Embryology PDF

Summary

This document provides an overview of embryology, focusing on the processes of spermatogenesis and oogenesis. It details the cellular stages and hormonal influences involved in gamete formation.

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INTRODUCTION TO BODY STRUCTURE 85

GENERAL EMBRYOLOGY
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Meiotic divisions and crossing over

Spermatogenesis
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GAMETOGENESIS
Definitions
Primary sexual organ: it is the organ containing the cells capable of forming a gamete
(half of the future human being). They are the testis in males and the ovaries in
females.
Primary sex cells: The cells which are capable of forming a gamete. They are the
spermatogonium in males and oogonium in females.
Gametogenesis: it is formation of a gamete (sperms in males and ova in females).
Mitotic division: is the division of a cell leading to two daughter cells similar to each
other and to the mother cell.
Meiotic division: is the division of a cell leading to two daughter cells not similar to each
other or the mother cell. It shows a decrease in the number or the amount of
chromosomes and DNA. In gametogenesis there are two meiotic divisions:
First meiotic division:
The 46 chromosomes in the nucleus of a cell arranges into two columns (each
contains 23 chromosomes).
Each chromosome incompletely splits into two chromatids.
Crossing over: each chromosome exchanges a segment with its neighboring
chromosome (this leads to uncounted number of chromosomal variations).
The cell divides into 2 cells (each containing 23 chromosomes).
Second Meiotic division:
Each of the 23 chromosomes splits completely into two chromatids.
Each chromatid develops into complete chromosome (note that the two
chromatids are not identical, So, the newly formed chromosomes are not
similar).
The cell divides into 2 cells (each containing 23 chromosomes).

SPERMATOGENESIS
Definition: formation of a sperm from spermatogonium.
Site: in seminiferous tubules of the testis.
Process:
Spermatogonia lies on the basement membrane of the seminiferous tubules. It
contains 46 chromosomes (44+X+Y).
Each spermatogonium divides by mitosis forming 2 daughter spermatogonia (each
contains 46 chromosomes (44+X+Y).
One of the daughter spermatogonia (spermatogonia A) remains in contact with
basement membrane while the other (spermatogonia B) starts to mature.
Spermatogonia B enlarges in size and transforms into primary spermatocyte
(44+X+Y chromosomes). Primary spermatocyte is the largest germ cell.
Primary spermatocyte divides by 1st meiotic division forming two secondary
spermatocytes (22+X and 22+Y chromosomes). This division decreases the number
of chromosomes.
Each secondary spermatocyte divides by 2nd meiotic division forming two
spermatids (22+X or 22+Y). This division decreases the amount of DNA in each
chromosome.
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Sperm

Scanning EM of sperms

Abnormal forms of sperms
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Spermiogenesis: is the transformation of spermatid into sperm:
The nucleus of the spermatid becomes the head of the sperm.
The Golgi apparatus of the spermatid becomes the head (acrosome) cap of the
sperm (containing enzymes to facilitate the penetration of ova).
One of the centrioles of the spermatid elongates forming the axial filament of the
sperm (middle piece and tail).
The mitochondria of the spermatid surrounds the upper part of the axial filament
forming the middle piece.
The rest of the axial filament forms the tail of the sperm.
The neck is a narrow junction between the head and the middle piece.
The sperm is about 55 μm (0.055 mm) long where the head is 5 μm and the tail is
50 μm (1/10).
Characteristics of spermatogenesis:
The process from the mitotic division of spermatogonia to the formation of the sperm
lasts for about 2 months.
The spermatogenesis results in formation of 4 sperms from each spermatogonium
with a preservation of a copy for further spermatogenesis (that’s why spermatogenesis
does not stop by age).
The sperms passing from testis are immotile, they acquire motility during passage in
epididymis (2 weeks).
Each testis is divided into 200 compartments, each contains 2 seminiferous tubules,
each of them is 2 feet long. A large number of sperms are continuously formed.
SEMINAL FLUID (SEMEN)
❖ It consists of sperms (formed in testis and transported through epididymis, vas deference
and ejaculatory duct) and secretions from male genital glands (mainly seminal vesicles
and prostate).
Normal parameters of semen:
Amount: 2-6 ml/ ejaculate. Lower volume is called hypospermia (hypo = below), the
absence of semen with ejaculation is known as aspermia (a = no).
Sperms count: 20-200 million sperm/ ml (40-1200 million sperms/ ejaculate). Lower
values are called oligozoospermia (oligo = few).
Vital sperms: ≥ 60%. Lower values are called necrozoospermia (necro = dead).
Normal sperm forms: (≥ 4%), Some abnormal forms are capable of fertilization. Lower
values are called teratozoospermia (terato = malformed).
Sperm motility: ≥ 40% and ≥ 30% with aggressive motility. Lower values are called
asthenozoospermia (astheno = weak).
❖ Out of the ejaculated sperms, only 500 sperms reach the ampulla of Fallopian tubes (site
of fertilization). This process lasts 2 hours after ejaculation.
❖ Sperms survives for 2 days in female genital tract.
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Oogenesis
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OOGENESIS

Definition: formation of a ova from oogonium.
Site: in the cortex of ovaries.
Process:
Oogonia contains 46 chromosomes (44 + X + X).
Oogonium enlarges in size and transform into primary spermatocyte (44+X+X
chromosomes).
Primary oocyte divides by 1st meiotic division forming two cells; one secondary
oocytes (22+X) and the other degenerates forming 1st polar body (22+X).
Secondary oocyte divides by 2nd meiotic division forming two cells; mature ova
(22+X) and the other degenerate forming 2nd polar body (22+X).
Characteristics of Oogenesis:
Oogenesis timing:
⎯ During female intrauterine life, all oogonia are transformed to primary oocytes,
which starts 1st meiotic division but does not complete it.
⎯ With each ovarian cycle, primary oocyte completes the first meiotic division
forming secondary oocyte and 1st polar body, the secondary oocyte starts the 2nd
meiotic division but does not complete it, this is the cell which is ovulated.
⎯ If fertilization occurs, secondary oocyte completes the 2nd meiotic division
forming mature ova and 2nd polar body.
Oogenesis population
⎯ During intrauterine life, the oogonia undergoes several mitotic divisions reaching
5 million, most of them degenerate and only 1 million are transformed into
primary oocytes (at birth), only 40.000 primary oocytes survive to the age of
puberty.
⎯ Starting from puberty, each ovarian cycle 20-100 primary oocytes start the
process of ova formation, only one of them succeeds. The large consumed number
are necessary for hormonal production to complete the process.
⎯ The oogenesis results in formation of 1 ovum from 20-100 oocyte (that’s why
oogenesis stops by age leading to menopause).
⎯ Only one ovum is produced each month. It lasts for 12-24 hours only.
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Follicle development
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OVARIAN FOLLICLES AND OVULATION
Primary follicle: during intrauterine development, each primary oocytes is surrounded by a
single layer of flat follicular cells.
Secondary follicle: at puberty, and parallel to the development of primary oocyte into
secondary oocyte, the follicular cells become granulosa cells (multilayers of cubical cells
containing granules (hence the name).
Tertiary follicle: cavities start to appear between granulosa cells.
Mature Graafian follicle:
The cavities enlarge and unite forming an antrum (= chamber).
The outer layer of the follicle is called stratum granulosum (= granular layer).
The secondary oocyte with its surrounding cells is called cumulus oophorous (=
ovarian elevation) and is formed of:
⎯ Secondary oocyte.
⎯ Zona pellucida (= transparent zone): a membrane surrounding the secondary
oocyte.
⎯ Corona radiata (= radiating crown): the granulosa cells around the zona
pellucida.
The ovarian tissue due to the compression of enlarging follicle becomes compact and
form a capsule called theca folliculi which is further divided into:
⎯ Theca interna: formed of connective tissue cells which secrete estrogen.
⎯ Theca externa: formed of fibrous tissue.
Ovulation: due to the enlargement of the follicle and pressure on the ovarian cortex, the
overlying cortex becomes ischemic and rupture leading to:
The secondary oocyte with the surrounding zona pellucida and corona radiata leaves
the ovary and enters the Fallopian tube.
The rest of the granulosa cells and surrounding theca interna cells start to accumulate
yellow pigments forming corpus luteum (= yellow body) and secrete progesterone
and small amount of estrogen.
⎯ If fertilization occurs, the dividing cells secrete HCG which stimulates the corpus
luteum to enlarge and continue secreting progesterone during the first half of
pregnancy (corpus luteum of pregnancy) till it is replaced by placenta.
⎯ If no fertilization occurs the corpus luteum gradually degenerates within ten days
(corpus luteum of menstruation → corpus albicans).
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Ovarian cycle
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OVARIAN CYCLE
❖ It is cyclic changes which occur in the ovarian follicles under the effects of the pituitary
hormones.
❖ This cycle occurs monthly from puberty to menopause.
Phases of ovarian cycle:
Follicular phase: the pituitary gland starts to secrete FSH which leads to:
Primary oocyte completes the 1st meiotic division forming secondary oocyte and
1st polar body.
Maturation of primary follicle to mature Graafian follicle. The granulosa cells
secrete estrogen which at certain level has negative feedback on FSH (decreases
its secretion) and stimulates LH secretion (also from pituitary gland).
The high estrogen level of this phase is responsible for the proliferative phase of
uterine cycle.
Ovulation: caused by LH surge leading to liberation of secondary oocyte with its
surroundings from the ovary.
Luteal phase:
LH secreted from pituitary gland causes corpus luteum to secrete progesterone
and small amount of estrogen (both suppress FSH stopping crossing cycles).
If fertilization occurs, the corpus luteum enlarges and continues secreting
progesterone leading to inhibition of FSH → stopping new cycles.
If fertilization does not occur, corpus luteum gradually degenerates, and
progesterone level decreases leading to an increase in FSH hormone causing
initiation of a new cycle.
The high progesterone level of this phase is responsible for the secretory phase of
uterine cycle.
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Ovarian and uterine cycles
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UTERINE (MENSTRUAL) CYCLE
❖ The uterus is a muscular organ lined with endometrium formed of basal, compact and
spongy layers.
❖ The uterine cycle is a monthly changes which occurs in the uterine endometrium under
the effect of the ovarian hormones.
❖ This cycle occurs monthly (21-35 days) from puberty to menopause.
Phases of Uterine cycle:
Proliferative (estrogenic – follicular) phase :
Under the effect of estrogen (secreted by the granulosa cells during the follicular
phase of ovarian cycle).
The estrogen stimulates the basal layer to develop leading to construction of
compact and spongy layers (the cells increase in number, the glands and the
arteries increase in number and size).
It lasts for 10 days.
Secretory (progestational – luteal) phase :
The endometrium proliferates under the effects of progesterone (mainly) and
estrogen secreted by corpus luteum in the luteal phase of the ovarian cycle.
The cells enlarge and accumulate nutrients, the glands dilate and are filled with
glycogen and the arteries dilate and become spiral.
It lasts for 14 days.
If fertilization occurs, corpus luteum of pregnancy continues to secrete
progesterone keeping the enlarged endometrium with the dividing cells implanted
into it (the endometrium will be called decidua).
If fertilization does not occur, the corpus luteum degenerates with decreased
progesterone level leading to vasoconstriction of the uterine arteries causing
ischemia followed by shedding and bleeding.
Menstrual phase:
It occurs due to decreased estrogen and progesterone levels due to degeneration
of corpus luteum.
Shedding of the compact and spongy layers of endometrium occurs leaving only
the basal layer.
It lasts for 3-7 days.

MENOPAUSE
❖ It is cessation of ovarian cycle due to exhaustion of primary follicles during previous
cycles → little number of follicular cells is present to be stimulated by FSH → decreased
estrogen and progesterone levels → cessation of uterine cycle.
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Fertilization

Cleavage, morula and blastocyst
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FERTILIZATION
Definition: fusion between a single sperm and an ovum to form a fertilized ova (zygote).
Steps:
Capacitation:
It occurs during the passage of the sperm into the female genital tract due to
exposure to its enzymes.
It is chemical changes affecting the acrosomal cap and increased activity.
Acrosome reaction:
It occurs in Fallopian tube due to exposure to secondary oocyte.
It is perforations in the acrosomal cap leading to the release of its enzymes.
Penetration of corona radiata: by many sperms.
Penetration of zona pellucida: it occurs by a single sperm. However, many sperms are
needed to pore their enzymes.
Zonal reaction: chemical changes in zona pellucida so that it is not affected by
acrosomal enzymes anymore.
Fusion of cell membranes of the sperm and the secondary oocyte.
Completion of 2nd meiotic division and formation of mature ova and 2nd polar body.
Fusion of pronuclei: the head of the sperm (male pronucleus) and the nucleus of the ova
(female pronucleus) fuse together, leading to restoration of diploid number of
chromosomes (46) and detection of sex (44+XX is a female and 44+XY is a male).
The zygote starts cleavage (division of cells).
Hormonal effect: the dividing cells produce HCG which stimulates corpus luteum
growth (corpus luteum of pregnancy) → high progesterone and estrogen levels →
maintenance of secretory phase of uterine cycle and inhibition of FSH and LH leading
to ovarian cycle pause.
CLEAVAGE, MORULA AND BLASTOCYST
Definition of cleavage (segmentation): is repeated mitotic division of the zygote.
During cleavage the zygote moves by cilia of Fallopian tube towards the uterus.
The cells divide into 2-4-8-16-32 cells.
16-32 cells mass is called Morula (= mulberry).
The morula is still surrounded by zona pellucida and reaches the uterus on the 4th day
after fertilization.
During the 5th and 6th days, the uterine enzymes dissolve the zona pellucida and the
dividing cells shows a cavity between them. The cell mass is called blastocyst, the
cavity is called blastocoele and the cells are called blastomeres (nearly 64 cells) and
divides into:
⎯ Outer cell mass (trophoblast): nutrient cells.
⎯ Inner cell mass (embryoblasts): embryo forming cells.
On the 7th day of fertilization, the blastocyst implants inside the wall of uterus.
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Implantation

Normal and abnormal implantation
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IMPLANTATION

Definition: it is the invasion of the blastocyst to the endometrium of the uterus.
Duration: between 7th and 14th day after fertilization.
Site: usually in the endometrium of the upper 1/3 of the uterus (post wall).
Mechanism:
The trophoblast over the embryoblast (embryonic pole) projects forming finger like
processes and produces enzyme to invade the endometrium (which is prepared
forming nutrient filled cells, glycogen rich glands and spiral arteries).
The last part of blastocyst sinks into the uterus (ab-embryonic pole), the site of
implantation is closed by fibrinous tissue followed by regeneration of the epithelium.
Accordingly, the whole trophoblasts are inside the endometrium (and not just attached
to it).
Changes of blastocyst during implantation (2nd week after fertilization):
The trophoblasts divide into:
Outer syncytiotrophoblasts: loose its cell walls for easier penetration
Inner cytotrophoblasts.
Both layers secrete HCG maintaining corpus luteum (of pregnancy).
The embryoblasts arrange into a bilaminar disc with two layers of cells:
Ectoderm: columnar cells.
Endoderm: cubical cells.
The blastocoele is divided by the disc into two cavities:
Amniotic cavity: dorsal to ectoderm. Its roof is called amnion (amniotic membrane)
and is formed from cells derived from trophoblasts.
Primary yolk sac: ventral to endoderm. Endodermal cells migrate to line it forming
(Heuser's membrane).
Abnormal sites of implantation:
1) Placenta Previa: implantation in the lower part of the uterus. The developing
placenta will be under the fetus (previa = exceeding).
2) Ectopic pregnancy:
a) Tubal pregnancy: in the uterine tube.
b) Ovarian pregnancy: in the ovary.
c) Abdominal pregnancy: in the abdominal cavity.
⎯ Ectopic pregnancy does not complete due to lack of adequate uterine nutrition. It
invades the organ implanted at and causes its rupture or bleeding.
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Chorionic vesicle

Chorionic villi

Parts of chorion and decidua
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CHORIONIC VESICLE
Formation:
Cytotrophoblast cells form a new layer inner to it called extraembryonic mesoderm
(EEM).
spaces appear inside EEM forming extraembryonic coelom (EEC) which divides
EEM into outer layer lining the cytotrophoblast & inner layer surrounding the
amniotic cavity and yolk sac.
Part of the EEM will still connect the outer and inner layers (connecting stalk or
future umbilical cord) dorsal to amniotic cavity.
Now the blastocyst is called chorionic vesicle.
The outer wall of the chorionic vesicle is called chorion, and is formed of
(syncytiotrophoblast, cytotrophoblast and EEM lining the trophoblast).
The chorion gives finger like processes called chorionic villi which invades the
uterine wall. The spaces between the chorionic villi (intervillous spaces) are filled
with maternal blood.
The chorionic villi surround the whole chorionic vesicle, then the villi will enlarge
deep in uterine wall (chorion frondosum), and atrophies towards the uterine cavity
(chorion leave).
Stages of chorionic villi:
1) Primary villi: formed of syncytiotrophoblast + cytotrophoblast.
2) Secondary villi: formed of syncytiotrophoblast + cytotrophoblast and extraembryonic
mesoderm.
3) Tertiary villi: formed of syncytiotrophoblast + cytotrophoblast and extraembryonic
mesoderm invaded by fetal blood vessels. It is further divided into:
a) Stem (anchoring) villi: each extends from the base of the chorion (chorionic
plate) towards the uterine wall.
b) Branching (free absorbing) villi: small villi branching from the stem villi and
surrounded by maternal blood. They are the sites of exchange of nutrients and
gases between the maternal and fetal blood.
Parts of chorion
1) Chorion frondosum: the part of the chorion invading the uterine wall. It shows
numerous branching tertiary villi.
2) Chorion leave: The part of the chorion facing the uterine cavity. It is less developed.
DECIDUA
Definition: it is the endometrium after implantation. It maintains its secretory phase under
the effect of progesterone (of corpus luteum and placenta). The stromal endometrial cells
are called decidua cells. The decidua falls as a single mass during labor (decidua = fall).
Features:
1) The endometrial stromal cells (decidua cells): enlarge and filled with nutrients.
2) The endometrial glands: becomes larger, tortuous and filled with glycogen and
mucin.
3) The blood vessels: engorged, spiral. They are invaded by chorionic villi pouring
maternal blood between them.
Parts of decidua:
1) Decidua basalis: deep to the blastocyst.
2) Decidua capsularis: superficial to blastocyst (separating it from uterine cavity).
3) Decidua parietalis: the rest of the endometrium.
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Primitive streak & primitive node

Notochord

Neural tube
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CHANGES IN THE EMBRYOBLASTS
❖ At the stage of blastocyst, the embryoblasts are the inner cell mass. During implantation
the embryoblasts arrange into a bilaminar disc (ectoderm and endoderm).
❖ The disc is at first rounded, then oval, then pear shaped with a wide cranial end and
narrow caudal end.
PRIMITIVE STREAK & PRIMITIVE NODE
Formation:
Some midline caudal ectodermal cells proliferate to form a thick rod like structure
called primitive streak.
The cells at the cranial end of the primitive streak proliferate to form the primitive
node.
A depression occurs in the primitive node called primitive pit.
NOTOCHORD
Formation:
Some cells of the primitive node proliferate and form a median solid cord called
notochordal process, between the ectoderm and endoderm. It extends cranially to
prechordal plate (prechordal = before the cord).
The primitive pit deepens inside the notochordal process transforming it into
notochordal canal.
The floor of the notochordal canal degenerates with the underlying endoderm. So, a
connection is formed between the amniotic cavity and the yolk sac (neuroenteric
canal).
The remaining roof and sides of the notochordal process form the notochordal plate,
then enfolds to form solid definitive notochord (notochord = cord of the back) which
is the primitive axis of the embryo.
NEURAL TUBE
Formation:
The central part of the ectoderm between primitive node and prechordal plate thickens
to form neural plate.
The neural plate invaginates to form neural groove, which has two neural folds on
its sides. The junction between the ectoderm and the neural groove on each side
shows a longitudinal strip called neural crest.
The neural folds fuse with each other to form the neural tube.
The neural tube separates from the surface ectoderm and sinks down below it but
above the notochord. The neural crest becomes dorsolateral to the neural tube.
The neural tube has two openings at its ends called the cranial and caudal
neuropores, which close by the end of the 4th week.
The neural tube differentiates forming the central nervous system. While the neural
crest differentiates forming dorsal root ganglion and other structures.
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Intraembryonic mesoderm

Somites
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INTRAEMBRYONIC MESODERM (IEM)
Formation:
Cells from primitive streak and primitive node migrate between ectoderm and
endoderm and form intraembryonic mesoderm (IEM).
IEM separates ectoderm from endoderm except at:
Prechordal plate (Buccopharyngeal membrane): it is the future mouth, lies cranial
to notochord, here, the endodermal cells become columnar and fuse tightly with
the overlying ectoderm.
Cloacal membrane: it is the future anal canal and urethra, it lies caudal to primitive
streak.
The IEM of both sides meat ant to prechordal plate (the most cranial part is called
septum transversum (future diaphragm) followed caudally by cardiogenic area
(future heart). It also crosses midline post to cloacal membrane (here it is connected to
connecting stalk (future umbilical cord).
Derivatives of IEM: on each side of the notochord, the IEM is divided into three parallel
craniocaudal masses (from medial to lateral):
1) Paraxial mesoderm:
It is divided into cubical masses called somites, which appear in a craniocaudal
sequence. The first pair of somites appear on the 20th day of development and the
last one in the 5th week.
There are 42–44 pairs of somites; 4 occipital, 8 cervical, 12 thoracic, 5 lumbar, 5
sacral and 8–10 coccygeal.
Each somite is divided into three parts:
a) Sclerotome: ventromedial, it surrounds the notochord and differentiates into
vertebral column and ribs.
b) Myotome: intermediate, it differentiates into the muscles of the back.
c) Dermatome: dorsolateral, it differentiates into the dermis of the skin, which
cover the muscles of the back. (both the skin and the muscles of the back are
supplied by dorsal rami of the spinal nerves).
2) Intermediate cell mass: it is the nephrogenic area, it differentiates into most of the
urogenital system.
3) Lateral plate mesoderm:
Many small cavities appear in that plate. These cavities fuse together to form a u
shaped cavity called intraembryonic coelom (IEC) whose base is cranial to the
oropharyngeal membrane. The IEC divides the lateral plate mesoderm into:
a) Somatic (parietal) layer: dorsal layer in contact with ectoderm, differentiates
into the dermis, bones, joints, muscles and vessels of the limbs and ventral part
of the trunk.
b) Splanchnic (visceral) layer: ventral layer in contact with endoderm,
differentiates into the connective tissue, smooth muscles and vessels of the
viscera (gastrointestinal, respiratory and urogenital systems).
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Folding
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FOLDING

Timing: 4th week of pregnancy.
Causes:
Rapid growth of the cranial part of the neural tube.
Expansion of amniotic cavity.
Results of folding:
Formation of folds:
1) Head fold (cranial).
2) Tail fold (caudal).
3) Two lateral folds.
Fusion of similar germ layers: the three layers of the embryonic disc fold together.
After complete folding each layer unites with the similar one of the opposite side, all
around the connecting stalk (future umbilical cord). The ectoderm becomes the outer
layer surrounding the embryo (future epidermis).
Formation of the gut and definitive yolk sac:
The endoderm and most of the yolk sac invaginates within the folds.
The endoderm will form a tube inside the folds (gut) which is further divided into:
a) Foregut: in the head fold.
b) Midgut: between the lateral folds.
c) Hindgut: in the tail fold.
A small part of the yolk sac becomes outside the fold but still connected to the
midgut by vitelline (vitello intestinal) duct (vitellus = Yolk sac). This part is
called definitive Yolk sac.
Rearrangement of positions:
The cranial part of neural tube (future brain) becomes the most cranial structure
and forms a large forebrain bulge.
The prechordal plate (future mouth) lies caudal to the developing brain.
The cardiogenic area (future heart) becomes caudal to the prechordal plate and
forms a large Pericardial bulge.
Septum transversum (future diaphragm) becomes caudal to the cardiogenic area.
The connecting stalk (future umbilical cord) becomes ventral near the definitive
yolk sac.
The cloacal membrane (future anal canal and urethra) becomes caudal to
connecting stalk.
The amniotic cavity surrounds the whole embryo.
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Placenta
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CHANGES IN THE TROPHOBLASTS
PLACENTA
Formation: formed of chorion frondosum and decidua basalis.
Microscopic features:
The chorion projects chorionic villi invading decidua basalis.
The part of the chorion forming the base of chorionic villi is called chorionic plate.
The chorionic villi deepen inside the decidua but does not reach the muscular layer of
the uterus, to prevent that, the cytotrophoblasts of the stem villi pierce their overlying
syncytiotrophoblasts and join each other deep to the chorionic vesicle, forming
cytotrophoblastic shell separating it from the deeper layers of decidua.
Placental barrier: it is the layers separating the fetal blood (inside the fetal blood vessels
of chorionic villi) from the maternal blood between the villi.
At the first 20 weeks of pregnancy, the barrier is formed of syncytiotrophoblast,
cytotrophoblast, extraembryonic mesoderm and endothelium of the fetal vessels.
After 20 weeks of development, the barrier is formed of syncytiotrophoblast and
endothelium of fetal vessels, to facilitate material exchange between maternal and
fetal blood.
Macroscopic features (at birth):
Discoid in shape.
500 gm in weight.
15 – 20 cm in diameter. Occupying 20-30% of the endometrium.
It is about 3 cm thick in the center, and gradually thins towards the periphery (1 cm).
Surfaces:
Maternal: irregular, formed of 15–20 irregular projections called cotyledons. The
cotyledons are separated by placental septa, arising from the decidua basalis.
Fetal: smooth, covered by amniotic membrane, the umbilical cord is attached near the
center.
Functions of the placenta:
1) Respiratory: O2 passes from maternal to fetal blood and CO2 passes from fetal to
maternal blood (replacing lungs function).
2) Nutritive: nutrients pass from maternal to fetal blood (replacing GIT function).
3) Excretory: waste products pass from fetal to maternal blood (replacing kidneys
function).
4) Endocrinal (secretory): the placenta secretes:
a) Human chorionic gonadotrophins (HCG): which maintains the corpus luteum
for the 1st half of pregnancy.
b) Estrogen and progesterone.
c) Lactogen, relaxin and other hormones.
5) Immunological: Some antibodies pass from maternal to fetal blood.
6) Protective: The placental barrier prevents passage of some infective agents and
harmful drugs from maternal to fetal blood. However, some bacteria (e.g., syphilis),
viruses (e.g., German measles), parasites (e.g., toxoplasma) and drugs (e.g.,
morphine) may pass the placental barrier causing harmful effects on fetus.
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Placenta previa

Placental anomalies
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Anomalies of the placenta:
1) Position anomalies (placenta previa): the placenta is lower than the fetus due to
implantation in the lower part of the uterus. Further divided into:
a) lateral placenta previa: the placenta is attached to the lower uterine segment but
above the cervix.
b) Marginal placenta previa: the placenta is attached to the margin of the uterine
cervix.
c) Central placenta previa: the placenta is covering the internal os of cervix.
N.B.: the lower uterine segment is the most growing and stretched part of the
uterus. This may cause repeated tears in the placenta and repeated
hemorrhages during pregnancy. It is completely forbidden to perform a PV
(per vaginal) examination in that case as it may cause placental injury and
fatal bleeding.
2) Shape anomalies:
a) Bilobed (bipartite - bidiscoid) placenta: the placenta is formed of two discoid
equal parts.
b) Trilobed (tripartite - tridiscoid) placenta: the placenta is formed of three discoid
equal parts.
c) Accessory (succenturiate) placenta: small part of the placenta is separated from
the main part.
N.B.: in these cases, a part of the placenta may remain in the uterus after delivery,
leading to postpartum hemorrhage.
d) Diffuse (membranous) placenta: placenta occupying a wide area of
endometrium, due to spreaded chorion frondosum.
3) Umbilical cord attachment anomalies
a) Battledore placenta: the umbilical cord is attached to the periphery of the
placenta.
b) Velamentous attachment of umbilical cord: the umbilical cord is attached to fetal
membranes away from placenta. However, the umbilical vessels are still
connected to the placenta.
4) Placenta accreta (= adherent): abnormally fixed placenta to the uterus, due to deep
invasion of chorionic villi reaching the muscle layer of the uterus.
INTRODUCTION TO BODY STRUCTURE 114

Umbilical cord
Quora
INTRODUCTION TO BODY STRUCTURE 115
UMBILICAL CORD
Formation and progress:
At the stage of chorionic vesicle, the extraembryonic mesoderm lines the trophoblasts
and covers the amniotic cavity and yolk sac. The two layers are separated by
extraembryonic coelom except a part dorsocaudal to amniotic cavity called the
connecting stalk.
After folding, the connecting stalk moves to the ventral aspect of the embryo. It
elongates gradually with the growth of the fetus allowing free movements.
Contents:
1) Warton’s jelly: the EEM of the connecting stalk.
2) Umbilical vessels:
a) Two (Rt & Lt) umbilical arteries: carries non oxygenated blood from the fetus to
the placenta.
b) Two (Rt & Lt) umbilical veins: the Rt rapidly disappears. The Lt vein carries
oxygenated blood from the placenta to the fetus.
3) Vitelline duct: which connects the midgut to the definitive yolk sac. Later this duct
disappears.
4) Urachus (distal part of allantois).
Macroscopic features (at birth):
50–60 cm in length.
1–2 cm in diameter.
Covered by amniotic membrane.
Anomalies of umbilical cord:
1) Very long cord: may wind around the neck of the fetus causing hypoxia and may
cause true knots.
2) Very short cord: may cause early separation of the placenta.
3) Knots of the cord:
a) True knots: usually accompanied by long cord and excessive movement of the
fetus. It is a fatal condition.
b) False knots: localized collections of Wharton’s jelly.
4) Abnormal attachment of the cord to the placenta (battledore placenta and velamentous
attachment of umbilical cord).
INTRODUCTION TO BODY STRUCTURE 116

Amniotic cavity
Science direct
INTRODUCTION TO BODY STRUCTURE 117
AMNIOTIC CAVITY, AMNION AND AMNIOTIC FLUID
Formation and progress:
At the stage of blastocyst, the amniotic cavity is dorsal to embryonic disc. Its roof is
formed of amnioblasts (cells derived from cytotrophoblasts) and the floor is formed
by ectoderm.
At the stage of chorionic vesicle, the EEM separates the amniotic cavity from the
cytotrophoblasts.
After folding, the amniotic cavity surrounds the whole embryo. And reflects at the
umbilical ring to cover the umbilical cord.
The amnion is the membrane enclosing the amniotic cavity.
Sources of amniotic fluid:
Maternal: diffusion through the chorion.
Fetal: amniotic cells and fetal urine.
Circulation of the amniotic fluid: the fetus swallow the amniotic fluid → the fluid is
absorbed through fetal GIT → circulating in fetal circulation → secreted through fetal
kidney as urine to the amniotic fluid → swallowed again.
Functions of the amniotic fluid :
1) Protection against external trauma (water cushion).
2) Symmetrically distributes the pressure on the embryo preventing asymmetrical
growth.
3) Prevents adherence between embryoblasts and its derivatives and trophoblasts and its
derivatives.
4) Keeps aseptic environment around the embryo.
5) Keeps constant temperature of the embryo.
6) Allows free movement of the fetus encouraging muscular development.
7) Development of vital mechanisms before birth:
a) Swallowing.
b) GIT absorption.
c) Circulation.
d) Kidney functions and urine formation.
e) Urination.
8) During labor, the amniotic sac enters the cervix of the uterus helping its dilatation.
9) Before birth, the amniotic cavity ruptures and its sterile fluid cleans the birth canal.
Anomalies of amniotic fluid:
The normal amount of amniotic fluid is 750-1500 ml (at full term).
Oligohydramnios: it is less than 400 ml amniotic fluid.
Causes:
⎯ Renal agenesis.
⎯ Urinary tract obstruction.
Risk: adhesions
Polyhydramnios: it is more than 2000 ml amniotic fluid.
Causes:
⎯ Idiopathic.
⎯ Maternal diabetes.
⎯ Neural tube defect (e.g., anencephaly): defective development of the brain
with defective swallowing.
⎯ GIT obstruction.
Risk: premature rupture of amniotic membrane and premature labor.
INTRODUCTION TO BODY STRUCTURE 118

Yolk sac

Anomalies of vitelline canal

Anomalies of urachus
Quizlet / Stuartsumida / Research gate / Slide share
INTRODUCTION TO BODY STRUCTURE 119

Yolk sac
Formation and progress:
Primary Yolk sac: at the stage of blastocyst, the yolk sac is ventral to embryonic disc. Its
roof is formed by endoderm and the rest of the wall is formed of Heuser's membrane
(cells derived from endoderm).
Secondary yolk sac: at the stage of chorionic vesicle, the EEM surrounds the yolk sac. In
this stage, a small pouch (called the allantois) projects from the yolk sac inside the
connecting stalk.
Tertiary (definitive) yolk sac: after folding, the yolk sac divides into
The gut (sucked inside the embryo).
Definitive yolk sac: pushed to the connecting stalk.
Vitelline duct: connecting both, it disappears separating the gut from the yolk sac.
Functions of the yolk sac:
1) Nutritive function: of minimal importance in humans.
2) The endoderm of its roof forms the epithelial lining of the gut and respiratory system.
3) The allantois forms part of the urinary bladder.
4) Primary germ cells (spermatogonia and oogonia) develop from yolk sac and migrate
to gonads.
Anomalies of vitelline duct:
1) Vitelline ligament: the duct is fibrosed but does not disappear.
2) Vitelline cyst: the duct is fibrosed but a middle part of it is patent.
3) Meckel’s diverticulum: the part of the duct attached to the gut is patent, the rest
disappears.
4) Vitelline sinus: the part of the duct attached to the umbilicus is patent, the rest
disappears.
5) Vitelline fistula: the whole duct is patent.
ALLANTOIS
Formation and progress:
It is a diverticulum from the secondary yolk sac inside the connecting stalk. It is lined
with endoderm.
After folding it connects the hind gut (derived from endoderm) to the umbilical cord
(derived from connecting stalk).
The part connected to the hind gut will form part of the urinary bladder.
The part extending to the umbilical cord is called the urachus which will obliterate
forming median umbilical ligament connecting the urinary bladder to the umbilicus.
It is surrounded by allantoic vessels.
Anomalies of allantois:
1) Urachal cyst: the urachus is fibrosed but a middle part of it is patent.
2) Urachal diverticulum: the part of the urachus attached to the urinary bladder is
patent, the rest is fibrosed.
3) Urachal sinus: the part of the urachus attached to the umbilicus is patent, the rest is
fibrosed.
4) Urachal fistula: the whole urachus is patent.