2010 BGD Lecture - Development of the Embryo/Fetus 1: Difference between revisions

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#REDIRECT [[BGDA Lecture - Development of the Embryo/Fetus 1]]
[[File:BGDsmall.jpg|left]]
==Introduction==
==Introduction==
* Begin by reviewing the recent Foundations [[2010 Foundations Lecture - Introduction to Human Development|Lecture]] and [[2010 Foundations Practical - Introduction to Human Development|Practical]].
* Begin by reviewing the recent Foundations [[2010 Foundations Lecture - Introduction to Human Development|Lecture]] and [[2010 Foundations Practical - Introduction to Human Development|Practical]].
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* The lecture will also introduce early fetal membranes and placentation.
* The lecture will also introduce early fetal membranes and placentation.
* [http://embryology.med.unsw.edu.au/Medicine/BGDlecture5.htm Previous 2008 Lecture]
* [http://embryology.med.unsw.edu.au/Medicine/BGDlecture5.htm Previous 2008 Lecture]
==Lecture Audio==
{| border='0px'
|-
| [[File:Mark_Hill.jpg|60px|left]]
|
BGD Cycle A 2010 Audio - Dr Mark Hill Thursday 6th May 2010 10-11am Clancy Auditorium  (This recording is not the UNSW Clancy iLecture, available elsewhere).
* [[2010_BGD_Lecture_-_Development_of_the_Embryo/Fetus_1|lecture page]]
* [[Media:BGD2010-EmbryoLecture01.mp3|listen]]
* [[:File:BGD2010-EmbryoLecture01.mp3|download]] (6.6 Mb MP3 53:21)
|-
|}


==Gametogenesis==
==Gametogenesis==
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* [[S#spermatogonia|Spermatogonia]] - are the first cells of spermatogenesis
* [[S#spermatogonia|Spermatogonia]] - are the first cells of spermatogenesis
* [[P#Primary spermatocyte|Primary spermatocytes]] - large, enter the prophase of the first meiotic division
* [[P#Primary spermatocyte|Primary spermatocytes]] - large, enter the prophase of the first meiotic division
* Secondary spermatocytes - small, complete the second meiotic division
* [[S#secondary spermatocyte|Secondary spermatocytes]]  - small, complete the second meiotic division
* Spermatids - immature spermatozoa
* [[S#spermatid|Spermatid]] - immature spermatozoa
* Spermatozoa - differentiated gamete
* [[S#spermatozoa|Spermatozoa]] - differentiated gamete


::'''Spermatozoa development:''' [[P#primordial germ cell|primordial germ cell]] -  [[S#spermatogonia|spermatogonia]] - [[P#primary spermatocyte|primary spermatocyte]] - [[S#secondary spermatocyte|secondary spermatocytes]] - [[S#spermatid|spermatid]] - [[S#spermatozoa|spermatozoa]]
::'''Spermatozoa development:''' [[P#primordial germ cell|primordial germ cell]] -  [[S#spermatogonia|spermatogonia]] - [[P#primary spermatocyte|primary spermatocyte]] - [[S#secondary spermatocyte|secondary spermatocytes]] - [[S#spermatid|spermatid]] - [[S#spermatozoa|spermatozoa]]
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</gallery>
</gallery>


::'''Ovarian Follicle Stages:''' [[P#primordial follicle|primordial follicle]] - [[P#primary_follicle|primary follicle]] - [[S#secondary_follicle|secondary follicle]] - [[P#preovulatory_follicle|preovulatory follicle]]
::'''Ovarian Follicle Stages:''' [[P#primordial follicle|primordial follicle]] - [[P#primary_follicle|primary follicle]] - [[S#secondary_follicle|secondary follicle]] - [[T#tertiary_follicle|tertiary follicle]] - [[P#preovulatory_follicle|preovulatory follicle]]




'''Follicle cells''' (support cells) '''Theca cells''' (produce hormone)
'''Follicle cells''' (support cells) '''Theca cells''' (produce hormone)


[http://www.ncbi.nlm.nih.gov/books/bv.fcgi?rid=mboc4.figgrp.3716 MBoC - Figure 20-18. Influence of Sry on gonad development] | [http://www.ncbi.nlm.nih.gov/bookshelf/br.fcgi?book=endocrin&part=A972&rendertype=box&id=A1230 Endocrinology - Comparative anatomy of male and female reproductive tracts]
'''Links:''' [http://www.ncbi.nlm.nih.gov/books/bv.fcgi?rid=mboc4.figgrp.3716 MBoC - Figure 20-18. Influence of Sry on gonad development] | [http://www.ncbi.nlm.nih.gov/bookshelf/br.fcgi?book=endocrin&part=A972&rendertype=box&id=A1230 Endocrinology - Comparative anatomy of male and female reproductive tracts]


==Fertilization==
==Fertilization==
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[[File:Trilaminar_embryo.jpg|thumb|Trilaminar embryo SEM]]
[[File:Trilaminar_embryo.jpg|thumb|Trilaminar embryo SEM]]
Gastrulation, (Greek = belly) means the formation of gut, but has been used in a more looser sense to to describe the formation of the trilaminar embryo. The epiblast layer, consisting of totipotential cells, derives all 3 embryo layers: endoderm, mesoderm and ectoderm. The primitive streak is the visible feature which represents the site of cell migration to form the additional layers. Historically, gastrulation was one of the earliest observable morphological event occurring in the frog embryo.
Gastrulation, (Greek = belly) means the formation of gut, but has been used in a more looser sense to to describe the formation of the trilaminar embryo. The [[E#epiblast|epiblast layer]], consisting of totipotential cells, derives all 3 embryo layers:[[E#endoderm|endoderm]], [[M#mesoderm|mesoderm]] and [[E#ectoderm|ectoderm]]. The [[P#primitive streak|primitive streak]] is the visible feature which represents the site of cell migration to form the additional layers. Historically, gastrulation was one of the earliest observable morphological event occurring in the frog embryo.


* '''primitive node''' - region in the middle of the early embryonic disc epiblast from which the primitive streak extends caudally (tail)
* [[P#primitive node|primitive node]] - region in the middle of the early embryonic disc epiblast from which the primitive streak extends caudally (tail)
** nodal cilia establish the embryo left/right axis
** nodal cilia establish the embryo left/right axis
** axial process extends from the nodal epiblast
** axial process extends from the nodal epiblast
* '''primitive streak''' - region of cell migration from the epiblast layer forming sequentially the two germ cell layers (endoderm and mesoderm)
* [[P#primitive streak|primitive streak]] - region of cell migration from the epiblast layer forming sequentially the two germ cell layers (endoderm and mesoderm)


[[File:Trilaminar_embryo_cartoon.jpg|400px|Trilaminar embryo]]
[[File:Trilaminar_embryo_cartoon.jpg|400px|Trilaminar embryo]]
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[[Image:Stage7 axial process.jpg|thumb|Stage7 axial process]]
[[Image:Stage7 axial process.jpg|thumb|Stage7 axial process]]


The notochord is a structure which has an early mechanical role in embryonic disc folding and a major signaling role in patterning surrounding embryonic tissue development. This signaling role patterns many different tissues (neural plate, neural tube, somites, endodermal organs). It has its own sequence of development from a primitive axial process and is a developmental feature not present in the adult anatomy.
The [[N#notochord|notochord]] is a structure which has an early mechanical role in embryonic disc folding and a major signaling role in patterning surrounding embryonic tissue development. This signaling role patterns many different tissues ([[N#neural plate|neural plate]], [[N#neural tube|neural tube]], [[S#somite|somites]], endodermal organs). It has its own sequence of development from a primitive axial process and is a developmental feature not present in the adult anatomy.


[http://embryology.med.unsw.edu.au/Movies/larsen/notoch.mov Movie - notochord 1] [http://embryology.med.unsw.edu.au/Movies/larsen/noto.mov Movie - notochord 2]
[http://embryology.med.unsw.edu.au/Movies/larsen/notoch.mov Movie - notochord 1] [http://embryology.med.unsw.edu.au/Movies/larsen/noto.mov Movie - notochord 2]
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'''Mesoderm''' means the "middle layer" and it is from this layer that nearly all the bodies connective tissues are derived. In early mesoderm development a number of transient structures will form and then be lost as  tissue structure is patterned and organised. Humans are vertebrates, with a "backbone", and the first  mesoderm structure we will see form after the notochord will be '''[[S#somite|somites]]'''.
'''Mesoderm''' means the "middle layer" and it is from this layer that nearly all the bodies connective tissues are derived. In early mesoderm development a number of transient structures will form and then be lost as  tissue structure is patterned and organised. Humans are vertebrates, with a "backbone", and the first  mesoderm structure we will see form after the notochord will be '''[[S#somite|somites]]'''.


'''Coelom''', meaning "cavity", and major fluid-filled cavities can be seen to form both within the embryo (intraembryonic coelom) and outside the embryo (extraembryonic coelom). The '''intraembryonic coelom''' is the single primitive cavity that lies within the mesoderm layer that will eventually form the 3 major anatomical body cavities ('''[[P#pericardial cavity|pericardial]], [[P#pleural cavity|pleural]], [[P#peritoneal cavity|peritoneal]]''').
'''Coelom''', meaning "cavity", and major fluid-filled cavities can be seen to form both within the embryo ([[I#intraembryonic coelom|intraembryonic coelom]]) and outside the embryo (extraembryonic coelom). The '''intraembryonic coelom''' is the single primitive cavity that lies within the mesoderm layer that will eventually form the 3 major anatomical body cavities ('''[[P#pericardial cavity|pericardial]], [[P#pleural cavity|pleural]], [[P#peritoneal cavity|peritoneal]]''').


<gallery>
<gallery>
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</gallery>
</gallery>


[[File:Stage11 sem10c.jpg||thumb|stage 9 Embryo]]
[[File:Stage11 sem100c.jpg||thumb|stage 11 Embryo]]


Somite initially forms 2 main components
Somite initially forms 2 main components
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==Week 4 Neuralation==
==Week 4 Neuralation==
<gallery>
<gallery>
File:Stage10_SEM1.jpg|Stage 10 Embryo (Week 4, 22 - 23 days)
File:Stage10_SEM1.jpg|[[Carnegie_stage_10|Stage 10]] (22 - 23 days)
File:Stage10_sem2.jpg|Stage 10 Embryo (Week 4, 22 - 23 days)
File:Stage10_sem2.jpg|[[Carnegie_stage_10|Stage 10]] (22 - 23 days)
File:Stage11 SEM1.jpg|Stage 11 Embryo (Week 4, 23 - 26 days)
File:Stage11_sem6.jpg|[[Carnegie_stage_11|Stage 11]] (23 - 26 days)
File:Stage12_SEM3.jpg|Stage 11 Embryo (Week 4, 26 - 30 days)
File:Stage12_SEM3.jpg|[[Carnegie_stage_12|Stage 12]] (26 - 30 days)
</gallery>
</gallery>
Ectoderm - 2 parts  
Ectoderm - 2 parts  
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===Neural Plate===
===Neural Plate===
 
[[File:Neural tube defect meningomyelocele.jpg|thumb|meningomyelocele]]
[[Image:Neural_plate_movie_icon.jpg]][[Image:Neuralplate cartoon.png]]
[[Image:Neural_plate_movie_icon.jpg]][[Image:Neuralplate cartoon.png]]


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[[File:Placenta blood.jpg|thumb|fetal blood]]
[[File:Placenta blood.jpg|thumb|fetal blood]]
* 2 populations of cells  
* 2 populations of cells  
** peripheral- form endothelial cells  
** peripheral- form [[E#endothelium|endothelial cells]] that form the lining of all blood vessels
** core- form blood cells (haemocytoblasts)  
** core- form blood cells ([[H#haemocytoblast|haemocytoblasts]])  
* all vessels (arteries and veins) appear initially the same
* all vessels (arteries and veins) appear initially the same


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# '''Secondary Villi''' - [[C#cytotrophoblast|cytotrophoblast]] + [[E#extraembryonic mesoderm|extraembryonic mesoderm]]
# '''Secondary Villi''' - [[C#cytotrophoblast|cytotrophoblast]] + [[E#extraembryonic mesoderm|extraembryonic mesoderm]]
# '''Tertiary Villi''' - [[C#cytotrophoblast|cytotrophoblast]] +  [[E#extraembryonic mesoderm|extraembryonic mesoderm]] + blood vessels
# '''Tertiary Villi''' - [[C#cytotrophoblast|cytotrophoblast]] +  [[E#extraembryonic mesoderm|extraembryonic mesoderm]] + blood vessels
<gallery>
File:Gray0036.gif|Primary chorionic villi
File:Gray0037.gif|Tertiary chorionic villi 
File:Placenta anchoring villi.jpg|Placenta anchoring villi
</gallery>


There are two main types of early villi:
There are two main types of early villi:

Latest revision as of 09:56, 18 September 2014

BGDsmall.jpg

Introduction

  • Begin by reviewing the recent Foundations Lecture and Practical.
  • This lecture covers conceptus development from fertilization to implantation to trilaminar embryo formation.
  • The lecture will also introduce early fetal membranes and placentation.
  • Previous 2008 Lecture

Lecture Audio

Mark Hill.jpg

BGD Cycle A 2010 Audio - Dr Mark Hill Thursday 6th May 2010 10-11am Clancy Auditorium (This recording is not the UNSW Clancy iLecture, available elsewhere).


Gametogenesis

Male

The testes have two functions.

  1. produce the male gametes or spermatozoa
  2. produce male sexual hormone, testosterone (internal and external genitalia, sex characteristics)
Spermatozoa development: primordial germ cell - spermatogonia - primary spermatocyte - secondary spermatocytes - spermatid - spermatozoa

Sertoli cells (support cells) Interstitial cells or Leydig cells (produce hormone)

Female

The ovaries have two functions.

  1. produce the female gametes or oocytes
  2. produce female hormones, estrogen and progesterone (secondary sex characteristics, menstrual cycle)
Ovarian Follicle Stages: primordial follicle - primary follicle - secondary follicle - tertiary follicle - preovulatory follicle


Follicle cells (support cells) Theca cells (produce hormone)

Links: MBoC - Figure 20-18. Influence of Sry on gonad development | Endocrinology - Comparative anatomy of male and female reproductive tracts

Fertilization

Early zygote showing polar bodies
  • Oogenesis - 1 gamete produced/meiosis + 3 polar bodies, meiosis is slow, 1 egg produced and released at ovulation
  • Spermatogenesis - 4 gametes produced/meiosis, meiosis is fast, 200-600 million sperm released at ejaculation


Ovulation icon.jpg Fertilization 001 icon.jpg

Fertilization Site

  • Fertilization usually occurs in first 1/3 of uterine tube (oviduct, Fallopian tube)
  • Fertilization can also occur outside uterine tube associated with In Vitro Fertilization (IVF, GIFT, ZIFT...) and ectopic pregnancy
  • The majority of fertilized eggs do not go on to form an embryo

Fertilization - Spermatozoa

Fertilization - Oocyte

Embryo mitosis icon.jpg Week1 001 icon.jpg

Week 1 and 2

Week1 summary.jpg

Week 2 Implantation

Week2 001 icon.jpg Chorion 001 icon.jpg

Week 3 Gastrulation

gastrulation
Trilaminar embryo SEM

Gastrulation, (Greek = belly) means the formation of gut, but has been used in a more looser sense to to describe the formation of the trilaminar embryo. The epiblast layer, consisting of totipotential cells, derives all 3 embryo layers:endoderm, mesoderm and ectoderm. The primitive streak is the visible feature which represents the site of cell migration to form the additional layers. Historically, gastrulation was one of the earliest observable morphological event occurring in the frog embryo.

  • primitive node - region in the middle of the early embryonic disc epiblast from which the primitive streak extends caudally (tail)
    • nodal cilia establish the embryo left/right axis
    • axial process extends from the nodal epiblast
  • primitive streak - region of cell migration from the epiblast layer forming sequentially the two germ cell layers (endoderm and mesoderm)

Trilaminar embryo

Mesoderm 001 icon.jpg

Notochord

Stage7 axial process

The notochord is a structure which has an early mechanical role in embryonic disc folding and a major signaling role in patterning surrounding embryonic tissue development. This signaling role patterns many different tissues (neural plate, neural tube, somites, endodermal organs). It has its own sequence of development from a primitive axial process and is a developmental feature not present in the adult anatomy.

Movie - notochord 1 Movie - notochord 2

  • axial process an initial epiblast hollow epithelial tube which extends in the midline from the primitive pit, cranially in the embryonic disc (toward the oral membrane).
    • neuroenteric canal is a transient communication between the amnionic cavity and the yolk sac cavity formed by the axial process.
  • notochordal plate forms from the axial process merging with the endoderm layer.
  • notochord forms from the notochordal plate which then separates back into the mesoderm layer as a solid column of cells lying in the midline of the embryonic disc and running rostro-caudally (head to tail).
    • An alternate name for the notochord is "axial mesoderm".

Somitogenesis

stage 9 Embryo
stage 10 Embryo

Mesoderm means the "middle layer" and it is from this layer that nearly all the bodies connective tissues are derived. In early mesoderm development a number of transient structures will form and then be lost as tissue structure is patterned and organised. Humans are vertebrates, with a "backbone", and the first mesoderm structure we will see form after the notochord will be somites.

Coelom, meaning "cavity", and major fluid-filled cavities can be seen to form both within the embryo (intraembryonic coelom) and outside the embryo (extraembryonic coelom). The intraembryonic coelom is the single primitive cavity that lies within the mesoderm layer that will eventually form the 3 major anatomical body cavities (pericardial, pleural, peritoneal).

stage 11 Embryo

Somite initially forms 2 main components

  • ventromedial- sclerotome forms vertebral body and intervertebral disc
  • dorsolateral - dermomyotome forms dermis and skeletal muscle

Somite 001 icon.jpg

Week 4 Neuralation

Ectoderm - 2 parts

  • midline neural plate (columnar cells)
  • lateral surface ectoderm (cuboidal cells)
    • sensory placodes
    • epidermis of skin, hair, glands, anterior pituitary, teeth enamel

Neural Plate

meningomyelocele

Neural plate movie icon.jpgNeuralplate cartoon.png

Neuralplate 001 icon.jpg Neuraltube 001 icon.jpg

Cardiogenesis

Early Development of Heart Tube

Human heart SEM1.jpg

Heart Tube Fusion

The Human Heart from day 10 to 25 (scanning electron micrograph)

  • forms initially in splanchnic mesoderm of prechordal plate region - cardiogenic region
    • growth and folding of the embryo moves heart ventrallly and downward into anatomical position
  • week 3 begins as paired heart tubes that fuse to form single heart tube
  • begins to beat in Humans- day 22-23
Week3 folding icon.jpg

Blood Islands

fetal blood
  • 2 populations of cells
  • all vessels (arteries and veins) appear initially the same

Blood Formation

Mouse hematopoietic stem cell location
  • blood formation from stem cells occurs initially in the extraembryonic mesoderm of the yolk sac
  • then later (week 5) throughout embryonic mesenchyme
  • blood stem cells then migrate into the liver
    • then spleen, bone marrow, lymph nodes

Red Blood Cells

The only cells in the blood are nearly entirely fetal red blood cells (RBC).

These red blood cells differ from adult red blood cells in:

  • often remaining nucleated
  • contain fetal haemoglobin - has different oxygen and carbon dioxide binding characteristics

Early Placentation

Week2 001 icon.jpg

Placenta and placental membranes
Placenta anchoring villi

The trophoblast layer has now differentiated into two morphologically distinct cellular layers.

Early Utero-Placental exchange - transfer of nutrition from maternal lacunae filled with secretions from uterine glands and maternal blood from blood vessels. The development of trophoblast villi extending into the uterine decidua.

There are three stages of villi development:

  1. Primary Villi - cytotrophoblast
  2. Secondary Villi - cytotrophoblast + extraembryonic mesoderm
  3. Tertiary Villi - cytotrophoblast + extraembryonic mesoderm + blood vessels

There are two main types of early villi:

  • Anchoring villi - attached to decidua
  • Floating villi - not attached to decidua, floating in maternal lacunae.

Additional Reading

The following material is not part of todays lecture, these are 2009 science lectures and other resources that relate to the concepts covered in much more detail. Cardiac Embryology was a 2009 medical student ILP embryology education project completed in my laboratory.

Cell Division/Fertilization | Week 1&2 Development | Week 3 Development | Mesoderm Development | Ectoderm, Early Neural, Neural Crest | Early Vascular Development | Placenta | Cardiac Embryology | Movies


Glossary Links

Glossary: A | B | C | D | E | F | G | H | I | J | K | L | M | N | O | P | Q | R | S | T | U | V | W | X | Y | Z | Numbers | Symbols | Term Link
2010 BGD: Lecture 1 | Lecture 2 | Practical 3 | Practical 6 | Practical 12

Cite this page: Hill, M.A. (2024, March 29) Embryology 2010 BGD Lecture - Development of the Embryo/Fetus 1. Retrieved from https://embryology.med.unsw.edu.au/embryology/index.php/2010_BGD_Lecture_-_Development_of_the_Embryo/Fetus_1

What Links Here?
© Dr Mark Hill 2024, UNSW Embryology ISBN: 978 0 7334 2609 4 - UNSW CRICOS Provider Code No. 00098G