GAD L10 Third week of embryonic development_235441c9914800d3ec5787cca23a712e.pdf

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Embryology

Trilaminar Germ Disc
(Third Week of Development)

By Dr. Sally Mohsen
Assistant Professor of Anatomy
and Embryology
 objectives

1. Outline the formation of intra-embryonic mesoderm and
intraembryonic coelom.
2. Describe the process of gastrulation and fate map established during
this process.
3. Outline the formation of primitive streak and primitive node.
4. Outline formation of notochord.
5. Describe the development of trophoblast.

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 Gastrulation

GASTRULATION:
It is the most characteristic event occurring during the third week of
gestation.
The process establishes all three germ layers (ectoderm, mesoderm,
and endoderm) in the embryo.
Gastrulation begins with formation of the primitive streak on the
surface of the epiblast.
The primitive streak is a narrow groove with slightly bulging regions
on either side. It is vaguely defined, but in a 15- to 16-day embryo, it
is clearly visible.
The primitive node is the cephalic end of the streak, consists of a
slightly elevated area surrounding the small primitive pit.
The primitive pit is a depression in the center of primitive node.

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 Cells of the epiblast migrate toward the primitive streak. They become flask-shaped,
detach from the epiblast, and slip beneath it. This inward movement is known as
invagination.
Once the cells have invaginated, some displace the hypoblast, creating the embryonic
endoderm, and others come to lie between the epiblast and newly created endoderm to
form mesoderm. Cells remaining in the epiblast then form ectoderm.
Cell migration and specification are controlled by fibroblast growth factor 8 (FGF8),
which is synthesized by streak cells themselves.
As more and more cells move between the epiblast and hypoblast layers, they begin to
spread laterally and cranially.
Thus, the epiblast, through the process of gastrulation, is the source of all of the germ
layers, and cells in these layers will give rise to all of the tissues and organs in the
embryo.
In the cranial part of the embryonic disc, the cells of the hypoblast become tall
columnar forming a thickening called the prochordal plate which is firmly attached to
the overlying epiblastic disc (oral membrane) on 14th day.
With the appearance of prochordal plate, the pole of the embryo is determined & also
the central axis (right & left halves). This becomes the cranial end & other tail end.

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 Notochord
The notochord is a midline structure develops
from upper end of primitive streak to lower end of
prochordal plate.
Notochordal Process: cells multiply in the midline
between ectoderm and endoderm, reaching lower
end of prochordal plate. (17th to 18th day)
Notochordal canal: primitive pit extends into the
notochordal process, converting it into a canal.
Floor of the notochordal canal break down,
notochordal canal communicates with yolk sac and
also with amniotic cavity through primitive pit.

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 At the point where the pit forms an indentation in the epiblast,
the neurenteric canal temporarily connects the amniotic and yolk
sac cavities.
Intra-embryonic mesoderm spreads everywhere in the disc
except in prochordal plate, where ectoderm & endoderm are
adherent without mesoderm inbetween & is very thin.
This will later forms buccopharyngeal membrane (oral cavity)

The cloacal membrane is formed at the caudal end of the
embryonic disc. This membrane, which is similar in structure to the
oropharyngeal membrane, consists of tightly adherent ectoderm
and endoderm cells with no intervening mesoderm (future
urogenital region).
When the cloacal membrane appears, the posterior wall of the
yolk sac forms a small diverticulum that extends into the
connecting stalk. This diverticulum, the allantoenteric diverticulum,
or allantois, appears around the 16th day of development.

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 Prenotochordal cells invaginating in the primitive node move forward
cranially in the midline until they reach the prechordal plate.

The notochord and prenotochordal cells extend cranially to the
prechordal plate (an area just caudal to the oropharyngeal membrane) and
caudally to the primitive pit.

The notochordal plate is a two cell layers in the midline of the embryo
where prenotochordal cells become intercalated in the hypoblast.

They then form a solid cord of cells, the definitive notochord, which
underlies the neural tube and serves as the basis for the axial skeleton

Notochord acts as a forerunner in the development of vertebral column
& induces the formation of neural tube. Notochord cells persists in first
decade of life as nucleus pulposus of inter-vertebral disc.

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GROWTH OF THE EMBRYONIC DISC
The embryonic disc, initially flat and almost round, gradually becomes
elongated, with a broad cephalic and a narrow caudal end.
Expansion of the embryonic disc occurs mainly by a continuous migration
of cells from the primitive streak in the cephalic region. Their subsequent
migration forward and laterally continues until the end of the fourth week.
At that stage, the primitive streak shows regressive changes, rapidly
shrinks, and soon disappears.
That the primitive streak at the caudal end of the disc continues to supply
new cells until the end of the fourth week has an important bearing on
development of the embryo.
In the cephalic part, germ layers begin their specific differentiation by the
middle of the third week, whereas in the caudal part, differentiation begins by
the end of the fourth week.
Thus gastrulation, or formation of the germ layers, continues in caudal
segments while cranial structures are differentiating, causing the embryo to
develop cephalocaudally.

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FATE MAP ESTABLISHED DURING GASTRULATION

Regions of the epiblast that migrate and ingress through the primitive streak have been
mapped, and their ultimate fates have been determined as follows:
Cells that ingress through the cranial region of the node become prechordal plate and
notochord
Cells migrating at the lateral edges of the node and from the cranial end of the streak
become paraxial mesoderm
Cells migrating through the midstreak region become intermediate mesoderm.
Cells migrating through the more caudal part of the streak form lateral plate
mesoderm.
Cells migrating through the caudal most part of the streak contribute to
extraembryonic mesoderm (the other source of this tissue is the primitive yolk sac
[hypoblast]).

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FURTHER DEVELOPMENT OF THE TROPHOBLAST

By the beginning of the third week, the trophoblast is characterized by primary
villi that consist of a cytotrophoblastic core covered by a syncytial layer.
During further development, mesodermal cells penetrate the core of primary villi
and grow toward the decidua. The newly formed structure is known as a secondary
villus.
By the end of the third week, mesodermal cells in the core of the villus begin to
differentiate into blood cells and small blood vessels, forming the villous capillary
system. The villus is now known as a tertiary villus or definitive placental villus.
Capillaries in tertiary villi make contact with capillaries developing in the
mesoderm of the chorionic plate and in the connecting stalk. These vessels, in turn,
establish contact with the intraembryonic circulatory system, connecting the placenta
and the embryo.
Hence, when the heart begins to beat in the fourth week of development, the
villous system is ready to supply the embryo proper with essential nutrients and
oxygen.

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 Cytotrophoblastic cells in the villi penetrate progressively into the
overlying syncytium until they reach the maternal endometrium. Here they
establish contact with similar extensions of neighboring villous stems,
forming a thin outer cytotrophoblast shell. This shell gradually surrounds
the trophoblast entirely and attaches the chorionic sac firmly to the maternal
endometrial tissue.
Villi that extend from the chorionic plate to the decidua basalis (decidual
plate: the part of the endometrium where the placenta will form; are called
stem or anchoring villi. Those that branch from the sides of stem villi are
free (terminal) villi, through which exchange of nutrients and other factors
will occur.
The chorionic cavity, meanwhile, becomes larger, and by the 19th or 20th
day, the embryo is attached to its trophoblastic shell by a narrow connecting
stalk. The connecting stalk later develops into the umbilical cord, which
forms the connection between the placenta and embryo.

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 References
1. Langman’s Medical Embryology, 12th edition.
2. Essentials of Human Embryology, by A.K. Datta, 5 th edition
3. Before we are born, by More & Persuad
4. Internet websites (for videos)

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