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Female and Male: Reproductive anatomy & physiology
Professor Julian Jenkins, D.M, F.R.C.O.G. Director Medical Sciences, OB/GYN
Ferring International Center SAFerring International Center SACH 1162 St. Prex, Switzerland
Overview
FemaleA tAnatomyPhysiologyRelevance physiology to infertility treatment
MaleAnatomy
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yPhysiologyRelevance physiology to infertility treatment
Overview
FemaleA tAnatomyPhysiologyRelevance physiology to infertility treatment
MaleAnatomy
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yPhysiologyRelevance physiology to infertility treatment
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Female and Male Anatomy
SSimilarities&
Differences
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How many oocytes ovulate?
In utero over 5,000,000 oocytes developBy birth typically only 2,000,000 oocytes remainBy puberty typically 400,000 oocytes remainUsually only 1 oocyte is released each month from puberty to menopauseSo in a life time around 400 oocytes ovulate
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So in a life time around 400 oocytes ovulate
How many sperm are ejaculated?
From puberty stem cells in testicles produce 10 30 billion sperm per month10-30 billion sperm per month.These move through seminiferous tubules to epididymis.Sperm production takes a few months then mature in epididymis in a few daysTypically 40,000,000 sperm per ml in 5 ml
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Typically 40,000,000 sperm per ml in 5 ml ejaculate ie 200,000,00 sperm released in a single ejaculate.
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Overview
FemaleA tAnatomyPhysiologyRelevance physiology to infertility treatment
MaleAnatomy
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yPhysiologyRelevance physiology to infertility treatment
Female Reproductive Organs
Ovary
Fallopian TubeUterus
Ovary
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Vagina
Laparoscopy
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Hysteroscopy
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Female Anatomy
Bladder
Vagina
Uterus
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Uterus
Ovary
Rectum
Transvaginal Ultrasound
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Overview
FemaleA tAnatomyPhysiologyRelevance physiology to infertility treatment
MaleAnatomy
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yPhysiologyRelevance physiology to infertility treatment
Hypothalamic pituitary ovarian axis
Hypothalamus
GnRH pulses
Pituitary gland
LHFSH
Ovary
Oestrogens /
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Oestrogens / Progesterone
Uterus, Breasts etc.
Ovary
Two-cell, two-gonadotrophin theory
Hormone production in ovarian follicle is due to co-ordinated action of two cells acting together.
Granulosa cellsGranulosa cellsTheca cellsTheca cells
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Theca cells • Convert cholesterols
to progesterone • Convert progesterone
to androgens
Granulosa cells • Convert cholesterols
to progesterone• Convert androgens to
oestrogens
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FSHFSH
Two-cell, two-gonadotrophin theory
GonadatrophinsFSH FSH Follicle stimulating HormoneFollicle stimulating HormoneLH LH Luteinising HormoneLuteinising HormonehCG hCG Human Chorionic GonadotrophinHuman Chorionic Gonadotrophin
The activity of the two cells is controlled by two gonadotrophins acting together.
Granulosa cellsGranulosa cellsTheca cellsTheca cells
pp
Theca cells Granulosa cells
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LH activityLH activity
Theca cells • only respond to LH
(or similar but more potent hCG following conception)
• respond to FSH • as follicle develops start to
respond to LH (or hCG post conception)
Two-cell, two-gonadotrophin theory
Thecal Cells (LH activity)
Granulosa cells(FSH & LH activity)(LH activity)
Cholesterol
Progesterone
Androgens
(FSH & LH activity)Cholesterol
Progesterone
Androgens
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Androgens
Oestrogens
Androgens
Oestrogens
FSHFSH
Menstrual cycle – the start
FSH activates the proliferation and maturation of
Granulosa cellsGranulosa cells
Androgens transferred to
granulosa cells
AA
AA
AA
AAAA
AA
Theca cellsTheca cellsCholesterols ►
androgens
• LH acts on theca
maturation of granulosa cells
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LH activityLH activity
LH acts on theca cells and promotes androgen production
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FSHFSH
Menstrual cycle - oestradiol
• FSH induces aromatase activity in the granulosa cells,
Granulosa cellsGranulosa cells
Androgens transferred to
granulosa cells
AA
AA
AA
AAAA
AA
Androgens ►estradiol
Theca cellsTheca cellsCholesterols ►
androgens
the granulosa cells, facilitating the conversion of androgens to estradiol
• FSH induces the development of LH/hCG receptors
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EEEE
EEEE
EE
EstradiolEstradiol
LH activityLH activity
LH/hCG receptors
FSHFSH
Menstrual cycle - oocyte • Together FSH and LH activity results in
follicular growth, estradiol production and oocyte maturation
Granulosa cellsGranulosa cells
Androgens transferred to
granulosa cells
AA
AA
AA
AAAA
AA
Androgens ►estradiol
Oocyte Oocyte maturationmaturation
Follicular Follicular
Theca cellsTheca cellsCholesterols ►
androgens
y
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growthgrowth
EE
EEEE
EEEE
EE
EstradiolEstradiol
LH activityLH activity
Menstrual cycle - ovulationOvulation
e
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Menstrual cycle - progesterone
Following ovulation ovarian follicle forms corpus luteum pproducing large amounts of progesterone lasts 2 weeks then menstruation follows … unless
Following embryo implantation embryo produces human Chronic Gonadotrophin (hCG) hCG stimulates LH/hCG receptors on corpus luteum to continue
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to produce progesterone, which prevents menstruation and supports early pregnancy.
Overview
FemaleA tAnatomyPhysiologyRelevance physiology to infertility treatment
MaleAnatomy
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yPhysiologyRelevance physiology to infertility treatment
Insufficient LH activity to balance FSH hyperstimulation will lead to excess progesterone, too soon.
Thecal Cells (LH activity)
Granulosa cells(FSH & LH activity)(LH activity)
Cholesterol
Progesterone
Androgens
(FSH & LH activity)Cholesterol
Progesterone
Androgens
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Androgens
Oestrogens
Androgens
Oestrogens
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Hence different gonadotrophins used for ovarian stimulation could affect clinical outcome.
Different composition of gonadotrophins
Difference in endocrine profiles
Embryo quality Endometrial receptivity
O i
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Ongoing pregnancy
Live births
Overview
FemaleA tAnatomyPhysiologyRelevance physiology to infertility treatment
MaleAnatomy
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yPhysiologyRelevance physiology to infertility treatment
Male Reproductive Organs
Testes outside body to keep cool
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Barrier between blood & sperm to prevent immune response to sperm
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Overview
FemaleA tAnatomyPhysiologyRelevance physiology to infertility treatment
MaleAnatomy
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yPhysiologyRelevance physiology to infertility treatment
Male reproductive systemHypothalamus
GnRH pulses
Pituitary gland
LH
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Testis
Male reproductive systemHypothalamus
GnRH pulses
Pituitary gland
LH
Leydig cells
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Testosterone
Testis
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Male reproductive systemHypothalamus
GnRH pulses
Pituitary gland
LH
Leydig cells
FSH
Sertoli cells
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Testosterone
Testis
Male reproductive systemHypothalamus
GnRH pulses
Pituitary gland
LH
Leydig cells
FSH
Sertoli cells
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Testosterone
Testis Sperm Production
Overview
FemaleA tAnatomyPhysiologyRelevance physiology to infertility treatment
MaleAnatomy
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yPhysiologyRelevance physiology to infertility treatment
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Stimulating sperm production in men, who lack gonadotrophins (Male hypogonadism)
Initial phase to raise serum testosteronehCG stimulation (because LH half life too short) forhCG stimulation (because LH half life too short) for LEYDIG CELLSInjections thrice weekly for few months
Then stimulate sperm productionThen also add FSH stimulation for SERTOLI CELLS
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Injections thrice weekly may take 6 months or longer
Conclusions
Although similarities exist between females and males there are big differencesand males, there are big differences
e.g. 1 oocyte vs over 10 billion sperm per month.
Understanding gonadotrophin physiology helps to plan optimal treatment of infertile couples
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couples.