Y1S1 MHSBLEC Gametogenesis PDF

Summary

These lecture notes cover gametogenesis, focusing on spermatogenesis and oogenesis. The material includes discussion of chromosomes, mitosis, meiosis, and clinical correlations of chromosomal abnormalities. The notes are for a first-year, first-semester course on microscopic human structural biology.

Full Transcript

(MICRO LEC) – (MICROSCOPIC HUMAN STRUCTURAL BIOLOGY 1A)
(GAMETOGENESIS & Dr. Mariemids I. Borlaza)
(Y1S1_Week 3_August/2024) DIMAYACYAC - SALAMANCA - SALAS - SAMSON - SANCHEZ - SANTIAGO - SAROCA - SICAT - TABBILOS - TALOSIG
- TAWASIL - TEOPENGCO - ULANG - UMALI - VENDIVIL

Conceptus
OUTLINE
Embryology ○ includes all structures that develop from the zygote, both
Terminologies embryonic and extraembryonic
Stages of Human Development Embryo
○ Prefertilization
Primordial Germ Cells
○ end of 8th week
Chromosomes Fetus
Mitosis ○ 9th week to birth
Meiosis
Clinical Correlation
○ Chromosomal Abnormalities STAGES OF HUMAN DEVELOPMENT
Trisomy 21
Trisomy 18
Klinefelter’s Syndrome
Turner’s Syndrome
○ Structural Abnormalities
Cri-du-chat Syndrome
Spermatogenesis
Spermatogenic Cells
Spermiogenesis
Clinical Correlation
○ Male Factor Infertility
Oogenesis
In Utero
Before Puberty
At Puberty
During Ovulation
Under the Microscope
Week 1 of Human Development
○ Fertilization
Phases of Fertilization
Results of Fertilization
Cleavage Prefertilization Events
Morula
Inside the Uterus ○ Spermatogenesis
Ovulation ○ Oogenesis
Implantation Fertilization
Week 2 of Human Development
Embryonic
○ Week 1 of human development
Fetal Period ○ Week 2 of human development
REFERENCES Embryonic Period
Gametogenesis PPT Fetal Period
Langman's Medical Embryology 14th ed
Prefertilization
EMBRYOLOGY

Why Study Embryology?

Provide knowledge essential for creating health care
strategies for better reproductive outcomes
Improvements in prenatal diagnoses and treatments,
therapeutic procedures and mechanisms to prevent birth
defects

TERMINOLOGIES

Embryology
○ Study of the DEVELOPMENTAL changes from
fertilization up to birth (single cell - ZYGOTE to a baby in
9 months)
Fertilization
○ union of sperm and egg cells to form zygote

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DEVELOPMENT BEGINS WITH FERTILIZATION: CHROMOSOMES
○ Male gamete (sperm) + female gamete (oocyte) = Humans have approximately 23,000 genes on 46
zygote chromosomes
○ Gametes derived from PRIMORDIAL GERM CELLS 23 homologous pairs to form diploid number of 46
Autosomes: 22 pairs of matching chromosomes
(PGC)
Sex chromosomes: 1 pair
○ XX - genetically female
PRIMORDIAL GERM CELLS (PGC) ○ XY - genetically male
○ One chromosome derived from oocyte and
Formed in the epiblast during the second week sperm each containing haploid of 23
Eventually it will move to the primitive streak during gastrulation chromosomes
and migrate to the wall of the yolk sac. Union of the gametes will restore the
46 chromosomes
Fourth week, these cells begin to migrate from the yolk sac
toward the developing gonads, where they arrive by the end
MITOSIS
of the fifth week.
Process whereby one cell divides giving rise to 2
Mitosis to increase the number of cells
daughter cells that are genetically identical to the parent
In the gonad, these germ cells will undergo gametogenesis cell.
○ Meiosis - reduce the number of chromosomes For cell repair and regeneration
Phases: Prophase, Metaphase, Anaphase, and
Primordial germ cells (PGCs) give rise to spermatogonial stem Telophase (PMAT)
cells. At regular intervals, cells emerge from this stem cell
population to form type A spermatogonia, and their production
marks the initiation of spermatogenesis. Type A cells undergo a MITOSIS
limited number of mitotic divisions to form clones of cells. The last
cell division produces type B spermatogonia, which then divides
to form four primary spermatocytes.

From the multiplication of Mitosis to eventually Meiosis in the
gonads which will cause reduction on the number of
chromosomes and cytodifferentiation to be able to complete their
maturation.

PRIMORDIAL GERM CELLS (PGC)

Various stages of mitosis. In Prophase, chromosomes are
visible as slender threads. Doubled chromatids become
clearly visible as individual units during Metaphase. At no
time during do members of a chromosome pair unite.
Blue, paternal chromosomes; Red, maternal
chromosomes

An embryo at the end of the third week, showing the
position of primordial germ cells (PGCs) in the wall of the
yolk sac, close to the attachment of the future umbilical
cord. From this location, these cells migrate to the
developing gonad.

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MITOSIS of two chromatids. C. Intimately paired homologous
chromosomes interchange fragments [crossover]. Note
the chiasma. D. Double-structure chromosomes pull apart.
E. Anaphase of the first meiotic division. F, G. During the
second meiotic division, the double-structured
chromosomes split at the centromere. At completion of
division, chromosomes in each of the four daughter cells
are different from each other.
Cross overs:
○ Critical event in Meiosis I
○ Interchange of chromatid segments between paired
homologous chromosomes
○ Genetic variability is enhanced because there is
redistribution of genetic material.

MEIOSIS
MEIOSIS

Phases: Prophase, Metaphase, Anaphase, and
Telophase
Cell division that takes place in the germ cells to
generate male and female gametes (sperm and egg
respectively)
○ Spermatogenesis - Male
○ Oogenesis - Females
Requires 2 cell divisions, to reduce number of
chromosomes to haploid number 23
○ Meiosis I - results to formation of 2 secondary
gametocytes (23 pairs chromosomes, 2N)
○ Meiosis II - results to formation of 4 gametes
(23 chromosomes, 1N)

The main purpose of the meiosis is to eventually form the
gametes.
Clinical Correlation

MEIOSIS CHROMOSOMAL ABNORMALITIES
Numerical or structural
Important cause of birth defects and spontaneous
abortions
Most common chromosomal abnormalities in abortuses:
○ 45, X (Turner’s Syndrome)
○ Triploidy
○ Trisomy 16

First and second meiotic divisions. A. Homologous
chromosomes approach each other. B. Homologous
chromosomes pair, and each member of the pair consists

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Trisomy 18 (Edward Syndrome)
MECHANISM BEHIND CHROMOSOMAL ANOMALIES

Common cause of early pregnancy loss (10 weeks
AOG)
Those born alive usually die in 2 months and only 5%
live beyond 1-year-old
Clinical features:
○ Intellectual disability
○ Congenital heart defects
○ Low set of ears, flexion of fingers and hands,
syndactyly
○ Micrognathia
○ Renal abnormalities

TRISOMY 21 VS TRISOMY 18

In normal meiosis, disjunction occurs - as a result,
gametes with 23 single chromosomes are produced.
In nondisjunction - abnormal gametes are produced; either
24 or 22 single chromosomes are produced
Fertilization between normal gamete and abnormal
gamete
○ Example:
23 + 24 = 47 (Trisomy)
23 + 22 = 45 (Monosomy)
Klinefelter’s Syndrome

NUMERICAL ABNORMALITIES ONLY in MALES
Detected by amniocentesis
Trisomy 21 (Down Syndrome)
We get samples transabdominal ultrasound guided aspiration of
Extra copy of chromosome 21 amniotic fluid
Results from meiotic nondisjunction (95%),
nondisjunction occurs in oocyte formation 47, XXY
Increase risk with increasing maternal age, >/40yo (1 in Nondisjunction of XX homologue
100) Pathognomonic: presence of Barr bodies (condensation
Clinical features: of inactivated X chromosome)
○ Growth retardation Clinical features:
○ Intellectual disability ○ Sterility
○ Craniofacial abnormalities (upward slanting ○ Testicular atrophy
eyes, epicanthal, ○ gynecomastia
○ flat facies and small ears 1 in 500 males
○ Cardiac defects
○ Hypotonia
○ increased risk: leukemia, infections, thyroid
dysfunctions and premature aging

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KLINEFELTER’S SYNDROME TURNER’S SYNDROME

KLINEFELTER’S SYNDROME VS. TURNER’S SYNDROME

STRUCTURAL ABNORMALITIES

Involve one or more chromosomes
Turner’s Syndrome Results from breakage of chromosome
secondary to environmental factors and drugs
45, X Deletions of chromosomes
ONLY in FEMALES
Most common cause: nondisjunction in male gamete Cri-du-chat Syndrome
Paternal naman siya. Kapag sobrang tanda nung father yun yung
nagiging problema. Partial deletion of the short arm of chromosome 5
Absence of ovaries, short stature, webbed neck, skeletal Cat-like cry, microcephaly, intellectual disability and
congenital heart disease.
deformities, broad chest with widely spaced nipples
The only monosomy compatible with life

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CRI-DU-CHAT SYNDROME

SPERMATOGENESIS
Once a male begins developing secondary sex characteristics,
Begins at puberty
his brain starts to develop further. The hypothalamus produces
Transformation of spermatogonia to spermatozoa
gonadotropin-releasing hormone (GnRH), which influences the
anterior pituitary gland to produce luteinizing hormone (LH) and
follicle-stimulating hormone (FSH).

Spermatogenesis is regulated by LH production by the pituitary
gland. LH binds to receptors on Leydig cells and stimulates
testosterone production, which in turn binds to Sertoli cells to
promote spermatogenesis. Follicle-stimulating hormone is also
Spermatogenesis, which begins at puberty, includes all of the
essential because its binding to Sertoli cells stimulates testicular
events by which spermatogonia are transformed into
fluid production and synthesis of intracellular androgen receptor
spermatozoa. At birth, germ cells in the male infant can be
proteins, all of which will help in development of
recognized in the sex cords of the testis as large, pale cells.
spermatogenesis.

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Two secondary spermatocytes (meiosis II) –
four spermatids

Take Note:
Primordial cells remain dormant until puberty
Maturation of sperm begins at puberty
One primary spermatocyte gives rise to four (4) daughter
cells = all four (4) develop into mature gametes

Testosterone, along with follicle-stimulating hormone, stimulates
the Sertoli cells of the testes, leading to the production of inhibin
and the upregulation of testosterone-binding globulin (TBG)
receptors. This upregulation of the receptors allows further
stimulation of these cells by testosterone, resulting in the
activation of spermatogenesis.

The PGCs or Primordial germ cells give rise to spermatogonial
stem cells and then at regular intervals, these cells will emerge
from these stem cell populations to eventually form your type A
spermatogonia. Their production will mark the initiation of
spermatogenesis. These type A cells will undergo a limited
number of mitotic divisions to form clones of cells. The last cell
division will produce this type B spermatogonia which will, then,
divide to form 4 primary spermatocytes. These primary
spermatocytes will undergo prolonged prophase - 22 days
followed by meiosis I and formation of secondary spermatocytes.

SPERMATOGENESIS

Process by which spermatogonia develop into sperm
(approximately 64-72 days)
Primordial germ cells-gonad (week 4): remain dormant Contains 3 phases:
until puberty ○ Spermatogonial Phase
At puberty, differentiate into spermatogonia:
Primary spermatocytes (meiosis I)
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stem cells divide to replace In the Epididymis
themselves and provide a population
of committed spermatogonia When fully formed, Spermatozoa enters the
○ Spermatocyte Phase seminiferous tubules and pushed toward the epididymis
Primary spermatocytes undergo to obtain full motility
meiosis to reduce both the ○ Although initially only slightly motile,
chromosome and amount of DNA spermatozoa obtain full motility in the
○ Spermatid Phase (spermiogenesis) epididymis
Final stage of maturation of spermatocytes occurs
Spermatogenic Cells post-ejaculation
Post capacitation, spermatocytes are not able to
SPERMATOGONIA fertilize a secondary oocyte

Stem cell, diploid chromosomes (46 chromosomes or 44
xy)
Primary spermatocyte
○ 44 xy
Secondary spermatocyte
○ 22 x / 22 y or haploid
Spermatid (22 x / 22 y)
Sperm Cell (22 x / 22 y)

Spermiogenesis

Series of changes resulting in the transformation of
spermatids into spermatozoa
Changes includes:
○ Formation of acrosome (very important
during fertilization; covers half of the nucleus
surface): contains enzymes to assist in
penetration of egg during fertilization
○ Condensation of nucleus
○ Formation of neck, middle piece, and tail
○ Shedding of most of the cytoplasm as residual
bodies that are phagocytized by Sertoli cells
The time required for a spermatogonium to develop into
a mature spermatozoon is approximately 74 days The testes are responsible for making the testosterone (primary
male sex hormone and necessary for the production of sperm).
Note: 300 million sperm cells are produced daily after the 74 days Within the testes are coiled masses of tubes called the
seminiferous tubules. These tubules are responsible
for producing the sperm cells through a process
called spermatogenesis.

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LPO view of the Seminiferous tubules. Inside these
tubules are different stages of spermatogenic cells.

At birth, the germ cells in the male infant can be recognized in the
sex cord of the testis which you can see in figure A, as large pale
cells surrounded by supporting cells. These supporting cells
which are derived from the surface epithelium of the testis, are
actually in the same manner as the follicular cells. They become
sustentacular cells or what we call the sertoli cells. As you can
see here this is a cross section of the seminiferous tubules at
puberty. You have to take note of the different stages of
spermatogenesis and the developing cells embedded in the
cytoplasmic processes supporting sertoli cells which you can see
here.

Testis

Each lobule of testis consists of 1 to 4 seminiferous
tubules
Connective tissue stroma – Interstitial tissue containing
Leydig cells

TESTIS SPERMATOGENIC CELLS
Spermatogonia
Primary spermatocyte
Secondary spermatocyte
Spermatid
Sperm cell

The sertoli cells are actually the blood barrier, these are the
different spermatogenic cells

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Infertile as long as they do not use any form or method of
protection. Mostly female factors ang cause ng infertility. 10-15%
are male factors.

Infertility Problems in the Philippines
○ Common causes:
Male factor (25%)
Ovulatory dysfunction
Tubal factor
○ Peritoneal factor
Pelvic endometriosis
Pelvic adhesive diseases
○ Uncommon causes:
Cervical or interactive factor
Endometrial or uterine factor
○ Male causes:
Genetic abnormalities:
Varicocele
SERTOLI CELLS Cigarette smoking
Oxidative stress
Columnar cells; supporting cell
Note: If the patient comes into the clinic, we also work up the
male.
Important in the formation or in collecting substances to affect the
developing sperm. These products may include hormones which
are toxic to your developing sperms. Physical Examination and Work Up: MALE

SEMEN ANALYSIS
SEMINIFEROUS TUBULE
You have to have at least 300 million produced sperm daily.
Abnormalities in semen analysis: 20% of infertile
couples
2-3 days of abstinence before semen collection

In order to have proper or appropriate number/sample of semen

WHO REFERENCE VALUES FOR HUMAN SEMEN
CHARACTERISTICS (2010)

Semen volume (mL) 1.5

Sperm concentration 15
(million/mL)

Total number 39
(million/ejaculate)

Total motility (%) 40
HPO view of the Seminiferous tubules. Normal forms (%) 4
A. Spermatogonium occupying the base of the tubules
B. Primary spermatocytes are marked by the presence
of mitotic figures What we look into semen analysis is the morphology which is an
C. Spermatids near the lumen important parameter which is correlated to fertilized capability.
D. Leydig cells or supporting cells Morphology would include the tail and head. The degree of sperm
motility should be determined which usually occurs 15-20 minutes
after ejaculation. All of the listed items above are important to be
Clinical Correlation able to fertilize an egg.

MALE FACTOR - INFERTILITY

Infertility is a disease of the reproductive system defined
as failure to achieve a clinical pregnancy after 12
months or more of unprotected intercourse
Affects 10-15 % of reproductive - aged couples

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Oogenesis IN UTERO

Once PGCs have arrived in the gonad of a genetic
female, they differentiate into oogonia
Mitotic divisions, and by the end of the third month, they
are arranged in clusters surrounded by a layer of flat
epithelial cells
Majority of oogonia continue to divide by mitosis, but
some of them arrest their cell division in prophase of
meiosis I and form primary oocytes

5th month AOG: total number of germ cells in the ovary
reaches its maximum, estimated at 7 million. At this
time, cell death begins, and many oogonia as well as
primary oocytes degenerate and become atretic.
7th month: majority of oogonia have degenerated except
for a few near the surface.
All surviving primary oocytes have entered prophase of
meiosis I, and most of them are individually surrounded
by a layer of flat follicular epithelial cells

MUST KNOW!!
Maturation of Oocytes begins before birth
Process of oogonia differentiating into mature oocytes. Maturation of Oocytes at puberty
One primary oocyte gives rise to four (4) daughter cells
Maturation happens in
but only one will develop into a mature gamete
- Males = During puberty
- Females = Usually starts in the utero

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BEFORE PUBERTY In male, the involvement of hypothalamus, pituitary gland, are
important anatomical landmarks to be able to fully understand
Primary oocytes remain arrested in prophase and do not these.
finish their first meiotic division before puberty is reached
Total number of primary oocytes at birth is estimated to
vary from 600,000 to 800,000.
During childhood, most oocytes become atretic; only
approximately 40,000 are present by the beginning of
puberty, and fewer than 500 will be ovulated.

This is why we sometimes associate that a female has body
clock, because to uterus from utero to menopause, nagbabawas
ng nagbabawas ang ovarian follicles

Primary oocytes
○ 7 millions at 5 months of fetal life
○ 2 millions at birth
○ 40,000 at puberty
Secondary oocytes – 12 are ovulated /year; 480 over the
entire reproductive life ( 40 yrs x 12 )
○ number of time that a female can possibly get
pregnant
Again, the hypothalamus will produce the gonadotropin hormone.
Th gonadotropin hormone will stimulate the pituitary gland to
produce luteinizing hormone and follicle stimulating hormone.

This luteinizing hormone will cause production of theca cells,
production of androgens and testosterones (influences the
granulosa cells).

Follicle stimulating hormone will influence the granulosa cells to
convert androstenedione to estrogen. Luteinizing hormone and
the production of estrogen will cause ovulation. Ovulation is
important to be able to release an egg that will eventually be
fertilized by a sperm.

Ovarian Endometrial Cycle and Follicular development

Ovarian - Menstrual Cycle

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As follicles continue to grow, secondary to the
These are the days/cycle of a woman (1st pic)
continuous production of LSH and FSH, the cells of the
These are the different hormones produced (2nd and 3rd
theca folliculi will organize into:
pic)
○ Theca interna- an inner layer of secretory cells
As well as what is happening in the endometrial lining
○ Theca externa - outer fibrous capsule
(4th pic)
this stratification is very important in converting
Follicular development and endometrial thickening are
your androstenedione into estrogen
both important in pregnancy/fertilization in order to have
a good egg and a good bed for the zygote/blastocyst to
implant in.
Any problem that concerns your hypothalamus, acranial
mass or pituitary gland, thyroid has similar molecular
sub-unit to FSH and LSH that can affect your normal
menstrual cycle, production of hormones, affect the
follicular development and endometrium which will affect
the possibility of pregnancy.

AT PUBERTY

AT PUBERTY: PRIMORDIAL FOLLICLES

ANATOMY OF GRAAFIAN CELL

Granulosa Cells surrounding the oocyte remain intact and
form the cumulus oophorus.
At maturity, the mature vesicular (graafian) follicle may
be 25 mm or more in diameter.
○ pinakamagandang egg to look into via ultrasound to
see if responsive sa ovulating agents yung mga
patients for infertility, tinitignan yung egg via
ultrasound if they have formed the Graafian follicle

pool of growing follicles is established and continuously
maintained from the supply of primordial follicles.
DURING OVULATION
Primordial follicles begin to grow, surrounding follicular
cells change from flat to cuboidal and proliferate to
produce a stratified epithelium of granulosa cells
○ Primary follicle - unit for stratified epithelium of
granulosa cells.

With each ovarian cycle, a number of follicles begin to
develop, but usually, only one reaches full maturity.
Surge in LH induces the preovulatory growth phase.
Meiosis I is completed, resulting in formation of two
daughter cells of unequal size, each with 23 double
structured chromosomes
The cell then enters meiosis II but arrests in metaphase
approximately 3 hours before ovulation.

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Meiosis II is completed, only if the oocyte is fertilized; UNDER THE MICROSCOPE:
Otherwise, the cell degenerates approximately 24 hrs
after ovulation.
Binabantayan namin is the mature Graafian follicle
because of the LH surge there will be ruptured and will
release isang magandang matured egg. The mature egg
will go to the fallopian tube and will be fertilized by the
sperm cell.

DIFFERENT STAGES OF FOLLICULAR DEVELOPMENT

cross section of the ovary

Shown here is the different phases of follicular
development
From primary follicle to flatten cells of primordial follicles to
the growing follicles to the mature Graafian follicles to be
influenced already by the luteinizing hormone to be able to
release the egg with secondary oocyte because of
ovulation. If there is no pregnancy, it will become corpus
albicans and then the cycle again.
The different stages of follicular development,
different hormones, as well as the primary and
secondary oocyte. Iba yung nasa loob ng follicular
development ( what will call the oocyte; its either the
primary or secondary oocyte)

Under the microscope: On the developing follicles, you
must observe the cortex area. Here you would be able to
appreciate the different developing follicles.
medulla- containing only connective tissues and blood
vessels

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Eventually, it will form zona pellucida. Then there will be
already a stratification to become the antral follicle. This antral
follicle will further cause a maturation of cells to be able to be
stratified into your theca externa and theca interna to
eventually produce mature Graafian follicle.

Now with continuous development and secretion of
different hormones, it will now become Primary
Unilaminar follicle.

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SPERMATOGENESIS VS OOGENESIS

FERTILIZATION
Mature Graafian Follicle

Fusion of male and female gametes
Most commonly occurring in the ampullary part of the
fallopian tube
○ The Ampullary part is the widest area of the
fallopian tube hence it is the most common site
of fertilization.

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WHAT HAPPENS TO THE SPERM?
MALE AND FEMALE PRONUCLEI FUSE FORMING A
ZYGOTE
The sperm is made up of the head and the tail. In the head,
theres a Capacitation.

Capacitation
Period of conditioning in the female reproductive tract
Lasts approximately 7 hours
Involves epithelial interaction between the sperm and
mucosal surface of the tube
Glycoprotein coat and plasma membrane at the
acrosomal region (of the sperm) is removed

Acrosome reaction

Binding to the zona pellucida
The head will try to penetrate the mature egg and it will first come
into contact with the zona pellucida
ZP3 and ZP4 enzymes produced by the zona pellucida
○ They are the ones necessary for the head of RESULTS OF FERTILIZATION
the sperm to penetrate into the zona pellucida Restoration of the diploid number of chromosomes
○ Half from the father and half from the mother
Determination of the sex of the new individual
PHASES OF FERTILIZATION
○ X-carrying sperm produces female embryo
(XX)
○ Y-carrying sperm produces male embryo (XY)
Initiation of cleavage

Remember…
Chromosomal and Genetic sex of an embryo is
determined at fertilization by the kind of sperm that
fertilizes the ovum but the male and female
morphological characteristics do not begin to develop
until the 7th week
Early genital systems in the two sexes are similar =
indifferent stage of sexual development

CLEAVAGE

Penetration of the corona radiata
Penetration of the zona pellucida
○ Only one sperm can penetrate and eventually
the membrane will close off so that other sperm
cells will not be able to penetrate the zone
pellucida
Fusion of the oocyte and sperm cell membranes
○ Cortical and zona reactions to prevent
polyspermy (the closure so that other sperms
will not penetrate)
There will be fusion of the oocyte and the sperm cell membranes.
○ Resumption of the 2nd meiotic division forming
the female pronucleus Form a 2-cell stage, undergoes series of mitotic division
○ Metabolic activation of the egg to increase the number of cells.
Blastomeres: product of each cleavage division

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MORULA OVULATION TO IMPLANTATION

Blastomeres form a MORULA (16 cell) by undergoing
compaction
Morula enters the uterine cavity

Once it implants in the uterine cavity, it is already called morula.

INSIDE THE UTERUS After ovulation..
○ Fertilization – 12 – 24 hrs after ovulation
BLASTOCYST FORMATION WITH THE FOLLOWING ○ 2 cell stage – 30 hrs after fertilization
PARTS ○ Morula – 3 days of age
○ Blastocyst – 5 days of age

IMPLANTATION

Inner cell mass
positioned at one end of pole called as embryonic pole
also called as Embryoblast = Embryo

Outer cell mass
is called as Trophoblast = Placenta

Blastocyst cavity
Penetration of embryoblast pole in the uterine mucosa Day 7 after fertilization
on about the 6th day Within the posterior superior wall of the uterus
Functional layer of endometrium during the secretory
phase of the menstrual cycle
Zona pellucida must degenerate for implantation to
occur
There would be follicular rupture causing ovulation, it will release
the mature egg. What goes out from the mature graafian follicle is
actually the cumulus oophorus together with the zona pellucida

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together with the primary oocyte. Once it ruptures, it becomes be two-celled, four-cells, eight-celled, and then becoming a
your secondary oocyte already. morula, to blastocyst and implanted blastocyst, 6 days after
fertilization.
STAGES OF HUMAN DEVELOPMENT
What would be the most common clinical correlation that you can
account for when we talked about fertilization? One would be the
ectopic pregnancy. Triad symptoms of ectopic pregnancy would
include severe hypogastric pain, amenorrhea, spotting, and a
positive pregnancy test.

CASE: ECTOPIC PREGNANCY

Now after that of course, there would already be formation of
embryonic period and fetal period. Like what we have defined a
while ago, the embryonic period is until the 8th week age of
gestation. Fetal period will be until the 9th week and until the term
or what we called 37 weeks and above until the 42nd week of
gestation.

OVULATION TO IMPLANTATION When we say ectopic pregnancy, it is a pregnancy outside of the
uterus. Most commonly in the fallopian tube, specifically at the
ampullary part because it is the most common site of fertilization.
Ectopic pregnancy can also happen in other areas, like the
ovaries, cervix, previous cesarean scar, even in the abdominal
area, anywhere within the pelvic cavity. But the most common is
in the ampullary part of the fallopian tube.

What happens in ectopic pregnancy? – There is a failure of the
morula to go into the uterine cavity to be implanted. Doon lang
siya naka-implant sa area ng fallopian tube. That’s why it will not
grow there. Eventually because of the diameter of the fallopian
tube and the growing zygote, it will not be able to accommodate.
Eventually it will rupture. Sometimes, patient comes in in severe
pain, hypotensive, anemic because of hemoperitoneum already.

The most common thing that we do especially in ruptured ectopic
pregnancy is to do exploration, open up the abdomen, do
laparotomy and remove the fallopian tube. If the fallopian tube is
So this one is just an illustration, telling you the ovulation to removed, there is still a chance for the patient to be pregnant
implantation. As you can see here, we have the ovary, we have because she has another fallopian tube. Unfortunately, for this
the maturing follicle, you have your corpus luteum and then this patient, the risk of another ectopic pregnancy is higher already,
one the maturing follicle, it will eventually replace a mature egg because she has a previous history of ectopic pregnancy already.
and then, carrying the secondary oocyte, it will go into the widest
area of the fallopian tube. The sperm will come from here of
course with sexual contact, and then it will go up to meet in the
fallopian tube the mature egg. And then once they combine,
meaning there is already fertilization, to form the zygote. here will
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 MICRO LEC – GAMETOGENESIS

EMBRYONIC TO FETAL PERIOD Ovarian - Menstrual Cycle

EMBRYONIC PHASE YOUTUBE VIDEOS
Continues growth of the embryo
Formation of bilaminar germ disc
Differentiation to:
○ Cytotrophoblast
○ Syncitiotrophoblast
Implantation and formation of placenta
Establishment of uteroplacental blood flow

For the embryonic phase, it’s just actually the stage for
embryogenesis.

FETAL PERIOD

For the fetal period, I will not expound so much on the
development or embryogenesis or fetal development mismo
because it is not part of the learning outcome.

But just an overview, this is the stages from implantation, to
organogenesis to the fetal period. So those are the structures that
will be formed depending on the age of gestation. So in this line
you will see the different age of gestation (pointed at horizontal
line above yung may 1,2,3,4)

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