Hypothalamus Pituitary Axis.ppt
PaulineMakahamadze
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Mar 09, 2023
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About This Presentation
Physiology endocrine
Slide Content
Hypothalamus and the Pituitary
Gland
DrK. Nyatanga
Gland
DrK. Nyatanga
Objectives
•Describe the physiologic and anatomic
relationships between the
hypothalamus and pituitary.
•Identify the hypothalamic releasing
and inhibitory factors controlling the
secretion of each of the anterior
pituitary hormones.
•Know the posterior & anterior pituitary
hormones, their functions and
conditions that result from deficiency
and oversecretion
•Describe the physiologic and anatomic
relationships between the
hypothalamus and pituitary.
•Identify the hypothalamic releasing
and inhibitory factors controlling the
secretion of each of the anterior
pituitary hormones.
•Know the posterior & anterior pituitary
hormones, their functions and
conditions that result from deficiency
and oversecretion
Hypothalamus and pituitary
This consortium forms the most
complex and dominant portion of the
entire endocrine system
Output of this unit regulates the
function of the thyroid gland, adrenal
gland and also shares in control of
somatic growth, lactation, milk
secretion and water metabolism
This consortium forms the most
complex and dominant portion of the
entire endocrine system
Output of this unit regulates the
function of the thyroid gland, adrenal
gland and also shares in control of
somatic growth, lactation, milk
secretion and water metabolism
Hypothalamus and pituitary
Hypothalamic function
Plays a key role in the regulation of
pituitary function
It receives afferents from
◦Thalamus
◦Limbic system
◦reticular formation
◦Eyes
◦Neocortex
Plays a key role in the regulation of
pituitary function
It receives afferents from
◦Thalamus
◦Limbic system
◦reticular formation
◦Eyes
◦Neocortex
Pituitary gland
Embryological development of the pituitary
1.The hypophysis is an amalgam of two tissues.
2.Early in gestation a finger of ectoderm grows upward from the
roof of the mouth.
3.This protrusion is called Rathke's pouch and will develop into the
anterior pituitary or adenohypophysis.
4.Another finger of ectodermal tissue envaginates ventrally from the
developing brain.
5.This extension of the ventral brain will become the posterior
pituitary or neurohypophysis.
6.The two tissues grow into one another and become tightly
apposed
1.The hypophysis is an amalgam of two tissues.
2.Early in gestation a finger of ectoderm grows upward from the
roof of the mouth.
3.This protrusion is called Rathke's pouch and will develop into the
anterior pituitary or adenohypophysis.
4.Another finger of ectodermal tissue envaginates ventrally from the
developing brain.
5.This extension of the ventral brain will become the posterior
pituitary or neurohypophysis.
6.The two tissues grow into one another and become tightly
apposed
Anatomy
Anatomy
Pituitary lies in the sella turcica of
sphenoid bone below hypothalamus at
base of brain
Blood supply is from the superior and
inferior hypophyseal arteries
There is a portal system from the
median eminence
Pituitary has two lobes the anterior
and the posterior
Pituitary lies in the sella turcica of
sphenoid bone below hypothalamus at
base of brain
Blood supply is from the superior and
inferior hypophyseal arteries
There is a portal system from the
median eminence
Pituitary has two lobes the anterior
and the posterior
Anterior
pituitary/Adenohypophysis
Traditionally cells are divided into
chromophobes and chromophils
Chromophobes contain and secrete
IL6
Chromophils are further divided into
basophils and acidophils
Acidophils secrete GH and Prolactin
while basophils secrete ACTH, TSH,
LH, and FSH
Histology
pituitary/Adenohypophysis
Traditionally cells are divided into
chromophobes and chromophils
Chromophobes contain and secrete
IL6
Chromophils are further divided into
basophils and acidophils
Acidophils secrete GH and Prolactin
while basophils secrete ACTH, TSH,
LH, and FSH
Histology
Neuroendocrineroles
The neurohypophysis is an extension
of the hypothalamus.
◦neurohypophysis (posterior or neural
pituitary).
◦It composed of bundles of axons from
hypothalamic neurosecretory neurons
intermixed with glial cells.
2 hormones ADH and oxytocin are
synthesised in the hypothalamus, stored
and secreted by posterior pituitary
The neurohypophysis is an extension
of the hypothalamus.
◦neurohypophysis (posterior or neural
pituitary).
◦It composed of bundles of axons from
hypothalamic neurosecretory neurons
intermixed with glial cells.
2 hormones ADH and oxytocin are
synthesised in the hypothalamus, stored
and secreted by posterior pituitary
cntd
Close connections with the ANS allow
coordination btwn ANS and pituitary
function
Therefore pituitary function can be
influenced by pain, sleep, emotion,
light and possibly thought
HP axis is under the influence of blood
borne substances and neural input
Close connections with the ANS allow
coordination btwn ANS and pituitary
function
Therefore pituitary function can be
influenced by pain, sleep, emotion,
light and possibly thought
HP axis is under the influence of blood
borne substances and neural input
Hypophysiotropichormones
These are hormones secreted by the
hypothalamus which influence pituitary
function
They are either releasing or inhibiting
factors
The hormones include CRH, TRH,
GHRH, GnRH, Dopamine, serotonin
These are hormones secreted by the
hypothalamus which influence pituitary
function
They are either releasing or inhibiting
factors
The hormones include CRH, TRH,
GHRH, GnRH, Dopamine, serotonin
Anterior pituitary is exposed to higher
concentration of these hormones than
blood
Most are peptides except dopamine
It was once believed that each factor
was responsible for release of one
pitiutary hormone.
However, this is not the case
concentration of these hormones than
blood
Most are peptides except dopamine
It was once believed that each factor
was responsible for release of one
pitiutary hormone.
However, this is not the case
TRH increases prolactin release and
somatostatin can inhibit release of
TSH in addition to GH
Dopamine (PIF) inhibit prolactin
secretion
somatostatin can inhibit release of
TSH in addition to GH
Dopamine (PIF) inhibit prolactin
secretion
Hypothalamic Pituitary Axis
Posterior Pituitary
Post Pituitary
It is responsible for secretion of
vasopressin and oxytocin
These are nonapeptides or
octapeptides depending on whether
cysteine or cystine is considered
The structures of the two hormones
are similar, with 2 different amino acid
residues
They are synthesised in the
hypothalamus
It is responsible for secretion of
vasopressin and oxytocin
These are nonapeptides or
octapeptides depending on whether
cysteine or cystine is considered
The structures of the two hormones
are similar, with 2 different amino acid
residues
They are synthesised in the
hypothalamus
Post Pituitary
Vasopressin is synthesised mainly in
the SON and oxytocin is synthesised
mainly in the PVN, although both
nuclei produce each hormone
Due to the similarity in structure
vasopressin has 20% of the activity of
oxytocin and oxytocin has 0.5% to 1%
of the activity of vasopressin
Vasopressin is synthesised mainly in
the SON and oxytocin is synthesised
mainly in the PVN, although both
nuclei produce each hormone
Due to the similarity in structure
vasopressin has 20% of the activity of
oxytocin and oxytocin has 0.5% to 1%
of the activity of vasopressin
Argininevasopressin and
oxytocin
oxytocin
What would happen to the
secretion of posterior pituitary
hormones if there was
transectionof the connection
between the hypothalamus and
pituitary gland?
secretion of posterior pituitary
hormones if there was
transectionof the connection
between the hypothalamus and
pituitary gland?
Argininevasopressin(ADH)
Basically involved in the regulation of
water balance and blood pressure
Acts on 3 receptors V1 (V1a, V1b), V2
and (V3)
V2 is through the mediation of cAMP
and V1 (IP3 and DAG)
Basically involved in the regulation of
water balance and blood pressure
Acts on 3 receptors V1 (V1a, V1b), V2
and (V3)
V2 is through the mediation of cAMP
and V1 (IP3 and DAG)
Physiological effects of ADH
Increases permeability of collecting
ducts to water
Increases urea reabsorption in the
inner medullary collecting duct
Increase sodium absorption in TAL by
activating the NaK-
2Cl transporter
Increases permeability of collecting
ducts to water
Increases urea reabsorption in the
inner medullary collecting duct
Increase sodium absorption in TAL by
activating the NaK-
2Cl transporter
Physiological effects of ADH
Vasoconstriction
Increases glycogenolysis in the liver
Depresses the cardiovascular centres
Increases ACTH secretion from
corticotrophes (stress)
Increases synthesis of factor VIII and
vWF
Vasoconstriction
Increases glycogenolysis in the liver
Depresses the cardiovascular centres
Increases ACTH secretion from
corticotrophes (stress)
Increases synthesis of factor VIII and
vWF
Increasing permeability of
collecting ducts to water
Through V2 receptors(cAMP)
Involves insertion of water channels in
the luminal membrane known as
aquaporins
There are several types of aquaporins:
1, 2, 3, 6 and 7 are found in the
kidney, 4 in the brain and 5 in salivary
glands
Vasopressin acts to increase the
concentration of aquaporin 2 on
membranes
collecting ducts to water
Through V2 receptors(cAMP)
Involves insertion of water channels in
the luminal membrane known as
aquaporins
There are several types of aquaporins:
1, 2, 3, 6 and 7 are found in the
kidney, 4 in the brain and 5 in salivary
glands
Vasopressin acts to increase the
concentration of aquaporin 2 on
membranes
Stimuli which increase the
secretion of vasopressin
Increased osmotic pressure of
plasma
Decreased ECF volume(at least
20 %), (via cardiopulmonary
receptors)
Angiotensin II,
Pain, emotion,stress
secretion of vasopressin
Increased osmotic pressure of
plasma
Decreased ECF volume(at least
20 %), (via cardiopulmonary
receptors)
Angiotensin II,
Pain, emotion,stress
Stimuli which increase the
secretion of vasopressin include
Nausea and vomiting
Standing,
Adrenergic stimuli
Nicotine,
Morphine,
Carbamazepine
Exercise
secretion of vasopressin include
Nausea and vomiting
Standing,
Adrenergic stimuli
Nicotine,
Morphine,
Carbamazepine
Exercise
Stimuli which increase the
secretion of vasopressin include
secretion of vasopressin include
Factors decreasing secretion
Decreased effective osmotic pressure
Increased ECF volume
Alcohol
Parasympathetic innervation
Stretching of the atrial baroreceptors
Atrial natriuretic peptide
Clonidine
Haloperidol
Decreased effective osmotic pressure
Increased ECF volume
Alcohol
Parasympathetic innervation
Stretching of the atrial baroreceptors
Atrial natriuretic peptide
Clonidine
Haloperidol
Clinical Correlates
Excess ADH leads to SIADH
Insufficient ADH leads to Diabetes
Insipidus
Excess ADH leads to SIADH
Insufficient ADH leads to Diabetes
Insipidus
Syndrome of Inappropriate ADH
secretion (SIADH)
Due to inappropriately elevated ADH
that cause water retention in excess of
Na+
Excess water causes dilutional
hyponatremia
secretion (SIADH)
Due to inappropriately elevated ADH
that cause water retention in excess of
Na+
Excess water causes dilutional
hyponatremia
Causes of SIADH
Malignancy eglung ,
gastrointestinal,renal
Trauma –head injury , post surgery
Cerebrum diseases eginfections like
meningitis
Stimulation of volume receptors like in
artificial ventilation
Drug induced eg
thiazides,chlorpropamide
Infections egpneumonia
Malignancy eglung ,
gastrointestinal,renal
Trauma –head injury , post surgery
Cerebrum diseases eginfections like
meningitis
Stimulation of volume receptors like in
artificial ventilation
Drug induced eg
thiazides,chlorpropamide
Infections egpneumonia
(SIADH)
Diseases in the lung also decrease
tonic inhibition of ADH secretion
leading to an increase in ADH
secretion
This will result in hyponatremia
Excessive ECF volume will be lowered
by the ‘escape phenomenon’
It is treated using demeclocycline
Diseases in the lung also decrease
tonic inhibition of ADH secretion
leading to an increase in ADH
secretion
This will result in hyponatremia
Excessive ECF volume will be lowered
by the ‘escape phenomenon’
It is treated using demeclocycline
Features of the syndrome
Hyponatremia (Na+ < 135 mmol/L)
Hypotonicity ( osmolality
<280moSm/kg )
Urine osmolality (>100moSm/kg)
Increased urinary Na+
excretion(>40mmol/L)
Hyponatremia (Na+ < 135 mmol/L)
Hypotonicity ( osmolality
<280moSm/kg )
Urine osmolality (>100moSm/kg)
Increased urinary Na+
excretion(>40mmol/L)
Diabetes Insipidus
Is due to deficient secretion of ADH
The symptoms are polyuria and
polydipsia
It can be neurogenic or nephrogenic
Is due to deficient secretion of ADH
The symptoms are polyuria and
polydipsia
It can be neurogenic or nephrogenic
NephrogenicDI
One interesting form of this condition is
inherited X –Linked receessive
Gene for V2 is located on the X
chromosome
It can also be due to lithium or
hypercalcemia or hypokalemia
It does not respond to desmopressin (a
vasopressin analogue)
It can be treated using thiazide diuretics
One interesting form of this condition is
inherited X –Linked receessive
Gene for V2 is located on the X
chromosome
It can also be due to lithium or
hypercalcemia or hypokalemia
It does not respond to desmopressin (a
vasopressin analogue)
It can be treated using thiazide diuretics
NephrogenicDI
It can be treated using thiazide
diuretics
How do thiazides act???
It can be treated using thiazide
diuretics
How do thiazides act???
Oxytocin
Is derived from oxy-meaning rapid
and tocia meaning labour
Acts on oxytocin receptors(PLC)
which uses Ca ++ as a second
messenger
Is derived from oxy-meaning rapid
and tocia meaning labour
Acts on oxytocin receptors(PLC)
which uses Ca ++ as a second
messenger
Actions of Oxytocin
On the mammary gland: it is important for
the milk let down reflex
Augmentation of labour by increasing
uterine contractions
Ejaculation in males
May be involved in luteolysis
May be responsible for propulsion of
sperms in the female during or after
intercourse
On the mammary gland: it is important for
the milk let down reflex
Augmentation of labour by increasing
uterine contractions
Ejaculation in males
May be involved in luteolysis
May be responsible for propulsion of
sperms in the female during or after
intercourse
Secretion can be increased by
Suckling
Stimulation of female external
genitalia and cervix
Thought of the baby, (tender thoughts)
Cervical dilatation
Suckling
Stimulation of female external
genitalia and cervix
Thought of the baby, (tender thoughts)
Cervical dilatation
Pregnancy
Progesterone decreases synthesis of
oxytocin receptors
Towards labour estrogen increases
the synthesis of oxytocin receptors in
the myometrium
Progesterone decreases synthesis of
oxytocin receptors
Towards labour estrogen increases
the synthesis of oxytocin receptors in
the myometrium
Side effects of oxytocinoverdose
Water intoxication
Neonatal jaundice
Uterine overstimulation-uterine rupture
Hypotension (transient)
Water intoxication
Neonatal jaundice
Uterine overstimulation-uterine rupture
Hypotension (transient)
Secretion decreased by
Pain or physical discomfort
Breast feeding under embarrassing
circumstances
Fear and anger
Pain or physical discomfort
Breast feeding under embarrassing
circumstances
Fear and anger
Clinical correlates
Deficiency of this hormone has no
known problems
Deficiency of this hormone has no
known problems
Anterior Pituitary
Hormones secreted by the gland
appear to divide into 3 groups
A) ACTH Related peptides
e.g. ACTH, B endorphin, B
Lipotropin , B MSH
B) Glycoproteins
eg FSH, TSH and LH
C) Somatomammotropins
Hormones secreted by the gland
appear to divide into 3 groups
A) ACTH Related peptides
e.g. ACTH, B endorphin, B
Lipotropin , B MSH
B) Glycoproteins
eg FSH, TSH and LH
C) Somatomammotropins
Glycoproteins
They have two subunits an alpha and
beta
Alpha subunits are identical or closely
similar and they do not have biological
activity
Beta chains confer hormone specificity
Beta chains alone have little biological
activity
They have two subunits an alpha and
beta
Alpha subunits are identical or closely
similar and they do not have biological
activity
Beta chains confer hormone specificity
Beta chains alone have little biological
activity
c) Somatomammotropins
Prolactin
GH
Prolactin
GH
Growth Hormone
GH
Secreted by somatomammotrophs of
pituitary
Wide range of metabolic activity which
may involve every type of cell
Some of its effects are mediated by
somatomedins
GH release is controlled by GHRH
and GHIH (somatostatin)
Secreted by somatomammotrophs of
pituitary
Wide range of metabolic activity which
may involve every type of cell
Some of its effects are mediated by
somatomedins
GH release is controlled by GHRH
and GHIH (somatostatin)
GH secretion rate reflects
Metabolic requirements (decreased
glucose, increased Aas)
Neural factors (eg stress, circadian
rhythms)
Metabolic requirements (decreased
glucose, increased Aas)
Neural factors (eg stress, circadian
rhythms)
Structure
Gene for GH is on chr 17
hGH has intrinsic lactogenic activity
GH is bound to a protein in plasma
that is a large fragment of EC domain
of receptors
Concentration of fragment is an index
of number of GH receptor in the
tissues
About half of GH is protein bound and
the T1/2 is 6 –20 mins
Gene for GH is on chr 17
hGH has intrinsic lactogenic activity
GH is bound to a protein in plasma
that is a large fragment of EC domain
of receptors
Concentration of fragment is an index
of number of GH receptor in the
tissues
About half of GH is protein bound and
the T1/2 is 6 –20 mins
Effects of GH
In liver
◦RNA synthesis is increased
◦Increased protein synthesis
◦Increased gluconeogenesis, glycogenolysis
◦Increased somatomedin
◦In Adipose tissue
◦Decreased glucose uptake
◦Increased lipolysis; hence decreased adiposity
In liver
◦RNA synthesis is increased
◦Increased protein synthesis
◦Increased gluconeogenesis, glycogenolysis
◦Increased somatomedin
◦In Adipose tissue
◦Decreased glucose uptake
◦Increased lipolysis; hence decreased adiposity
In Muscle
Decreased glucose uptake
Increased amino acid uptake
Increased protein synthesis
Anti insulin effect in muscle
Increased lean body mass
Increased calcium absorption in
Gastrointestinal tract and decreased
sodium and potassium excretion in
kidney
Decreased glucose uptake
Increased amino acid uptake
Increased protein synthesis
Anti insulin effect in muscle
Increased lean body mass
Increased calcium absorption in
Gastrointestinal tract and decreased
sodium and potassium excretion in
kidney
Somatomedins
Polypeptide growth factors secreted
by liver and other tissues
Principal circulating somatomedins are
-IGF I (somatomedin C)
-IGF II
They are closely related to insulin but
C chains are not separated
Polypeptide growth factors secreted
by liver and other tissues
Principal circulating somatomedins are
-IGF I (somatomedin C)
-IGF II
They are closely related to insulin but
C chains are not separated
Somatomedins (cont.)
There are 6 binding proteins
IGF I is mainly bound to IGFBP 3
(95%).
GH increases synthesis of this protein
The protein directs IGF to their
specific receptors
IGF receptor is similar to that of insulin
IGFs are essential for embyronic
development
There are 6 binding proteins
IGF I is mainly bound to IGFBP 3
(95%).
GH increases synthesis of this protein
The protein directs IGF to their
specific receptors
IGF receptor is similar to that of insulin
IGFs are essential for embyronic
development
Effects of Somatomedins
Increase protein sythesis
Increase RNA synthesis
Increase DNA synthesis
Increase cell size and number
This leads to increased organ size and
function
Increase protein sythesis
Increase RNA synthesis
Increase DNA synthesis
Increase cell size and number
This leads to increased organ size and
function
Effects on chrondrocytes
Increased amino acid uptake
Increase protein synthesis
Increase RNA synthesis
Increase DNA synthesis
Increase collagen
Increase chrondoiton sulfate
Increase cell size and number
This increases linear growth
Increased amino acid uptake
Increase protein synthesis
Increase RNA synthesis
Increase DNA synthesis
Increase collagen
Increase chrondoiton sulfate
Increase cell size and number
This increases linear growth
Other effects of
Somatomedins
Stimulate neuronal survival
Stimulate myelin synthesis
Somatomedins
Stimulate neuronal survival
Stimulate myelin synthesis
Control of GH release
Stimulation
◦Glucose and free fatty acid decrease
◦Increase in amino acids
◦Fasting and prolonged caloric deprivation
◦Deep sleep
◦Exercise
Stimulation
◦Glucose and free fatty acid decrease
◦Increase in amino acids
◦Fasting and prolonged caloric deprivation
◦Deep sleep
◦Exercise
Cntd
Estrogens and androgens
Dopamine and serotonin
Alpha adrenergic agonists
Enkephalins
Stress (due to pain, surgery,
psychogenic)
Estrogens and androgens
Dopamine and serotonin
Alpha adrenergic agonists
Enkephalins
Stress (due to pain, surgery,
psychogenic)
Inhibition
Glucose increase
Free fatty acid increase
Cortisol
Obesity
Pregnancy
Somatostatin
hGH
Glucose increase
Free fatty acid increase
Cortisol
Obesity
Pregnancy
Somatostatin
hGH
Control of GH secretion
Physiology of growth
Growth is a complex process
It is also affected by thyroid hormones,
insulin, glucocorticoids, nutrition and
genetic factors
Growth is a complex process
It is also affected by thyroid hormones,
insulin, glucocorticoids, nutrition and
genetic factors
Role of nutrition
Food supply is the most important
extrinsic factor affecting growth
A diet should be adequate in proteins,
vitamins and calories
Fasting and protein deprivation
decreases IGF secretion
Age at which deficiency occurs is of
importance
Food supply is the most important
extrinsic factor affecting growth
A diet should be adequate in proteins,
vitamins and calories
Fasting and protein deprivation
decreases IGF secretion
Age at which deficiency occurs is of
importance
Growth Periods
In humans there are two periods of rapid
growth which are
i) Infancy and
ii) Late puberty before growth stops
The 2
nd
growth spurt is due to GH, sex
hormones, and cessation of growth due to
closure of epiphyses
Sex hormones increase spikes of IGF I
release
In humans there are two periods of rapid
growth which are
i) Infancy and
ii) Late puberty before growth stops
The 2
nd
growth spurt is due to GH, sex
hormones, and cessation of growth due to
closure of epiphyses
Sex hormones increase spikes of IGF I
release
In infants there is episodic growth
Thyroid hormones are critical during
this period
Thyroid hormones potentiate the
action of IGF I and are permissive to
the effects of GH.
They are necessary for normal GH
secretion
Thyroid hormones are critical during
this period
Thyroid hormones potentiate the
action of IGF I and are permissive to
the effects of GH.
They are necessary for normal GH
secretion
Insulin is also important for growth.
When deficient, IGF I secretion is
decreased
Adrenocortical hormones other than
androgens have a permissive effect
on growth
However, Glucocorticoid treatment
can slow or stop growth in children
When deficient, IGF I secretion is
decreased
Adrenocortical hormones other than
androgens have a permissive effect
on growth
However, Glucocorticoid treatment
can slow or stop growth in children
Catch Up Growth
In periods of severe stress like
illnesses children do not grow
They will be below the expected
averages compared to peers of the
same age
They will, after they recover,
experience a period of growth which is
greater than average to catch up with
their peers –catch up growth
In periods of severe stress like
illnesses children do not grow
They will be below the expected
averages compared to peers of the
same age
They will, after they recover,
experience a period of growth which is
greater than average to catch up with
their peers –catch up growth
Short Stature
Short stature can be due to
i) GHRH deficiency
ii) GH deficiency
iii) Deficient secretion of IGF I
iv) Other causes
Isolated GH deficiency is usually due
to deficient GHRH
Short stature can be due to
i) GHRH deficiency
ii) GH deficiency
iii) Deficient secretion of IGF I
iv) Other causes
Isolated GH deficiency is usually due
to deficient GHRH
Laron Dwarfs
Is due to GH insensitivity due to loss
of function mutation in the receptor
The plasma IGF I and IGFBP 3 are
decreased, while the concentration of
GH is either normal or increased
Is due to GH insensitivity due to loss
of function mutation in the receptor
The plasma IGF I and IGFBP 3 are
decreased, while the concentration of
GH is either normal or increased
African Pygmies
They have a normal GH level and a modest
decrease in plasma level of GHBP
Plasma [IGF I] fails to increase at the time
of puberty
However, they experience less growth than
non pygmy controls throughout the pre
pubertal period
Explanation for short stature is still
unsettled
They have a normal GH level and a modest
decrease in plasma level of GHBP
Plasma [IGF I] fails to increase at the time
of puberty
However, they experience less growth than
non pygmy controls throughout the pre
pubertal period
Explanation for short stature is still
unsettled
Other Causes of short stature
Cretinism
Precocious Puberty
Gonadal dysgenesis (Turner’s
Syndrome)
Chronic abuse and neglect can cause
dwarfism (Psychosocial dwarfism –
Kasper Hauser Syndrome)
Achondroplasia
Cretinism
Precocious Puberty
Gonadal dysgenesis (Turner’s
Syndrome)
Chronic abuse and neglect can cause
dwarfism (Psychosocial dwarfism –
Kasper Hauser Syndrome)
Achondroplasia
Achondroplasia
It is the most common form of
dwarfism in humans
It is characterised by short limbs and a
normal trunk
It is inherited Autosomal Dominant
with complete penetrance
It is due to a mutation that codes for
fibroblast growth factor receptor 3
(FGFR3)
It is the most common form of
dwarfism in humans
It is characterised by short limbs and a
normal trunk
It is inherited Autosomal Dominant
with complete penetrance
It is due to a mutation that codes for
fibroblast growth factor receptor 3
(FGFR3)
Achondroplasia
Prolactin
Prolactin
Is a hormone principally concerned
with stimulating breast development
and milk production
It is secreted by acidophils and it has
receptors which resemble those for
GH
It is unique in that it is under
predominant inhibition from the
hypothalamus by dopamine
Is a hormone principally concerned
with stimulating breast development
and milk production
It is secreted by acidophils and it has
receptors which resemble those for
GH
It is unique in that it is under
predominant inhibition from the
hypothalamus by dopamine
Control of Secretion
Secretion is stimulated by
◦Sleep
◦Nursing
◦Breast stimulation in non lactating women
◦Stress
◦Hypoglycemia
◦Exercise
Secretion is stimulated by
◦Sleep
◦Nursing
◦Breast stimulation in non lactating women
◦Stress
◦Hypoglycemia
◦Exercise
cntd
Pregnancy
TRH (hypothyroidism)
Estrogens
Sexual intercourse in women
Histamine antagonists (H2) eg
cimetidine
-Dopamine antagonists
Pregnancy
TRH (hypothyroidism)
Estrogens
Sexual intercourse in women
Histamine antagonists (H2) eg
cimetidine
-Dopamine antagonists
Factors decreasing secretion
Dopamine
L Dopa
Apomorphine
Bromocriptine and related ergot
derivatives
Prolactin
Dopamine
L Dopa
Apomorphine
Bromocriptine and related ergot
derivatives
Prolactin
Effects of Prolactin
Stimulating breast development (done
in concert with other hormones like
estrogens, progesterone, cortisol, GH)
Causes milk production secretion from
breast after estrogen and
progesterone priming (increases
synthesis of casein and lactalbumin)
Inhibits action of gonadotropins
Stimulating breast development (done
in concert with other hormones like
estrogens, progesterone, cortisol, GH)
Causes milk production secretion from
breast after estrogen and
progesterone priming (increases
synthesis of casein and lactalbumin)
Inhibits action of gonadotropins
Effects of prolactin
dysfunction
In women prolactin deficiency
produces an inability to lactate
Hypersecretion of prolactin causes
hyperprolactenemia
dysfunction
In women prolactin deficiency
produces an inability to lactate
Hypersecretion of prolactin causes
hyperprolactenemia
Hyperprolactinemia
Is caused by chromophobe adenoma,
damage to pituitary stalk and tumors
secreting prolactin
It is characterised by
◦Loss of menses, decreased libido
◦Anovulation
◦Infertility and less often
◦Galactorrhea (lactation unassociated with
pregnancy).
◦Gynecomastia is uncommon
Is caused by chromophobe adenoma,
damage to pituitary stalk and tumors
secreting prolactin
It is characterised by
◦Loss of menses, decreased libido
◦Anovulation
◦Infertility and less often
◦Galactorrhea (lactation unassociated with
pregnancy).
◦Gynecomastia is uncommon
Excessive production of GH
Leads to either gigantism or
acromegaly
Gigantism occurs when there is an
excessive secretion before epiphyses
close and acromegaly occurs after
epiphyseal closure
Is usually due to microadenomas of
the GH secreting cells in the pituitary
Leads to either gigantism or
acromegaly
Gigantism occurs when there is an
excessive secretion before epiphyses
close and acromegaly occurs after
epiphyseal closure
Is usually due to microadenomas of
the GH secreting cells in the pituitary
Acromegaly-features
Enlarged hands and feet (spade like
hands)
Prognathism,coarse facial features,
bulbous nose, prominent bony ridges
Hirsutism
-Gynecomastia and lactation
Osteoarthritic vertebral changes
Enlarged hands and feet (spade like
hands)
Prognathism,coarse facial features,
bulbous nose, prominent bony ridges
Hirsutism
-Gynecomastia and lactation
Osteoarthritic vertebral changes
Visual field changes (bitemporal
hemianopia)
Carpal tunnel syndrome
Glucose intolerance
Proximal myopathy
Cardiac failure (and also ischemia)
hemianopia)
Carpal tunnel syndrome
Glucose intolerance
Proximal myopathy
Cardiac failure (and also ischemia)
B MSH, B Lipotropin
Function of B lipotrophin is unsettled
but it may be for mobilisation of fats
MSH is important for skin
pigmentation
It increases synthesis of melanin
It is under the control of hypothalamus
via MIF
ACTH can also cause skin
pigmentation
Function of B lipotrophin is unsettled
but it may be for mobilisation of fats
MSH is important for skin
pigmentation
It increases synthesis of melanin
It is under the control of hypothalamus
via MIF
ACTH can also cause skin
pigmentation
Pituitary Hyperfunction
Acromegaly
Cushing’s Syndrome (Nelson’s
syndrome –tumors secreting ACTH)
Hyperprolactenemia
Tumors secreting other anterior
pituitary hormones are rare
Acromegaly
Cushing’s Syndrome (Nelson’s
syndrome –tumors secreting ACTH)
Hyperprolactenemia
Tumors secreting other anterior
pituitary hormones are rare
Pituitary Insufficiency
It is usually caused by tumors of
anterior pituitary and suprasellar cysts
Pituitary infarction can also lead to
pituitary insufficiency (Sheehan’s
syndrome, hemorrhagic fevers)
It is usually caused by tumors of
anterior pituitary and suprasellar cysts
Pituitary infarction can also lead to
pituitary insufficiency (Sheehan’s
syndrome, hemorrhagic fevers)
Clinical Features
It is characterised by
◦Growth inhibition
◦Hypothyroidism
◦Hypogonadism
◦Inability to cope with stress
◦Pallor
It is characterised by
◦Growth inhibition
◦Hypothyroidism
◦Hypogonadism
◦Inability to cope with stress
◦Pallor
Other Anterior Pituitary
Hormones
Regulate the function of peripheral
glands
i) TSH –thyroid gland
ii) ACTH –adrenal cortex
iii) Gonadotropins –Gonads
These will be covered in subsequent
lectures
Hormones
Regulate the function of peripheral
glands
i) TSH –thyroid gland
ii) ACTH –adrenal cortex
iii) Gonadotropins –Gonads
These will be covered in subsequent
lectures
3/9/2023 98
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