <br />
|-<br />
| Aicardi Goutieres Syndrome 1 (AGS1) <br />
|TREX1, RNASEH2A, RNASEH2B, RNASEH2C, SAMHD1<br />
|-<br />
| Alagille Syndrome<br />
|JAG1 or NOTCH2<br />
|- <br />
| Alpers-Huttenlocher Syndrome <br />
|POLG <br />
|-<br />
| Alpha-1-antitrypsin deficiency <br />
|SERPINA1 <br />
|-<br />
| Alpha-Mannosidosis<br />
| MAN2B1 <br />
|-<br />
| Alpha Thalassemia <br />
|HBA1 or HBA2 <br />
|-<br />
| Alports Syndrome<br />
|COL4A3, COL4A4, COL4A5<br />
|-<br />
| Alzheimer's Disease - early onset (Type 3 and 4) <br />
|APP, PSEN1, or PSEN2<br />
|-<br />
| Amyotrophic Lateral Sclerosis 1 (ALS1) <br />
|C9orf72, SOD1, TARDBP, FUS, ANG, ALS2, SETX, VAPB <br />
|-<br />
| Argininosuccinic Aciduria <br />
| ASL<br />
|-<br />
| Arrhythmogenic Right Ventricular Cardiomyopathy/ Dysplasia (ARVC/D)<br />
| DSG2; DSP; PKP2<br />
|-<br />
| Ataxia Telangiectasia<br />
| ATM<br />
|-<br />
| Bardet-Biedl Syndrome (BBS)<br />
| BBS1; BBS10<br />
|-<br />
| Barth Syndrome<br />
| TAZ<br />
|-<br />
| Beta Thalassaemia<br />
| HBB<br />
|-<br />
| Birt-Hogg-Dubé Syndrome<br />
| FLCN<br />
|-<br />
| Breast Ovarian Cancer Familial Susceptibility (BRCA2)<br />
| BRCA1; BRCA2<br />
|-<br />
| Canavan Disease <br />
| ASPA<br />
|-<br />
| Carnitine-Acylcarnitine Translocase Deficiency <br />
| SLC25A20<br />
|-<br />
| Cerebral Arteriopathy with Subcortical Infarcts & Leukoencephalopathy (CADASIL)<br />
| NOTCH3<br />
|-<br />
| Cerebral Cavernous Malformation<br />
| CCM1<br />
|-<br />
| Charcot-Marie-Tooth Disease<br />
| GJB1; MPZ; NEFL; PMP22<br />
|-<br />
| CHARGE Syndrome<br />
| CHD7<br />
|-<br />
| Cherubism<br />
| SH3BP2<br />
|-<br />
| Choroideremia<br />
| CHM<br />
|-<br />
| Chronic Granulomatous Disease<br />
| CYBB; NCF1<br />
|-<br />
| Ciliary Dyskinesia<br />
| DNAH5<br />
|-<br />
| Citrullinemia<br />
| ASS1<br />
|-<br />
| Cleidocranial Dysplasia<br />
| RUNX2<br />
|-<br />
| Cockayne Syndrome<br />
| ERCC6<br />
|-<br />
| Congenital Adrenal Hyperplasia<br />
| CYP21A2<br />
|-<br />
| Congenital Cataracts<br />
| GJA8; VSX2<br />
|-<br />
| Congenital Diarrhea, Syndromic<br />
| SPINT2<br />
|-<br />
| Congenital Disorders of Glycosylation (CDG)<br />
| ALG1; ALG6; CDG1C; DOLK; PMM2<br />
|-<br />
| Cornelia de Lange Syndrome <br />
| NIPBL<br />
|-<br />
| Craniosynostosis<br />
| TWIST1<br />
|-<br />
| Crouzon Syndrome<br />
| FGFR2<br />
|-<br />
| Cysteinyl Leukotriene Receptor 1 Deficiency <br />
| CYSLTR1<br />
|-<br />
| Cystic Fibrosis<br />
| CFTR<br />
|-<br />
| Diamond –Blackfan Anemia <br />
| RPS19<br />
|-<br />
| Duchenne Muscular Dystrophy <br />
| DMD<br />
|-<br />
| Dyskeratosis congenita (Male embryos only)<br />
| DKC1<br />
|-<br />
| Ectodermal dysplasia (Hypohidrotic)<br />
| EDA; EDA1; GJB6; IKBKG<br />
|-<br />
| Familial Adenomatous polyposis coli (FAP)<br />
| APC<br />
|-<br />
| Familial Dysautonomia<br />
| IKBKAP<br />
|-<br />
| Fanconi Anemia <br />
| FANCA; FANCC; FANCD2; FANCF; FANCG; FANCJ<br />
|-<br />
| Fragile X Syndrome (FRAX)<br />
| FMR1<br />
|-<br />
| Galactosemia <br />
| GALT<br />
|-<br />
| Gangliosidosis<br />
| GLB1<br />
|-<br />
| Glanzmann Thrombasthenia <br />
| ITGA2B<br />
|-<br />
| Glutaric Acidemia (aciduria)<br />
| GCDH <br />
|-<br />
| Glycogen Storage Disease <br />
| G6PC; GAA; SLC37A4<br />
|-<br />
| Haemophilia A<br />
| F8<br />
|-<br />
| Haemophilia B<br />
| F9<br />
|-<br />
| Hereditary Nonpolyposis Colorectal Cancer: Lynch Syndrome<br />
| MLH1; MSH2; MSH6<br />
|-<br />
| Holt Oram Syndrome<br />
| TBX5<br />
|-<br />
| Huntington Disease<br />
| HD<br />
|-<br />
| Hydrocephalus<br />
| L1CAM<br />
|-<br />
| Ichthyosis <br />
| ABCA12; STS<br />
|-<br />
| Incontinentia Pigmenti (IP)<br />
| NEMO<br />
|-<br />
| Joubert Syndrome 5<br />
| INPP5E<br />
|-<br />
| Krabbe Disease<br />
| GALC<br />
|-<br />
| Leber Congenital Amaurosis (LCA)<br />
| CEP290; GUCY2D<br />
|-<br />
| Leigh Syndrome (Infantile Subacute Necrotising Encephalopathy)<br />
| LRPPRC<br />
|-<br />
| Lesch Nyan Syndrome<br />
| HPRT1<br />
|-<br />
| Leukocyte Adhesion Deficiency (Type I)<br />
| ITGB2<br />
|-<br />
| Li-Fraumeni Syndrome<br />
| TP53<br />
|-<br />
| Macular Dystrophy Retinal <br />
| VMD2<br />
|-<br />
| Maple Syrup Urine Disorder (MSUD)<br />
| BCKDHB<br />
|-<br />
| Marfan Syndrome <br />
| FBN1<br />
|-<br />
| Menkes Syndrome<br />
| ATP7A<br />
|-<br />
| Mitochondrial DNA Depletion Syndrom <br />
| POLG; RRM2B; SUCLA2; TK2<br />
|-<br />
| Mucolipidosis type II<br />
| GNPTAB<br />
|-<br />
| Multiple Endocrine Neoplasia<br />
| MEN1; MEN2A; MEN2B<br />
|-<br />
| Multiple Exostoses<br />
| EXT1; EXT2 <br />
|-<br />
| Myotubular myopathy<br />
| MTM1 <br />
|-<br />
| Nail-Patella Syndrome<br />
| LMX1B<br />
|-<br />
| Neurofibromatosis Type 1<br />
| NF1<br />
|-<br />
| Neurofibromatosis Type 2 <br />
| NF2<br />
|-<br />
| Noonan Syndrome<br />
| KRAS, PTPN11; SOS1<br />
|-<br />
| Norrie Disease<br />
| NDP<br />
|-<br />
| Ocular Albinism <br />
| GPR143<br />
|-<br />
| Oculocutaneous Albinism <br />
| OCA2; TYR <br />
|-<br />
| Oculodentaldigital Dysplasia<br />
| GJA1<br />
|-<br />
| Optic Atrophy<br />
| OPA1<br />
|-<br />
| Ornithine Transcarbamylase Deficiency <br />
| OTC<br />
|-<br />
| Osteogenesis imperfeca <br />
| COL1A1; COL1A2<br />
|-<br />
| Osteopetrosis <br />
| CLCN7; OSTM1; TCIRG1<br />
|-<br />
| Pachyonychia Congenita <br />
| KRT16; KRT6A<br />
|-<br />
| Pancreatitis, Hereditary<br />
| PRSS1 <br />
|-<br />
| Papillorenal syndrome <br />
| PAX2<br />
|-<br />
| Phenylketonuria <br />
| PAH <br />
|-<br />
| This table does not cover the complete list of diseases that PGD can be applied to.<br />
|}<br />
<br />
==Laws & Legal status==<br />
===Australia=== <br />
PGD is currently used to detect serious genetic conditions to improve the outcome of Assisted Reproductive Technologies (ART). In very rare cases it may be used to select an embryo with compatible tissue for a sibling who has a life-threatening disease where other means of treatment is unavailable. This is with the conditions that the use of PGD will not affect the welfare and interests of the child to be born. The parents must also receive adequate counselling and have full understanding of the procedures of PGD. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"> National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art</ref><br />
The use of PGD for sex-selection is prohibited with the exception of reducing the risk of the transmission of serious sex-linked genetic conditions. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"/><br />
===Brazil=== <br />
The laws regarding PGD in Brazil are not strictly regulated. They are vague and there is limited information surround the activities of assisted reproduction in general in the country <ref name="PMID25493379"><pubmed>25493379</pubmed></ref>.<br />
===Czech Republic===<br />
The laws in the Czech Republic allow those with a “defined indication in order to exclude risk of serous genetically conditioned disease and defects with embryos before they are implanted into the cavity of the uterus”. Couples that undergo any assisted reproductive treatment including PGD have to be married. Sex-selection is illegal except in regards to serious sex-linked genetic diseases <ref name="PMID24777348"><pubmed>24777348</pubmed></ref>.<br />
===Greece=== <br />
In Greece, ART is open to those up to the age of 50 with written consent. It can only be used if a medical necessity is present such as the susceptibility of serious hereditary diseases. Sex selection is banned apart from cases of sex-linked diseases and sexually transmitted diseases <ref name="PMID24777348"/>.<br />
===Portugal=== <br />
ART is only available to those who are married or have a similar type of relationship for at least two years. The couples cannot be of the same sex and must be at least 18 years of age. Sex selection is illegal except in cases of sex-linked diseases. The use of PGD is illegal if the predictive value of genetic tests are very low <ref name="PMID24777348"/>.<br />
===Spain===<br />
PGD can be applied to “serious hereditary diseases not amenable to postnatal curative treatment” and “detection of other abnormalities which may compromise the viability of the pre-embryo”. If PGD is to be used for any other purpose authorisation must be acquired <ref name="PMID24777348"/>.<br />
===Sweden=== <br />
The use of PGD is strictly regulated and couples must achieve authorisation of the National Board of Health and Welfare. It can only be used it can only be used if the child is at risk to inheriting a serious chromosomal or monogenetic disease. It cannot be used for selection of specific characteristics <ref name="PMID24777348"/>.<br />
===United Kingdom===<br />
Those involved with carrying out the IVF treatment must have a license from the Human Fertilisation and Embryology Authority (HFEA). Only embryos that are approved by the HFEA can be implanted where the embryonic nuclear or mitochondrial DNA cannot be altered with the exception of preventing mitochondrial diseases <ref name="PMID24777348"/>. <br />
==Future/Current Research==<br />
===Noninvasive Preimplantation Genetic Testing without Embryo Biopsy===<br />
Different parameters of gametes, zygotes, embryos (“vacuoles in sperm heads, spindle position in mature oocytes, cleavage intervals of zygote, and embryo developmental dynamics”) may correlate with aneuploidy rates. This knowledge may be applied in potential noninvasive preimplantation diagnostic methods. Several methods have been proposed and are currently further researched<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Sperm Selection====<br />
Intracytoplasmic morphologically selected sperm injection (IMSI) is common procedure in IVF treatment to improve fertilization rates in patients with poor semen quality. In addition, studies have found that IMSI improves embryo development and that spermatozoa with large vacuoles in their heads correlate with increased aneuploidy rates and disturbed chromosomal structures. Thus, selecting spermatozoa based on morphological hallmarks may decrease aneuploidy rates in the fertilized embryos. As with polar body biopsies, however, this approach will solely be applicable if evidence for severe male detrimental contribution is given<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Blastocoel Fluid Extraction====<br />
In addition, a less invasive retrieval of material for diagnosis could include the extraction of the blastocoel fluid. The cavity of the blastocyst, lined by the trophectoderm, is filled with this blastocoel fluid, which contains metabolites of both trophectoderm and inner cell mass origin. The retrieval does not require a biopsy but merely a small opening to extract the fluid and, thus, causes less harm to the embryo. Multiple studies have applied this method<ref name="PMID22020776"><pubmed>22020776</pubmed></ref> <ref name="PMID23148560"><pubmed>23148560</pubmed></ref> and it may in the future become of clinical relevance.<br />
<br />
{|border="1"<br />
| [[File:Aspiration_of_the_Blastocoel_Fluid.jpeg]]<br />
|-<br />
| Aspiration of the Blastocoel Fluid using a ICSI pipette<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
|}<br />
<br />
<br />
Next to metabolites, the blastocoel fluid can contain DNA. Studies have shown that genomic DNA is present in about 90% of the blastocoel fluid samples tested. Typically the fluid is removed with an ICSI pipette from a day five blastocyst through its mural trophectoderm until the blastocyst fully collapses around the embryo. Several concerns regarding this method in a clinical setting have been raised. The collected DNA may be contaminated by the culture media that contains DNA fractions. The DNA may also be least representative of the actual embryos genome as the DNA may originate from abnormal or degenerated cells. Even though labelled noninvasive, the blastocyst still undergoes manipulation to some degree which may affect its viability. Thus, more research is required until this method can evolve from research to clinical use<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
====Proteomics====<br />
The protein secretome of blastocysts may be representative of its chromosome constitution Recent studies have found biomarkers such as lipocalin-1, interleukin-10, tumor necrosis factor, stem cell factor, and chemokine ligand 13 to be differently secreted by aneuploid blastocyst than by euploid ones. The most significant biomarker appears to be interleukin-10. Paired with novel proteomic technologies and mass spectrometry this knowledge when extended may contribute to a new invasive preimplantation genetic diagnosis method<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Embryo Morphology====<br />
Using time lapse imaging the embryo’s morphology can be closely observed and potential aneuploidy characteristics detected. Such characteristics may include the time of division to five cells, the time between the division from three to four cells, and the duration of the division from one to two and subsequently to three. In addition, the morphological quality of ICM an TE has been positively associated with aneuploidy or euploidy prognosis<ref name="PMID26246880"><pubmed>26246880</pubmed></ref>. These may give rise to an embryo quality screening prior to implantation<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
===Utilization of Diseased Cell Lines===<br />
==Ethics==<br />
==References==<br />
<br />
<references/><br />
<br />
<br />
{{StudentPage2015}}</div>Z5017878https://embryology.med.unsw.edu.au/embryology/index.php?title=2015_Group_Project_6&diff=2065472015 Group Project 62015-10-19T11:41:06Z<p>Z5017878: </p>
<hr />
<div>{{ANAT2341Project2015header}}<br />
<br />
<br />
=Prenatal Genetic Diagnosis=<br />
==Introduction==<br />
==History==<br />
Prenatal Genetic Diagnosis was historically conducted post-implantation in the first 2 trimesters <ref> Blackburn, S.L. (2003) '''Maternal, Fetal & Neonatal physiology: a Clinical perspective''' (2nd ed.). Seattle: Saudners </ref>, testing for overall fetal growth, complications of pregnancy, birth defects as well as chromosomal or genetic abnormalities<ref> Sadler T.W.(2012) '''Langman's Medical Embryology''' (12th ed.) Philadelphia: Lipincott, Wiliams & Wilkins, a Wolters Kluwer Business </ref>. Due to advancements in Artificial Reproductive Technologies ( ART) in the past 2 decades , these genetic tests are now conducted as a part of Preimplantation Genetic Diagnosis (PGD) <ref><pubmed>20638568</pubmed></ref> and art used to eliminate the rsik of passing on a genetic disorder to an offspring, before implantation, it ha now become a preventative measure. . In 1990 Preimplantation genetic testing was first used in 1990 on humans to diagnose recessive X-linked diseases in the embryos of pregnant women undergoing IVF. <ref><pubmed>2330030</pubmed></ref> PGD is offered as an alternative to prenatal diagnosis in detecting genetic disorders in high risk couples <ref><pubmed>26168107</pubmed></ref> and avoid passing an inherited disease to the offspring, by selecting genetically "normal" embryos for implantation ,to give the best chance of successful implantation , stable pregnancies and healthy children. <br />
<ref><pubmed>23499002</pubmed></ref><br />
<br />
==Preimplantation Genetic Diagnosis==<br />
[[File:Preimplantation Genetic Diagnosis Procedure.jpeg|700px|thumb|centre| Simplified steps for PGD]]<br />
<br />
<br />
Preimplantation genetic diagnosis (PGD) is used to test the genetic makeup of embryos to detect single gene disorders, chromosomal abnormalities and mitochondrial disorders. It also has applications in gender selection for diseases with unequal gender distributions <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Some diseases commonly involved with PGD include cystic fibrosis, spinal muscular atrophy and beta – thalassaemia <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press.">Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press</ref> <ref name="PMID17823145"><pubmed>17823145</pubmed></ref>. It was first used in the United Kingdom in the 1980s of arenoleucodystrophy and primarily focusing on sex- linked disorders <ref name="PMID17823145"/><ref name="PMID23150080"><pubmed>23150080</pubmed></ref>. PGD is now capable of detecting single cell defects (molecular) and chromosomal disorders resulting from the inversion, translocation or deletion of chromosomes (cytogenic) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>,<ref name="PMID11325751"><pubmed>11325751</pubmed></ref>. PGD can be applied to the embryo at different stages. That is on polar bodies, blastomeres or blastocyst <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>.<br />
Depending on the type of genetic disorder, PGD utilises different methods of genetic testing. These include Fluorescence in situ hybridisation (FISH) which is used for sex – linked disorders and detects chromosomal rearrangements <ref name="PMID11325751"/><ref name="PMID17876073"><pubmed>17876073</pubmed></ref> and Embryo halotyping which allows the identification of chromosomes causing the inherited disorder through knowledge of the pattern of closely linked markers <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. Polymerase chain reaction (PCR) is also widely used to detect molecular abnormalities <ref name="PMID11325751"/>.<br />
PGD is tightly regulated and supported by large organisations namely The American Society for Reproductive Medicine, The European Society for Human Reproduction and Embryology (ESHRE), The European Society of Human Genetics and the Preimplantation Genetic Diagnosis International Society <ref name="PMID25500181><pubmed>25500181</pubmed></ref>.<br />
===Sex-linked disorders===<br />
The determination of a disease as gender specific usually correlates with the presence or absence of specific genes such as SRY on the Y chromosome. It is known that females have two X chromosomes and males have an X and a Y chromosome where abnormalities are more prevalent on the X chromosome. PGD can be used for sex selection where only male embryos are transferred to reduce the chance of inheriting X-linked disorders. However, this does not completely eradicate the problem as male embryos remain susceptible to inheriting an affected X chromosome. Sex determination is only used when the specific mutation is unknown and has yet to be discovered <ref name="PMID24866878"><pubmed>24866878</pubmed></ref>.<br />
===Single gene defects===<br />
Single gene defects can be dominant, recessive, autosomal or X-linked. They are commonly diagnosed using PCR and although the PCR available today is complex and capable of combatting a large range of disease the development of new protocols has been proven to be difficult due to the small DNA sample available <ref name="PMID26168107"><pubmed>26168107</pubmed></ref><br />
===Mitochondrial disorders===<br />
Mitochondrial disorders also known as oxidative phosphorylation disorders arise from mutations in the nuclear DNA or mitochondrial DNA <ref name="PMID26312584"><pubmed>26312584</pubmed></ref>. They pose as a problem because they are unrecognisable until the mutations in the cell reach a detrimental level <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Mitochondrial disorders cause miscarriages and stillbirths as well as death in children and young adults. The effects can either be contained in a single organ or more commonly involve multiple organ failure where organs with high energy demands such as the brain, liver muscle and heart and heavily influenced. They are usually occur spontaneously or result from inheritance from the mother. Since mitochondria are solely inherited from the mother oocyte donations have been used as a solution to combat mitochondrial disorders. Additionally, there has been an increasing use in PGD where embryos that stay under the given threshold of 18% gene-mutations are allowed to be transferred and result in normal development. New technology in the areas of nuclear gene transfer and genome editing are also being experimented with <ref name="PMID26312584"/>. <br />
===Chromosomal disorders===<br />
Chromosomal disorders can be reciprocal, Robertsonian translocations, inversions, deletions and insertions <ref name="PMID26168107"/>. . Data from ESHRE collected between 2010 and 2011 has shown that the most common chromosomal abnormality confronted in PGD are reciprocal chromosomal abnormalities <ref name"PMID26071418"><pubmed>26071418</pubmed></ref>. PGD has also been used successfully for Robertsonian translocations (RT), a type of structural translocation. Children who carry RT are phenotypically normal, however in their later years it is found that they will suffer from infertility and repeated miscarriages due to the high frequency of abnormal embryos <ref name="PMID22081077"><pubmed>22081077</pubmed></ref>. PCR and FISH are the two main techniques used for chromosomal disorders. To be able to conduct the examinations the cells are required to be at the metaphase stage <ref name="PMID26168107"/>. <br />
==Preimplantation Genetic Screening==<br />
Prenatal Genetic Screening (PGS) involves an array of methods or ideas that aim to segregate embryos that have genetic flaws and those that are healthy <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. The occurrence of aneuploidy is high around the stages of early embryonic development and they are the most common cause if miscarriages and congenital birth defects <ref name= "PMID26085841"><pubmed>26085841</pubmed></ref>. They have little effect on the morphology of the embryo making them difficult to identify thus identification heavily relies on genetic testing <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. <br />
Genetic sampling is most commonly conducted using Microarray Comparative Genomic Hybridisation (aCGH) as well as FISH, Quantitative PCR and Single Nucleotide Polymorphism (SNP) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. These methods collectively aim to assess numeral and structural chromosomal errors <ref name= "PMID26085841"/>. Studies have also introduced Next- Generation Sequencing (NGS) <ref name= "PMID26085841"/> and Whole Genome Amplification used to screen imbalances in the complete 24-chromosomes <ref name="PMID25953353"><pubmed>25953353</pubmed></ref><br />
Statistics from ESHRE have shown that the most common indications for PGS is advanced age, followed by repeated implantation failure or recurrent miscarriage and male infertility <ref name="PMID26071418"><pubmed>26071418</pubmed></ref>.<br />
====Indications====<br />
A low percentage of structural abnormalities in chromosomes are responsible for the cause of miscarriages. Despite this, they are the most prevalent type of chromosomal abnormality accounted for in PGD <ref name="PMID20638568"/>. The presence of specific gene cycles, initiation of embryonic protein synthesis and evident physiological development are all indicative of a successful in vitro fertilisation procedure <ref name="PMID11576737"><pubmed>11576737</pubmed></ref>. To eliminate further errors from occurring during the PGD procedure it is recommended to undertake further prenatal testing such as amniocentesis in the later stages <ref name="PMID20638568"/>. <br />
=====Advanced maternal age=====<br />
Data provided by the ESHRE has shown that the mean age of women undergoing PGS is 39 years <ref name="PMID26071418"/>. Women of advanced age have been shown to have a lower rate of pregnancies reaching childbirth <ref name="PMID18583331"><pubmed>18583331</pubmed></ref>. The highlighted concern revolves around the increased occurrence of aneuploidy following maternal age. The optimal age range for the lowest aneuploidy incidence was found to be between 27 to 37 years of age (6%) then progressively higher in women aged up to 42 (33%) and most common in those 44 and above (53%) <ref name="PMID24355045"><pubmed>24355045</pubmed></ref>. <br />
=====Recurrent pregnancy loss / IVF failure=====<br />
Recurrent pregnancy loss is defined as three or more IVF failures after cumulative transfer of more than 10 good-quality embryos. These are primarily caused by two main factors, reduced endometrium receptivity or embryonic defects. Endometrium receptivity can be negatively influences by instances including uterine pathologies such as thin endometrium, altered expression of adhesive molecules and immunological factors. Additionally, embryonic defects may be due to genetic abnormalities, embryonic aneuploidy or zona hardening. Endometriosis and hydrosalpinx has been known to effect both the endometrium and embryo <ref name="PMID23260857"><pubmed>23260857</pubmed></ref>.<br />
=====Human leukocyte antigen matching=====<br />
First used in 2001, HLA matching is an option given to parents to save a child with haematological or immunological disease through conceiving another child who would potentially be able to donate cord blood or haematopoietic stem cells from the bone marrow for transplantation. The process namely PGD-HLA has shown to improve haematopoietic stem cell transplant (HSCT). PGD-HLA can only be performed when HSCT is not needed urgently due to the time needed to conceive and delivery the baby <ref name="PMID25500181"><pubmed>25500181</pubmed></ref>. It is most commonly applied to children suffering from relapsed leukaemia <ref name="PMID22524201"><pubmed>22524201</pubmed></ref>. In a case study PGD-HLA was proven to successfully cure 10 diseases including Fanconi anaemia, Diamond-Blackfan anaemia and beta thalassemia <ref name="PMID25066893><pubmed>25066893</pubmed></ref>.<br />
==Biopsy Methods==<br />
Biopsy, the removal of genetic materials, from oocytes or embryos in the preimplantation stage is the primary step in PGD. For the past two decades these biopsies have been performed at three stages, the polar body, blastomere, and blastocyst, and the methodologies optimized to ensure the embryo’s viability. The most common approach involves biopsies at the cleavage stage. However, polar body and blastocyst biopsies are increasingly more often tested and applied. Approached for opening the zona pellucida involve next to the traditional mechanical and chemical means, novel approaches such as noncontact lasers. Their application may simplify and secure the procedure significantly. The most challenging question about PGD procedures remains at what stage biopsies should be taken. Much controversy has developed around this topic, highlighting the varying disadvantages and advantages of temporal biopsies. <ref name="PMID22723007"><pubmed>22723007</pubmed></ref><br />
<br />
{|border="1" align="left"<br />
|-bgcolor="pink" <br />
|<br />
| Time of Biopsy<br />
| Advantages <br />
| Disadvantages<br />
|- <br />
| Polar Body<br />
| Day 1<br />
| No harm to oocyte<br />
| Only maternal DNA is tested, often needs to be coupled with other biopsies<br />
|-bgcolor="pink"<br />
| Blastomere<br />
| Day 3<br />
| …<br />
| … <br />
|-<br />
| Trophectoderm<br />
| Day 5 and 6 <br />
| Little harm, large amount of genetic material<br />
| Opening of blastocyst necessary, small time window for procedure<br />
|}<br />
<br />
{|border="1"<br />
| [[File:Polar_Body,_Blastomere,_and_Trophectoderm_Biopsy.jpeg]]<br />
|-<br />
| Polar body (A), blastomere (B) and trophectoderm (C) biopsies<ref name="PMID25625041"><pubmed>25625041</pubmed></ref>.<br />
|}<br />
<br />
PMID 24305177<br />
===Polar Body Analysis===<br />
Day 1<br />
====Description====<br />
Polar body (PB) biopsy, which was introduced in 1990, offers a promising alternative to biopsies performed at the blastomere stage for PGD/S indications on legal and practical grounds. <br />
Description: Consequent embryo development does not necessitate the presence of the first and second PB and their removal may not be crucial. PB biopsy requires precise timing. Keeping track of the meiotic cell cycle is necessary to perform a successful biopsy and, therefore, PB biopsy usually is applied in combination with intracytoplasmic sperm injection (ICSI). During the maturation from the germinal vesicle stage to the metaphase-II stage the first PB is formed. A cytoplasmic bridge containing spindle remnants, that are still in contact with the cellular genetic material, links this PB to the oolemma for about 90 minutes after extrusion. It is possible to visualize these remnants by polarization microscopy and it is crucial to not perform the biopsy until the first PB is no longer firmly attached to the oolemma as this indicates an immature embryo.The oocyte tolerates mechanical zona dissection best during hours four until six after ICSI as the oolemma has stabilized by that time because of the cortical granule reaction. Over time the first PB degenerates stressing a temporal biopsy and its optimal extraction time window is four to 12 hours after ICSI. The second PB forms around two to four hours after ICSI. However, its optimal time window for biopsy is set to be eight to 16 hours after ICSI. This is due to the second PB being attached to the oolemma with spindle remnants until six hours after ICSI. Biopsy at this point may cause enucleation of the oocyte. In addition, studies have shown that the amplification efficiency of second PB’s DNA is worse if the PB is extracted prior to eight hours after ICSI. <br />
Thus, it is possible to perform sequential and simultaneous biopsies for the first and second PB. If performed, sequentially the first PB may be removed four to 12 hours and the second PB eight to 16 hours after ICSI. The optimal time window for a biopsy for both the first and second PB simultaneously is eight to 12 hours after ICSI. It is highly preferred to analyze both PBs due to potential aneuploidies in either PB and crossing overs during meiosis<ref name="PMID22723007"/>. <br />
====Procedure====<br />
Chemical opening achieved with for example acidic tyrode’s solution of the zona pellucida is not tolerated by the oocyte and may have detrimental effects on the embryo’s development. Therefore, the access to the perivitelline space of the oocyte is provided by mechanical zona dissection or by laser. Both techniques work well if performed by experienced embryologist. However, laser-assisted biopsy is less time consuming when compared to manual dissection. It is critical to consider the size of the introduced opening as it will remain permanent. If it is too large the blastomere may be lost during embryo development and if it is too small it may interfere with hatching of the embryo during blastocyst stage<ref name="PMID22723007"/><br />
<br />
{|border="1"<br />
| [[File:Polar_Body_Biopsy.jpeg]]<br />
|-<br />
| The presence of a faint but clearly identifiable strand connecting PB2 to the <br />
oolemma. The biopsy was performed ∼9 h after ICSI<ref name="PMID21908464"><pubmed>21908464</pubmed></ref>.<br />
|}<br />
<br />
{|border="1"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JTaQzszVr8o</html5media><br />
|-<br />
| Laser-assisted polar body biopsy<ref>RIUK, R. (2013, June 25) Polar Body Biopsy [Video file]. Retrieved from https://www.youtube.com/watch?v=JTaQzszVr8o</ref><br />
|}<br />
<br />
====Advantages & Disadvantages====<br />
PB biopsies can only investigate the maternal contributions to the embryo as they are of maternal origin. Thus, this procedure is appropriate for PGD solely for monogenetic diseases from the maternal side. Recessive diseases may be evaluated with PB biopsies on the basis that the embryo’s outcome will be determined by the paternal contribution. (...) It may still be applied for PGS as most aneuploidies either arise during meiosis or origin from the maternal genome. However, diagnosis error has been reported due to the lack of considering paternal contributions. <br />
Because PB biopsies are performed very early it is not yet known whether the oocyte will develop into a viable embryo. Thus, PBs are commonly frozen or fixed after biopsy and depending on the state of the embryo only chosen PBs will be tested. This is primarily an economic issue as many genetic testing procedures are very cost-intensive<ref name="PMID22723007"/>.<br />
<br />
{|border="1"<br />
| [[File:Implantation_predictive_value_of_euploid_screening_results.jpeg]]<br />
|-<br />
| The sustained implantation predictive value (with 95 % confidence interval) of a euploid screening result obtained from the first polar body (PB1), PB1 and the second polar body (PB2), or a direct embryo biopsy for each stage of embryo transfer (cleavage-stage and blastocyst stage)<ref name="PMID25106935"><pubmed>25106935</pubmed></ref>.<br />
|}<br />
<br />
===Blastomere biopsy===<br />
Day 3 <br />
====Description====<br />
Blastomere biopsy has been the prevalent method for PGD and PGS in the last two decades. At least one, but up to two, blastomeres are biopsied on day three of the cleavage stage embryo. The right number of blastomeres removed is a controversial topic as two cells allow for more genetic material and more accurate results. However, removing two cells might be too invasive and damaging to the embryo. (Study)<ref name="PMID21748341"><pubmed>21748341</pubmed></ref><br />
====Procedure====<br />
Initially a hole was drilled into the zona pellucida using acid tyrodes and the blastomeres are removed via aspiration with a pipette<ref name="PMID21748341"/>.<br />
<br />
{|border="1"<br />
| [[File:Aspiration_of_a_Blastomere.jpeg]]<br />
|-<br />
| Aspiration of a Blastomere into the biopsy pipette<ref name=" PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
|}<br />
<br />
{|border="1"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=TbridWVwipI</html5media><br />
|-<br />
| Laser-assisted blastomere biopsy<ref>Sukprasert, M. (2014, March 5) Day 3 Blastomere Biopsy 1 [Video file]. Retrieved from https://www.youtube.com/watch?v=TbridWVwipI</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
===Trophectoderm biopsy===<br />
Day 5 and 6<br />
====Description====<br />
The improvement of embryo culture media allowed the in vitro development of human embryos until the blastocyst stage and opened up the possibility to take blastocyst biopsies. During day three to day five the haploid maternal and paternal genomes work together for the first time to form the genome of the embryo. The maternal epigenetic control lessens significantly while preparing for implantation with precisely arranged events happening. The first event includes a rapid increase in the number of embryonic cells which are active in mitotic divisions and apoptosis of aberrant cells. This is followed by the formation of blastocoel (cavitation) which results from the flattening of cell located on the outside of the blastomere. Now the blastocyst will expand until the embryo hatches by rupturing the zona pellucida. The cells of the blastocyst will differentiate to form two distinct cell lineages, the outer trophectoderm and the inner cell mass<ref name="PMID22723007"/>.<br />
====Procedure====<br />
Trophectoderm biopsy is usually performed in Hepes buffered biopsy medium and opening approaches include needle cutting which has been replaced by lasers in past years. Different research groups report different timings of the opening to be the most successful. Some open the blastocyst on day three or four by creating a 25 µm which causes the trophectoderm to herniate through this hole and is, thus, accessible for biopsy. Others create this hole about four hours before biopsy which allows sufficient herniation of trophectoderm cells. It is also possible to open the blastocyst immediately before biopsy. This avoids an extra step and the inner cell mass usually is easy to locate. Blastocyst biopsies involve the removal of trophectoderm cells and the ideal time for the procedure is day five. Successful biopsies on day six have been performed, while little is known about the results of biopsies on day seven. However, since the window of implantation in humans is from day eight to ten after ovulation, day seven biopsies appear to be possible<ref name="PMID22723007"/>.<br />
-collapse of trophoblasts<br />
-possible: biopsy of hatched blastocyst, holding pipette careful mild suction force to hold embryo near ICM <br />
-Cryopreservation<br />
<br />
{|border="1"<br />
| [[File:Microscopic images of human blastocysts for biopsy.jpeg]]<br />
|-<br />
| (A) Some trophectoderm cells in a blastocyst started to hatch and (B) the trophectoderm cells were biopsied with assisted laser cutting. Images in C–D show the blastocysts after vitrification and warming. Blastocysts had been cultured for 2–4 hrs after warming, showing good (ICM and trophectoderm cells) hatched (C) and hatching (D) blastocysts. The hatching blastocyst in (E) has good ICM but fair trophectoderm while the blastocyst in (F) has both fair ICM and trophectoderm. Arrows indicate ICMs and arrow heads indicate trophectoderm cells. Bar = 40 µm<ref name="PMID2190846"><pubmed>2190846</pubmed></ref>.<br />
|}<br />
<br />
<br />
{|border="1"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JI_TQ8d8tNM</html5media><br />
|-<br />
| Laser-assisted blastocyst biopsy (at 00:50 min)<ref>Coco, R. (2014, April 30) Trophectoderm biopsy in a Hatching blastocyst protruding ICM [Video file]. Retrieved from https://www.youtube.com/watch?v=JI_TQ8d8tNM</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
Blastocyst biopsies are believed to be less damaging to the embryo and appear to be unrelated to implantation rates. In addition, this biopsy method allows for a larger extraction of cells for genetic testing. However, since they are performed late in in vitro development, the time window for genetic testing is relatively small. Fast and accurate genetic testing methods are needed to ensure a successful and safe result from this biopsy. Thus, blastocyst biopsies may gain more popularity in the future whn such methods have been developed or improved<ref name="PMID22723007"/>. <br />
<br />
<br />
==Genetic Techniques==<br />
<br />
===PCR===<br />
====Description====<br />
Polymerase chain reaction (PCR) amplifies DNA specific to genetic sequence of interest . PCR was developed by Kay Mullis in the 1980s, for which he was awarded the Nobel prize for chemistry in 1993. <ref> Pubmed Docs (2015) Polymerase Chain Reaction (PCR) Pubmen. Retrieved from [http://www.ncbi.nlm.nih.gov/probe/docs/techpcr/]</ref> This technique enables clinicians to monitor and diagnose diseases using minute samples such as embryonic cells, blood & tissue. <ref>Roche (2015) PCR: How We Copy DNA. Roche Molecular Systems Inc. retrieved From [http://molecular.roche.com/pcr/Pages/Process.aspx]</ref> PCR has many important applications like DNA fingerprinting, genetic mapping, detection of viruses and bacteria as well as being used to detect genetic disorders, as a part of PGD, in conjunction with IVF. It is used to detect molecular abnormalities such as single gene disorders like Tay Sach, Cycstic fibrosis, Duchenne Muscular Dystrophy, Thalassemia, Huntington disease, Spinal muscular atrophy and many more. Molecular and Genetic analysis require a significant amount of DNA, which we would not have without PCR. It revolutionized the study of DNA, replacing all previous recombinant DNA technology. <ref> Mullins, K., Francois, F.& Gibbs R.A. (1994 ) The Polymerase Chain Reaction. p3. Springer- Science +Business Media. Birkhauser, Boston<br />
Available at [https://books.google.com.au/books?hl=en&lr=&id=gjrTBwAAQBAJ&oi=fnd&pg=PR5&dq=kary+mullis+PCR&ots=mpzAyRh5ZY&sig=PQ4goNoKJ90tb3-MkPk62zrTGbw#v=onepage&q=kary%20mullis%20PCR&f=false] </ref> <br />
<br />
====Procedure====<br />
<br />
Sample are obtained from the the blastocyst, a polar body biopsy or the blastomeres stages of the embryo. <br />
Stage 1 Denaturing: separating the target strands of DNA <br />
The obtained sample is heated to roughly 90 degrees celcius, this heat causes breaks the relatively weak bonds between nucleotides that form DNA. the double stranded DNA to split into 2 single strands of DNA that are used as templates.<br />
Stage 2 Annealing: Binding the Primers to the target DNA sequence <br />
PCR will only copy the target sequence of DNA specified by specific PCR primer. These synthesized primers Oligonucleotides are small artificial pieces of DNA. <br />
TAQ polymerase enzyme synthesize 2 new strands of DNA duplicate to the single sample DNA stand template indicated by these primers. During this stage the reaction is cooled to a temperature between 40-60 degrees Celsius. <br />
Stage 3- Extension- making copies <br />
Each of these 2 copies are then used again as templates generating 2 further replications This cycle can occur as many 30 -40 times within a couple hours leading to billions of extra copies of the original DNA segment. The optimal temperature for the further replication is roughly 72 degrees Celsius. <br />
<br />
This process mediated by a thermocycler machine that is programmed to alter the temperature of the reaction every couple of minutes, perpetuating the cycle of DNA denaturing and synthesis. <br />
This process, generates exponential exact copy of the original template DNA sequence. <br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
!PCR cycles<br />
<br />
|{|<br />
|-bgcolor="lightpink"<br />
| '''PCR Cycle'''<br />
| '''Target Copies'''<br />
|-<br />
| 1<br />
| 2<br />
|-bgcolor="pink"<br />
| 2<br />
| 4<br />
|-<br />
| 3<br />
| 8<br />
|-bgcolor="pink"<br />
| 4<br />
| 16<br />
|-"<br />
| 5 <br />
| 32<br />
|-bgcolor="pink"<br />
| 6 <br />
| 64<br />
|-<br />
| 7 <br />
| 128<br />
|-bgcolor="pink"<br />
| 8<br />
| 256<br />
|- <br />
| 9<br />
| 512 <br />
|-bgcolor="pink"<br />
| 10<br />
| 1024<br />
|-<br />
| 15<br />
| 32,768<br />
|-bgcolor="pink"<br />
| 20 <br />
| 1,048,578<br />
|-<br />
| 25<br />
| 33,554,432<br />
|-bgcolor="pink"<br />
| 30 <br />
| 1,073,741,842<br />
|-<br />
|}<br />
<br />
<br />
<br />
<br />
{|border="1" align="right"<br />
|-bgcolor="pink" <br />
| '''Advantages''' <br />
|'''Disadvantages'''<br />
|- <br />
| fast and inexpensive way of copying a target sequence of DNA<br />
| only during this exponential DNA replication phase can we determine the starting quantity sequence contained in the original sample ( template DNA strand)<br />
|-bgcolor="pink"<br />
| aids the diagnosis of single cell defects<br />
| PCR reaction is limited by the presence of inhibitors present in the sample : reagent inhibitors <br />
|-<br />
| rapid generation of results within a couple hours<br />
| self annealing due to the accumulation of the product -stopping exponential amplification for the target sequence and reach a plateau<br />
quantification of the end point of reaction of PCR products unreliable - therefore that is why we require real time quantitative RT-PCR necessary<br />
<ref> NIS (2015) Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref><br />
|-bgcolor="pink"<br />
| can start from a single molecule of DNA, therefore is more sensitive <br />
| <br />
|-<br />
| has a flexible primer design enabling<br />
| <br />
|-bgcolor="pink"<br />
| overcame previous issues associated with the limited availability of sites of end<br />
| <br />
|-<br />
| generates the DNA copies exponentially<br />
| <br />
|-bgcolor="pink"<br />
| enables DNA amplification required for molecular and genetic analysis<br />
| <br />
|-<br />
|Valid diagnostic method in selecting unaffected embryos for embryo transfer <ref> Dreesen, J., Drusedaul, M., Smeets, H., Die-Smulders, C., Coonen, E., Dumoulin, J., Gielen, M., Evers, J., Herbergers, J. & Geradets, J. (2008) Validation of preimplantation genetic diagnosis by PCR analysis: genotype comparison of the blastomere and corresponding embryo, implications for clinical practice. Mol. Hum. Reprod. 14 (10):573-579.doi: 10.1093/molehr/gan052. Retrieved from [http://molehr.oxfordjournals.org/content/14/10/573.short] </ref> <ref><pubmed>20966460</pubmed></ref><br />
|<br />
|}<br />
<br />
<br />
<br />
<br />
<br />
<br />
<br />
<br />
<br />
===Fluorescent In Situ Hybridisation (FISH)===<br />
<br />
<br />
====Description====<br />
Fluorescence in situ hybridization (FISH) the one of the most effective and rapid <ref name="PMID26338801"><pubmed>26338801</pubmed></ref> Preimplantation Genetic Diagnosis (PGD). This techniques used to locate a specific DNA sequences within a chromosome. FISH facilitates the clinical diagnosis of chromosomal abnormalities indicated by sequential duplications, deletions and rearrangements of chromosome, that are usually missed with microscopic analysis. This technique is especially relevant for female embryos with X-linked diseases,<ref><pubmed>20809319</pubmed></ref> that have no other mutation specific tests [http://www.ncbi.nlm.nih.gov/pubmed/20809319] As part of PGD, samples are collected from various stages of the embyro,and they are able to conducted tests on the blastocyst, a polar body biopsy and the blastomeres <ref><pubmed>21748341</pubmed></ref>. FISH is 99% effective when used in conjunction with competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities<ref name="PMID26338801"/>.<br />
<br />
====Procedure==== <br />
<br />
Samples are collected from either the blastocyst, a polar body biopsy or the blastomeres stages of the embryo <ref><pubmed>21748341</pubmed></ref>. <br />
DNA strands are heated and denatured causing their the individual DNA strands to break apart<br />
Probes are single complimentary stands of DNA a that have been tagged with small chemical agents that glow brightly in the presence of a specific region on a chromosome. These specific probes then hybridize and join to their complementary DNA strand. <br />
The fluorescent tags enable the researchers to correctly identify the presence or lack thereof and location of the specific chromosomes that they are testing for. <ref><pubmed>17876073</pubmed></ref><br />
Researcher analyse the results by identifying the number and the relative location of the fluorescent dots generated by the FISH images.<ref><pubmed>17970921</pubmed></ref><br />
The probe will not fully hybridise if there has been a duplication or a deletion of the DNA - indicating chromosomal and sex chromosomal anomalies like trisomies and aneuploidies. <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref><br />
<br />
<br />
Different probes are used for different purposes: <ref>Unique, Rare Chromosome Disorder Support Group (2013) Fluorescence in situ hybridisation (FISH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/Other/FISH%20FTNW.pdf]</ref><br />
*'''Locus specific tags''' detect very small imbalances, and locate isolated small portions <br />
of genes within a chromosome<br />
*'''Alphoid/Centomeric Repeat probes''' are developed from the repetitive sequence located in the middle region of each chromosome, useful in determining the number of chromosomes , detecting rearrangement and when used in conjunction with locus probes to determine the absence of genetic material on a chromosome. <br />
*'''Paint Probes''' are collections of smaller probes with their own stains that bind to a different section on the chromosome - allowing the full chromosome too be labeled a unique colour, this "full colour map" can be used to know the spectral karyotype- full chromosomal mapping is useful in examining chromosomal abnormalities. <br />
<br />
{|border="1"<br />
| [[File:Fluorescent In Situ Hybridisation (FISH).jpg|thumb|right|'''FISH''' We are able to tag Specific DNA sequences using Probes which have been tagged with fluorescent Labels.This technique enables the clinical diagnosis of chromosomal abnormalities, indicated by sequential duplication, deletions and rearrangements of chromosome <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref>]]<br />
|}<br />
<br />
<br />
<br />
{|border="1" align="right"<br />
|-bgcolor="pink" <br />
| rowspan="7" |'''Advantages''' <br />
| FISH is 99% effective when used in conjunction with Competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities.<ref><pubmed>26338801</pubmed></ref><br />
|-bgcolor="pink" <br />
| Rapid generation of results<br />
|-bgcolor="pink" <br />
| Identifies very small translocations and aneuploidies that occur within chromosomes, that would usually be missed under microscopic analysis<br />
|-bgcolor="pink" <br />
| Indicates whether the accessed chromosomes are normal <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|-bgcolor="pink" <br />
| Tests for the most common chromosomal abnormalities - down syndrome chromosomes 13,16,18,21 and 22 <ref><pubmed>21749752</pubmed></ref><br />
|-bgcolor="pink" <br />
| It may be used to compare the chromosomal gene arrangements in related species<br />
|-bgcolor="pink" <br />
| can be used to identify and remove inheritable X-linked disease or sex chromasome anomalies such as Duchennes Muscular Dystrophy, hemophilia, ectodermal dysplasia <ref><pubmed>17876073</pubmed></ref><br />
|-bgcolor="white"<br />
| rowspan="4"|'''Disadvantages'''<br />
| FISH destroys all cells tested <ref> O'Connor, C. (2008) Fluorescence in situ hybridization (FISH). Nature Education 1(1):171. retrieved from [http://www.nature.com/scitable/topicpage/fluorescence-in-situ-hybridization-fish-327] </ref><br />
|-<br />
| It does not fully access all chromosomes (only ~ 12)<br />
|-<br />
| Analysis of results is dependent upon the dot quality impacted by hybridisation efficiency or the camera sensitivity <ref><pubmed>17970921</pubmed></ref><br />
|-<br />
| some studies indicate that using FISH on a day-3 embryo biopsy decreases the rate of live births <ref><pubmed>26168107</pubmed></ref><br />
|<br />
|}<br />
<br />
<br />
<br />
===Array Comparative Genomic Hybridisation (aCGH)===<br />
====Description====<br />
<br />
aCGH also known as Microarray analysis efficiently scans the entire genome for chromosomal imbalances. CGH was initially developed to detect the number of changes in a solid tumor mass. It uses 2 genomes comparing the sample to the control, with each labeled in a different fluorescent dye<ref><pubmed>1876176</pubmed></ref>. Earlier CGH techniques were limited by the resolution of the imaging <ref> Lichter, P., et al. Comparative genomic hybridization: Uses and limitations. Seminars in Hematology 37, 348–357 (2000)</ref> , these initial limitations were overcome by using Microarrays in conjunction with CGh to improve the resolution of the imaging, Array Comparative Genomic Hybridisation (aCGH). This method compares sample and control microarrayed slides containing small segments of DNA (probes). <ref> Lucito, R., et al. Representational oligonucleotide microarray analysis: A high-resolution method to detect genome copy number variation. Genome Research 13, 2291–2305 (2003) </ref> the Probes used will vary according from the small (25-85 base pairs) oligonucleotides manufactured to highlight different target sequences, to the very large genomic clones (80,000- 200,00 base pairs), and as these are significantly smaller than the traditional metaphase chromosomes used for CGH, generating a higher resolution of image. <ref><pubmed>22467166</pubmed></ref>.aCGH is used as a diagnostic tool for prenatal detection f chromosomal abnormalities <ref><pubmed>19012303</pubmed></ref>.<br />
<br />
<br />
====Procedure====<br />
<ref> Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432] </ref><br />
The sample is obtained (skin, blood or fetal cells) and DNA is obtained. <br />
As a part of PGD fetal cell samples are collected from; the fertilized egg polar bodies, the blastomere (day 3 embryo) or the blastocyst/tropoectoderm stage (day 5 embryo).<br />
Sample DNA is labeled with one fluorescent dye, and the control DNA is labeled with a different colored fluorescent dye. the control DNA is used as the base point of reference. <br />
heated and denatured single DNA strands then hybridize to their complementary single strand probes, which are then combined and applied to a microarray and the results are run through a computer program and a digital imaging system is used to quantify the results( fluorescent intensities of the labeled probes). <br />
<br />
simple explanation of aCGH : [Genomics Education (2014) Genetic Testing for Health: aCGH|https://vimeo.com/84757281]<br />
<ref>Genomics Education (2014) Genetic Testing for Health: aCGH [video file] Vimeo [https://vimeo.com/84757281]</ref><br />
<br />
<br />
The fluorescent ratio and the hybridization signal at different locations on the genome of the control DNA are used to identify any variances present in the sample DNA. aCGH facilitates the clinical diagnosis of submicroscopic chromosomal duplication, deletion and rearrangements indicative of chromosomal disorders such as trisomies 1-22and specific sex linked disorders. <br />
Duplications in the DNA are displayed by the computer program as spikes/ peaks over an established threshold and deletions in DNA are displayed by the computer program as spikes/ toughs beneath this threshold <br />
-computer screening image- <br />
-drawn diagram of method-<br />
<br />
<br />
<br />
{|border="1" align="right"<br />
|-bgcolor="pink" <br />
| '''Advantages''' <br />
| '''Disadvantages'''<br />
|-<br />
| multiple applications: prenatal genetic diagnosis, cancer diagnosis, <ref><pubmed>20193845</pubmed></ref> genetic screening for developmental delay (learning disabilities) <ref><pubmed>17309648</pubmed></ref>. or congenital anomalies that are suspected to be genetic in origin <ref>NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation . retrieved from [http://www.phgfoundation.org/file/5237/]</ref><br />
| translocations and inversions of DNA are not detected<br />
|-bgcolor="pink"<br />
| trace represents all chromosomes present in the human genome chromosomes 1-22 and the X & Y chromosomes, and therefore is the most accurate method for testing whole embryo aneuploidy<br />
| limited ability diagnosing specific polyploidies such as triploidy <ref> Unique, Rare Chromosome Disorder Support Group (2013) Microarray-based Comparative Genomic Hybridiation (array CGH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/other/array%20cgh%20ftnw.pdf] </ref><br />
|-<br />
| aCGH has been extensively tested, and Validated, and is now used world wide.<br />
| will not detect mosaicism detection <20% (cultures where >1 of 5 cells are trisomy 12)<br />
|-bgcolor="pink"<br />
| detects deletions and additions and rearrangements as well as amplification, of the WHOLE genome, simultaneously.<br />
| will not detect balanced chromosomal rearrangement<br />
|-<br />
| detects submicroscopic alterations<br />
| will not detect duplications or deletions <80kb<br />
|-bgcolor="pink"<br />
| used as a diagnostic tool for prenatal detection of chromosomal abnormalities <ref><pubmed>22034057</pubmed></ref><br />
| will not detect point mutations within genes <ref>Washington department of education (CGH- FAQ for physicians. Signature Genomic LAboratories, LLC. Retrieved from [https://depts.washington.edu/dbpeds/Lab%20Tests/SignatureCGH-physician_FAQ.pdf]</ref><br />
|-<br />
| provides high resolution genomewide screening of segmental genomic copy number variations<br />
| will not detect chromosomal position of genomic gains<br />
|-bgcolor="pink"<br />
| very accurate when used in conjunction with FISH<br />
| will not detect loos of heterozygosity (LOH) or Absence of heterozygosity (AOH) <ref>WiCell Research Institute Inc. (2012) Comparative Genomic Hybridization Microarray. <br />
retrieved from [http://www.wicell.org/home/cytogenetic-services/cgh-microarray/array-comparative-genomic-hybridization-acgh.cmsx]</ref><br />
|-style="background:pink"<br />
|Alone is more reliable and in detecting chromosomal abnormalities, with a higher implantation success rate, than FISH <ref><pubmed>20494259</pubmed></ref><br />
|<br />
|-bgcolor="pink"<br />
|Allows an in depth research focus upon specific types of rearrangements within selected chromosomal regions, a recent particular area of interest is subtelomeric and pericentromeric rearrangements<br />
|<br />
|-<br />
|reduces the risk of failed implantation and miscarriage, improving the chance of a healthy baby <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|<br />
|}<br />
<br />
<br />
<br />
===Next Generation Sequencing===<br />
====Description====<br />
The development and advances within ART in the past 20 years, as well as the increasing popularity of IV, has lead to an influx of new technologies developed to screen embryos for chromosomal anomalies, which are covered by the umbrella term of Next generation Sequencing (NGS). NGS is a general term used to describe all of the new and emerging screening techniques currently being introduced and used as part of PGD for IVF . NGS screens for single gene disorders as well as conducting extensive and very comprehensive chromosome diagnosis by sequencing, counting, and accurately assembling millions of DNA reads, simultaneously. <ref><pubmed>23499002</pubmed></ref> There is a movementfor NGS to replace the other limited testing techniques and be used as the standard. <br />
====Procedure====<br />
Samples are collected from either blastomere or the blastocyst/tropoectoderm and processed for analysis by a computer system. <br />
The methodology of each process is unique to the technique being used. <br />
<br />
<br />
<br />
{|border="1" align="right"<br />
|-bgcolor="pink" <br />
| '''Advantages'''<br />
| '''Disadvantages'''<br />
|-bgcolor="white"<br />
| cheaper<br />
| there are limited information available to clinical applications of NGS <ref><pubmed>26100406</pubmed></ref><br />
|-bgcolor="pink"<br />
| opens new diagnostic possibilities<br />
|<br />
|-bgcolor="white"<br />
| accurately tests all 24 chromosomes<br />
| <br />
|-bgcolor="pink"<br />
| tests for the presence of monogenic diseases of known genetic background<br />
| <br />
|-bgcolor="white"<br />
| reduces the number of biopsies required for diagnosis<br />
| <br />
|-bgcolor="pink"<br />
| higher detection rate of small translocations<br />
| <br />
|-bgcolor="white"<br />
| highly accurate is testing for compound point mutations, chromosomal duplication, deletions and insertions <ref><pubmed>23312231</pubmed></ref><br />
| <br />
|-bgcolor="pink"<br />
| it accurately detects chromosomal aneuploidy and unbalanced rearrangement <ref><pubmed>25685330</pubmed></ref><br />
| <br />
|-bgcolor="white"<br />
| NGS single gene disorder screenings can conducted in conjunction with PCR comprehensive chromosomal screening<br />
|<br />
|-bgcolor="pink"<br />
| Reduces human error <br />
|<br />
|-bgcolor="white"<br />
| better detects the presence of mosaicism<br />
|<br />
|-bgcolor="pink"<br />
| work well in conjunction with CGH and aCGH as part of PGD, improving the chances of IVF. <ref> Morris, R. S. (2015 ) Next generation sequencing for PCG|PGS|CCS. IVF1 retrieved from [http://www.ivf1.com/next-generation-sequencing for-pgd] </ref><br />
|<br />
|}<br />
<br />
<br />
<br />
<br />
<br />
<br />
==Diagnosis==<br />
There are a large amount of diseases that PGD can apply to, below are descriptions of the diseases that PGD are more commonly used for. <br />
===Cystic Fibrosis===<br />
Cystic fibrosis is a single gene disorder. It is autosomal recessive and involves mutations in the cystic fibrosis transmembrane conductance regulator (CTFR) gene. The CTFR gene is normally responsible for the decrease in chloride and the transport of bicarbonate in epithelial cells thus playing a major physiological role. In PGD procedures, identification of the gene is assisted by microsatellite markers that have similar composition to the CTFR gene itself. Biopsy of two cells at the blastocyst stage is recommended if markers are not available. There are many variations of cystic fibrosis the most common being P.Phe508del <ref name="PMID26014425"><pubmed>26014425</pubmed></ref>.<br />
===Duchenne Muscular Dystrophy ===<br />
Duchenne Muscular Dystrophy is an X-linked recessive disease. It involves the Xp21 gene where majority of the mutations are chromosomal deletions with a smaller percentage resulting from duplications <ref name="PMID18359022"><pubmed>18359022</pubmed></ref>.<br />
===β – Thalassemia=== <br />
β – Thalassemia is known as the most common type of autosomal recessive inherited disorder among haemoglobinopathies. It involves the adult β-globin gene and is associated with the absent or decreased expression of the gene. This is commonly caused by a single nucleotide change in the gene. PGD has been used successfully worldwide to identify the β-globin gene where its application is usually performed on a single blastomere or polar body <ref name="PMID19064120">19064120</pubmed></ref>.<br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
! Applicable diseases for PGD <ref>Genoma Group (2014). Retrieved September 18th, 2015, from http://www.preimplantationgeneticdiagnosis.it/genetic-diseases-diagnosed-by-pgd.htm </ref>, <ref>Genesis Genetics (2015). Retrieved September 18th, 2015, from http://genesisgenetics.org/pgd/what-we-test-for/</ref>, <ref>Human Fertilisation & Embryology Authority (2015). Retrieved Septembr 18th, 2015, from http://guide.hfea.gov.uk/pgd/</ref><br />
<br />
|{<br />
| '''Disease'''<br />
| '''Involved Genes'''<br />
|-<br />
| 5 Alpha Reductase Deficiency (5ARD)<br />
| SRD5A2 <br />
|-<br />
| Achondroplasia<br />
|FGFR3 <br />
|-<br />
| Acute Intermittent Porphyria <br />
| ALAD, ALAS2, CPOX, FECH, HMBS, PPOX, UROD, or UROS<br />
|-<br />
| Adrenoleukodystrophy (Adrenomyeloneuropathy)<br />
| ABCD1 <br />
|-<br />
| Agammaglobulinaemia (x-linked) <br />
|BTK <br />
|-<br />
| Agammaglobulinemia Bruton Tyrosine Kinase (BTK) <br />
|BTK <br />
|-<br />
| Aicardi Goutieres Syndrome 1 (AGS1) <br />
|TREX1, RNASEH2A, RNASEH2B, RNASEH2C, SAMHD1<br />
|-<br />
| Alagille Syndrome<br />
|JAG1 or NOTCH2<br />
|- <br />
| Alpers-Huttenlocher Syndrome <br />
|POLG <br />
|-<br />
| Alpha-1-antitrypsin deficiency <br />
|SERPINA1 <br />
|-<br />
| Alpha-Mannosidosis<br />
| MAN2B1 <br />
|-<br />
| Alpha Thalassemia <br />
|HBA1 or HBA2 <br />
|-<br />
| Alports Syndrome<br />
|COL4A3, COL4A4, COL4A5<br />
|-<br />
| Alzheimer's Disease - early onset (Type 3 and 4) <br />
|APP, PSEN1, or PSEN2<br />
|-<br />
| Amyotrophic Lateral Sclerosis 1 (ALS1) <br />
|C9orf72, SOD1, TARDBP, FUS, ANG, ALS2, SETX, VAPB <br />
|-<br />
| Argininosuccinic Aciduria <br />
| ASL<br />
|-<br />
| Arrhythmogenic Right Ventricular Cardiomyopathy/ Dysplasia (ARVC/D)<br />
| DSG2; DSP; PKP2<br />
|-<br />
| Ataxia Telangiectasia<br />
| ATM<br />
|-<br />
| Bardet-Biedl Syndrome (BBS)<br />
| BBS1; BBS10<br />
|-<br />
| Barth Syndrome<br />
| TAZ<br />
|-<br />
| Beta Thalassaemia<br />
| HBB<br />
|-<br />
| Birt-Hogg-Dubé Syndrome<br />
| FLCN<br />
|-<br />
| Breast Ovarian Cancer Familial Susceptibility (BRCA2)<br />
| BRCA1; BRCA2<br />
|-<br />
| Canavan Disease <br />
| ASPA<br />
|-<br />
| Carnitine-Acylcarnitine Translocase Deficiency <br />
| SLC25A20<br />
|-<br />
| Cerebral Arteriopathy with Subcortical Infarcts & Leukoencephalopathy (CADASIL)<br />
| NOTCH3<br />
|-<br />
| Cerebral Cavernous Malformation<br />
| CCM1<br />
|-<br />
| Charcot-Marie-Tooth Disease<br />
| GJB1; MPZ; NEFL; PMP22<br />
|-<br />
| CHARGE Syndrome<br />
| CHD7<br />
|-<br />
| Cherubism<br />
| SH3BP2<br />
|-<br />
| Choroideremia<br />
| CHM<br />
|-<br />
| Chronic Granulomatous Disease<br />
| CYBB; NCF1<br />
|-<br />
| Ciliary Dyskinesia<br />
| DNAH5<br />
|-<br />
| Citrullinemia<br />
| ASS1<br />
|-<br />
| Cleidocranial Dysplasia<br />
| RUNX2<br />
|-<br />
| Cockayne Syndrome<br />
| ERCC6<br />
|-<br />
| Congenital Adrenal Hyperplasia<br />
| CYP21A2<br />
|-<br />
| Congenital Cataracts<br />
| GJA8; VSX2<br />
|-<br />
| Congenital Diarrhea, Syndromic<br />
| SPINT2<br />
|-<br />
| Congenital Disorders of Glycosylation (CDG)<br />
| ALG1; ALG6; CDG1C; DOLK; PMM2<br />
|-<br />
| Cornelia de Lange Syndrome <br />
| NIPBL<br />
|-<br />
| Craniosynostosis<br />
| TWIST1<br />
|-<br />
| Crouzon Syndrome<br />
| FGFR2<br />
|-<br />
| Cysteinyl Leukotriene Receptor 1 Deficiency <br />
| CYSLTR1<br />
|-<br />
| Cystic Fibrosis<br />
| CFTR<br />
|-<br />
| Diamond –Blackfan Anemia <br />
| RPS19<br />
|-<br />
| Duchenne Muscular Dystrophy <br />
| DMD<br />
|-<br />
| Dyskeratosis congenita (Male embryos only)<br />
| DKC1<br />
|-<br />
| Ectodermal dysplasia (Hypohidrotic)<br />
| EDA; EDA1; GJB6; IKBKG<br />
|-<br />
| Familial Adenomatous polyposis coli (FAP)<br />
| APC<br />
|-<br />
| Familial Dysautonomia<br />
| IKBKAP<br />
|-<br />
| Fanconi Anemia <br />
| FANCA; FANCC; FANCD2; FANCF; FANCG; FANCJ<br />
|-<br />
| Fragile X Syndrome (FRAX)<br />
| FMR1<br />
|-<br />
| Galactosemia <br />
| GALT<br />
|-<br />
| Gangliosidosis<br />
| GLB1<br />
|-<br />
| Glanzmann Thrombasthenia <br />
| ITGA2B<br />
|-<br />
| Glutaric Acidemia (aciduria)<br />
| GCDH <br />
|-<br />
| Glycogen Storage Disease <br />
| G6PC; GAA; SLC37A4<br />
|-<br />
| Haemophilia A<br />
| F8<br />
|-<br />
| Haemophilia B<br />
| F9<br />
|-<br />
| Hereditary Nonpolyposis Colorectal Cancer: Lynch Syndrome<br />
| MLH1; MSH2; MSH6<br />
|-<br />
| Holt Oram Syndrome<br />
| TBX5<br />
|-<br />
| Huntington Disease<br />
| HD<br />
|-<br />
| Hydrocephalus<br />
| L1CAM<br />
|-<br />
| Ichthyosis <br />
| ABCA12; STS<br />
|-<br />
| Incontinentia Pigmenti (IP)<br />
| NEMO<br />
|-<br />
| Joubert Syndrome 5<br />
| INPP5E<br />
|-<br />
| Krabbe Disease<br />
| GALC<br />
|-<br />
| Leber Congenital Amaurosis (LCA)<br />
| CEP290; GUCY2D<br />
|-<br />
| Leigh Syndrome (Infantile Subacute Necrotising Encephalopathy)<br />
| LRPPRC<br />
|-<br />
| Lesch Nyan Syndrome<br />
| HPRT1<br />
|-<br />
| Leukocyte Adhesion Deficiency (Type I)<br />
| ITGB2<br />
|-<br />
| Li-Fraumeni Syndrome<br />
| TP53<br />
|-<br />
| Macular Dystrophy Retinal <br />
| VMD2<br />
|-<br />
| Maple Syrup Urine Disorder (MSUD)<br />
| BCKDHB<br />
|-<br />
| Marfan Syndrome <br />
| FBN1<br />
|-<br />
| Menkes Syndrome<br />
| ATP7A<br />
|-<br />
| Mitochondrial DNA Depletion Syndrom <br />
| POLG; RRM2B; SUCLA2; TK2<br />
|-<br />
| Mucolipidosis type II<br />
| GNPTAB<br />
|-<br />
| Multiple Endocrine Neoplasia<br />
| MEN1; MEN2A; MEN2B<br />
|-<br />
| Multiple Exostoses<br />
| EXT1; EXT2 <br />
|-<br />
| Myotubular myopathy<br />
| MTM1 <br />
|-<br />
| Nail-Patella Syndrome<br />
| LMX1B<br />
|-<br />
| Neurofibromatosis Type 1<br />
| NF1<br />
|-<br />
| Neurofibromatosis Type 2 <br />
| NF2<br />
|-<br />
| Noonan Syndrome<br />
| KRAS, PTPN11; SOS1<br />
|-<br />
| Norrie Disease<br />
| NDP<br />
|-<br />
| Ocular Albinism <br />
| GPR143<br />
|-<br />
| Oculocutaneous Albinism <br />
| OCA2; TYR <br />
|-<br />
| Oculodentaldigital Dysplasia<br />
| GJA1<br />
|-<br />
| Optic Atrophy<br />
| OPA1<br />
|-<br />
| Ornithine Transcarbamylase Deficiency <br />
| OTC<br />
|-<br />
| Osteogenesis imperfeca <br />
| COL1A1; COL1A2<br />
|-<br />
| Osteopetrosis <br />
| CLCN7; OSTM1; TCIRG1<br />
|-<br />
| Pachyonychia Congenita <br />
| KRT16; KRT6A<br />
|-<br />
| Pancreatitis, Hereditary<br />
| PRSS1 <br />
|-<br />
| Papillorenal syndrome <br />
| PAX2<br />
|-<br />
| Phenylketonuria <br />
| PAH <br />
|-<br />
| This table does not cover the complete list of diseases that PGD can be applied to.<br />
|}<br />
<br />
==Laws & Legal status==<br />
===Australia=== <br />
PGD is currently used to detect serious genetic conditions to improve the outcome of Assisted Reproductive Technologies (ART). In very rare cases it may be used to select an embryo with compatible tissue for a sibling who has a life-threatening disease where other means of treatment is unavailable. This is with the conditions that the use of PGD will not affect the welfare and interests of the child to be born. The parents must also receive adequate counselling and have full understanding of the procedures of PGD. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"> National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art</ref><br />
The use of PGD for sex-selection is prohibited with the exception of reducing the risk of the transmission of serious sex-linked genetic conditions. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"/><br />
===Brazil=== <br />
The laws regarding PGD in Brazil are not strictly regulated. They are vague and there is limited information surround the activities of assisted reproduction in general in the country <ref name="PMID25493379"><pubmed>25493379</pubmed></ref>.<br />
===Czech Republic===<br />
The laws in the Czech Republic allow those with a “defined indication in order to exclude risk of serous genetically conditioned disease and defects with embryos before they are implanted into the cavity of the uterus”. Couples that undergo any assisted reproductive treatment including PGD have to be married. Sex-selection is illegal except in regards to serious sex-linked genetic diseases <ref name="PMID24777348"><pubmed>24777348</pubmed></ref>.<br />
===Greece=== <br />
In Greece, ART is open to those up to the age of 50 with written consent. It can only be used if a medical necessity is present such as the susceptibility of serious hereditary diseases. Sex selection is banned apart from cases of sex-linked diseases and sexually transmitted diseases <ref name="PMID24777348"/>.<br />
===Portugal=== <br />
ART is only available to those who are married or have a similar type of relationship for at least two years. The couples cannot be of the same sex and must be at least 18 years of age. Sex selection is illegal except in cases of sex-linked diseases. The use of PGD is illegal if the predictive value of genetic tests are very low <ref name="PMID24777348"/>.<br />
===Spain===<br />
PGD can be applied to “serious hereditary diseases not amenable to postnatal curative treatment” and “detection of other abnormalities which may compromise the viability of the pre-embryo”. If PGD is to be used for any other purpose authorisation must be acquired <ref name="PMID24777348"/>.<br />
===Sweden=== <br />
The use of PGD is strictly regulated and couples must achieve authorisation of the National Board of Health and Welfare. It can only be used it can only be used if the child is at risk to inheriting a serious chromosomal or monogenetic disease. It cannot be used for selection of specific characteristics <ref name="PMID24777348"/>.<br />
===United Kingdom===<br />
Those involved with carrying out the IVF treatment must have a license from the Human Fertilisation and Embryology Authority (HFEA). Only embryos that are approved by the HFEA can be implanted where the embryonic nuclear or mitochondrial DNA cannot be altered with the exception of preventing mitochondrial diseases <ref name="PMID24777348"/>. <br />
==Future/Current Research==<br />
===Noninvasive Preimplantation Genetic Testing without Embryo Biopsy===<br />
Different parameters of gametes, zygotes, embryos (“vacuoles in sperm heads, spindle position in mature oocytes, cleavage intervals of zygote, and embryo developmental dynamics”) may correlate with aneuploidy rates. This knowledge may be applied in potential noninvasive preimplantation diagnostic methods. Several methods have been proposed and are currently further researched<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Sperm Selection====<br />
Intracytoplasmic morphologically selected sperm injection (IMSI) is common procedure in IVF treatment to improve fertilization rates in patients with poor semen quality. In addition, studies have found that IMSI improves embryo development and that spermatozoa with large vacuoles in their heads correlate with increased aneuploidy rates and disturbed chromosomal structures. Thus, selecting spermatozoa based on morphological hallmarks may decrease aneuploidy rates in the fertilized embryos. As with polar body biopsies, however, this approach will solely be applicable if evidence for severe male detrimental contribution is given<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Blastocoel Fluid Extraction====<br />
In addition, a less invasive retrieval of material for diagnosis could include the extraction of the blastocoel fluid. The cavity of the blastocyst, lined by the trophectoderm, is filled with this blastocoel fluid, which contains metabolites of both trophectoderm and inner cell mass origin. The retrieval does not require a biopsy but merely a small opening to extract the fluid and, thus, causes less harm to the embryo. Multiple studies have applied this method<ref name="PMID22020776"><pubmed>22020776</pubmed></ref> <ref name="PMID23148560"><pubmed>23148560</pubmed></ref> and it may in the future become of clinical relevance.<br />
<br />
{|border="1"<br />
| [[File:Aspiration_of_the_Blastocoel_Fluid.jpeg]]<br />
|-<br />
| Aspiration of the Blastocoel Fluid using a ICSI pipette<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
|}<br />
<br />
<br />
Next to metabolites, the blastocoel fluid can contain DNA. Studies have shown that genomic DNA is present in about 90% of the blastocoel fluid samples tested. Typically the fluid is removed with an ICSI pipette from a day five blastocyst through its mural trophectoderm until the blastocyst fully collapses around the embryo. Several concerns regarding this method in a clinical setting have been raised. The collected DNA may be contaminated by the culture media that contains DNA fractions. The DNA may also be least representative of the actual embryos genome as the DNA may originate from abnormal or degenerated cells. Even though labelled noninvasive, the blastocyst still undergoes manipulation to some degree which may affect its viability. Thus, more research is required until this method can evolve from research to clinical use<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
====Proteomics====<br />
The protein secretome of blastocysts may be representative of its chromosome constitution Recent studies have found biomarkers such as lipocalin-1, interleukin-10, tumor necrosis factor, stem cell factor, and chemokine ligand 13 to be differently secreted by aneuploid blastocyst than by euploid ones. The most significant biomarker appears to be interleukin-10. Paired with novel proteomic technologies and mass spectrometry this knowledge when extended may contribute to a new invasive preimplantation genetic diagnosis method<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Embryo Morphology====<br />
Using time lapse imaging the embryo’s morphology can be closely observed and potential aneuploidy characteristics detected. Such characteristics may include the time of division to five cells, the time between the division from three to four cells, and the duration of the division from one to two and subsequently to three. In addition, the morphological quality of ICM an TE has been positively associated with aneuploidy or euploidy prognosis<ref name="PMID26246880"><pubmed>26246880</pubmed></ref>. These may give rise to an embryo quality screening prior to implantation<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
===Utilization of Diseased Cell Lines===<br />
==Ethics==<br />
==References==<br />
<br />
<references/><br />
<br />
<br />
{{StudentPage2015}}</div>Z5017878https://embryology.med.unsw.edu.au/embryology/index.php?title=2015_Group_Project_6&diff=2065452015 Group Project 62015-10-19T11:35:59Z<p>Z5017878: </p>
<hr />
<div>{{ANAT2341Project2015header}}<br />
<br />
<br />
=Prenatal Genetic Diagnosis=<br />
==Introduction==<br />
==History==<br />
Prenatal Genetic Diagnosis was historically conducted post-implantation in the first 2 trimesters <ref> Blackburn, S.L. (2003) '''Maternal, Fetal & Neonatal physiology: a Clinical perspective''' (2nd ed.). Seattle: Saudners </ref>, testing for overall fetal growth, complications of pregnancy, birth defects as well as chromosomal or genetic abnormalities<ref> Sadler T.W.(2012) '''Langman's Medical Embryology''' (12th ed.) Philadelphia: Lipincott, Wiliams & Wilkins, a Wolters Kluwer Business </ref>. Due to advancements in Artificial Reproductive Technologies ( ART) in the past 2 decades , these genetic tests are now conducted as a part of Preimplantation Genetic Diagnosis (PGD) <ref><pubmed>20638568</pubmed></ref> and art used to eliminate the rsik of passing on a genetic disorder to an offspring, before implantation, it ha now become a preventative measure. . In 1990 Preimplantation genetic testing was first used in 1990 on humans to diagnose recessive X-linked diseases in the embryos of pregnant women undergoing IVF. <ref><pubmed>2330030</pubmed></ref> PGD is offered as an alternative to prenatal diagnosis in detecting genetic disorders in high risk couples <ref><pubmed>26168107</pubmed></ref> and avoid passing an inherited disease to the offspring, by selecting genetically "normal" embryos for implantation ,to give the best chance of successful implantation , stable pregnancies and healthy children. <br />
<ref><pubmed>23499002</pubmed></ref><br />
<br />
==Preimplantation Genetic Diagnosis==<br />
[[File:Preimplantation Genetic Diagnosis Procedure.jpeg|700px|thumb|centre| Simplified steps for PGD]]<br />
<br />
<br />
Preimplantation genetic diagnosis (PGD) is used to test the genetic makeup of embryos to detect single gene disorders, chromosomal abnormalities and mitochondrial disorders. It also has applications in gender selection for diseases with unequal gender distributions <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Some diseases commonly involved with PGD include cystic fibrosis, spinal muscular atrophy and beta – thalassaemia <ref name= "Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press.">Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press</ref> <ref name="PMID17823145"><pubmed>17823145</pubmed></ref>. It was first used in the United Kingdom in the 1980s of arenoleucodystrophy and primarily focusing on sex- linked disorders <ref name="PMID17823145"/><ref name="PMID23150080"><pubmed>23150080</pubmed></ref>. PGD is now capable of detecting single cell defects (molecular) and chromosomal disorders resulting from the inversion, translocation or deletion of chromosomes (cytogenic) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>,<ref name="PMID11325751"><pubmed>11325751</pubmed></ref>. PGD can be applied to the embryo at different stages. That is on polar bodies, blastomeres or blastocyst <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>.<br />
Depending on the type of genetic disorder, PGD utilises different methods of genetic testing. These include Fluorescence in situ hybridisation (FISH) which is used for sex – linked disorders and detects chromosomal rearrangements <ref name="PMID11325751"/><ref name="PMID17876073"><pubmed>17876073</pubmed></ref> and Embryo halotyping which allows the identification of chromosomes causing the inherited disorder through knowledge of the pattern of closely linked markers <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. Polymerase chain reaction (PCR) is also widely used to detect molecular abnormalities <ref name="PMID11325751"/>.<br />
PGD is tightly regulated and supported by large organisations namely The American Society for Reproductive Medicine, The European Society for Human Reproduction and Embryology (ESHRE), The European Society of Human Genetics and the Preimplantation Genetic Diagnosis International Society <ref name="PMID25500181><pubmed>25500181</pubmed></ref>.<br />
===Sex-linked disorders===<br />
The determination of a disease as gender specific usually correlates with the presence or absence of specific genes such as SRY on the Y chromosome. It is known that females have two X chromosomes and males have an X and a Y chromosome where abnormalities are more prevalent on the X chromosome. PGD can be used for sex selection where only male embryos are transferred to reduce the chance of inheriting X-linked disorders. However, this does not completely eradicate the problem as male embryos remain susceptible to inheriting an affected X chromosome. Sex determination is only used when the specific mutation is unknown and has yet to be discovered <ref name="PMID24866878"><pubmed>24866878</pubmed></ref>.<br />
===Single gene defects===<br />
Single gene defects can be dominant, recessive, autosomal or X-linked. They are commonly diagnosed using PCR and although the PCR available today is complex and capable of combatting a large range of disease the development of new protocols has been proven to be difficult due to the small DNA sample available <ref name="PMID26168107"><pubmed>26168107</pubmed></ref><br />
===Mitochondrial disorders===<br />
Mitochondrial disorders also known as oxidative phosphorylation disorders arise from mutations in the nuclear DNA or mitochondrial DNA <ref name="PMID26312584"><pubmed>26312584</pubmed></ref>. They pose as a problem because they are unrecognisable until the mutations in the cell reach a detrimental level <ref name="PMID20638568"><pubmed>20638568</pubmed></ref>. Mitochondrial disorders cause miscarriages and stillbirths as well as death in children and young adults. The effects can either be contained in a single organ or more commonly involve multiple organ failure where organs with high energy demands such as the brain, liver muscle and heart and heavily influenced. They are usually occur spontaneously or result from inheritance from the mother. Since mitochondria are solely inherited from the mother oocyte donations have been used as a solution to combat mitochondrial disorders. Additionally, there has been an increasing use in PGD where embryos that stay under the given threshold of 18% gene-mutations are allowed to be transferred and result in normal development. New technology in the areas of nuclear gene transfer and genome editing are also being experimented with <ref name="PMID26312584"/>. <br />
===Chromosomal disorders===<br />
Chromosomal disorders can be reciprocal, Robertsonian translocations, inversions, deletions and insertions <ref name="PMID26168107"/>. . Data from ESHRE collected between 2010 and 2011 has shown that the most common chromosomal abnormality confronted in PGD are reciprocal chromosomal abnormalities <ref name"PMID26071418"><pubmed>26071418</pubmed></ref>. PGD has also been used successfully for Robertsonian translocations (RT), a type of structural translocation. Children who carry RT are phenotypically normal, however in their later years it is found that they will suffer from infertility and repeated miscarriages due to the high frequency of abnormal embryos <ref name="PMID22081077"><pubmed>22081077</pubmed></ref>. PCR and FISH are the two main techniques used for chromosomal disorders. To be able to conduct the examinations the cells are required to be at the metaphase stage <ref name="PMID26168107"/>. <br />
==Preimplantation Genetic Screening==<br />
Prenatal Genetic Screening (PGS) involves an array of methods or ideas that aim to segregate embryos that have genetic flaws and those that are healthy <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. The occurrence of aneuploidy is high around the stages of early embryonic development and they are the most common cause if miscarriages and congenital birth defects <ref name= "PMID26085841"><pubmed>26085841</pubmed></ref>. They have little effect on the morphology of the embryo making them difficult to identify thus identification heavily relies on genetic testing <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. <br />
Genetic sampling is most commonly conducted using Microarray Comparative Genomic Hybridisation (aCGH) as well as FISH, Quantitative PCR and Single Nucleotide Polymorphism (SNP) <ref name="Coward, K. & Wells, D. (2013). Textbook of Clinical Embryology New York: Cambridge University Press."/>. These methods collectively aim to assess numeral and structural chromosomal errors <ref name= "PMID26085841"/>. Studies have also introduced Next- Generation Sequencing (NGS) <ref name= "PMID26085841"/> and Whole Genome Amplification used to screen imbalances in the complete 24-chromosomes <ref name="PMID25953353"><pubmed>25953353</pubmed></ref><br />
Statistics from ESHRE have shown that the most common indications for PGS is advanced age, followed by repeated implantation failure or recurrent miscarriage and male infertility <ref name="PMID26071418"><pubmed>26071418</pubmed></ref>.<br />
====Indications====<br />
A low percentage of structural abnormalities in chromosomes are responsible for the cause of miscarriages. Despite this, they are the most prevalent type of chromosomal abnormality accounted for in PGD <ref name="PMID20638568"/>. The presence of specific gene cycles, initiation of embryonic protein synthesis and evident physiological development are all indicative of a successful in vitro fertilisation procedure <ref name="PMID11576737"><pubmed>11576737</pubmed></ref>. To eliminate further errors from occurring during the PGD procedure it is recommended to undertake further prenatal testing such as amniocentesis in the later stages <ref name="PMID20638568"/>. <br />
=====Advanced maternal age=====<br />
Data provided by the ESHRE has shown that the mean age of women undergoing PGS is 39 years <ref name="PMID26071418"/>. Women of advanced age have been shown to have a lower rate of pregnancies reaching childbirth <ref name="PMID18583331"><pubmed>18583331</pubmed></ref>. The highlighted concern revolves around the increased occurrence of aneuploidy following maternal age. The optimal age range for the lowest aneuploidy incidence was found to be between 27 to 37 years of age (6%) then progressively higher in women aged up to 42 (33%) and most common in those 44 and above (53%) <ref name="PMID24355045"><pubmed>24355045</pubmed></ref>. <br />
=====Recurrent pregnancy loss / IVF failure=====<br />
Recurrent pregnancy loss is defined as three or more IVF failures after cumulative transfer of more than 10 good-quality embryos. These are primarily caused by two main factors, reduced endometrium receptivity or embryonic defects. Endometrium receptivity can be negatively influences by instances including uterine pathologies such as thin endometrium, altered expression of adhesive molecules and immunological factors. Additionally, embryonic defects may be due to genetic abnormalities, embryonic aneuploidy or zona hardening. Endometriosis and hydrosalpinx has been known to effect both the endometrium and embryo <ref name="PMID23260857"><pubmed>23260857</pubmed></ref>.<br />
=====Human leukocyte antigen matching=====<br />
First used in 2001, HLA matching is an option given to parents to save a child with haematological or immunological disease through conceiving another child who would potentially be able to donate cord blood or haematopoietic stem cells from the bone marrow for transplantation. The process namely PGD-HLA has shown to improve haematopoietic stem cell transplant (HSCT). PGD-HLA can only be performed when HSCT is not needed urgently due to the time needed to conceive and delivery the baby <ref name="PMID25500181"><pubmed>25500181</pubmed></ref>. It is most commonly applied to children suffering from relapsed leukaemia <ref name="PMID22524201"><pubmed>22524201</pubmed></ref>. In a case study PGD-HLA was proven to successfully cure 10 diseases including Fanconi anaemia, Diamond-Blackfan anaemia and beta thalassemia <ref name="PMID25066893><pubmed>25066893</pubmed></ref>.<br />
==Biopsy Methods==<br />
Biopsy, the removal of genetic materials, from oocytes or embryos in the preimplantation stage is the primary step in PGD. For the past two decades these biopsies have been performed at three stages, the polar body, blastomere, and blastocyst, and the methodologies optimized to ensure the embryo’s viability. The most common approach involves biopsies at the cleavage stage. However, polar body and blastocyst biopsies are increasingly more often tested and applied. Approached for opening the zona pellucida involve next to the traditional mechanical and chemical means, novel approaches such as noncontact lasers. Their application may simplify and secure the procedure significantly. The most challenging question about PGD procedures remains at what stage biopsies should be taken. Much controversy has developed around this topic, highlighting the varying disadvantages and advantages of temporal biopsies. <ref name="PMID22723007"><pubmed>22723007</pubmed></ref><br />
<br />
{|border="1" align="left"<br />
|-bgcolor="pink" <br />
|<br />
| Time of Biopsy<br />
| Advantages <br />
| Disadvantages<br />
|- <br />
| Polar Body<br />
| Day 1<br />
| No harm to oocyte<br />
| Only maternal DNA is tested, often needs to be coupled with other biopsies<br />
|-bgcolor="pink"<br />
| Blastomere<br />
| Day 3<br />
| …<br />
| … <br />
|-<br />
| Trophectoderm<br />
| Day 5 and 6 <br />
| Little harm, large amount of genetic material<br />
| Opening of blastocyst necessary, small time window for procedure<br />
|}<br />
<br />
{|border="1"<br />
| [[File:Polar_Body,_Blastomere,_and_Trophectoderm_Biopsy.jpeg]]<br />
|-<br />
| Polar body (A), blastomere (B) and trophectoderm (C) biopsies<ref name="PMID25625041"><pubmed>25625041</pubmed></ref>.<br />
|}<br />
<br />
PMID 24305177<br />
===Polar Body Analysis===<br />
Day 1<br />
====Description====<br />
Polar body (PB) biopsy, which was introduced in 1990, offers a promising alternative to biopsies performed at the blastomere stage for PGD/S indications on legal and practical grounds. <br />
Description: Consequent embryo development does not necessitate the presence of the first and second PB and their removal may not be crucial. PB biopsy requires precise timing. Keeping track of the meiotic cell cycle is necessary to perform a successful biopsy and, therefore, PB biopsy usually is applied in combination with intracytoplasmic sperm injection (ICSI). During the maturation from the germinal vesicle stage to the metaphase-II stage the first PB is formed. A cytoplasmic bridge containing spindle remnants, that are still in contact with the cellular genetic material, links this PB to the oolemma for about 90 minutes after extrusion. It is possible to visualize these remnants by polarization microscopy and it is crucial to not perform the biopsy until the first PB is no longer firmly attached to the oolemma as this indicates an immature embryo.The oocyte tolerates mechanical zona dissection best during hours four until six after ICSI as the oolemma has stabilized by that time because of the cortical granule reaction. Over time the first PB degenerates stressing a temporal biopsy and its optimal extraction time window is four to 12 hours after ICSI. The second PB forms around two to four hours after ICSI. However, its optimal time window for biopsy is set to be eight to 16 hours after ICSI. This is due to the second PB being attached to the oolemma with spindle remnants until six hours after ICSI. Biopsy at this point may cause enucleation of the oocyte. In addition, studies have shown that the amplification efficiency of second PB’s DNA is worse if the PB is extracted prior to eight hours after ICSI. <br />
Thus, it is possible to perform sequential and simultaneous biopsies for the first and second PB. If performed, sequentially the first PB may be removed four to 12 hours and the second PB eight to 16 hours after ICSI. The optimal time window for a biopsy for both the first and second PB simultaneously is eight to 12 hours after ICSI. It is highly preferred to analyze both PBs due to potential aneuploidies in either PB and crossing overs during meiosis<ref name="PMID22723007"/>. <br />
====Procedure====<br />
Chemical opening achieved with for example acidic tyrode’s solution of the zona pellucida is not tolerated by the oocyte and may have detrimental effects on the embryo’s development. Therefore, the access to the perivitelline space of the oocyte is provided by mechanical zona dissection or by laser. Both techniques work well if performed by experienced embryologist. However, laser-assisted biopsy is less time consuming when compared to manual dissection. It is critical to consider the size of the introduced opening as it will remain permanent. If it is too large the blastomere may be lost during embryo development and if it is too small it may interfere with hatching of the embryo during blastocyst stage<ref name="PMID22723007"/><br />
<br />
{|border="1"<br />
| [[File:Polar_Body_Biopsy.jpeg]]<br />
|-<br />
| The presence of a faint but clearly identifiable strand connecting PB2 to the <br />
oolemma. The biopsy was performed ∼9 h after ICSI<ref name="PMID21908464"><pubmed>21908464</pubmed></ref>.<br />
|}<br />
<br />
{|border="1"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JTaQzszVr8o</html5media><br />
|-<br />
| Laser-assisted polar body biopsy<ref>RIUK, R. (2013, June 25) Polar Body Biopsy [Video file]. Retrieved from https://www.youtube.com/watch?v=JTaQzszVr8o</ref><br />
|}<br />
<br />
====Advantages & Disadvantages====<br />
PB biopsies can only investigate the maternal contributions to the embryo as they are of maternal origin. Thus, this procedure is appropriate for PGD solely for monogenetic diseases from the maternal side. Recessive diseases may be evaluated with PB biopsies on the basis that the embryo’s outcome will be determined by the paternal contribution. (...) It may still be applied for PGS as most aneuploidies either arise during meiosis or origin from the maternal genome. However, diagnosis error has been reported due to the lack of considering paternal contributions. <br />
Because PB biopsies are performed very early it is not yet known whether the oocyte will develop into a viable embryo. Thus, PBs are commonly frozen or fixed after biopsy and depending on the state of the embryo only chosen PBs will be tested. This is primarily an economic issue as many genetic testing procedures are very cost-intensive<ref name="PMID22723007"/>.<br />
<br />
{|border="1"<br />
| [[File:Implantation_predictive_value_of_euploid_screening_results.jpeg]]<br />
|-<br />
| The sustained implantation predictive value (with 95 % confidence interval) of a euploid screening result obtained from the first polar body (PB1), PB1 and the second polar body (PB2), or a direct embryo biopsy for each stage of embryo transfer (cleavage-stage and blastocyst stage)<ref name="PMID25106935"><pubmed>25106935</pubmed></ref>.<br />
|}<br />
<br />
===Blastomere biopsy===<br />
Day 3 <br />
====Description====<br />
Blastomere biopsy has been the prevalent method for PGD and PGS in the last two decades. At least one, but up to two, blastomeres are biopsied on day three of the cleavage stage embryo. The right number of blastomeres removed is a controversial topic as two cells allow for more genetic material and more accurate results. However, removing two cells might be too invasive and damaging to the embryo. (Study)<ref name="PMID21748341"><pubmed>21748341</pubmed></ref><br />
====Procedure====<br />
Initially a hole was drilled into the zona pellucida using acid tyrodes and the blastomeres are removed via aspiration with a pipette<ref name="PMID21748341"/>.<br />
<br />
{|border="1"<br />
| [[File:Aspiration_of_a_Blastomere.jpeg]]<br />
|-<br />
| Aspiration of a Blastomere into the biopsy pipette<ref name=" PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
|}<br />
<br />
{|border="1"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=TbridWVwipI</html5media><br />
|-<br />
| Laser-assisted blastomere biopsy<ref>Sukprasert, M. (2014, March 5) Day 3 Blastomere Biopsy 1 [Video file]. Retrieved from https://www.youtube.com/watch?v=TbridWVwipI</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
===Trophectoderm biopsy===<br />
Day 5 and 6<br />
====Description====<br />
The improvement of embryo culture media allowed the in vitro development of human embryos until the blastocyst stage and opened up the possibility to take blastocyst biopsies. During day three to day five the haploid maternal and paternal genomes work together for the first time to form the genome of the embryo. The maternal epigenetic control lessens significantly while preparing for implantation with precisely arranged events happening. The first event includes a rapid increase in the number of embryonic cells which are active in mitotic divisions and apoptosis of aberrant cells. This is followed by the formation of blastocoel (cavitation) which results from the flattening of cell located on the outside of the blastomere. Now the blastocyst will expand until the embryo hatches by rupturing the zona pellucida. The cells of the blastocyst will differentiate to form two distinct cell lineages, the outer trophectoderm and the inner cell mass<ref name="PMID22723007"/>.<br />
====Procedure====<br />
Trophectoderm biopsy is usually performed in Hepes buffered biopsy medium and opening approaches include needle cutting which has been replaced by lasers in past years. Different research groups report different timings of the opening to be the most successful. Some open the blastocyst on day three or four by creating a 25 µm which causes the trophectoderm to herniate through this hole and is, thus, accessible for biopsy. Others create this hole about four hours before biopsy which allows sufficient herniation of trophectoderm cells. It is also possible to open the blastocyst immediately before biopsy. This avoids an extra step and the inner cell mass usually is easy to locate. Blastocyst biopsies involve the removal of trophectoderm cells and the ideal time for the procedure is day five. Successful biopsies on day six have been performed, while little is known about the results of biopsies on day seven. However, since the window of implantation in humans is from day eight to ten after ovulation, day seven biopsies appear to be possible<ref name="PMID22723007"/>.<br />
-collapse of trophoblasts<br />
-possible: biopsy of hatched blastocyst, holding pipette careful mild suction force to hold embryo near ICM <br />
-Cryopreservation<br />
<br />
{|border="1"<br />
| [[File:Microscopic images of human blastocysts for biopsy.jpeg]]<br />
|-<br />
| (A) Some trophectoderm cells in a blastocyst started to hatch and (B) the trophectoderm cells were biopsied with assisted laser cutting. Images in C–D show the blastocysts after vitrification and warming. Blastocysts had been cultured for 2–4 hrs after warming, showing good (ICM and trophectoderm cells) hatched (C) and hatching (D) blastocysts. The hatching blastocyst in (E) has good ICM but fair trophectoderm while the blastocyst in (F) has both fair ICM and trophectoderm. Arrows indicate ICMs and arrow heads indicate trophectoderm cells. Bar = 40 µm<ref name="PMID2190846"><pubmed>2190846</pubmed></ref>.<br />
|}<br />
<br />
<br />
{|border="1"<br />
| <html5media height="300" width="400">https://www.youtube.com/watch?v=JI_TQ8d8tNM</html5media><br />
|-<br />
| Laser-assisted blastocyst biopsy (at 00:50 min)<ref>Coco, R. (2014, April 30) Trophectoderm biopsy in a Hatching blastocyst protruding ICM [Video file]. Retrieved from https://www.youtube.com/watch?v=JI_TQ8d8tNM</ref><br />
|}<br />
<br />
<br />
====Advantages & Disadvantages====<br />
Blastocyst biopsies are believed to be less damaging to the embryo and appear to be unrelated to implantation rates. In addition, this biopsy method allows for a larger extraction of cells for genetic testing. However, since they are performed late in in vitro development, the time window for genetic testing is relatively small. Fast and accurate genetic testing methods are needed to ensure a successful and safe result from this biopsy. Thus, blastocyst biopsies may gain more popularity in the future whn such methods have been developed or improved<ref name="PMID22723007"/>. <br />
<br />
<br />
==Genetic Techniques==<br />
<br />
===PCR===<br />
====Description====<br />
Polymerase chain reaction (PCR) amplifies DNA specific to genetic sequence of interest . PCR was developed by Kay Mullis in the 1980s, for which he was awarded the Nobel prize for chemistry in 1993. <ref> Pubmed Docs (2015) Polymerase Chain Reaction (PCR) Pubmen. Retrieved from [http://www.ncbi.nlm.nih.gov/probe/docs/techpcr/]</ref> This technique enables clinicians to monitor and diagnose diseases using minute samples such as embryonic cells, blood & tissue. <ref>Roche (2015) PCR: How We Copy DNA. Roche Molecular Systems Inc. retrieved From [http://molecular.roche.com/pcr/Pages/Process.aspx]</ref> PCR has many important applications like DNA fingerprinting, genetic mapping, detection of viruses and bacteria as well as being used to detect genetic disorders, as a part of PGD, in conjunction with IVF. It is used to detect molecular abnormalities such as single gene disorders like Tay Sach, Cycstic fibrosis, Duchenne Muscular Dystrophy, Thalassemia, Huntington disease, Spinal muscular atrophy and many more. Molecular and Genetic analysis require a significant amount of DNA, which we would not have without PCR. It revolutionized the study of DNA, replacing all previous recombinant DNA technology. <ref> Mullins, K., Francois, F.& Gibbs R.A. (1994 ) The Polymerase Chain Reaction. p3. Springer- Science +Business Media. Birkhauser, Boston<br />
Available at [https://books.google.com.au/books?hl=en&lr=&id=gjrTBwAAQBAJ&oi=fnd&pg=PR5&dq=kary+mullis+PCR&ots=mpzAyRh5ZY&sig=PQ4goNoKJ90tb3-MkPk62zrTGbw#v=onepage&q=kary%20mullis%20PCR&f=false] </ref> <br />
<br />
====Procedure====<br />
<br />
Sample are obtained from the the blastocyst, a polar body biopsy or the blastomeres stages of the embryo. <br />
Stage 1 Denaturing: separating the target strands of DNA <br />
The obtained sample is heated to roughly 90 degrees celcius, this heat causes breaks the relatively weak bonds between nucleotides that form DNA. the double stranded DNA to split into 2 single strands of DNA that are used as templates.<br />
Stage 2 Annealing: Binding the Primers to the target DNA sequence <br />
PCR will only copy the target sequence of DNA specified by specific PCR primer. These synthesized primers Oligonucleotides are small artificial pieces of DNA. <br />
TAQ polymerase enzyme synthesize 2 new strands of DNA duplicate to the single sample DNA stand template indicated by these primers. During this stage the reaction is cooled to a temperature between 40-60 degrees Celsius. <br />
Stage 3- Extension- making copies <br />
Each of these 2 copies are then used again as templates generating 2 further replications This cycle can occur as many 30 -40 times within a couple hours leading to billions of extra copies of the original DNA segment. The optimal temperature for the further replication is roughly 72 degrees Celsius. <br />
<br />
This process mediated by a thermocycler machine that is programmed to alter the temperature of the reaction every couple of minutes, perpetuating the cycle of DNA denaturing and synthesis. <br />
This process, generates exponential exact copy of the original template DNA sequence. <br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
!PCR cycles<br />
<br />
|{|<br />
|-bgcolor="lightpink"<br />
| '''PCR Cycle'''<br />
| '''Target Copies'''<br />
|-<br />
| 1<br />
| 2<br />
|-bgcolor="pink"<br />
| 2<br />
| 4<br />
|-<br />
| 3<br />
| 8<br />
|-bgcolor="pink"<br />
| 4<br />
| 16<br />
|-"<br />
| 5 <br />
| 32<br />
|-bgcolor="pink"<br />
| 6 <br />
| 64<br />
|-<br />
| 7 <br />
| 128<br />
|-bgcolor="pink"<br />
| 8<br />
| 256<br />
|- <br />
| 9<br />
| 512 <br />
|-bgcolor="pink"<br />
| 10<br />
| 1024<br />
|-<br />
| 15<br />
| 32,768<br />
|-bgcolor="pink"<br />
| 20 <br />
| 1,048,578<br />
|-<br />
| 25<br />
| 33,554,432<br />
|-bgcolor="pink"<br />
| 30 <br />
| 1,073,741,842<br />
|-<br />
|}<br />
<br />
<br />
<br />
<br />
{|border="1" align="right"<br />
|-bgcolor="pink" <br />
| '''Advantages''' <br />
|'''Disadvantages'''<br />
|- <br />
| fast and inexpensive way of copying a target sequence of DNA<br />
| only during this exponential DNA replication phase can we determine the starting quantity sequence contained in the original sample ( template DNA strand)<br />
|-bgcolor="pink"<br />
| aids the diagnosis of single cell defects<br />
| PCR reaction is limited by the presence of inhibitors present in the sample : reagent inhibitors <br />
|-<br />
| rapid generation of results within a couple hours<br />
| self annealing due to the accumulation of the product -stopping exponential amplification for the target sequence and reach a plateau<br />
quantification of the end point of reaction of PCR products unreliable - therefore that is why we require real time quantitative RT-PCR necessary<br />
<ref> NIS (2015) Polymerase Chain Reaction (PCR) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000207]</ref><br />
|-bgcolor="pink"<br />
| can start from a single molecule of DNA, therefore is more sensitive <br />
| <br />
|-<br />
| has a flexible primer design enabling<br />
| <br />
|-bgcolor="pink"<br />
| overcame previous issues associated with the limited availability of sites of end<br />
| <br />
|-<br />
| generates the DNA copies exponentially<br />
| <br />
|-bgcolor="pink"<br />
| enables DNA amplification required for molecular and genetic analysis<br />
| <br />
|-<br />
|Valid diagnostic method in selecting unaffected embryos for embryo transfer <ref> Dreesen, J., Drusedaul, M., Smeets, H., Die-Smulders, C., Coonen, E., Dumoulin, J., Gielen, M., Evers, J., Herbergers, J. & Geradets, J. (2008) Validation of preimplantation genetic diagnosis by PCR analysis: genotype comparison of the blastomere and corresponding embryo, implications for clinical practice. Mol. Hum. Reprod. 14 (10):573-579.doi: 10.1093/molehr/gan052. Retrieved from [http://molehr.oxfordjournals.org/content/14/10/573.short] </ref> <ref><pubmed>20966460</pubmed></ref><br />
|<br />
|}<br />
<br />
<br />
<br />
<br />
<br />
<br />
<br />
<br />
<br />
===Fluorescent In Situ Hybridisation (FISH)===<br />
<br />
<br />
====Description====<br />
Fluorescence in situ hybridization (FISH) the one of the most effective and rapid <ref name="PMID26338801"><pubmed>26338801</pubmed></ref> Preimplantation Genetic Diagnosis (PGD). This techniques used to locate a specific DNA sequences within a chromosome. FISH facilitates the clinical diagnosis of chromosomal abnormalities indicated by sequential duplications, deletions and rearrangements of chromosome, that are usually missed with microscopic analysis. This technique is especially relevant for female embryos with X-linked diseases,<ref><pubmed>20809319</pubmed></ref> that have no other mutation specific tests [http://www.ncbi.nlm.nih.gov/pubmed/20809319] As part of PGD, samples are collected from various stages of the embyro,and they are able to conducted tests on the blastocyst, a polar body biopsy and the blastomeres <ref><pubmed>21748341</pubmed></ref>. FISH is 99% effective when used in conjunction with competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities<ref name="PMID26338801"/>.<br />
<br />
====Procedure==== <br />
<br />
Samples are collected from either the blastocyst, a polar body biopsy or the blastomeres stages of the embryo <ref><pubmed>21748341</pubmed></ref>. <br />
DNA strands are heated and denatured causing their the individual DNA strands to break apart<br />
Probes are single complimentary stands of DNA a that have been tagged with small chemical agents that glow brightly in the presence of a specific region on a chromosome. These specific probes then hybridize and join to their complementary DNA strand. <br />
The fluorescent tags enable the researchers to correctly identify the presence or lack thereof and location of the specific chromosomes that they are testing for. <ref><pubmed>17876073</pubmed></ref><br />
Researcher analyse the results by identifying the number and the relative location of the fluorescent dots generated by the FISH images.<ref><pubmed>17970921</pubmed></ref><br />
The probe will not fully hybridise if there has been a duplication or a deletion of the DNA - indicating chromosomal and sex chromosomal anomalies like trisomies and aneuploidies. <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref><br />
<br />
<br />
Different probes are used for different purposes: <ref>Unique, Rare Chromosome Disorder Support Group (2013) Fluorescence in situ hybridisation (FISH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/Other/FISH%20FTNW.pdf]</ref><br />
*'''Locus specific tags''' detect very small imbalances, and locate isolated small portions <br />
of genes within a chromosome<br />
*'''Alphoid/Centomeric Repeat probes''' are developed from the repetitive sequence located in the middle region of each chromosome, useful in determining the number of chromosomes , detecting rearrangement and when used in conjunction with locus probes to determine the absence of genetic material on a chromosome. <br />
*'''Paint Probes''' are collections of smaller probes with their own stains that bind to a different section on the chromosome - allowing the full chromosome too be labeled a unique colour, this "full colour map" can be used to know the spectral karyotype- full chromosomal mapping is useful in examining chromosomal abnormalities. <br />
<br />
{|border="1"<br />
| [[File:Fluorescent In Situ Hybridisation (FISH).jpg|thumb|right|'''FISH''' We are able to tag Specific DNA sequences using Probes which have been tagged with fluorescent Labels.This technique enables the clinical diagnosis of chromosomal abnormalities, indicated by sequential duplication, deletions and rearrangements of chromosome <ref>NIS (2015) Flourescent in Situ Hydridization (FISH) National Human Genome Research Institute retrieved from [https://www.genome.gov/10000206]</ref>]]<br />
|}<br />
<br />
<br />
<br />
{|border="1" align="right"<br />
|-bgcolor="pink" <br />
| rowspan="7" |'''Advantages''' <br />
| FISH is 99% effective when used in conjunction with Competitive Genomic Hybridisation (CGH) to diagnose chromosomal abnormalities.<ref><pubmed>26338801</pubmed></ref><br />
|-<br />
| Rapid generation of results<br />
|-<br />
| Identifies very small translocations and aneuploidies that occur within chromosomes, that would usually be missed under microscopic analysis<br />
|-<br />
| Indicates whether the accessed chromosomes are normal <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|-<br />
| Tests for the most common chromosomal abnormalities - down syndrome chromosomes 13,16,18,21 and 22 <ref><pubmed>21749752</pubmed></ref><br />
|-<br />
| It may be used to compare the chromosomal gene arrangements in related species<br />
|-<br />
| can be used to identify and remove inheritable X-linked disease or sex chromasome anomalies such as Duchennes Muscular Dystrophy, hemophilia, ectodermal dysplasia <ref><pubmed>17876073</pubmed></ref><br />
|-bgcolor="white"<br />
| colspan="4" |'''Disadvantages'''<br />
| FISH destroys all cells tested <ref> O'Connor, C. (2008) Fluorescence in situ hybridization (FISH). Nature Education 1(1):171. retrieved from [http://www.nature.com/scitable/topicpage/fluorescence-in-situ-hybridization-fish-327] </ref><br />
|-<br />
| It does not fully access all chromosomes (only ~ 12)<br />
|-<br />
| Analysis of results is dependent upon the dot quality impacted by hybridisation efficiency or the camera sensitivity <ref><pubmed>17970921</pubmed></ref><br />
|-<br />
| some studies indicate that using FISH on a day-3 embryo biopsy decreases the rate of live births <ref><pubmed>26168107</pubmed></ref><br />
|<br />
|}<br />
<br />
<br />
<br />
===Array Comparative Genomic Hybridisation (aCGH)===<br />
====Description====<br />
<br />
aCGH also known as Microarray analysis efficiently scans the entire genome for chromosomal imbalances. CGH was initially developed to detect the number of changes in a solid tumor mass. It uses 2 genomes comparing the sample to the control, with each labeled in a different fluorescent dye<ref><pubmed>1876176</pubmed></ref>. Earlier CGH techniques were limited by the resolution of the imaging <ref> Lichter, P., et al. Comparative genomic hybridization: Uses and limitations. Seminars in Hematology 37, 348–357 (2000)</ref> , these initial limitations were overcome by using Microarrays in conjunction with CGh to improve the resolution of the imaging, Array Comparative Genomic Hybridisation (aCGH). This method compares sample and control microarrayed slides containing small segments of DNA (probes). <ref> Lucito, R., et al. Representational oligonucleotide microarray analysis: A high-resolution method to detect genome copy number variation. Genome Research 13, 2291–2305 (2003) </ref> the Probes used will vary according from the small (25-85 base pairs) oligonucleotides manufactured to highlight different target sequences, to the very large genomic clones (80,000- 200,00 base pairs), and as these are significantly smaller than the traditional metaphase chromosomes used for CGH, generating a higher resolution of image. <ref><pubmed>22467166</pubmed></ref>.aCGH is used as a diagnostic tool for prenatal detection f chromosomal abnormalities <ref><pubmed>19012303</pubmed></ref>.<br />
<br />
<br />
====Procedure====<br />
<ref> Theisen, A. (2008) Microarray-based Comparative Genomic Hybridization (aCGH). Nature Education 1(1):45. Retrieved from [http://www.nature.com/scitable/topicpage/microarray-based-comparative-genomic-hybridization-acgh-45432] </ref><br />
The sample is obtained (skin, blood or fetal cells) and DNA is obtained. <br />
As a part of PGD fetal cell samples are collected from; the fertilized egg polar bodies, the blastomere (day 3 embryo) or the blastocyst/tropoectoderm stage (day 5 embryo).<br />
Sample DNA is labeled with one fluorescent dye, and the control DNA is labeled with a different colored fluorescent dye. the control DNA is used as the base point of reference. <br />
heated and denatured single DNA strands then hybridize to their complementary single strand probes, which are then combined and applied to a microarray and the results are run through a computer program and a digital imaging system is used to quantify the results( fluorescent intensities of the labeled probes). <br />
<br />
simple explanation of aCGH : [Genomics Education (2014) Genetic Testing for Health: aCGH|https://vimeo.com/84757281]<br />
<ref>Genomics Education (2014) Genetic Testing for Health: aCGH [video file] Vimeo [https://vimeo.com/84757281]</ref><br />
<br />
<br />
The fluorescent ratio and the hybridization signal at different locations on the genome of the control DNA are used to identify any variances present in the sample DNA. aCGH facilitates the clinical diagnosis of submicroscopic chromosomal duplication, deletion and rearrangements indicative of chromosomal disorders such as trisomies 1-22and specific sex linked disorders. <br />
Duplications in the DNA are displayed by the computer program as spikes/ peaks over an established threshold and deletions in DNA are displayed by the computer program as spikes/ toughs beneath this threshold <br />
-computer screening image- <br />
-drawn diagram of method-<br />
<br />
<br />
<br />
{|border="1" align="right"<br />
|-bgcolor="pink" <br />
| '''Advantages''' <br />
| '''Disadvantages'''<br />
|-<br />
| multiple applications: prenatal genetic diagnosis, cancer diagnosis, <ref><pubmed>20193845</pubmed></ref> genetic screening for developmental delay (learning disabilities) <ref><pubmed>17309648</pubmed></ref>. or congenital anomalies that are suspected to be genetic in origin <ref>NHS Array Comparitive Genomic Hybridisation (arrayCGH) pgh foundation . retrieved from [http://www.phgfoundation.org/file/5237/]</ref><br />
| translocations and inversions of DNA are not detected<br />
|-bgcolor="pink"<br />
| trace represents all chromosomes present in the human genome chromosomes 1-22 and the X & Y chromosomes, and therefore is the most accurate method for testing whole embryo aneuploidy<br />
| limited ability diagnosing specific polyploidies such as triploidy <ref> Unique, Rare Chromosome Disorder Support Group (2013) Microarray-based Comparative Genomic Hybridiation (array CGH) Rarechromo.org retrieved from [http://www.rarechromo.org/information/other/array%20cgh%20ftnw.pdf] </ref><br />
|-<br />
| aCGH has been extensively tested, and Validated, and is now used world wide.<br />
| will not detect mosaicism detection <20% (cultures where >1 of 5 cells are trisomy 12)<br />
|-bgcolor="pink"<br />
| detects deletions and additions and rearrangements as well as amplification, of the WHOLE genome, simultaneously.<br />
| will not detect balanced chromosomal rearrangement<br />
|-<br />
| detects submicroscopic alterations<br />
| will not detect duplications or deletions <80kb<br />
|-bgcolor="pink"<br />
| used as a diagnostic tool for prenatal detection of chromosomal abnormalities <ref><pubmed>22034057</pubmed></ref><br />
| will not detect point mutations within genes <ref>Washington department of education (CGH- FAQ for physicians. Signature Genomic LAboratories, LLC. Retrieved from [https://depts.washington.edu/dbpeds/Lab%20Tests/SignatureCGH-physician_FAQ.pdf]</ref><br />
|-<br />
| provides high resolution genomewide screening of segmental genomic copy number variations<br />
| will not detect chromosomal position of genomic gains<br />
|-bgcolor="pink"<br />
| very accurate when used in conjunction with FISH<br />
| will not detect loos of heterozygosity (LOH) or Absence of heterozygosity (AOH) <ref>WiCell Research Institute Inc. (2012) Comparative Genomic Hybridization Microarray. <br />
retrieved from [http://www.wicell.org/home/cytogenetic-services/cgh-microarray/array-comparative-genomic-hybridization-acgh.cmsx]</ref><br />
|-style="background:pink"<br />
|Alone is more reliable and in detecting chromosomal abnormalities, with a higher implantation success rate, than FISH <ref><pubmed>20494259</pubmed></ref><br />
|<br />
|-bgcolor="pink"<br />
|Allows an in depth research focus upon specific types of rearrangements within selected chromosomal regions, a recent particular area of interest is subtelomeric and pericentromeric rearrangements<br />
|<br />
|-<br />
|reduces the risk of failed implantation and miscarriage, improving the chance of a healthy baby <ref>Iyer, B. (2013) SlideShare PreImplantation genetic diagnosis(pgd) Retrieved Oct 2, 2015 [http://www.slideshare.net/iyerbk/pre-implantation-genetic-diagnosis-pgd?related=1]</ref><br />
|<br />
|}<br />
<br />
<br />
<br />
===Next Generation Sequencing===<br />
====Description====<br />
The development and advances within ART in the past 20 years, as well as the increasing popularity of IV, has lead to an influx of new technologies developed to screen embryos for chromosomal anomalies, which are covered by the umbrella term of Next generation Sequencing (NGS). NGS is a general term used to describe all of the new and emerging screening techniques currently being introduced and used as part of PGD for IVF . NGS screens for single gene disorders as well as conducting extensive and very comprehensive chromosome diagnosis by sequencing, counting, and accurately assembling millions of DNA reads, simultaneously. <ref><pubmed>23499002</pubmed></ref> There is a movementfor NGS to replace the other limited testing techniques and be used as the standard. <br />
====Procedure====<br />
Samples are collected from either blastomere or the blastocyst/tropoectoderm and processed for analysis by a computer system. <br />
The methodology of each process is unique to the technique being used. <br />
<br />
<br />
<br />
{|border="1" align="right"<br />
|-bgcolor="pink" <br />
| '''Advantages'''<br />
| '''Disadvantages'''<br />
|-bgcolor="white"<br />
| cheaper<br />
| there are limited information available to clinical applications of NGS <ref><pubmed>26100406</pubmed></ref><br />
|-bgcolor="pink"<br />
| opens new diagnostic possibilities<br />
|<br />
|-bgcolor="white"<br />
| accurately tests all 24 chromosomes<br />
| <br />
|-bgcolor="pink"<br />
| tests for the presence of monogenic diseases of known genetic background<br />
| <br />
|-bgcolor="white"<br />
| reduces the number of biopsies required for diagnosis<br />
| <br />
|-bgcolor="pink"<br />
| higher detection rate of small translocations<br />
| <br />
|-bgcolor="white"<br />
| highly accurate is testing for compound point mutations, chromosomal duplication, deletions and insertions <ref><pubmed>23312231</pubmed></ref><br />
| <br />
|-bgcolor="pink"<br />
| it accurately detects chromosomal aneuploidy and unbalanced rearrangement <ref><pubmed>25685330</pubmed></ref><br />
| <br />
|-bgcolor="white"<br />
| NGS single gene disorder screenings can conducted in conjunction with PCR comprehensive chromosomal screening<br />
|<br />
|-bgcolor="pink"<br />
| Reduces human error <br />
|<br />
|-bgcolor="white"<br />
| better detects the presence of mosaicism<br />
|<br />
|-bgcolor="pink"<br />
| work well in conjunction with CGH and aCGH as part of PGD, improving the chances of IVF. <ref> Morris, R. S. (2015 ) Next generation sequencing for PCG|PGS|CCS. IVF1 retrieved from [http://www.ivf1.com/next-generation-sequencing for-pgd] </ref><br />
|<br />
|}<br />
<br />
<br />
<br />
<br />
<br />
<br />
==Diagnosis==<br />
There are a large amount of diseases that PGD can apply to, below are descriptions of the diseases that PGD are more commonly used for. <br />
===Cystic Fibrosis===<br />
Cystic fibrosis is a single gene disorder. It is autosomal recessive and involves mutations in the cystic fibrosis transmembrane conductance regulator (CTFR) gene. The CTFR gene is normally responsible for the decrease in chloride and the transport of bicarbonate in epithelial cells thus playing a major physiological role. In PGD procedures, identification of the gene is assisted by microsatellite markers that have similar composition to the CTFR gene itself. Biopsy of two cells at the blastocyst stage is recommended if markers are not available. There are many variations of cystic fibrosis the most common being P.Phe508del <ref name="PMID26014425"><pubmed>26014425</pubmed></ref>.<br />
===Duchenne Muscular Dystrophy ===<br />
Duchenne Muscular Dystrophy is an X-linked recessive disease. It involves the Xp21 gene where majority of the mutations are chromosomal deletions with a smaller percentage resulting from duplications <ref name="PMID18359022"><pubmed>18359022</pubmed></ref>.<br />
===β – Thalassemia=== <br />
β – Thalassemia is known as the most common type of autosomal recessive inherited disorder among haemoglobinopathies. It involves the adult β-globin gene and is associated with the absent or decreased expression of the gene. This is commonly caused by a single nucleotide change in the gene. PGD has been used successfully worldwide to identify the β-globin gene where its application is usually performed on a single blastomere or polar body <ref name="PMID19064120">19064120</pubmed></ref>.<br />
<br />
{| class="wikitable mw-collapsible mw-collapsed"<br />
! Applicable diseases for PGD <ref>Genoma Group (2014). Retrieved September 18th, 2015, from http://www.preimplantationgeneticdiagnosis.it/genetic-diseases-diagnosed-by-pgd.htm </ref>, <ref>Genesis Genetics (2015). Retrieved September 18th, 2015, from http://genesisgenetics.org/pgd/what-we-test-for/</ref>, <ref>Human Fertilisation & Embryology Authority (2015). Retrieved Septembr 18th, 2015, from http://guide.hfea.gov.uk/pgd/</ref><br />
<br />
|{<br />
| '''Disease'''<br />
| '''Involved Genes'''<br />
|-<br />
| 5 Alpha Reductase Deficiency (5ARD)<br />
| SRD5A2 <br />
|-<br />
| Achondroplasia<br />
|FGFR3 <br />
|-<br />
| Acute Intermittent Porphyria <br />
| ALAD, ALAS2, CPOX, FECH, HMBS, PPOX, UROD, or UROS<br />
|-<br />
| Adrenoleukodystrophy (Adrenomyeloneuropathy)<br />
| ABCD1 <br />
|-<br />
| Agammaglobulinaemia (x-linked) <br />
|BTK <br />
|-<br />
| Agammaglobulinemia Bruton Tyrosine Kinase (BTK) <br />
|BTK <br />
|-<br />
| Aicardi Goutieres Syndrome 1 (AGS1) <br />
|TREX1, RNASEH2A, RNASEH2B, RNASEH2C, SAMHD1<br />
|-<br />
| Alagille Syndrome<br />
|JAG1 or NOTCH2<br />
|- <br />
| Alpers-Huttenlocher Syndrome <br />
|POLG <br />
|-<br />
| Alpha-1-antitrypsin deficiency <br />
|SERPINA1 <br />
|-<br />
| Alpha-Mannosidosis<br />
| MAN2B1 <br />
|-<br />
| Alpha Thalassemia <br />
|HBA1 or HBA2 <br />
|-<br />
| Alports Syndrome<br />
|COL4A3, COL4A4, COL4A5<br />
|-<br />
| Alzheimer's Disease - early onset (Type 3 and 4) <br />
|APP, PSEN1, or PSEN2<br />
|-<br />
| Amyotrophic Lateral Sclerosis 1 (ALS1) <br />
|C9orf72, SOD1, TARDBP, FUS, ANG, ALS2, SETX, VAPB <br />
|-<br />
| Argininosuccinic Aciduria <br />
| ASL<br />
|-<br />
| Arrhythmogenic Right Ventricular Cardiomyopathy/ Dysplasia (ARVC/D)<br />
| DSG2; DSP; PKP2<br />
|-<br />
| Ataxia Telangiectasia<br />
| ATM<br />
|-<br />
| Bardet-Biedl Syndrome (BBS)<br />
| BBS1; BBS10<br />
|-<br />
| Barth Syndrome<br />
| TAZ<br />
|-<br />
| Beta Thalassaemia<br />
| HBB<br />
|-<br />
| Birt-Hogg-Dubé Syndrome<br />
| FLCN<br />
|-<br />
| Breast Ovarian Cancer Familial Susceptibility (BRCA2)<br />
| BRCA1; BRCA2<br />
|-<br />
| Canavan Disease <br />
| ASPA<br />
|-<br />
| Carnitine-Acylcarnitine Translocase Deficiency <br />
| SLC25A20<br />
|-<br />
| Cerebral Arteriopathy with Subcortical Infarcts & Leukoencephalopathy (CADASIL)<br />
| NOTCH3<br />
|-<br />
| Cerebral Cavernous Malformation<br />
| CCM1<br />
|-<br />
| Charcot-Marie-Tooth Disease<br />
| GJB1; MPZ; NEFL; PMP22<br />
|-<br />
| CHARGE Syndrome<br />
| CHD7<br />
|-<br />
| Cherubism<br />
| SH3BP2<br />
|-<br />
| Choroideremia<br />
| CHM<br />
|-<br />
| Chronic Granulomatous Disease<br />
| CYBB; NCF1<br />
|-<br />
| Ciliary Dyskinesia<br />
| DNAH5<br />
|-<br />
| Citrullinemia<br />
| ASS1<br />
|-<br />
| Cleidocranial Dysplasia<br />
| RUNX2<br />
|-<br />
| Cockayne Syndrome<br />
| ERCC6<br />
|-<br />
| Congenital Adrenal Hyperplasia<br />
| CYP21A2<br />
|-<br />
| Congenital Cataracts<br />
| GJA8; VSX2<br />
|-<br />
| Congenital Diarrhea, Syndromic<br />
| SPINT2<br />
|-<br />
| Congenital Disorders of Glycosylation (CDG)<br />
| ALG1; ALG6; CDG1C; DOLK; PMM2<br />
|-<br />
| Cornelia de Lange Syndrome <br />
| NIPBL<br />
|-<br />
| Craniosynostosis<br />
| TWIST1<br />
|-<br />
| Crouzon Syndrome<br />
| FGFR2<br />
|-<br />
| Cysteinyl Leukotriene Receptor 1 Deficiency <br />
| CYSLTR1<br />
|-<br />
| Cystic Fibrosis<br />
| CFTR<br />
|-<br />
| Diamond –Blackfan Anemia <br />
| RPS19<br />
|-<br />
| Duchenne Muscular Dystrophy <br />
| DMD<br />
|-<br />
| Dyskeratosis congenita (Male embryos only)<br />
| DKC1<br />
|-<br />
| Ectodermal dysplasia (Hypohidrotic)<br />
| EDA; EDA1; GJB6; IKBKG<br />
|-<br />
| Familial Adenomatous polyposis coli (FAP)<br />
| APC<br />
|-<br />
| Familial Dysautonomia<br />
| IKBKAP<br />
|-<br />
| Fanconi Anemia <br />
| FANCA; FANCC; FANCD2; FANCF; FANCG; FANCJ<br />
|-<br />
| Fragile X Syndrome (FRAX)<br />
| FMR1<br />
|-<br />
| Galactosemia <br />
| GALT<br />
|-<br />
| Gangliosidosis<br />
| GLB1<br />
|-<br />
| Glanzmann Thrombasthenia <br />
| ITGA2B<br />
|-<br />
| Glutaric Acidemia (aciduria)<br />
| GCDH <br />
|-<br />
| Glycogen Storage Disease <br />
| G6PC; GAA; SLC37A4<br />
|-<br />
| Haemophilia A<br />
| F8<br />
|-<br />
| Haemophilia B<br />
| F9<br />
|-<br />
| Hereditary Nonpolyposis Colorectal Cancer: Lynch Syndrome<br />
| MLH1; MSH2; MSH6<br />
|-<br />
| Holt Oram Syndrome<br />
| TBX5<br />
|-<br />
| Huntington Disease<br />
| HD<br />
|-<br />
| Hydrocephalus<br />
| L1CAM<br />
|-<br />
| Ichthyosis <br />
| ABCA12; STS<br />
|-<br />
| Incontinentia Pigmenti (IP)<br />
| NEMO<br />
|-<br />
| Joubert Syndrome 5<br />
| INPP5E<br />
|-<br />
| Krabbe Disease<br />
| GALC<br />
|-<br />
| Leber Congenital Amaurosis (LCA)<br />
| CEP290; GUCY2D<br />
|-<br />
| Leigh Syndrome (Infantile Subacute Necrotising Encephalopathy)<br />
| LRPPRC<br />
|-<br />
| Lesch Nyan Syndrome<br />
| HPRT1<br />
|-<br />
| Leukocyte Adhesion Deficiency (Type I)<br />
| ITGB2<br />
|-<br />
| Li-Fraumeni Syndrome<br />
| TP53<br />
|-<br />
| Macular Dystrophy Retinal <br />
| VMD2<br />
|-<br />
| Maple Syrup Urine Disorder (MSUD)<br />
| BCKDHB<br />
|-<br />
| Marfan Syndrome <br />
| FBN1<br />
|-<br />
| Menkes Syndrome<br />
| ATP7A<br />
|-<br />
| Mitochondrial DNA Depletion Syndrom <br />
| POLG; RRM2B; SUCLA2; TK2<br />
|-<br />
| Mucolipidosis type II<br />
| GNPTAB<br />
|-<br />
| Multiple Endocrine Neoplasia<br />
| MEN1; MEN2A; MEN2B<br />
|-<br />
| Multiple Exostoses<br />
| EXT1; EXT2 <br />
|-<br />
| Myotubular myopathy<br />
| MTM1 <br />
|-<br />
| Nail-Patella Syndrome<br />
| LMX1B<br />
|-<br />
| Neurofibromatosis Type 1<br />
| NF1<br />
|-<br />
| Neurofibromatosis Type 2 <br />
| NF2<br />
|-<br />
| Noonan Syndrome<br />
| KRAS, PTPN11; SOS1<br />
|-<br />
| Norrie Disease<br />
| NDP<br />
|-<br />
| Ocular Albinism <br />
| GPR143<br />
|-<br />
| Oculocutaneous Albinism <br />
| OCA2; TYR <br />
|-<br />
| Oculodentaldigital Dysplasia<br />
| GJA1<br />
|-<br />
| Optic Atrophy<br />
| OPA1<br />
|-<br />
| Ornithine Transcarbamylase Deficiency <br />
| OTC<br />
|-<br />
| Osteogenesis imperfeca <br />
| COL1A1; COL1A2<br />
|-<br />
| Osteopetrosis <br />
| CLCN7; OSTM1; TCIRG1<br />
|-<br />
| Pachyonychia Congenita <br />
| KRT16; KRT6A<br />
|-<br />
| Pancreatitis, Hereditary<br />
| PRSS1 <br />
|-<br />
| Papillorenal syndrome <br />
| PAX2<br />
|-<br />
| Phenylketonuria <br />
| PAH <br />
|-<br />
| This table does not cover the complete list of diseases that PGD can be applied to.<br />
|}<br />
<br />
==Laws & Legal status==<br />
===Australia=== <br />
PGD is currently used to detect serious genetic conditions to improve the outcome of Assisted Reproductive Technologies (ART). In very rare cases it may be used to select an embryo with compatible tissue for a sibling who has a life-threatening disease where other means of treatment is unavailable. This is with the conditions that the use of PGD will not affect the welfare and interests of the child to be born. The parents must also receive adequate counselling and have full understanding of the procedures of PGD. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"> National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art</ref><br />
The use of PGD for sex-selection is prohibited with the exception of reducing the risk of the transmission of serious sex-linked genetic conditions. <ref name="National Health and Medical Research Council (2007). Retrieved September 17, 2015, from https://www.nhmrc.gov.au/health-ethics/ethical-issues/assisted-reproductive-technology-art"/><br />
===Brazil=== <br />
The laws regarding PGD in Brazil are not strictly regulated. They are vague and there is limited information surround the activities of assisted reproduction in general in the country <ref name="PMID25493379"><pubmed>25493379</pubmed></ref>.<br />
===Czech Republic===<br />
The laws in the Czech Republic allow those with a “defined indication in order to exclude risk of serous genetically conditioned disease and defects with embryos before they are implanted into the cavity of the uterus”. Couples that undergo any assisted reproductive treatment including PGD have to be married. Sex-selection is illegal except in regards to serious sex-linked genetic diseases <ref name="PMID24777348"><pubmed>24777348</pubmed></ref>.<br />
===Greece=== <br />
In Greece, ART is open to those up to the age of 50 with written consent. It can only be used if a medical necessity is present such as the susceptibility of serious hereditary diseases. Sex selection is banned apart from cases of sex-linked diseases and sexually transmitted diseases <ref name="PMID24777348"/>.<br />
===Portugal=== <br />
ART is only available to those who are married or have a similar type of relationship for at least two years. The couples cannot be of the same sex and must be at least 18 years of age. Sex selection is illegal except in cases of sex-linked diseases. The use of PGD is illegal if the predictive value of genetic tests are very low <ref name="PMID24777348"/>.<br />
===Spain===<br />
PGD can be applied to “serious hereditary diseases not amenable to postnatal curative treatment” and “detection of other abnormalities which may compromise the viability of the pre-embryo”. If PGD is to be used for any other purpose authorisation must be acquired <ref name="PMID24777348"/>.<br />
===Sweden=== <br />
The use of PGD is strictly regulated and couples must achieve authorisation of the National Board of Health and Welfare. It can only be used it can only be used if the child is at risk to inheriting a serious chromosomal or monogenetic disease. It cannot be used for selection of specific characteristics <ref name="PMID24777348"/>.<br />
===United Kingdom===<br />
Those involved with carrying out the IVF treatment must have a license from the Human Fertilisation and Embryology Authority (HFEA). Only embryos that are approved by the HFEA can be implanted where the embryonic nuclear or mitochondrial DNA cannot be altered with the exception of preventing mitochondrial diseases <ref name="PMID24777348"/>. <br />
==Future/Current Research==<br />
===Noninvasive Preimplantation Genetic Testing without Embryo Biopsy===<br />
Different parameters of gametes, zygotes, embryos (“vacuoles in sperm heads, spindle position in mature oocytes, cleavage intervals of zygote, and embryo developmental dynamics”) may correlate with aneuploidy rates. This knowledge may be applied in potential noninvasive preimplantation diagnostic methods. Several methods have been proposed and are currently further researched<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Sperm Selection====<br />
Intracytoplasmic morphologically selected sperm injection (IMSI) is common procedure in IVF treatment to improve fertilization rates in patients with poor semen quality. In addition, studies have found that IMSI improves embryo development and that spermatozoa with large vacuoles in their heads correlate with increased aneuploidy rates and disturbed chromosomal structures. Thus, selecting spermatozoa based on morphological hallmarks may decrease aneuploidy rates in the fertilized embryos. As with polar body biopsies, however, this approach will solely be applicable if evidence for severe male detrimental contribution is given<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Blastocoel Fluid Extraction====<br />
In addition, a less invasive retrieval of material for diagnosis could include the extraction of the blastocoel fluid. The cavity of the blastocyst, lined by the trophectoderm, is filled with this blastocoel fluid, which contains metabolites of both trophectoderm and inner cell mass origin. The retrieval does not require a biopsy but merely a small opening to extract the fluid and, thus, causes less harm to the embryo. Multiple studies have applied this method<ref name="PMID22020776"><pubmed>22020776</pubmed></ref> <ref name="PMID23148560"><pubmed>23148560</pubmed></ref> and it may in the future become of clinical relevance.<br />
<br />
{|border="1"<br />
| [[File:Aspiration_of_the_Blastocoel_Fluid.jpeg]]<br />
|-<br />
| Aspiration of the Blastocoel Fluid using a ICSI pipette<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
|}<br />
<br />
<br />
Next to metabolites, the blastocoel fluid can contain DNA. Studies have shown that genomic DNA is present in about 90% of the blastocoel fluid samples tested. Typically the fluid is removed with an ICSI pipette from a day five blastocyst through its mural trophectoderm until the blastocyst fully collapses around the embryo. Several concerns regarding this method in a clinical setting have been raised. The collected DNA may be contaminated by the culture media that contains DNA fractions. The DNA may also be least representative of the actual embryos genome as the DNA may originate from abnormal or degenerated cells. Even though labelled noninvasive, the blastocyst still undergoes manipulation to some degree which may affect its viability. Thus, more research is required until this method can evolve from research to clinical use<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>. <br />
====Proteomics====<br />
The protein secretome of blastocysts may be representative of its chromosome constitution Recent studies have found biomarkers such as lipocalin-1, interleukin-10, tumor necrosis factor, stem cell factor, and chemokine ligand 13 to be differently secreted by aneuploid blastocyst than by euploid ones. The most significant biomarker appears to be interleukin-10. Paired with novel proteomic technologies and mass spectrometry this knowledge when extended may contribute to a new invasive preimplantation genetic diagnosis method<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
====Embryo Morphology====<br />
Using time lapse imaging the embryo’s morphology can be closely observed and potential aneuploidy characteristics detected. Such characteristics may include the time of division to five cells, the time between the division from three to four cells, and the duration of the division from one to two and subsequently to three. In addition, the morphological quality of ICM an TE has been positively associated with aneuploidy or euploidy prognosis<ref name="PMID26246880"><pubmed>26246880</pubmed></ref>. These may give rise to an embryo quality screening prior to implantation<ref name="PMID24783200"><pubmed>24783200</pubmed></ref>.<br />
===Utilization of Diseased Cell Lines===<br />
==Ethics==<br />
==References==<br />
<br />
<references/><br />
<br />
<br />
{{StudentPage2015}}</div>Z5017878