User talk:Z3462124

Artificial Reproductive Technologies (ART) Ass. Prof. Gilchrist--> womens health and IVF

Lab 2

IVF partnership between scientists and doctors -- management of patient and their needs as well as research in labs
Growing industry--> IVF and also research and technical sides
~5 million IVF offspring living today--> arguably greatest medical success stories of our time = an emotional process for couples
AUstralia has and continues to be a pioneer in this areas

Just under a million couples each year. 1/6 Australian couples are treated for infertility--> in 2010 ~3.3% of babies were IVF. IVF hormones cost the PBS ~$100 million/year--> movement out of the private sector. Subsidized by Medicare (a large portion covered- particularly the drugs and ~six rounds of IVF) therefore it is not as expensive in aus.

Marriage of Science Research and Medicine;

Wolrds first IVF baby born in 1978-- Louise Brown-- very controversial- born in cambridge BOB EDWARDS won the Nobel Prize for Medicine for his role in the production of IVF technologies--- extremely controversial (unhealthy children)

Donor Sperm= 1960; poor quality/ no sperm

artificial insemination

Ovulation induction= 1960

failure of follicle to ovulate
One injection of hCG to induce ovulation

Donor Egg= no/ poor quality eggs -->1984

Pre-implantation genetic diagnosis= 1988

diagnosing genetic abnormalities
ability to remove cystic fibrosis (single gene following Mendilian ratio- very easy to detect) from a family--> are we removing evolution in a Darwinian sense?
Very controversial at the time
10 embryos--> 5 are carriers; 2.5 are affected and 2.5 are unaffected
1 blastomere (cell) is extracted and tested for the disease (once removed and tested the blastocyst is destroyed--- no huge implications for the embryo)
it is possible to sequence an entire genome from the one cell (predicting higher propencities for strokes or CVD -- Illegal in Australia)
process= Comparactive Genomic hybridisation)
eg's Aneuploidy, trisomy 21, translocations, single gene defects
in AUS only legal if the offspring will be affected by a devastating disease eg Trisomy 21 --> no sex selection, unless for a sex linked disease

Sperm Injection = 1992

instead of bathing egg in sperm
70-80% of all IVF are now CSI
sperm is injected into the oocyte

Blastocyst Development- 1994

decades of research of metabolic need of pre-implanatation embryos

Sex selection= 1998

capacity to sort X or Y bearing chromosome sperm and being able to inseminate based on chromosome
production of only male or female embryos
only allowed in aus. based on sex linked diseases
China-- very high pressure for sex selection= single child policy and a tradition for male children (it is not legal but it does happen)

Dolly= 2000

stem cells, cloning and genetic transfer
first demonstration of being able to clone an animal
therefore you can easily clone a human-- the same technology therefore very controversial
gvmt bodies and regulatory bodies preventing the cloning of humans-- banned in most/all countries (laws restrict drs actions--> no dr is going to break the law)
problem is-- certain aspects of technology leads to health problems of the embryo

Ovarian reserve testing = 2005

the ability to approximate the number of oocytes a woman has left-- blood test to measure AMH and AFC (ultrasound) can be used to estimate the Ovarian reserve
important due to the increase in average maternal age
womans fertility depletes almost completely at 40 (due to the loss of primordial follicles)
can sell eggs in America-- clincaly and comercialy relavant in the last 10 years
new form is being developed that tests for a hormone released directly from the oocyte
particularly relevant for young women with cancer or a carrier of breast cancer gene (allowing women to preserve ovarian reserve prior to treatments that can deplete/destroy the ovary)

OOcyte Freezing, social freezing =2008

ability to delay child bearing years
in conjunction with ORT

Whole genome screening of embryos= 2013

shanghai
examining all the genes in an embryo

Recently= mitochondrial transfer-- three types of genetic material in offspring

Built on the back of 20 years of animal research

Bovine industry--> freezing of embryos

allowing freezing of embryos in liquid nitrogen

IVF

1.Ovarian Hyperstimulation--> to generate multiple follicles and oocytes-- stems from animal research

normally only one follicle reaches ovulation
~30 follicles do not make it to ovulation but will also be lost
Inject patient with FSH (pituitary) promoting the growth of follicles--> tightly controlled by negative feedback of progesterone
Increase FSH (~10 injections and pituitary down regulation stopping the negative feedback) resulting in ~20 follicles rather than 1
Oestrogen produced by follicles granulosa cells-- 20 x more oestrogen produced with the ovulation of 20 follicles resulting in Ovarian Hyperstimulation Syndrome
Large dose of hCG-- analog to LH-- stimulating maturation of oocyte in the follicle and allowing them to be collected
LH normally stimulates ovulation

2. Oocyte Pick-up--> originally by laproscopy (through the abdominal wall); ~20 years to trans-vaginal oocyte recovery (ultrasound probe with needle at end inserted into vagina and through the ovary wall-- out-patient procedure, usually under light sedation)

3. Sperm retrieval--> ~90% via masturbation; some by surgery ( problems with ejaculation or low numbers of sperm-- from epidydimis or testes)

capacitation-- cultured for a few hours

4. IVF

occurs in a dish
ICSI-- sperm injection into the oocyte via two glass needles --> guarantees that the sperm gets into the oocyte (practically curing male infertility over night)
very technical procedure- lots of patients and a growing area of ART

5. Embryo culture

With 8 cells the embryo can be frozen and transfered into the patient (day 3)
Blastocyst growth is more common to be transferred into the patient-- higher likelihood for success

6. Transfer of Embryo

Ovarian in Vitro Maturation-- collection of follicles at a less mature stage (cultured for ~24 hours before going to IVF)

follicle arrested at P1
mature as normally once in a solution of LH (complex medium, protein, FSH)
differences to IVF--- there are no hormones; the oocyte is just picked up and then cultured in vitro

Lab 3

Transition from week 3 trilaminar embryo into early development (weeks 3 & 4)

WEEK3

Crown-rump measurement (~3cm) --> not an actual measurement of the embryo due to shrinkage (a result of fixation) and different fixatives and variables result in different degrees of shrinkage.
Major events occurring in week 3
amniotic sac on the dorsal side of the embryo--> sac lined with ectoderm (embryonic and epithelium lining cavity)
surface of amniotic sac --> extra embryonic mesoderm-- contributing to fetal membranes and placenta
Corionic cavity lined with extra-embryonic mesoderm
endoderm forms the ventral side of the embryo
Cranial end--> cardiogenic region; differentiating within mesoderm
folding of embryo ventrally bringing connecting stalk to the ventral side of embryo
umbilicus --> site of connection of chord, yolk stalk etc
sac covering embryo-- therefore the remainder of embryonic and fetal development occurs within the sac
oral membrane -- primitive mouth area
folding of the yolk sac into the embryo forms the fore, mid and hind gut
beneath heart-- transverse septum (mesoderm) contributing to liver development and the central tendon of the diaphragm
fold of endoderm extending into the connecting stalk -- blind ended tube (hollow)-- allantois (remnant of evolution or an unidentified specialised function) forming the superior end of the urinary bladder
Midgut connected by yolk stalk to the yolk sac (outside the embryo)
blood vessels that form on the yolk sac are important to the development of portal vasculature
Head paraxial mesoderm segments into somites (44-48 pairs) in a rostro-caudial direction (from head to bottom)
Intermediate Mesoderm forms 3 pairs of kidneys (pronephros, mesonephros and metanephros)
Lateral plate mesoderm --> horse shoe cavity around the cranial end separting mesoderm into somatic and splanchnic mesoderm (forming heart)
horse shoe cavity forms the 3 body cavities (pericardial, pleural and peritoneal)

WEEK4

embryo has different stem cells in different locations eg GIT, skin etc
if they grow out of control-- form tumors and cancers
totipotential eg blastomere--> undifferentiated cells that can form many tissues or cells
Primary vesicles (3) form and these then subdivide into the 5 secondary vesicles
GIT nervous system--> innervation of peristalsis (regulated by enteric ns)
Pharyngeal Arches ( 1-4 +6 --> 1 is largest and 4+6 fuse)
arch 5 if it occurs is a transient structure--> present in non-humans
each sensory system has its own placode that is associated with it eg otic placode forming the entire inner ear; optic placode forms the lens of the eye
limb buds initially formed (upper) on either side of the heart
limb buds are ecto and endoderm

ABNORMALITIES

Neural rube defects
defective fusion of the neural folds--> dysraphism
folate in flour
still a slight occurance of these abnormalities because there are many ways to generate these abnormalities independent of folate eg clef palate

Lab 4

Blood and early development of the Cardio-vascular system

fetal cells necessary to make placenta only available at implantation
blastocyst--> major player on placental development (trophoblast- forming syncitiotrophoblast and cytotrophoblasts)
syn-- outside, multi nucleated, synthesis hCG (secreted locally and taken up by maternal blood at lacunae)
cyt-- inside, single nucleus
luteum is yellow when producing hormone and albicans is white when not producing hormone
luteum produces estrogen and progesterone
progesterone suspends uterus lining in the secretory phase and therefore preserving implantation
placenta takes over from luteum--> endocrine role
extra-villus cytotrophoblast--> surround ends of placental vessels and important in maintaining placental blood flow
decidualisation--> important in contributing maternal component of placenta
three extra-embryonic chambers -- amniotic, yolk sac and chorionic cavity (largest space outside of embryo, lined with extra-embryonic mesoderm)
conceptus-- embryo and extra-embryonic cells--> all cellular products
when conceptus is divided (wk2-4)- uterine side vs. maternal blood side
uterine side--> not richly vascularised and small amount of villus development
Maternal blood side --> access nutrients, strong growth factor drive, large amount of villus development and richly vascularised
chorion laeve--> smooth, not many villi
chorion frondosum --> leafy chorion; side where placenta will form
desudua vasalis-- maternal contribution to placenta
capsularis -- lie over chorion laeva
parietalis
three stages of villi development--primary, secondary and tertiary
primary villi--> trophoblastic shell cells
secondary villi--> extra-embryonic mesoderm grows into villi
tertiary villi--> formation of blood vessels
fetal infections passed through the placenta eg malaria -- a number of immune structures to pass through
abnormal placentation-- in lobes or cord not centric can lead to impaired embryonic development
embryonic contribution to the placenta-- cytotrophoblast layer, trophoblast column (connecting site for villi), anchoring villi (attaching to maternal decidua), syncitiotrophoblast (as islands and on the outside of cytotrophoblasts)
cytotrophoblasts-- transient, from cuboidal to squamous and can degenerate
no direct contact between maternal and fetal blood
during pregnancy-- arterial/venous shunt formed in uterine wall (homogenous oxygen level within lacunae)
Eclampsia-- hypertension resulting in the decrease of oxygen exchange
accreta--> abnormal adherence and the absence of basalis