Endocrine System - PDF

Summary

These notes provide an introduction to the endocrine system, covering glands such as the pituitary, pineal, adrenal, thyroid, parathyroid, and endocrine pancreas. The document also details the various functions and regulation of these glands and hormones.

Full Transcript

 Introduction
 Endocrine glands
1. Pituitary
2. Pineal
3. Adrenal
4. Thyroid
5. parathyroid
6. Endocrine pancreas
 Together the nervous & endocrine systems
coordinate functions of all body systems
1. The nervous system controls body actions
through nerve impulses ( rapid responses )
EX. causes muscles to contract or glands to
secrete
2. The endocrine system controls body activities
by releasing hormones ( slow & diffused effect)
EX. altering metabolism, regulating growth &
development, and influencing reproductive
processes
  Ductless glands that produce & release hormones into the
extracellular space through diffusion

 The hormones have different pathways to exert their action

The hormones may:
 Enter the blood stream to reach their target organs (endocrine)
 Or may affect nearby cells (paracrine )
 Or acts on the same cell that produced it (autocrine)

Endocrine
Endocrine
glands
Release Hormones Paracrine

Autocrine
  Cells must have specific membrane or
intracellular receptors to which hormones
can bind

 Are chemical signals
that are secreted by the
endocrine cells to
regulate the metabolic
functions of other cells (
target cells )
 Amino acid based : EX. Thyroid &
adrenomedullary hormones
 Protein & peptide : EX. all other hormones
 Steroids derived from cholesterol EX. Sex
hormones ( testosterone, progesterone,
estrogen) & adrenocortical hormones

* Endocrine glands derived from
mesoderm produce steroid hormones;
those derived from ectoderm or
endoderm produce amines, peptides,
or protein hormones
 Water-soluble hormones (all amino acid-based
hormones except thyroid hormone) exert their effects
by activating plasma membrane receptors,
intracellular second messenger is released
 Lipid-soluble hormones (steroids and thyroid hormone)
diffuse into the cell, bind to intracellular receptors,
migrate to the nucleus, and alter the gene expression
 Most hormone synthesis and release is regulated
through negative feedback mechanisms
 Endocrine gland stimuli may be humoral, neural, or
hormonal
 The major endocrine glands
 Pituitary gland
 Pineal body
 Thyroid gland
 Parathyroid gland
 Adrenal gland
 Endocrine component of Glands endocrine tissue
constitutes only part of the parenchyma of the organ
 Pancreas & kidneys
 ovaries & testes
 Diffuse Neuroendocrine cells Small groups or individual
endocrine cells found in a variety of other organs, e.g.
GIT & kidneys
 Capsule

Stroma Septa

Histological Reticular
organization fibers

Cells of the
Parenchyma
gland
 Endocrine cells are all specialized for secretion
 Their specific appearance depends on the
nature of the secretory product & on the cellular
machinery need to manufacture and store that
product (peptide or steroid)
 Endocrine cells are commonly arranged into
cords or groups
 The cells are closely associated with fenestrated
capillaries
 The hypothalamus is the major integrating link
between the nervous and endocrine systems
 It oversees many internal body conditions

 It receives nervous stimuli
from receptors throughout
the body
 the hypothalamus
stimulates cellular activity
in various parts of the body
by directing and
regulating the release of
hormones from the
pituitary gland
Hypophysis (under growth)
Location: in the sella turcica of the sphinoid bone
in the base of the skull
 It has 2 subdivisions, which develop from different
embryologic sources (dual origin):

1. Adenohypophysis develops from an evagination
(out pocketing) of the oral ectoderm (Rathke's
pouch) of the roof of the primitive mouth or
stomodium

2. Neurohypophysis develops from neural
ectoderm as a down growth of the floor of
diencephalon
1. Anterior pituitary (adenohypophysis) :
Consists of :
1. Pars distalis (or the anterior lobe)
2. Pars tuberalis
3. Pars intermedia
2. Posterior pituitary (neurohypophysis) :
Consists of :
1. Pars nervosa
2. Infundibulum with its stalk attached to the
hypothalamus at the median eminence
 two groups of vessels
coming off the internal
carotid artery
1. The superior
hypophyseal arteries
supply the median
eminence and the
infundibular stalk
2. The inferior
hypophyseal arteries
provide blood mainly for
the neurohypophysis, with
a small supply to the stalk
 The superior hypophyseal arteries form a primary
capillary network irrigating the stalk and median
eminence
 The capillaries then rejoin to form venules that
branch again as a larger secondary capillary
network in the adenohypophysis (pars distalis )
1. Vascular connection : with the anterior pituitary
 Occurs through releasing & inhibiting hormones
produced by neurons of the hypothalamus
( neurosecretory cells of dorsal medial, ventral
medial & infundibular nuclei)

 These hormones released into the primary plexus
and transported through hypophyseal portal veins
to the secondary plexus that supplies the anterior
pituitary
2. Neural connection with the posterior pituitary
 occurs through hormones produced by the cell
bodies of the neurosecretory cells ( Supraoptic
& paraventricular nuclei )

 These hormones are packaged in vesicles &
transported through the axon (hypothalamo-
hypophyseal tract), and stored in the axon
terminals that lie in the posterior pituitary
 Develops from Rathke's pouch, a
diverticulum of the oral ectoderm
 The adenohypophysis consists of:
1. Pars distalis
2. Pars intermedia
3. Pars tuberalis
 accounts for 75% of the adenohypophysis
 covered by a thin fibrous capsule

 The main components are:
1. Cords (groups)of epithelial cells
2. Fenestrated sinusoidal capillaries
3. Fibroblasts which produce reticular fibers for
support
Based on staining affinity the cells are 2 groups:
1. Chromophils
2. Chromophobes
 Represents 48% of the cells in pars distalis
Are secretory cells in which hormone is stored in
cytoplasmic granules
Larger & more dense stained cytoplasm

Are of 2 groups according to
their affinity to acidic or
basic dyes:
1. Acidophils : smaller , 37%,
granules stain orange-red
with eosin
2. Basophils : larger , 11%,
granules stain blue with
basic dyes
 Acidophils Basophils

 Subtypes of basophilic
& acidophilic cells are Somatotropic Thryrotropic
identified by
transmission EM or by
immunohistochemistry
and are named for
Mamotropic Gonadotropic
their specific
hormones or target
cells

Corticotropic
Somatotrophs
Secrete STH somatotropin(or growth
hormone GH)
Increase cellular metabolic rates
Target all body tissues (bone, muscles, liver
& adipose )

Mamotrophs
Secrete prolactin
Stimulate breast development & milk
secretion
Thryrotrophs
Secrete TSH(Thyroid stimulating hormone)

Gonadotrophs
Secrete FSH (Follicle-stimulating
hormone)stimulate growth of ovarian
follicles in females & spermatogenesis in
males
LH (luteinizing hormone OR interstitial cell-
stimulating hormone (ICSH); Leydig cells in
male & corpus luteum in female
Corticotrophs
Secrete ACTH (Adrenal corticotropin )
lipotrophin (lipid metabolism)
 Hormones & their
target tissues(cells)
 *Most of hormones secreted by
hypothalamus and anterior pituitary are
tropic hormones
*Tropic hormones are the hormones
that act on other endocrine glands (as
their target) to control the release of
their hormones

 Over production :
 In childhood ; before puberty leads to
gigantism (overgrowth of all bones)
 After puberty leads to acromegally ( over
growth of terminal portions of bones )

 Difficient production :
Leads to dwarfism
 Stain weakly
 Few or no secretory granules
 Represent a heterogeneous group,
including stem & undifferentiated progenitor
cells & any degranulated cells present
 Controlled primarily by hormones produced
by specialized neurons in hypothalamic
nuclei
 Most of these hormones are hypothalamic-
releasing hormones (five hormones, one for
each subtype of secretory cells )
 Two are hypothalamic-inhibiting hormones
for acidophilic cells ( somatotrophs &
mamotrophs )
 Negative feedback by hormones from the
target organs on secretion of the relevant
hypothalamic factors & on hormone
secretion by the relevant pituitary cells
 Is a funnel-shaped region surrounding the
infundibulum
 Most of the cells are basophilic gonadotropic
cells that secrete follicle-stimulating hormone
(FSH) and luteinizing hormone (LH)
 Is highly vascularized by arteries and the
hypophyseal portal system
 lies between the pars distalis & the pars
nervosa and contains colloid-filled cysts that
are remnants of Rathke's pouch
 Function of this region in adults is not clear,
but in the fetus the basophils produce
melanocyte-stimulating hormones (MSH)
important for melanocyte activity
 Consists of :
1. Pars nervosa
2. Infundibular stalk
 Unlike the pars disalis, it does not contain
secretory cells
 It is composed of neural tissue

 It consists of:
1. Unmylinated axons
2. Herring bodies
3. Pituicytes
4. Fenestrated capillaries
1. Unmylinated axons of the hypothalamo-hypophyseal
tract
 The cell bodies of these fibers present in the nuclei in the
hypothalamus that produce neurosecretions
2. Neurosecretory bodies or Herring bodies
 Distended axon terminals or axonal dilations containing
accumulations of neurosecretion( vasopressin (ADH)&
oxytocin ){ membrane-enclosed granules with either
oxytocin or vasopressin bound to carrier proteins called
neurophysin I and II respectively }
 Visible in the light microscope as faintly eosinophilic
structures
 3. Pituicytes :
 Are not secretory cells
 Highly branched glia cells support the axons
 Pituicytes contain lipid droplets, lipochrome
pigment, and intermediate filaments
 numerous cytoplasmic processes that contact
and form gap junctions with each other
 In addition to their support function they may
have trophic function
 Vasopressin & oxytocin
 Are peptide hormones
 Secreted by nuclei in hypothalamus & stored as Herring
bodies (axonal dilations )in pars nervosa
 Vasopressin (ADH ) is secreted by cell bodies of
neurons located mainly in the supraoptic nucleus of
the hypothalamus

 Oxytocin is secreted by cell bodies of neurons located
mostly in the paraventricular nucleus of the
hypothalamus

 Released in response to increased tonicity of
the blood, recognized by osmoreceptor cells in
the hypothalamus

The main effect of ADH is
to increase the
permeability of the
collecting ducts of the
kidney to water ( more water
is absorbed instead of being
eliminated in the urine
Thus, ADH helps to regulate
the osmotic balance of body
fluids
 The secretion of oxytocin is stimulated by breast-
feeding via sensory tracts that act on the
hypothalamus in a neurohormonal reflex called
the milk-ejection reflex

 Oxytocin stimulates
contraction of the
myoepithelial cells around
the alveoli & ducts of the
mammary glands during
nursing
 & contraction of uterine
smooth muscle during
childbirth
 Overproduction of ADH (Vasopressin) causes
excessive water retention
 Underproduction causes Diabetes insipidus –
characterizes by polyuria ( excessive
production of very diluted urine & excessive
thirst )
 Location: found in the posterior of the third
ventricle, attached to the brain by a short stalk
 Origin: develops with the brain from
neuroectoderm in the roof of the diencephalon
 Shape: cone or pine -shaped
 It is covered by the pia mater, which sends septa of
connective tissue into the gland
1. Pinealocytes are the secretory cells
 Have slightly basophilic cytoplasm
 Secretory vesicles, many mitochondria & long
cytoplasmic processes
 Produce melatonin, ( derived from serotonin )
a low molecular-weight tryptophan derivative
 Melatonin is secreted at night & serotonin is
secreted at day time
 enter the pineal gland along the septa
 associated indirectly with photoreceptive
neurons in the retinas and running to the
pinealocytes to stimulate melatonin release
in periods of darkness
 Most closely resemble astrocytes
 They have elongated nuclei more heavily
stained than those of pinealocytes
 long cytoplasmic processes
 Found in perivascular areas & between the
groups of pinealocytes
 Pineal astrocytes represent only about 5%
of the cells in the gland
 A characteristic feature (excellent land
marker in radiological & computer-assisted
tomography ) of the pineal gland
 Variously sized concretions of calcium &
magnesium salts
 Form by precipitation around extracellular
protein deposits
 Appear during childhood and gradually
increase in number & size with age
 Have no apparent effect on the gland's
function (unknown function)
 stimulated by darkness & inhibited by daylight
 Induces rhythmic changes or circadian rhythm (24-
hours biological cycle, day/night) in the activity of the
hypothalamus & pituitary gland (stimulates secretion of
growth hormone & inhibits the release of
gonadotropin)
 Melatonin delays development of gonads till puberty
(delays onset of puberty) suppress gonadotrophic
hormones
 Pineal distruction in males result in precocious puberty
 Melatonin induces the feeling of sleepiness
 It acts as antioxidant
 The gland Some times referred to as endocrine clock
 Location :
Paired organ near the superior poles of the kidneys embedded
in adipose tissue
 Shape:
flattened structures with a half-moon shape

 The right is pyramid-
shaped and sits
directly on top of the
right kidney
 The left is more
crescent-shaped and
lies along the medial
border of the left
kidney from the hilus
to its superior pole
 Covered by a dense CT capsule that sends
thin septa to the interior of the gland as
trabeculae
 Stroma of rich network of reticular fibers that
support the secretory cells
 The gland consists of two histologically &
functionally different regions
1. Adrenal cortex: a yellowish peripheral layer
2. Adrenal medulla: a reddish-brown central
layer
 The adrenal cortex & adrenal medulla can be
considered two organs with distinct origins,
functions, & morphologic characteristics that
become united during embryonic
development

 The cortex arises from mesoderm
 The medulla consists of cells derived from the
neural crest, from which sympathetic ganglion
cells also originate
 Accounts for 80%-90% of the gland
Contains cells that synthesize & secrete several
steroid hormones without storing them (no
secretory granules)
Cells of the adrenal cortex have characteristic
features of steroid-secreting cells
Central nuclei & acidophilic cytoplasm
Rich in lipid droplets
Abundant smooth ER which contain the
enzymes for cholesterol synthesis
Abundant mitochondria with tubular cristae
Three classes :
1. Mineralocorticoids
2. Glucocorticoids
3. Androgens
All are synthesized from cholesterol, the major
component of low-density lipoprotein
Hormone is synthesized by enzymes of SER &
mitochondria
As low-molecular-weight, lipid-soluble
molecules, steroids diffuse freely
through the plasma membrane and do
not require exocytosis to be released
from the cells
 The cords of cortical cells are arranged
differently and are specialized to
produce different classes of steroid
hormones
The cortex is subdivided histologically
into three concentric zones named,
from the capsule inward
1. Zona glomerulosa
2. Zona fasciculata
3. Zona reticularis
 The outer small zone Immediately inside the
connective tissue capsule
Forms 15% of the cortex
 The cells are columnar or pyramidal
The cells are arranged in spherical or
arched cords
The cells are surrounded by fenestrated
capillaries
 Secrete mineralocorticocoids
The principal product is aldosterone ( the major
regulator of salt & water balance, which acts to
stimulate Na+ reabsorption & water in the distal
convoluted tubules )
It also increase Na+ reabsorption by intestine
Decrease Na+ & increase K+ content of sweat &
saliva
Aldosterone secretion is stimulated by angiotensin II
and also by an increase in plasma K+ & decrease
Na+ concentrations, but only weakly by ACTH
 The intermediate layer of cells in the
suprarenal cortex
The largest layer of the cortex, accounts for up
to 80% of the cortex
 Polyhedral cells larger than the cells of the
zona glomerulosa
Arranged in radial columns, one to two layers
thick
Stain lightly acidophilic
Sinusoidal capillaries between the columns of
the cells
Many lipid droplets (appear vacuolated and
are called spongiocytes)
 Cells of this zone secrete glucocorticoids,
especially cortisol & small amount of androgens
Glucocorticoids function in the control of
carbohydrate, fat, and protein metabolism
Cortisol has anti-inflammatory effect & suppress
the immune response
Secretion of glucocorticoids is controlled by
ACTH from the anterior pituitary & negative
feedback
Stimulated also by stress & catecholamines
 The innermost layer of the suprarenal cortex
constituting about 7% of the cortex
 Darkly staining acidophilic cells
The cells are arranged in anastomosing cords
The cells are similar to the spongiocytes of the
zona fasciculata but are smaller
The cells contain fewer lipid droplets & more
lipofuscin pigment
Several cells near the suprarenal medulla are
dark with electron-dense cytoplasm and
pyknotic nuclei, which suggests that this zone
contains degenerating parenchymal cells
 Cells of the zona reticularis also produce
cortisol, but primarily secrete the weak
androgen dehydroepiandrosterone (DHEA)
which is converted to testosterone in several
other tissues
Secretion by these cells is stimulated by ACTH
& is under feedback regulation with the
pituitary and hypothalamus
At this age, a layer of fetal or provisional cortex,
comprising 80% of the total gland
The fetal cortex is thick & contain cells that secret
sulfated DHEA under the control of the fetal
pituitary
DEHA converted in the placenta to active
estrogens (and androgens), which mostly enter the
maternal circulation
After birth, the provisional cortex undergoes
involution while the permanent cortex organizes the
three layers (zones)
Hyperfunction:
 Cushing's syndrome: Increase production of
glucocorticoids
Cause: most often (90%) due to a pituitary adenoma that
results in excessive production of ACTH

 Conn's syndrome: increase production of aldosterone
Cause: adenoma or hyperplasia
Signs: hypertension &muscle weakness ( loss of k+ )

 Excessive production of adrenal androgens:
 in boys: precocious puberty
 in girls: hirsutism (abnormal hair growth) & virilization
(muscle bulk, body hair & deep voice)
Hypofunction:
Addison disease:
Cause: destruction of the adrenal cortex
& failure of secretion of both glucocorticoids &
mineralocorticoids
 Capsular arteries
Cortical arterioles
Medullary arterioles branch
into medullary capillary
network

 Adrenal medulla is more
vascular & have dual blood
supply :
1. Arterial blood from medullary
capillary
2. Blood of cortical capillaries
carrying cortical hormones
composed of :
Chromaffin cells (pheochrome) : large,
pale-staining polyhedral cells arranged in
cords or clumps
Few parasympathetic ganglion cells
A profuse supply of sinusoidal capillaries
between adjacent cords ( more vascular )

Chromaffin reaction :
The granules take yellowish brown color when
treated with chromic acid or chromium salts
 Origin of
medullary
cells

Chromaffin cells, arise from neural crest
cells, as do the postganglionic neurons of
sympathetic & parasympathetic ganglia.
Chromaffin cells can be considered modified
sympathetic postganglionic neurons, lacking
axons & dendrites and specialized as
secretory cells
Unlike cells of the cortex, medullary chromaffin cells
contain many electron-dense granules for hormone
storage & secretion
These granules contain catecholamines: epinephrine or
norepinephrine
About 80% of the catecholamines secreted from the
adrenal medulla is epinephrine

The granules of epinephrine-secreting cells are less
electron-dense & smaller than those of
norepinephrine-secreting cells
Catecholamine, together with Ca2+ and ATP, are
bound in a granular storage complex with proteins
called chromogranins
Medullary chromaffin
cells are innervated by
cholinergic endings of
preganglionic
sympathetic neurons,
from which impulses
trigger hormone
release by exocytosis

Catecholamines
derived from
tyrosine
 Medullary hormones deals with
physical & emotional stress
Get the body ready to fight or flight

The fight-or-flight response : produce
vasoconstriction, increased blood
pressure, changes in heart rate, and
metabolic effects such as elevated
blood glucose

 Adrenal medulla disorders
 Pheochromocytoma: a tumor of its cells that causes hyperglycemia &
transient elevations of blood pressure
 Composed of spherical aggregates of cells,
known as islets of Langerhans, that are
scattered among the exocrine acini
 There are more than 1 million islets in the
human pancreas, concentrated mainly at
the tail
 Very thin capsule of reticular fibers surrounds
each islet
 Origin: endodermal (epithelial cells )
 Each islet consists of polygonal
or rounded cells
 Smaller & more lightly stained
than the surrounding acinar
cells
 Arranged in cords that are
separated by a network of
fenestrated capillaries
 Autonomic nerve fibers contact
some of the endocrine cells
and the blood vessels
 By Routine stains or trichrome islet cells are
acidophilic or basophilic with fine
cytoplasmic granules
 4 types of cells on the bases of :
1. immunohistochemical staining
2. Size, electron density & distribution of their
secretory granules
1. Alpha (α) or A cells , 20% , secrete glucagon and are usually located
near the periphery of islets, stained pink with Gomori stain
their granules have homogenous electron dense
core & lower density peripheral zone
2. Beta (β)or B cells, 70%, produce insulin, are located centrally in islets,
smaller & most numerous cell type, stains blue with Gomori
their granules contain one or more dense crystals in a low density
matrix
3. Delta (δ)or D cells, 5-10% secreting somatostatin, are scattered and
much less abundant
Their granules are larger & less electron dense
4. F or PP cells , less than 5% secrete pancreatic polypeptide, more
common in islets located within the head of the pancreas
Their granules are small with variable density
are all polypeptides
Both insulin & glucagon are
important in the regulation of
carbohydrate, protein and lipid
metabolism
 Insulin is an anabolic
hormone, it increases the
storage of glucose, fatty
acids and amino acids in
cells and tissues (acts to
lower blood sugar)
 Glucagon is a catabolic
hormone, it mobilizes
glucose, fatty acids and
amino acids from stores into
the blood (acts to raise
blood sugar)
Sympathetic fibers during stressful situations,
emergencies, and exercise increase glucagon
release and inhibit insulin release
parasympathetic fibers during restful times and
during the digestion of a meal stimulate the
release of insulin
 Stimuli for insulin release primarily is high
blood glucose levels
 Glucagon is released in response to low
blood glucose levels
 Cell Quantity Hormone Hormone function
type
Alpha 20% glucagon Increases blood glucose level
(α Cells)

Beta 70% insulin Decreases blood glucose level
(β cells )

Delta 5-10% somatostatin Paracrine: inhibits hormone release
(δ cells ) from endocrine pancreas & enzymes
from exocrine pancreas
Endocrine: inhibits release of GH &
TSH in anterior pituitary & HCl
secretion by gastric parietal cells

F cells rare Pancreatic Stimulates activity of gastric chief
(PPcells) polypeptide cells; inhibits bile secretion,
pancreatic enzyme & bicarbonate
secretion & intestinal motility
 Insulin-dependent or type 1 diabetes
usually affects persons younger than 20 years of
age
Results from partial or total autoimmune destruction
of beta cells & subsequent lack of insulin (insulin
insufficiency)
 Insulin-independent diabetes or type 2 diabetes
usually affects persons older than 40 years of age
results from a failure of cells to respond to insulin
(insulin resistance ) , and is frequently associated
with obesity
Location: in the cervical region anterior to the
larynx, consists of two lobes united by an isthmus
It is surrounded by dense,
irregular collagenous CT
capsule subdivide the gland
into lobules
parathyroid glands
embedded within the
capsule, on the posterior
aspect of the gland
 The thyroid originates from two main structures: the
primitive pharynx near the base of the future tongue
( main bulk of the gland ) begins as epithelial
diverticulum growing down from the endodermal
lining of the foregut
 & from the neural crest ( parafollicular cells )
 It originates from between the first and second
pharyngeal pouches
 It is mainly endodermal in origin
The thyroid follicle is the structural
and functional unit of the thyroid
gland (20-30 million)
The wall of the follicle is formed of:
1. Follicular cells = 98%
2. Parafollicular = 2%
The cells are resting on a
basement membrane
Central lumen filled with
acidophilic, gelatinous
substance ( colloid )
 Single layer
Cuboidal basophilic, central nucleus
Exhibit characters of protein secreting cells
Apical secretory granules
Abundant lysosomes
Surface microvilli
Follicular cells range in shape from squamous
to low columnar and the follicles are quite
variable in diameter
The size & cellular features of thyroid follicles
vary with their functional activity
 Active glands have more follicles of low
columnar epithelium
 Glands with mostly squamous follicular cells
are considered hypoactive
 Follicular cells produce the thyroid hormones
(T3 & T4)
 Found inside the basal lamina of the follicular
epithelium or as isolated clusters between
follicles
Derived from neural crest cells
Usually larger than follicular cells
Less intensely stained
They have a smaller amount of rough ER, large
Golgi complexes, and numerous small granules
containing polypeptide hormone
colloid

Thyroid is the only endocrine
gland whose secretory
product is stored in great
quantity & accumulated as
a colloid within the follicles
 Synthesize & secrete hormone calcitonin
( lower blood Ca2+ level )
by inhibiting bone resorption by osteoclasts
(decreases osteoclast activity)
& increases loss of Ca++ in urine
 Calcitonin secretion is triggered by elevated
blood Ca2+ levels
 It is a glycoprotein of high molecular
mass thyroglobulin the precursor for the
active thyroid hormones
 hormones T4 and T3 are stored in the
colloid, which is bound to thyroglobulin
 When the hormones are to be released,
the hormone-bound thyroglobulin is
endocytosed and the hormones are
cleaved from it by lysosomal proteases
Regulated by:
1. The iodide levels in the follicular cell
2. The binding of TSH to TSH receptors of the
follicular cells
This process involves the following steps:

TSH is secreted by
basophilic cells of
pars distalis
(anterior pituitary)
 Under stimulation of TSH
 Synthesized in RER & transported to Golgi to
form secretory vesicles
 Released into the lumen
 By the Na/I symporter in the basolateral cell
membrane of follicular cells
 Oxidation of iodide to active iodine by
membrane-bound thyroid peroxidase at the
luminal cell surface
 Transported to the lumen to iodinate the
tyrosine residues of stored thyroglobulin
 This result in formation of mono & di-
iodinated thyrosine which are conjugated
(coupling )to form T3 & T4
 In response to TSH follicular cells take up the
colloid by endocytosis
 Digestion & hydrolysis of thyroglobulin by
lysosomal enzymes
 Transported to the cytosol as T1,T2, T3 & T4
 T1& T2 remain in the cytoplasm & broken into
iodine & thyrosine to be reused
 T3 & T4 secreted through the basolateral
membrane into the blood capillaries
 T4 ( thyroxin )is the more abundant
compound, constituting 90% of the
circulating thyroid hormone
 It is a prohormone and a reservoir for active
T3
 but T3 is 2-10 folds more active (potent)
than T4
 The half-life of T3 is 1.5 days in comparison
with a week for T4
 Most of the thyroid hormone circulating in
the blood is bound to transport proteins
Thyroid hormones are important for growth,
for cell differentiation, and for the control of
the basal metabolic rate and oxygen
consumption in cells throughout the body.
Thyroid hormones affect protein, lipid, and
carbohydrate metabolism
1. TSH from anterior pituitary stimulates synthesis
& release of the hormones
 TSH also Increases the activity & height of
the epithelium
 TSH receptors at the base of follicular cells
2. Negative feed back
3. Iodine level
Thyroid hormone
act through
intracellular
receptors
Iodine dificiency Goiter
Enlargement of the thyroid gland due to iodine
deficiency which result in accumulation of non-
iodinated thyroglobulin in the lumen &
enlargement of thyroid
Goiters are endemic in
some regions of the
world, where dietary
iodide is scarce
Hypothyrodisim
Leads to cretinism in infants (congenital or iodine lack )
Autoimmune diseases of the thyroid, such as
Hashimoto disease, may impair its function, with
consequent hypothyroidism (fatigue, weight gain,
pale or puffy face, feeling cold, joint and muscle
pain)
Hyperthyrodisim
Cause Graves' disease an autoimmune disease in which
anti-TSH receptor antibodies bind to TSH receptors on
the thyroid and stimulate continuous thyroid hormone
release , bulging of the eyes (exophthalmos)may occur
 Usually 4 in number, are
located on the posterior surface
of the thyroid gland
 one parathyroid gland is
located on both poles (superior
and inferior) of the right and left
lobes of the thyroid gland
 Usually embedded in the larger
gland's capsule
 Derived from the pharyngeal
pouches—the superior glands
from the fourth pouch and the
inferior glands from the third
pouch
 Capsule , septa & clusters of secretory cells
 With increasing age many secretory cells are
replaced with adipocytes, which may
constitute more than 50% of the gland in
older people
 The parenchyma of the parathyroid glands is
composed of two cell types:
 Chief
cells
 Oxyphil cells
 polygonal cells with round nuclei and pale-
staining, slightly acidophilic cytoplasm
 The cytoplasm is filled with secretory granules
containing the polypeptide parathyroid
hormone or parathormone (PTH), a major
regulator of blood calcium levels
 The main target cell is osteoblast which release
osteoclast stimulating factor which increases
the number & activity of osteoclasts
 Parathyroid hormone also indirectly
increases the absorption of Ca2+ from the
gastrointestinal tract by stimulating the
PTH
synthesis
increases of vitamin
the number and D, which is necessary for
this absorption
activity of osteoclasts,
increases Ca and Mg
+2 +2

reabsorption from distal
tubules and inhibits the
reabsorption of HPO4-2 so
more is secreted in the
urine, and promotes
activation of vit D, which
increases the absorption of
Ca+2, Mg+2 from the GIT
Parathyroid hormone ( secreted by chief cells of
parathyroid )
&
calcitonin ( secreted by parafollicular cells of
thyroid )
have opposing effects & constitute a dual
mechanism to regulate blood levels of Ca2
 Less numerous, larger
 Stain more deeply with eosin than chief cells
 Oxyphils appear in groups & as isolated cells
 They have more abundant mitochondria than do
chief cells, but their Golgi apparatus is small and
there is little RER
 Glycogen in their cytoplasm
 Probably represent inactive phase of chief cells
 Appear around puberty and increase in number
 Unknown function
 Hyperparathyroidism:
concentrations of blood phosphate are decreased &
concentrations of blood Ca2+ are increased
Loss of bone minerals & deposits of calcium in organs, such as
kidneys & arteries
Osteitis fibrosa cystica: Bones are less stress-resistant and
prone to fractures
 Hypoparathyroidism:
concentrations of blood phosphate are increased &
concentrations of blood Ca2+ are decreased
The bones become denser and more mineralized
Causes spastic contractions of the skeletal muscles and
generalized convulsions ( spasm ) called tetany
Patients with hypoparathyroidism are treated with calcium
salts and vitamin D to promote Ca2+ uptake in the gut

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