Reproductive development_9cc0547843a43eca7736469597daccc1.pdf

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oligospermia-lack/absence of sperm

REPRODUCTIVE DEVELOPMENT
Maria Leonora D. De Leon, RN MAN
 * now an individual was formed

INTRAUTERINE DEVELOPMENT
inside XX-female
xy- male
z Chromosomes

The sex of an individual is determined at the moment
of conception by the chromosome information supplied
by the particular ovum and sperm that joined to create
the new life.
cortex
- controls reproduction
advenal
thatprodee ovary
organ
A GONAD is a body organ that produces the cells
necessary-for reproduction (the ovary for the females
and the testis in males).
 INTRAUTERINE DEVELOPMENT

At week 5 of intrauterine life, gonadal tissue is
already formed. In both sexes, two undifferentiated
ducts (1) the mesonephric (wolffian), and (2) gives rise to male

paramenosephric (mullerian) ducts. sender reveals
internal genitall :
usually 6 mos.
Of
pregnancy

gives rise to female * at first
, these 2 ducts look
2 mos. Of internal genitalia
pregnancy similar

-
At week 7 or 8, in chromosomal males this early
gonadal differentiates into primitive testes and begins
formation of testosterone.
responsible for the secondary sex

characteristics of a male
 INTRAUTERINE DEVELOPMENT
hormone
male
Presence of Testosterone influences the mesonephric
duct to develop into male reproductive organs, and
the paramesonephric duct regresses.
3 mos.

female hormone
~
-
Absence of Testosterone at week 10, the gonadal
tissue differentiates into ovaries and the
paramesonephric duct develops into② female
reproductive organs.
 INTRAUTERINE DEVELOPMENT
immature eggs
2-3 million decreases to 200
-

500K(puberty) -

lat birth

ALL of the OOCYTES (cells that will develop into eggs
throughout the woman’s mature years) are already
formed in ovaries at week 10 of intrauterine
development. 3 mos does the sperm and urine

of the tube
come out

same ?
5 -
6 months best for ultrasound isn't urine acidic
4 mos.

- sperm = alkaline environment

At week 12, the external genitals develop. In males,
under the influence of testosterone, penile tissue
elongates and the urogenital fold on the ventral
surface of the penis closes to form the urethra.
 INTRAUTERINE DEVELOPMENT

In females, with the absence of Testosterone, the
urogenital fold remains open to form the labia
minora.

What would be formed as scrotal tissue in the male
becomes the labia majora in the female.
 INTRAUTERINE DEVELOPMENT
biglang meron and

biglang wald

When testosterone is*
halted it results to a
chromosomal male with female-appearing genitalia.

If a woman is prescribed with testosterone during
pregnancy or due metabolic abnormality, produces a
- high testosterone it results to a chromosomal female
with male-appearing genitalia. buntis + pills (increases testosterone)

which in result to a female with male appearing
genitalia
* navuna mag develop

males
 PUBERTAL
DEVELOPMENT

Puberty is the
anterior
gland
pituitary
secretes
stage of life at
which secondary
sex changes
when
begin.
happens only
oocytes exist even at
reproductive organs
birth
matured (puberty

don't stop unlike
sebaceous glands = body odor
in females
(menopause(
PUBERTAL DEVELOPMENT
What hormone is
responsible in the

secondary sex characteristics
of
females ?
 PUBERTAL DEVELOPMENT
ROLE OF ANDROGEN
Androgenic hormones are responsible for muscular
development, physical growth, and the increase in
sebaceous gland secretions that causes acne in both
boys and girls.

In males, androgenic hormones are produced by the
adrenal cortex and the testes. In females, by the
E adrenal cortex and the ovaries.
it is a GONAD
 Females are the first to
PUBERTAL DEVELOPMENT
ROLE OF ANDROGEN
mature than males.

* mas namuna tumangkad ang

girls

Testosterone – the primary androgenic hormone.
Testosterone is low in males until pubertyO
(12-14
years).
Testosterone levels rise to influence the development
of the testes, scrotum, penis, prostate, seminal
vesicles, pubic hair, axillary and facial hair, laryngeal
enlargement, voice change, maturation of
spermatozoa, and closure of growth in long bones.
 PUBERTAL DEVELOPMENT
responsible fora
both
male secondary
fies ROLE OF ANDROGEN
femalecharacteris
sex

In girls, testosterone influences the enlargement of
the labia majora and clitoris and formation of axillary
and pubic hair.

Adrenarche – term used to describe the development
of pubic and axillary hair.
 PUBERTAL DEVELOPMENT
ROLE OF ESTROGEN
follicle stimulating
found in 0 varies ; unmatured eggs
hormone

At puberty, ovarian follicles are triggered by FSH and
begins to excrete a high level of the hormone
I
from APG

estrogen.
in ovulation
,

vital tion
menstrua
↑

Estrogen is consists of three compounds: (estrone
[E1], estradiol [E2], and estriol [E3]), but a single
substance in terms of action. chine check for invitro
 PUBERTAL DEVELOPMENT
ROLE OF ESTROGEN
hormones are in complete harmony

High levels of estrogen in girls at puberty influences
the development of the uterus, fallopian tubes, and
vagina, fat distribution, hair patterns, breast
development, and closes the epiphyses of long bones.
that is why girls
are earlier to stop
growing than boys

Thelarche is the term used to describe breast
development. * also manifests in males
 PUBERTAL DEVELOPMENT
SECONDARY CHARACTERISTICS
GIRLS BOYS
Growth spurt Increase in weight
Increase in the transverse Growth of testes
diameter of the pelvis Growth of face, axillary and
Breast development pubic hair
Growth of pubic hair Voice changes
Onset of menstruation Penile growth
Growth of axillary hair Increase in height
Vaginal secretions Spermatogenesis (Production
of sperm)
 PUBERTAL DEVELOPMENT
SECONDARY CHARACTERISTICS
usually irregular at first.

GIRLS regravity comes 2
years after
BOYS
Menarche (1st menstrual Spermatozoa are produce in
period) occurs at average age a continuous process.
of 12.4 years. Or it may Sperm production continuous
occur as early as age 9 or as from puberty throughout the
late as age 17.grade
male’s life.
3/4

Menstruation is not
dependent on ovulation.
 PUBERTAL DEVELOPMENT
SECONDARY CHARACTERISTICS
GIRLS
Menstruation becomes regular until ovulation occurs
consistently with them. It happens 1-2 years after menarche.
immature
days and 28

Ova is produced in a cycle pattern.
28 -
1

Ova stops to be produced at menopause (the end of the
fertile period in females).
ANATOMY & PHYSIOLOGY OF
THE REPRODUCTIVE SYSTEM
 Reproductive structures of
the female and male are
homologous. They arise
from the same matched
embryonic origin.

Gynecology – the study of
female reproductive
organs.

Andrology – the study of
the male reproductive
organs.
 Y. 3 months of
2 a fet us

Kulang lang sa distinction

6-7 mos.
 MALE REPRODUCTIVE SYSTEM
madaming folds MALE EXTERNAL STRUCTURES
I

(1) Scrotum is rugated, skin-covered muscular pouch
suspended from the perineum.
Chindi
nandoon
and testis

puede maipit
-
4 Spermatozoa

Scrotum’s functions are to O
warm = kills the sperm

support the testes, help
regulate the temperature of sperm. In cold weather, it
contracts to bring the testes closer to the body, in hot
weather, the muscle relaxes allowing the testes to fall
away from the body – This will keep the temperature
of the testes as even as possible to promote the
production and - viability of sperm.
capability
 Leydig's
cells
maturation of
sperm 20ft
I (long) * all structures are needed
for the full maturation of
sperm

68 days full maturation of sperm
=
 MALE REPRODUCTIVE SYSTEM
MALE EXTERNAL STRUCTURES

(2) Testes are two ovoid glands that lie in the
scrotum.
For each is encased by white fibrous capsule,
composed of several lobules with each lobule contains
interstitial cells (Leydig’s cells) and seminiferous
②
tubule. Seminiferous tubules produce spermatozoa.
Leydig’s cells are responsible for the production of
testosterone.
 MALE REPRODUCTIVE SYSTEM
MALE EXTERNAL STRUCTURES (TESTES)

Testes form in the pelvic cavity; descends at 34th to
38th week (late in pregnancy) into the scrotal sac
during intrauterine life.
pag hindi bumaba
hernia = ability
=
inguinal

to produce
hernia

children is not viable

Infants need to be monitored with undescended
testes because testicular descent does not readily
occur in extrauterine life as it does in utero.
Testes that remain in the pelvic cavity may not
produce viable sperm and associated with testicular
cancer.
 MALE REPRODUCTIVE SYSTEM
MALE EXTERNAL STRUCTURES (TESTES)

Sperm production starts when the hypothalamus
releases GnRH which in turn influences the APG to
release FSH and LH. FSH releases Androgen-Binding
Protein. LH releases testosterone. And the binding of
ABP and testosterone promotes sperm formation.
you need both LH and FSH to produce sperm

As testosterone increases, a feedback effect on the
hypothalamus and APG is created hence slows down
the production of FSH and LH and ultimately
decreases or regulates sperm production.
 Wro this ,
no

stimulation of the
APG
 MALE REPRODUCTIVE SYSTEM
MALE EXTERNAL STRUCTURES (TESTES)

In most males, one testis is slightly larger than the
other and is suspended slightly lower in the scrotum
than the other (usually the left one).
very sensitive any sperm sa temp.

Spermatozoa do not survive at temperature as high as
that of the body. The location of the testes outside of
the body is 1degree F lower than the body temp.

Normal testis is feel firm, smooth, and egg-shaped
 MALE REPRODUCTIVE SYSTEM
MALE EXTERNAL STRUCTURES

(3) The Penis is composed of three cylindrical masses
of erectile tissue in the penis shaft: two termed the
corpus cavernosa, and a third termed the corpus
spongiosum.

It serves as the outlet for both the urinary and the
reproductive tracts in men. Urethra passes through
these erectile tissue.
 MALE REPRODUCTIVE SYSTEM
MALE EXTERNAL STRUCTURES (PENIS)

With sexual excitement, nitric oxide is released from
endothelium of blood vessels and an increase in blood
flow to the arteries of the penis (engorgement). The
ischiocavernosus muscle at the base of the penis then
contracts, trapping both venous and arterial in the
three sections of erectile tissue and leading to
distention and erection of the penis.
Kailangan
3
mabilis straight
,

days lang nag-iintay and orum

#
Penile erection is stimulated by the parasympathetic
nerve innervation.
 MALE EXTERNAL STRUCTURES (PENIS)
At the distal end of the is
a bulging, sensitive ridge
of tissue – the glans. A
retractable casing of skin,
the prepuce, protects the
nerve-sensitive glans at
- prepare
of the
skin
birth.

Surgical removal of the
prepuce tissues is called
circumcision.
 MALE REPRODUCTIVE SYSTEM
MALE INTERNAL STRUCTURES

(1) Epididymis is the seminiferous tubule of each
testis, and tightly coiled. It is responsible for
conducting sperm from the tubule to the vas deferens
– the next step in the passage to the outside.
each testis has this structure it takes time
should be continuous as

20 feet long and some sperm stored in the epididymis.
for sperm to develop

bakit Kailangan mahaba ? neutralizes the environment
as urine is too acidic

Alkaline fluid, semen or seminal fluid (basic sugar &
mucin, a form of protein) that surrounds sperm at
maturity is produced by the cells lining of epididymis.
 MALE INTERNAL STRUCTURES
(EPIDIDYMIS)

At the epididymis level, sperm are immobile and
incapable of fertilization.
It takes 12-20 days for the sperm to travel the length
of the tube.
A total of 64 days for the sperm to mature.
Aspermia (absence of sperm) and Oligospermia (less
than 20million sperm/ml) are problems that do not
respond to therapy but only after 2months.
 MALE INTERNAL STRUCTURES
* nag mamature
na
(2) Vas Deferens (Ductus Deferens) is a hollow tube
surrounded by arteries and veins and protected by a
thick fibrous coating.
It carries sperm from the epididymis through the
inguinal canal into the abdominal cavity where it ends
at the seminal vesicles and the ejaculatory ducts.
Sperm mature as they pass through the vas deferens.
Still immobile because of the fairly acidic medium of
the semen produced at this level.
 MALE INTERNAL STRUCTURES
(VAS DEFERENS)

Spermatic cord consists of the blood vessels and the
vas deferens.

Varicocele or varicosity of the internal spermatic vein
appears to make a little difference with subfertility.
irreversible

Vasectomy (severing of the vas deferens to prevent
passage of sperm). A popular means of male birth
control.
 MALE INTERNAL STRUCTURES
(3) Seminal Vesicles are two convoluted pouches that
lie along the lower portion of the posterior surface of
the bladder and empty into the urethra by way of the
ejaculatory ducts.
need to survive

↑
They secrete a viscous alkaline liquid that has a high
sugar, protein, and prostaglandin content.
urethra = acidic

Sperm become increasingly motile with this added
fluid because it surrounds them with nutrients and
more favorable pH.
 MALE INTERNAL STRUCTURES

(4) Ejaculatory Ducts are two ducts that passes
through the prostate glad and join the seminal
vesicles to the urethra.
 MALE INTERNAL STRUCTURES
(5) Prostate Gland is a chestnut-sized gland that lies
just below the bladder.
The urethra passes through the center of it, like the
hole in a doughnut.
It secretes a thin, alkaline fluid and it further protects
sperm from being immobilized by the naturally low pH
level of the urethra.
In middle life, men develop benign prostate
hypertrophy – swelling that interferes with both
fertility and urination.
 MALE INTERNAL STRUCTURES
(6) Bulbourethral Glands or Cowper’s glands lie beside
the prostate gland and empty via short ducts into the
urethra.
Likewise secretes alkaline fluid that helps counteract
the acid secretion of the urethra and ensure safe
passage of spermatozoa.
Semen, is derived from the prostate gland (60%), the

Calkaline
seminal vesicles (30%), the epididymis (5%), and the
bulbourethral glands (5%).
fid
 MALE INTERNAL STRUCTURES

(7) Urethra is a hollow tube leading from the base of
the bladder. After passing the prostate gland,
continues to the outside through the shaft and glans
of the penis.

It is approximately 8 in (18 to 20 cm long).

It is lined with mucous membrane.
 FEMALE
REPRODUCTIVE SYSTEM
 FEMALE EXTERNAL STRUCTURES

asection The Vulva
Femalereproductive
s

(from the latin
word for
-
“covering”)
are the
structures that
form the
female
EXTERNAL
genitalia.
 FEMALE EXTERNAL STRUCTURES

(1) Mons Veneris is a pad of adipose tissue located
over symphysis pubis, the pubic bone joint.

It is covered by a triangle of coarse, curly hairs.

Its purpose is to protect the junction of the pubic
bone from trauma. need in labor para hindi mawarak/laceration
 FEMALE EXTERNAL STRUCTURES

(2) Labia Minora is just posterior to the mons veneris
spread two hairless folds of connective tissue.
-
BEFORE MENARCHE, these folds are fairly small. At
childbearing age, they are firm and full. AFTER
Eit
MENOPAUSE, they atrophy and again become smaller.
Normally it is pinkish, internal surface is covered with
mucous membrane and external with skin.
The area is abundant with sebaceous glands.
L
sperm survival
 FEMALE EXTERNAL STRUCTURES

(3) Labia Majora are two folds of adipose tissue
covered by loose connective tissue and epithelium
that are positioned lateral to the labia minora.

Covered by pubic hair to serve as a protection for the
external genitalia and the distal urethra and vagina.
 FEMALE EXTERNAL STRUCTURES

(4) Other External Organs
(4a) Vestibule is the flattened, smooth surface inside
the labia. The openings to the bladder (urethra) and
the uterus (the vagina) both arise from here.
to stimulate the sebaceous glands
X dry

(4b) Clitoris is a small (1 to 2 cm), rounded organ of
erectile tissue at the forward junction of the labia
minora. Covered by a fold skin, the prepuce. It is
sensitive to touch and temperature and is the center
of sexual arousal and orgasm in a woman.
 FEMALE EXTERNAL STRUCTURES
(4c) Skene’s glands (parauretral glands) are located
lateral to the urinary meatus, one on each side. Their
ducts open into the urethra.
(4d) Bartholin’s glands (vulvovaginal glands) are
located just lateral to the vaginal opening on both
sides. Their ducts open into the distal vagina.
②
Secretions from both of these glands help to lubricate
the external genitalia during coitus.
protect

The alkaline pH of their secretions helps to improve
sperm survival in the vagina.
 FEMALE EXTERNAL STRUCTURES
(4e) The② Fourchette is the ridge of tissue formed by
the posterior joining of the two labia minora and the
labia majora. This the structure that is sometimes cut
(episiotomy) during childbirth to enlarge the vaginal
opening.
-
(4f) Perineal muscle or perineal body is a muscular
area and it is easily stretched during childbirth to
allow enlargement of the vagina and passage of the
fetal head.
Pregnancy exercises (Kegel’s, squatting and tailor-
sitting) make the perineal muscle more flexible.
 nawawala if active
FEMALE EXTERNAL STRUCTURES
sa sports/ uses tampons

(4g) The Hymen is a tough but elastic semicircle tissue
that covers the opening of the vagina in childhood.
It is torn during the time of first sexual intercourse.

Many girls do not have an intact hymen because of the
use of tampons and active sports participation.

Imperforate hymen that is so complete that it does
not allow the menstrual blood to flow or for sexual
relations until it is surgically incised.
 FEMALE EXTERNAL STRUCTURES
bloodsupplyforstet the
(5) Vulvar Blood Supply is the blood supply of the
external genitalia coming from the pudendal artery
and a portion of the inferior rectus artery.
Venous return is through the pudendal vein. Pressure
on this vein by the fetal head can cause- extensive
- back-pressure and development of varicosities
(distended veins) in the labia majora.
It is rich with blood supply, hence subject to
hematomas due to trauma or childbirth.
Blood supply contributes to the rapid healing of any
tears in the area of childbirth.
 and
part

FEMALE EXTERNAL STRUCTURES
a
conly
-not the motor
in this area
anesthesia hindi masakit
↑ to kill nerve supplyI para
manganak)

(6) Vulvar Nerve Supply is the anterior portion of the
vulva that derives its nerve supply from the ilioinguinal
and genitofemoral nerves (L1 level).
The posterior vulva are supplied by the pudendal nerve
(S3 level).
A rich nerve supply makes the area extremely sensitive to
touch, pressure, pain and temperature.
Normal stretching of the perineum with childbirth causes
temporary loss of sensation in the area.
Anesthesia is administered locally to block the pudendal
nerve, eliminating pain at the perineum during childbirth.
FEMALE INTERNAL STRUCTURES

The Internal Organs
of the Female are
ovaries, fallopian
tubes, uterus and
the vagina.
 it mature
FEMALE INTERNAL STRUCTURES
clear liquid-makes

(1) Ovaries are approximately 4cm long by 2cm in
diameter and approximately 1.5 cm thick, or the size and
shape of almonds.
Grayish white and appear pitted, or with minute
indentations on the surface.
An unruptured, glistening, clear, fluid-filled graafian
follicle (an ovum to be discharged) or a miniature yellow
corpus luteum (the structure left behind after the ovum
has been discharged) can be observed on the surface of
ovary.
 too like
FEMALE INTERNAL STRUCTURES
~ suspended
Ovaries are located close to and on both sides of the
uterus in the lower abdomen.
Their function (female gonads) is to produce, mature, and
discharge ova (egg cells).
They produce estrogen and progesterone and initiate and
regulate -
menstrual cycles.
After menopause, or cessation of ovarian function, the
uterus, breasts, and ovaries all undergo atrophy or a
-
reduction in size because of lack of estrogen.
 FEMALE INTERNAL STRUCTURES

Ovarian function is necessary for maturation and
maintenance of secondary sex characteristics in females.
Ovaries secretes
estrogen

The estrogen secreted by the ovaries is important to
prevent osteoporosis or weakness of bones because of
withdrawal of calcium from the bones (happens after
menopause).

The production of estrogen keeps the cholesterol level
reduced thus limiting atherosclerosis (artery disease).
 FEMALE INTERNAL STRUCTURES

The ovaries are held suspended and in close contact with
the end of fallopian tubes by three supporting ligaments
attached to the uterus or the pelvic wall.

They are not covered by a layer of peritoneum and in this
way, ova can escape from them and enter the uterus by
way of fallopian tubes.
 FEMALE INTERNAL STRUCTURES

Ovaries have THREE Principal Divisions:

1. Protective layer of surface epithelium
2. Cortex, where the immature (primordial) oocytes
mature into ova and large amounts of estrogen and
- progesterone are produced.
3. Central Medulla, which contains the nerves, blood
vessels, lymphatic tissue, and some smooth muscle
tissue.
 DIVISION OF REPRODUCTIVE CELLS
(GAMETES)
o At birth, each ovary has 2 million immature ova
(oocytes), formed during the 1st five months of
intrauterine life.mitotic division

meiosis-reduces
-

multiply /duplicate
the number of chromosomes

o These cells have the unique ability to produce a new
individual but contain the usual components of cells: a
cell membrane, an area of clear cytoplasm, and a
nucleus containing chromosomes.
 DIVISION OF REPRODUCTIVE CELLS
immature orum
(GAMETES)
-

o The oocytes, like the sperm differ from all other body
cells in the number of chromosomes they contain in the
nucleus. meiosis-reduction process
-
23 chromosomes

①
 DIVISION OF REPRODUCTIVE CELLS
(GAMETES)
o Oocytes before ovulation and spermatozoa before it
-
matures, both will undergo meiosis (reduction division).
o After reduction division, an ovum has 22 autosomes
and an X sex chromosome. An spermatozoon has 22
autosomes and either an X or a Y sex chromosome.
o A new FEMALE individual = union of an ovum and an X-
carrying spermatozoon (an XX chromosome pattern).
o A new MALE individual = union of an ovum and a Y-
carrying spermatozoon (an XY chromosome pattern)
 MATURATION OF OOCYTES

o Primordial Follicle is a protective sac or thin layer of
cells that surrounds oocytes.
o Between 5 to 7 million ova form in the utero.
o Majority never developed, by birth only 2 million are
present.
o By age 7 years, only approximately 500,000 are
present in each ovary; by 22 years there are
approximately 300,000, and by menopause none are
left.
o Menopause is the point at which no functioning
oocytes remain in the ovaries.
 where
FEMALE INTERNAL STRUCTURES
structure place
takes
/fertilization
(2) Fallopian Tubes arise from each corner of the uterine
body and extend outward and backward until each opens
at its distal end, the ovary.
It is 10 cm long in a mature woman.
Their function is to convey the ovum from the ovaries to
the uterus and to provide a place for fertilization of the
ovum by sperm.
The isthmus portion of the tube is cut or sealed in a tubal
ligation.
The ampulla is where fertilization of an ovum occurs.
 FEMALE INTERNAL STRUCTURES

The lining of the fallopian tube is composed of mucous
membrane – contains mucus-secreting and ciliated (hair
covered) cells.
The muscle layer produces the peristaltic motions that
help the ovum travel along the length of the tube.
Migration of the ovum is also aided by the action of the
ciliated lining and the mucus which acts as a lubricant.
The mucus serves as a source of nourishment for the
fertilized egg, because it contains protein, water and
salts.
 FEMALE INTERNAL STRUCTURES

hair-like structure A direct pathway from
sucking motion
contraction for
vagina, uterus, and tubes to
ovum

the
to enter

fallopian tube
the peritoneum. This
pathway makes conception
wider
possible.
& ofe will be

implanted
where
takes
fertilization
place
This pathway is susceptible
to infection and diseases so
endometrium wilthicken
myometrium will contract progesterone clean technique must be
during childbirth
used during pelvic
opercul um
2 should be passive examinations or treatment.
or else

And sterile technique is
protection barrier early birth

done during vaginal
examination to ensure no
organisms can enter.
 FEMALE INTERNAL STRUCTURES

(3) The Uterus is a hollow, muscular, pear-shaped organ
located in the lower pelvis, posterior to the bladder and
anterior to the rectum. With maturity, the uterus is 5 cm
to 7 cm, 5 cm wide, 2,5 cm deep.
Its function is to receive the ovum from the fallopian
tube; provide a place for implantation and nourishment;
furnish protection to a growing fetus, and at maturity of
the fetus, expel it from a woman’s body.
After pregnancy, the uterus never return to its
nonpregnant size (9cm long, 6cm wide, 3cm thick).
 FEMALE INTERNAL STRUCTURES

(3a) The body or corpus is the uppermost part and forms
the bulk of the organ.
During pregnancy, the body expands to contain the
growing fetus.
The fundus is the portion of the body between the points
of attachment with the fallopian tubes. This part can be
palpated abdominally to determine the amount of uterine
growth, to measure the force of uterine contractions
during labor, and to assess that the uterus is returning to
its nonpregnant state after childbirth.
 FEMALE INTERNAL STRUCTURES

(3b) The Isthmus is a short segment between the body
and the cervix. It is 1-2 min length.

This enlarges during pregnancy to aid in accommodating
the growing fetus.

It is the portion of the uterus that is most commonly cut
when a fetus is born by a caesarian birth.
 FEMALE INTERNAL STRUCTURES

(3c) The Cervix is the lowest portion of the uterus. It is
1/3 of the total size of the uterus (2-5 cm long).
Cervical canal is the central cavity of the cervix.
Internal Cervical Os is the opening of the canal at the
junction of the cervix and isthmus.
External Cervical Os is the distal opening to the vagina.
The level of the external os is at the level of the ischial
spines (an important relationship in estimating the level
of the fetus at the birth canal).
 UTERINE AND CERVICAL COATS

The uterine wall consists
of three separate coats of
layers of tissue: an inner
fluid
one of mucous membrane
ovum with
=
graafian follicle

corpus
(the endometrium), a
middle one of a muscle
luteum crich in progesterone)
On the 14th I
day
thickening of

fibers (the myometrium),
covulation)
endometrium

and an outer one of a
connective tissue (the
perimetrium).
 UTERINE AND CERVICAL COATS

(1) Endometrium layer is important for menstrual
function.
The inner layer of the endometrium is highly sensitive
and responsive to hormones estrogen and progesterone.
It grows and becomes thick and capable in supporting a
pregnancy.
When pregnancy does not occur, this layer shed as the
menstrual flow.
 UTERINE AND CERVICAL COATS
(1a) Endocervix is the mucous lining of the cervix. It is also
affected by hormones. The cells at the cervical lining
secretes mucus to provide a lubricated surface so that
spermatozoa can readily pass through the cervix.
At the peak estrogen during a menstrual cycle, as much as
700ml of mucus is produced. When at its lowest, only a few
ml are produced.
These mucus are alkaline, decreasing the acidity of the upper
vagina, aiding sperm survival.
During pregnancy, endocervix becomes plugged with mucus,
forming a seal (operculum) to keep out ascending infections.
 UTERINE AND CERVICAL COATS

(2) The Myometrium or muscle layer of the uterus
composed of three interwoven layers of smooth muscle,
the fibers of which are arranged in longitudinal,
transverse, and oblique directions.
This network offers extreme strength to the organ.
Its function is to constrict the tubal junctions and
preventing regurgitation of menstrual blood into the
tubes.
It also holds the internal cervical os closed during
pregnancy to prevent preterm birth.
 UTERINE AND CERVICAL COATS

(2) The Myometrium or muscle layer of the uterus
composed of three interwoven layers of smooth muscle,
the fibers of which are arranged in longitudinal,
transverse, and oblique directions.
This network offers extreme strength to the organ.
Its function is to constrict the tubal junctions and
preventing regurgitation of menstrual blood into the
tubes.
It also holds the internal cervical os closed during
pregnancy to prevent preterm birth.
 UTERINE AND CERVICAL COATS

The muscle layers of myometrium have an equal pressure
to expel the fetus. This equal pressure is possible due to
the unique arrangement of the muscle fibers.
After childbirth this network of fibers will constrict the
blood vessels through the layers, thereby limiting blood
loss in the woman.
(3) The Perimetrium or the outermost layer of the uterus
serves as an additional support and strength to the
structure.
 UTERINE BLOOD SUPPLY

The large DESCENDING abdominal
aorta divides to form two iliac
arteries; main divisions of the iliac
arteries are the hypogastric
arteries.
These further divide to form the
arteries and supply to the uterus.
Because the uterine blood supply is
not far removed from the aorta, it
is abundant and adequate to supply
the growing needs of the fetus.
 UTERINE BLOOD SUPPLY

As an additional safeguard,
after supplying the ovary
with blood, the ovarian
artery (direct subdivision of
the aorta), joins the uterine
artery as a fail-safe system
to ensure that the uterus
will have an adequate
supply.
 UTERINE BLOOD SUPPLY

after birth , amount of
urine output is checked
The blood vessels that supply
because the

be affected
wreter

during
might
labor
the cells and lining of the
uterus are tortuous in
nonpregnant women. As
uterus enlarges with
pregnancy, the vessels
“unwind” and so can stretch
to maintain an adequate
blood supply.
 UTERINE BLOOD SUPPLY

QUESTION: Susan Mateo decides to
have a tubal ligation (clamping of
the fallopian tubes after the birth
of her baby. Why is observing her
for urine output after this this tube
surgery is always a critical
assessment?
Answer: A ureter may be injured by
a clamp if bleeding is controlled by
clamping of the uterine or ovarian
vessels.
 UTERINE NERVE SUPPLY

The uterus is supplied by efferent (motor) and afferent
(sensory nerves). The efferent nerves arise from the T5
through T10 spinal ganglia while afferent nerves at the
T11 and T12.
The sensory innervation of the uterus registers lower in
the spinal column, so this is why anesthetic solution can
be injected near T11 and T12 to control pain of uterine
contractions at labor, without stopping motor control –
PRINCIPLE OF EPIDURAL and SPINAL ANESTHESIA.
 UTERINE DEVIATIONS
puede
Several uterine deviations
(shape and position) may
·
hindi
magbunt is

interfere with fertility or
·
need clear
passage

pregnancy. A female fetus, the
uterus forms with a septum or
fibrous division, separating it
into two portions. As the fetus
matures, this septum dissolves,
so at birth no remnant of the
division remains. These
deviations may decrease the
ability to conceive or carry a
pregnancy to term.
 UTERINE
DEVIATIONS
A. Anteversion –
entire uterus is
tipped far
forward.
mahihirapan magbuntis
dahil sobrang forward
B. Anteflexion – the
body of the
uterus is bent
sharply forward
at the junction
with the cervix.
 UTERINE
DEVIATIONS
C. Retroversion –
entire uterus is
tipped forward

D. Retroflexion – the
body is bent sharply
back just the cervix.

These positions can
interfere fertility by
blocking the
migration of sperm.
 FEMALE INTERNAL STRUCTURES
(4) Vagina is a hollow, musculomembraneous canal located
posterior to the bladder and anterior to the rectum.It
extends from the cervix of the uterus to the external vulva.
Its function is to act as the organ of intercourse and to
convey sperm to the cervix so that sperm can meet with the
ovum in the fallopian tube.
With childbirth, it expands to serve as the birth canal.
Doderlein’s Bacillus is the lactose-fermenting bacteria
causing lactic acid to formed, makes the pH of the vagina
acidic detrimental to pathologic bacteria, preventing vaginal
infections.
FEMALE INTERNAL STRUCTURES

(5) The mammary
lactation
glands, or breasts
colostrum =
panlaban sa
temporary
mga sakit remain halted in
size and
development until a
rise of estrogen at
puberty.
The size increase
due to fat
depositions.
FEMALE INTERNAL STRUCTURES

Milk glands of the
breasts are divided
into approximately
20 lobes. All of the
glands in each lobe
produce milk by
ACINAR CELLS and
deliver it to nipple
through lactiferous
duct.
 FEMALE INTERNAL STRUCTURES
The nipple erects on manual or
sucking stimulation.
On stimulation, it transmits sensations
to the PPG to release oxytocin to
constrict milk glands and push milk
forward into the ducts to the nipple.
Areola is the round, dark
pigmentation surrounding the nipples.
Montgomery’s Tubercles are the area
appears rough surfaces because it
contains many sebaceous glands.
 FEMALE INTERNAL STRUCTURES
The blood supply to the breasts is
profuse and being supplied by
thoracic branches of the axillary,
internal mammary, and intercostal
arteries.
This blood supply is important in
bringing nutrients to the milk
glands, making it possible a
plentiful supply of milk for
breastfeeding.
 MENSTRUATION
(PHYSIOLOGY OF MENSTRUATION)
Maria Leonora D. De Leon, RN MAN