Reproductive Endocrinology II PDF

Summary

This document provides an overview of human reproduction, pregnancy, and parturition. It describes various aspects including the physiology of the sexual response, implantation of fertilized cells, and the development of the placenta. The document also details the hormonal maintenance of pregnancy, and the stages of parturition and lactation.

Full Transcript

Human reproduction,
pregnancy and parturition
 Intended learning outcomes
Human reproduction, pregnancy and parturition
Overview: Fertilisation, embryonic development and implantation. Pregnancy,
parturition and lactation and their endocrine control.

After the lecture and personal study, students should be able to:
Explain the physiology of the sexual response in the male and female
In simple terms, explain the implantation of fertilised cells into the uterus
Understand the development of placenta at the onset of pregnancy
Know the changes of endocrinology in pregnancy
Describe the physiology of major maternal adaptations and understand how these
changes might be beneficial during pregnancy or birth
Describe the endocrinology involved in the maintenance of gestation
Understand the major events occurring at each of the phases of parturition
Understand events which lead to lactation
Understand the endocrinology of the suckling response and explain how weaning
results in cessation of lactation
Sexual Arousal and Ejaculation
 Sexual arousal
4 stages:
Excitement
Psychogenic
and/or
somatogenic
Individualized –
personality and
culture
Plateau
Orgasm
Resolution
 Excitement
Male Female
Heightened sexual awareness Heightened sexual awareness
Testicular vasocongestion Vasodilation of vagina & external
Engorgement of penis è erection genitalia è swelling of labia
Erection of clitoris
Lubrication of vagina
Enlargement of breasts
Flush to skin
Fig. 20-13, p. 761
 Plateau

Male Female
Intensification of excitement As male. Also
↑ HR, BP, resp rate, muscle Vasodilation of lower 1/3 of vagina
tension causes tightening around penis
“Tenting effect” –
Uterus raises
Lifts cervix
Enlarges upper ½ of vagina
(makes room for ejaculate)
 Orgasm
Male Female

Intense physical pleasure Intense physical pleasure
Ejaculation Rhythmic contractions of pelvic
Rhythmic contractions of pelvic muscles every 0.8 secs, espec in
muscles every 0.8 secs lower 1/3 of vagina (“orgasmic
platform”)
↑ HR, BP, resp rate, muscle
tension ↑ HR, BP, resp rate, muscle tension
No ejaculation
No refractory period \ can have
another orgasm immediately
 Ejaculation
Motor neurone induced
Stimulation of mechanoreceptors rhythmic contraction (0.8 / sec)
in glans of penis of skeletal muscle at base of penis

Sympathetic response
Semen forced out
thro’ urethra

Contraction of smooth muscle in
Prostate è prostatic fluid EXPULSION
semen
Reproductive ducts è sperm
Seminal vesicles è s.v. fluid
Number of sperm per ejaculate
Secreted into (per 2.75 mL) approx 180
prostatic urethra million (66 million / mL)
> 20 million / mL – clinically
EMISSION infertile
Table 20-4, p. 759
 Resolution
Male Female

Temporal refractory No refractory period
period – men can’t
have orgasms in quick
succession
Relaxation
Relaxation
Return of body to pre
excitement state
Slowing of blood flow to Return of body to pre excitement state
penis
Implantation and Pregnancy
Fig. 20-23, p. 778
 Capacitation
v Freshly ejaculated sperm are incapable of fertilisation
v They must undergo capacitation (in the female repro tract)
surface of sperm altered by removal of glycoprotein coat
tail movements become whip like
cAMP levels rise to promote acrosomal reaction
Fig. 20-25, p. 780
 Penetration of the egg by the sperm
v Allurin released by mature ovum to attract sperm. Sperm
“smell” this chemical using an olfactory receptor (hOR17-4).
Detection tail movements and swimming in direction of the
signal
v Fertilin (protein on sperm) binds to integrin (adhesion molecule
on 2ºoocyte)
v Acrosomal reaction
Enzymes in the acrosomal tip allow a sperm to “burrow”
through the outer layers of ovum & enter cytoplasm
“Block to polyspermy” membrane changes triggered
Tail of sperm probably lost
v Final meitoic division of 2º oocyte triggered – 2nd polar body
formed & extruded
v Sperm & egg nuclei fuse (>1hr) èzygote
 Fimbriae -
Sweep ovum
into oviduct, carried along
by smooth muscle
contraction & cilia

Fig. 20-26, p. 781
Fig. 20-27a, p. 782
Fig. 20-27b, p. 782
Fig. 20-27c, p. 782
 Implantation 1
1. initial contact with epithelium of uterus – blastocyst sticky
Endometrium
uterine lining

Inner cell mass
Capillary

2. proteases released
from trophoblast Blastocoel

3.pathways created
Trophoblast
allowing trophoblast
cells to grow into
endometrium

4. trophoblast releases
nutrients for embryo
 Implantation 2
Trophoblast cells tunnel into the endometrial lining

Boundaries between trophoblast cells disintegrate –
“syncytiotrophoblast” will become foetal placenta

Trophoblast induces “decidualization” of endometrium –
increased local vascularization and nutrient storage

Blastocyst becomes buried in uterine lining by day 12
 Development of Placenta
§ Placenta derived from both trophoblast & decidual tissue

§ Trophoblast cells (chorion) differentiate into multinucleate
“syncytiotrophoblasts” which invade decidua and break down
capillaries to form cavities filled with maternal blood

§ Developing embryo sends capillaries into the syncytiotrophoblast
projections to form “placental villi”

§ Each villus contains foetal capillaries separated from maternal blood
by a thin layer of tissue – no direct contact between foetal & maternal
blood

§ 2 way exchange of respiratory gases, nutrients, metabolites etc
between mother and foetus, largely down diffusion gradient
Placenta and foetus Umbilical cord

Pool of maternal blood Amniotic sac

Placental villus

Uterine decidual tissue

Maternal arteriole

Maternal venule
Fetal vessels

Chorion
Chorionic tissue

Umbilical Umbilical
Placenta vein artery
Hormonal maintenance of pregnancy –
1st trimester
What stops the implanted foetus being swept away with the menstrual
lining during menstruation?
Human chorionic gonadotropin (hCG)
Produced by the blastocyst
Prolongs life of corpus luteum (now called c.l. of pregnancy)
For 10 further weeks, C.l. of pregnancy grows and produces
increasing concs of progesterone & oestrogen (1st trimester)
After 10 weeks, the placenta produces these hormones
\ uterine lining is maintained during pregnancy
Pregnancy test – hCG detected in urine throughout pregnancy
Morning sickness – hCG may trigger vomiting centre

At end of 1st trimester, hCG stimulates male foetal gonads to produce
steroid hormones è genitalia differentiation
 Hormonal maintenance of pregnancy
hCG secreted by Human chorionic gonadotropin (hCG)
chorion to oestr. & prog.
maintain levels rise as
pregnancy placenta
grows
Oestrogen

hCG sustains Progesterone
corpus luteum –
oestrogen &
progesterone Corpus
secreted to maintain luteum
pregnancy regresses-
no longer
needed for
steroid
output

Fertilization Delivery
 Why doesn’t oestrogen initially come from the placenta?
Why doesn’t the placenta secrete oestrogen in the first place?
- placenta does not possess all the enzymes needed for oestrogen
synthesis in the 1st trimester
Placenta requires dehydroepiandosterone (DHEA) from foetal adrenal
cortex, which takes time to develop
“foetoplacental unit” is used:
Maternal Blood Placenta Foetal blood Foetal adrenal cortex

cholesterol cholesterol

progesterone progesterone

DHEA DHEA
Oestrogen
(Oestriol)
oestrogen

Placenta CAN synthesise progesterone, but small amounts at first
 The roles of oestrogens and
progesterone in pregnancy
Secreted by the corpus luteum of preg in 1st trimester and
placenta in 2nd and 3rd trimesters

Oestrogens
Stimulate growth of myometrium musculature – to expel
foetus during labour
Stimulate development of mammary gland ducts

Progesterone
Suppresses contractions of uterine myometrium
Promotes formation of mucus plug
Stimulates development of mammary milk glands
 Gestation
Human gestation approx 38 weeks from conception, approx 40
weeks from last period
Embryo / foetus grows and develops

§ Mother undergoes physical changes:
§ Enlargement of uterus (and placenta)
§ Enlargement of breasts which become able to produce milk
§ ↑ blood vol (oestrogen stimulates angiotensinogen & renin
secretion. Aldosterone retains Na+ and water)
§ Weight gain
§ ↑ pulmonary ventilation & Vo2
§ ↑ GFR è ↑ urine
§ ↑ nutritional requirements for the mother
 Endocrine secretions of the placenta
during gestation
hCG
oestrogens and progesterone
Other placental hormones?
Human chorionic somatomammotropin (hCS): ↓ maternal glucose
utilization, ↑ plasma FA - ↑ glucose and FA availability for foetus ?
prepares breast glands for lactation ?
Parathyroid hormone – related peptide (PTHrp): Mobilises maternal
Ca2+ for calcification of foetal bones (if mother’s diet does not
contain enough Ca2+)
Relaxin : softens cervix, loosens pelvic connective tissue
Placental Corticotropin Releasing Hormone (CRH): stimulates DHEA
production by foetal adrenal cortex – important in initiation of
parturition
Table 20-5, p. 787
Parturition and Lactation
 Parturition
Labour, delivery or birth

Requires
§ Dilation of the cervical canal
§ To allow passage of the foetus
§ Contractions of uterine myometrium
§ To cause expulsion of the foetus
Preparation for parturition
Braxton-Hicks contractions
§ “false labour” – increased uterine sensitivity
Softening of cervix
§ Caused by relaxin & prostaglandins
§ Breakdown of cervical collagen fibres allows
cervix to dilate during labour
Relaxation of pelvic bones
§ Caused by relaxin
Foetus “drops”
§ Head is in contact with cervix
§ cf. a breech birth
 In proportion to
size of placenta?
What
(into fetal circulation)
appears to
initiate
labour?

CRH = corticotropin
releasing hormone

Increased oestrogen
synthesis by placenta
produces dose-
dependent changes in
uterus
§oestrogen increases density of oxytocin receptors in myometrium

§ maternal [oxytocin]p does not rise – parturition triggered by raised oxytocin
sensitivity of myometrium

§ oxytocin acts via IP3 - raises cytoplasmic [Ca++ ]

Uterine
contractions

Push fetus Positive
against cervix feedback
facilitates
progression of
parturition
(through
neuroendocrine
reflex)

Oxytocin Prostaglandin
secretion production
 1st stage of labour
Cervical dilation stage
May take many hours

Rupture of amniotic sac - “waters
break”
Lubricates birth canal

Cervix dilates to 10cm to
accommodate the baby’s head
Breech birth – another part of body
approaches cervix first
Cervix partially dilated
 2nd stage of labour
Delivery of the baby
Usually takes 30-90 minutes

Baby moves thro’ cervix to vagina
Stretch receptors in vagina trigger
contraction of abdominal wall to
augment uterine contractions
Mother can voluntarily contract abs
also (“push”)

After birth, the baby is freed from
placenta by cutting umbilical cord
Cord is tied and forms umbilicus
 3rd stage of labour
Delivery of the placenta placenta

Takes 15-30 minutes

Placenta separates from
myometrium and uterine
contractions cause it to be
expelled – “afterbirth”
Myometrium contracts and
prevents haemorrhage by
constricting uterine blood vessels Umbilical cord
at site of placental attachment
Involution
Shrinkage of uterus to pre-pregnancy size
Takes 4-6 weeks
Induced by
Fall in oestrogens and progesterone levels after placenta
is lost
Oxytocin which is released in response to breast feeding

LOCHIA
Development of the breast
In non- pregnant state, mostly adipose
adipose and rudimentary ducts tissue
ducts
Breast doesn’t fully develop until nipple
pregnancy
Development of glandular
structure lobules
Each duct terminates in a
lobule myoepithelial
Lobule made of milk cells
producing glands – alveoli
Milk secreted from
epithelial cells into lumen

milk
 What triggers development of the
breast?
During pregnancy,
↑ oestrogen è duct development
↑ progesterone è lobule formation
Prolactin (ant pit hormone) & human chorionic somatomammotropin
(placental hormone) è Synthesis of enzymes for milk production
Breasts are mature by month 4 of gestation
Prolactin also stimulates milk production after parturition
Stimulatory action of prolactin is blocked in later stages of pregnancy
by high levels of oestrogen and progesterone
Immediately after parturition oest & prog levels fall, allowing
prolactin to induce milk production
 Suckling
Suckling triggers
Neuroendocrine reflex - leads to secretion of
Prolactin è milk production
Oxytocin è milk ejection (a.k.a. LETDOWN)
Oxytocin stimulates contraction of myoepithelial cells
Oxytocin hastens involution
Oxytocin suppresses LH & FSH secretion – suppresses
menstrual cycle
 Suckling

Mechanoreceptors in nipple

Hypothalamus

Nervous Prolactin-inhibiting hormone (PIH) or
pathway prolactin-releasing hormone (PRH)(?)

Posterior pituitary Anterior pituitary

Oxytocin Prolactin

Contraction of
myoepithelial cells
surrounding alveoli
Milk secretion

Milk ejection
 Components of breast milk
More than 100 constituents
Delivers about 600-750 Kcal/L
Emulsion of particles isotonic with plasma
Water
Lactose about 7% but lower in colostrum
Lipids 3-5%
Vitamins
Minerals e.g., calcium, phosphate, sodium, Mg, Cl- etc
Immunoprotective agents – various – especially plentiful in
colostrum
Other proteins (including immunoglobulins) - Highest conc of
protein in colostrum
Colostrum = milk produced in first 5 days after birth
Cessation of breast milk production
No suckling
After weaning

No prolactin No oxytocin

No milk ejection
No milk production

Milk accumulates in alveoli

Pressure build up acts directly
on alveolar epithelial cells