Male Reproductive System PDF

Summary

This document provides an overview of the anatomy and physiology of the male reproductive tract. It discusses learning outcomes, the purpose of a reproductive system, development of testes and ovaries, the control of the reproductive system (neural and hormonal aspects). It covers topics including gross anatomy, histology, semen, spermatogenesis, hormones, and effects of testosterone.

Full Transcript

Anatomy & Physiology
of the
Male Reproductive Tract
RIZVI, Fahad
PHAS5001
LEARNING OUTCOMES
Describe the main anatomical features of the male
reproductive tract
Relate male anatomy to common clinical problems
Describe the main physiological functions of the male
reproductive system, including:
Hormonal regulation
Spermatogenesis
Male sexual response
 Why have a reproductive system?
In order to pass genetic information from generation to
generation.
The only body system not required to keep the BODY alive, but
required to keep the SPECIES alive.
Reproduction…
Is the process in which organisms
produce offspring by means of
germ cells called
Gametes
The produce gametes
andGonads
secrete the reproductive
hormones.
Female vs Male Anatomy
Development of
the testis and
ovaries
SRY gene encodes Testis
Determining Factor (TDF)

In the presence of TDF
testis will develop, and
testosterone from the
developing testis will
promote the development
of male external genitals.

In the absence of TDF,
ovaries will develop and
female genitals.
Development of
the testis and
ovaries

Males – Paramesonephric
tube will degenerate due to
Anti- mullerian hormone

Female – mesonephric will
degenerate and
paramesonephric remains
https://www.youtube.com/watch?v=hzjKRCU5Tq4
Development of the external genitals
 Neural
Control of the sexual act (Erection
and ejaculation)
Control of Sexual behaviour (in part)

the Hormonal
reproductiv Oestogen - FSH – LH – Testosterone
e system Development of reproductive
structures
Development of secondary sexual
characteristics (Body hair and
deepening voice)
Gametogenesis (Production of sperm
and egg)
Male Anatomy and Physiology
Sagital
Section
 Testes
Paired oval-shaped glands
Usually 4cm long and 2.5 cm Wide
Covered in a fibrous capsule tunica
albuginea
Outer layer is double layered tunica
vaginalis
Functional units are the seminiferous
tubules – found withing the lobules. In the
adult male, each testis may contain 300-
900 m of tubule...
It’s 1000 m from here to the train
station!
- Epithelial cells, columnar cells and
smooth muscle like myoid cells
Storage and maturation area (epididymis)
Testicles = Testes + epididymis + spermatic
chord
Gross anatomy
 Histolog Epididymis

y Tunica albuginea
Storage area

Fibroblasts
Myofibroblasts

Fibrous septa

Seminiferous tubules
Sperm production

Rete testis
Entrance to epididymi

Sagittal
section
Van Gieson
(collagen
Histolog
y BV

Septa

Transverse section, X 65
H&E (connective pink, nuclei
ST
purple) TA
Epididymis: Highly coiled. Nonmotile sperms are released into the epididymis as
move along the duct with fluid. Journey takes 20 days to become motile. Sperm
are ejaculated from here, if not, can be stored for several months. Epithelial cells
phagocytise the cells.
Ductus Deferens/Vas Deference: Is approx. 45 cm long. Runs upwards
from the epididymis to the pelvic cavity as part of the spermatic cord. Has
thick layer of stratified epithelium. It joins with the seminal gland and
makes…
Ejaculatory Duct: Enters the prostate and empties into the Urethra
Urethra: Terminal part that can carry both semen and urine –
(not together).
Spongy urethra = 15 cm and accounts for ¾ of the urethra –
Secreted mucus before ejaculation

Sagital
 Ductus (Vas) Deferens
Runs from tail of epididymis to ejaculatory duct
Smooth muscle - peristalsis
Vasectomy – ductus is ligated just distal to superficial
inguinal ring
 Seminal gland: Found on the surface of the bladder. The thick fibrous capsule layer
encloses smooth muscle cells that contact during ejaculation. Seminal fluid + sperm 
Ejaculatory duct  Urethra. Seminal fluid contains fructose, citric acid, coagulating
enzymes, prostaglandins + other substance to enhance sperm motility.
Prostate: Smooth muscle cells that contract during ejaculation and force
the prostatic secretions into the urethra. Fluid is a milky colour and allows
activation of sperms.
Bulbo-urethral glands: Pea sized gland located inferior to the
prostate. Produces thick mucus which drains into the urethra
which neutralises residual acidic urine and lubricates the penis
during ejaculation.

Sagital
Seminal Vesicles
2 x Accessory gland (~5cm long)
Develops as outgrowth of ductus deferens
Smooth muscle
Lies between bladder and rectum
Duct of seminal vesicle combines to join ductus
deferens to form: Ejaculatory duct
Seminal vesicles do not store sperm –they produce
alkaline fluid (~70-80% of ejaculate volume)
 Prostate
Fibromuscular(1/3) & glandular (2/3) ~ 20% seminal
fluid
Surrounds urethra
Lies between bladder and levator ani Prostatic
Closely related to the rectum utricle
Fibrou
(Digital Rectal Examination) s
Ejaculatory
Lymphatic drainage towards spinecapsu ducts x 2
le

Prostatic Urethral crest
Peripheral (PZ) ductules and sinus
Central (CZ)
Transitional (TZ)
Semen
Semen is a viscid whitish fluid of the male reproductive
tract consisting of spermatozoa suspended in secretions
of accessory glands
It consists of secretions from:
Spermatozoa from the Seminiferous tubules
Seminal vesicle fluid (50-70% volume)
Prostate fluid (20-30% volume)
Bulbourethral gland fluid (Cowper’s gland)
Normal ejaculation: 2-5ml
 Semen
It consists of secretions from:
Seminal vesicle fluid (50-70% volume)
Fructose for sperm to generate ATP for movement
Prostaglandins uterine contractility
Alkaline combat acid environment of FGT
Prostate fluid (20-30% volume)
PSA
Zinc
Citric acid and proteases to break down
semen clots
First coagulate and then decoagulate the
semen following ejaculation - temporary
thickening of semen helps retain it within
the female reproductive
Bulbourethral tract
gland fluid (Cowper’s gland)
Pre ejaculate - lubricant,
Clearing traces of acidic urine before
Glands and ducts… sperms journey

Sagital
Section
Spermatic Cord
Content and covering of the cord
described in 3’s:

1.Pampiniform plexus
2.Ductus deferens
3.Lymphatics

1.Testicular artery
2.Ductus deferens artery
3.Cremasteric artery

1.Genital nerve
2.Autonomic nerves
3.(Ilioinguinal nerve)
Testicle development
The testicle develops in a
retroperitoneal position

Gubernaculum -Testicle descends on
this fibrous cord
Processus vaginalis – fold of parieta
peritoneum.

The processus vaginalis is a
potential weak spot and is the
route taken by indirect inguinal
hernias
Inguinal Hernias
Indirect Direct
 Varicocele
https://www.ncbi.nlm.nih.gov/pubmed/28675168

Enlargement of testicular
venous pampiniform plexus
Increased testicular temp.
& oxidative stress
May impact on semen
quality
Some evidence that
surgical treatment can
restore fertility https://commons.wikimedia.org/wiki/File:Varicocele.png
Penis Corpus
cavernosum

Thin, relatively hairless
Corona
skin EUM
2 x corpus cavernosum Glans
1 x corpus spongiosum Corpus
spongiosum
Root = attached parts
Bulb

Hypospadias -
Congenital
defect
 Sexual stimuli: Touch/ sound / smell /
Erection emotional or mental activity
CNS responds by activating the parasympathetic nervous system

- Enlargement and stiffening of the penis
- Penis is flaccid when a male is not sexually aroused  arterioles
supplying to the erectile tissue are constricted

Erection of the penis is mediated through the parasympathetic
nervous system, and release of Nitric Oxide – a vasodilator
NO  relax SMC  blood vessel dilated erectile bodies fill with blood
Corpus cavernosa and spongiosum fills with blood, restricting veins.
 Ejaculatio
n

Ejaculation is mediated by the sympathetic nervous system via a
mass spinal reflex causing:
Constriction of the bladder sphincters muscle - preventing expulsion of
urine or reflux of semen into the bladder
Contraction of the ducts and glands – emptying substances into the
urethra
Contraction of the penis muscles to ‘shoot forth’ semen – speed up to
500 cm/s
Event or climax or orgasm  Resolution period (relaxation) – Unable to
achieve another orgasms for mintes during the latent or refractory period.
Male sexual response
Main phases of
male sexual
response

Ejaculati
Erection
on
Erectile Dysfunction
Failure to achieve or maintain an erection
Very common, ~50% men between 40-70 years old
Physical or psychological
Testosterone deficiency
Diabetes & Cardiovascular disease
Stress, performance anxiety
Certain drugs, e.g. SSRIs, antihypertensives, recreational
drugs
Sildenafil initially developed as a drug for angina
Relaxation of coronary arteries → increased blood flow →
pain relief
Spermatogenesis
Spermatogenesis
Sequence of events in the seminiferous tubules of the
testes that produces male gametes (sperm)
Begins around the age of 14 and continues throughout
life
Healthy adult male produces ~400 million sperm/day
Gamete formation involves meiosis
Unique type of nuclear formation that only occurs in the
gonads
Rate of spermatogenesis is determined by hormones
testosterone and FSH
Spermatogenesis

Spermatogenic cells

Epithelial cells

Tortora et al
Mitosis of Spermatogonia: Outer most
cells in contact with basal lamina are
spermatogonia stem cells. Divide by
mitosis until puberty.

Mitosis after puberty results in Type A
and Type B daughter cells. Type A
stays in the basal lamina and Type B
(makes 4 spem cells) become
primary spermatocyte at the lumen.

Meiosis of spermatocytes produces
spermatids. Primary spermatocyte
undergoes meiosis to make haploid
secondary spermatocytes which
produced spermatids by meoisis II.

Spermiogenesis: Elongation, shedding
cytoplasmic baggage and tail
formation for spermatids to produce
sperm cells/spermatazoa.
 Spermatogenesis
Cytoplasmic Bridges
Ensure sperm develop at the
same rate.

Tight Junctions
Stops immune system attacking
genetically different sperm

Sertoli Cells
Sperm development takes place
moving through the sertoli cells –
produce Inhibin and Androgen Binding
Protein
Hormones
Steroid Hormone Release is
Regulated by Negative Feedback
Hypothala
mus

GnR
H

Ant.
Pituitary
Gonadotro
phs
(FS L
H) H

Oestroge Gona Testoster
n d one

The principle is the hypothalamus – pituitary – gonad axis is
controlled by negative feedback
 The Hypothalamus–Pituitary Axis
Regulates Spermatogenesis
Hypothala
mus

GnR GnR
H H
Con
c.
Ant
60-90 min Pituitray

Gonadotro
FS L
phs
H H
GnRH is released in pulses every 60-90 min, throughout
the day, every day... (unlike women)
Testi Testoster
s one
This means that LH and FSH are also released in pulses.
Spermatoge
Appears to be critical in spermatogenesis – no pulses, nesis
no sperm
 Gonadotropin- releasing-hormone (GnRH)
released by the hypothalamus --> anterior
pituitary cells
GnRh controls the relase of Follicle
stimulating hormone (FSH) and luteinizing
FSH ad LH secreted into the blood
hormone (LH)
FSH causes the release of androgen binding
protein (ABP) from sustentocytes. ABP has a role
to maintaining a high testostrone level around the
spermatogenic cells.

LH causes further secretion of testosterone

Testosterone – enters the blood and allows
development of sex organs.
Increased level of testosterone brings about a
feedback look which inhibits GnRH release from
the hypothalamus.
Inhibin: protein hormone produced by
sustentocytes. Act as a baroreceptor – when
sperm count is high, more inhibin released –
inhibiting the pituitary gland releasing FSH and
hypothalamus releasing GnRH.

Tortora: Principles of human anatomy and physiology.
 Inhibin Inhibits FSH Release
A peptide hormone released by Sertoli cells
Hypothala
Sperm maturation is sufficient mus

Sertoli cells release inhibin GnR
inhibits FSH secretion by the anterior pituitary H

decreases sperm production Ant
Pituitray
Sperm maturation is proceeding too slowly
less inhibin is released by Sertoli cells Gonadotro
FS
phs
L
H H
more FSH will be secreted
sperm production will be increased Inhibi Testi Testoster
n s one

Spermatoge
nesis 44
Endocrine Regulation of Testis
Function
Testes are responsible for spermatogenesis and steroidgenesis.
FSH is critical for the initiation and first stages of
spermatogenesis
Testosterone is critical for spermatozoa maturation in epididymis
mediated via Sertoli cell secretion of Androgen Binding Protein
(ABP)

Androgens:
Testosterone and Dihydrotestosterone produced by Leydig cells
Ligands of the Androgen nuclear hormone receptor (AR)
Responsible for
Sexual differentiation and development (in utero)
Sexual maturation (puberty)
Maintenance of spermatogenesis (adulthood)
Effects of testosterone
Development of male primary and secondary sexual
characteristics
Primary: Secondary:
Enlargement / Hair growth and
differentiation of distribution
the male genitalia Skin texture
Ability to produce Changes in the
sperm cells larynx
Increased
metabolism
Skeletal muscle and
bone development