PH 131: Human Anatomy and Pathology with Pathophysiology - Endocrine System PDF

Summary

These lecture notes cover the endocrine system, including its functions, hormones, and different types of glands. The document also outlines local chemical messengers and feedback mechanisms. Topics include comparing the nervous system and endocrine system, and describing the structure and action of various hormones.

Full Transcript

PH 131: HUMAN ANATOMY AND PATHOLOGY WITH PATHOPHYSIOLOGY
ENDOCRINE SYSTEM
Prof. Vivien Fe F. Fadrilan-Camacho Trans 2

OUTLINE ENDOCRINE SYSTEM

A. Endocrine System Nervous System vs. Endocrine System
a. Functions Nervous System
b. Exocrine vs Endocrine
→ Via electrochemical impulses
c. Local Chemical Messengers
B. Hormones → Responses in milliseconds
a. Hormone Actions Endocrine System
b. Chemical Structure → Via hormones
c. Hormone Receptors
→ Responses occur after a lag period of seconds or
d. Hormone Responses
days; once initiated, responses are more prolonged
e. Feedback Mechanisms
i. Negative
ii. Positive FUNCTIONS
f. Hormone Clearance
g. Endocrine Gland Stimuli 1. Water balance
C. Hypothalamus a. Controls solute concentration of blood
a. Hypothalamic Control over Endocrine 2. Uterine contractions and milk release
Organs 3. Growth, metabolism, and tissue maturation
D. The Pituitary Gland 4. Ion regulation
a. Structure 5. Heart rate and blood pressure regulation
b. Hormones of Posterior Pituitary 6. Blood glucose control
i. Antidiuretic Hormone 7. Immune system regulation
ii. Propiomelanocortin 8. Reproductive functions control
iii. Melanocyte Stimulating Hormone,
Endorphins, Lipotropins
iv. Adrenocorticotrophic Hormone EXOCRINE VS. ENDOCRINE GLAND
(ACTH)
v. Growth Hormone (GH or Exocrine Gland
Somatotropin) Glands with ducts; produces non-hormonal substances
vi. LH, FSH, Prolactin
→ Membrane surface (e.g. sweat and salivary glands)
E. Thyroid Gland
a. Thyroid Hormones Endocrine Gland
i. Thyrotropin (TSH) and Thyroid
Ductless glands which produce hormones;
Hormones
b. Effects of T3 and T4 → Vascular and lymphatic drainage (e.g. pituitary,
c. Regulation of Calcitonin Secretion thyroid, parathyroid, adrenal, pineal, and thymus
d. Parathyroid Glands gland)
e. Effects of Parathyroid Hormone → Hypothalamus: neuroendocrine organ
F. Adrenal Glands → Organs with endocrine and exocrine products:
a. Hormones of Adrenal Cortex
✔ Pancreas
b. Adrenal Medulla
G. Pancreas ✔ Ovaries and testes
a. Glucagon
b. Insulin
c. Diabetes Mellitus (DM)
H. Hormones of the Reproductive System
a. Testosterone
b. Estrogen and Progesterone
I. Pineal Body
J. Thymus Gland, GI Tract, Kidneys
a. Thymosin
b. GI Tract
c. Kidneys
Figure 1. Differences in the Anatomical Structures of the
d. Adipose Tissue
Exocrine and Endocrine Glands
K. Hormone-like Substances
a. Autocines
b. Paracrines
L. Thyroid Disorders
a. Goiter
b. Hyperthyroidism (Grave’s Disease)
c. Hypothyroidism
M. Public Health Interventions

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 PH 131: HUMAN ANATOMY AND PATHOLOGY WITH PATHOPHYSIOLOGY
ENDOCRINE SYSTEM
Prof. Vivien Fe F. Fadrilan-Camacho Trans 2

5. Stimulates mitosis

CHEMICAL STRUCTURE

Proteins, Peptides and Amino Acid Derivatives
Bind to membrane bound receptors (except thyroid
hormones)
→ Proteins
✔ most hormones of the anterior pituitary
glands
→ Peptide hormones
✔ hormones of the posterior pituitary glands
→ Amino acid derivatives
✔ chemically modified; hormones of adrenal
medulla

Lipid Hormones
lipid soluble, which is the ability to dissolve through the
Figure 2. Anatomical Loci of the Principal Endocrine Glands and lipid (fat) portion of a membrane
Tissues → Steroid Hormones
✔ derived from cholesterol
LOCAL CHEMICAL MESSENGERS ✔ hormones produced by the adrenal cortex
and gonads
INTERCELLULAR CHEMICAL SIGNALS ✔ diffuse across the cell membrane and bind to
Autocrines intracellular receptor molecules
- Exert effects on the
Prostaglandins → Eicosanoids from Arachidonic Acid
same cells that secrete
Smooth muscle
them ✔ include prostaglandins, prostacyclins, and
contraction
Paracrines - Produced by a wide leukotrienes
Somatostatin variety of tissues and ✔ bound to membrane-bound receptors that
Inhibits release of secreted into tissue are associated with G proteins
insulin produced by spaces
other cells - Act on surrounding cells STRUCTURAL CATEGORIES OF HORMONES
- Secreted into blood by
Structural Category Examples
Hormone specialized cells
Thyroxine, insulin - Influences specific Growth hormone
activities Proteins Prolactin
Insulin
Neurohormone - Produced by neurons
Oxytocin, antidiuretic and functions like Follicle-stimulating hormone
Glycoproteins
hormone hormones Luteinizing hormone
(protein and
Thyroid-stimulating hormone
- Produced by neurons carbohydrates)
Parathyroid hormone
Neurotransmitter or and secreted by
Neuromodulator presynaptic nerve Thyrotropin-releasing hormone
Acetylcholine, terminals Oxytocin
epinephrine - Influences postsynaptic Antidiuretic hormone
cells Calcitonin
Glucagon
- Secreted into
Adrenocorticotropic hormone
Pheromone environment Polypeptides
Endorphins
Sex pheromones - Modifies physiology
Thymosin
and behavior
Melanocyte-stimulating hormone
Hypothalamic hormone
HORMONES Lipotropins
Somatostatin
Chemical substances secreted by cells into extracellular
Epinephrine
fluids Amino Acid Norepinephrine
Regulate the metabolic function of other cells in the Derivatives Thyroid hormones (both T3 and T4)
body Melatonin
Estrogen
HORMONE ACTIONS
Progestins (progesterone)
1. Alters plasma membrane permeability or membrane Steroids Testosterone
potential by opening or closing ion channels Mineralocorticoids (aldosterone)
Glucocorticoids (cortisol)
2. Stimulates synthesis of proteins or regulatory
molecules (e.g. enzymes) Prostaglandins
Thromboxanes
3. Actiavtes or deactivates enzymes Fatty Acid Derivatives
Prostacyclins
4. Induces secretory activity Leukotrienes

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 PH 131: HUMAN ANATOMY AND PATHOLOGY WITH PATHOPHYSIOLOGY
ENDOCRINE SYSTEM
Prof. Vivien Fe F. Fadrilan-Camacho Trans 2

Positive Feedback Mechanism
HORMONE RECEPTORS Occurs when biological action of the hormone causes
additional secretion of the hormone
Membrane-bound Receptors Luteinizing hormone (LH) is released as a result of the
Receptor sites on the outer surface of the cell stimulatory effect of estrogen on the anterior pituitary
membrane before ovulation.

Interact with large and water-soluble molecules → LH → ovaries → estrogen → LH

→ Receptors that directly alter membrane → After LH reaches an appropriate concentration, it
permeability exhibits negative feedback.

✔ opening and closing of ion channels
✔ e.g. Acetylcholine (Ach) and Na+ channels in
skeletal muscle membranes
→ Receptors that directly alter the activity of enzymes
✔ increase or decrease of enzyme activities
through the increase or decrease activity of
cyclic guanosine monophosphate (cGMP)
→ Receptors and G proteins
✔ activation of G proteins (complex proteins)
✔ inactive G protein (with α, β, σ subunits)
✔ GDP is bound to α subunit
✔ receptor binding
the α subunit separates from the β and σ,
then GTP replaces GDP
can open or close channels Figure 3. Feedback Mechanism of Menstrual Cycle (Ovulation)
activate enzymes
affect gene expression
HORMONE CLEARANCE
Intracellular Receptors 1. metabolic destruction by the tissues
Located in the cytoplasm or nucleus of the cell 2. binding with the tissues
Interact with small, lipid intercellular signals 3. excretion by the liver into the bile
4. excretion by the kidneys into the urine
HORMONE RESPONSES
ENDOCRINE GLAND STIMULI
1. Permissiveness
1. Humoral
a. situation when one hormone cannot exert its
a. direct response to changing blood levels
full effects without another hormone being
b. e.g. parathyroid hormone, insulin and
present
aldosterone
b. e.g. thyroid hormone on reproductive system
2. Neural
2. Synergism
a. stimulated by nerve fibers
a. occurs where more than one hormone
b. e.g. catecholamines
produces the same effects at the target cell
3. Hormonal
and their combined effects are amplified
a. in response to hormones produced by other
(1+1 = 2)
endocrine organs
b. e.g. glucagon and epinephrine
b. e.g. hypothalamic-pituitary axis
3. Antagonism
a. one hormone opposes the action of another
hormone
b. e.g. insulin and glucagon
FEEDBACK MECHANISMS

Negative Feedback Mechanism
Ensure a proper level of hormone activity at the target
tissue
After a stimulus causes release of the hormone,
products resulting from the action of the hormone tend
to suppress its further release.
The hormone has a negative feedback effect to prevent
oversecretion of the hormone or overactivity

Figure 4. Different Endocrine Gland Stimuli

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 PH 131: HUMAN ANATOMY AND PATHOLOGY WITH PATHOPHYSIOLOGY
ENDOCRINE SYSTEM
Prof. Vivien Fe F. Fadrilan-Camacho Trans 2

HYPOTHALAMUS THE PITUITARY GLAND
A neuro-endocrine organ; regulates the nervous system
and endocrine system activities by 3 different Pea on a stalk (infundibulum)
mechanisms: Controlled by hypothalamus
→ It secretes regulatory hormones that control Consists of two lobes: the neurohypophysis (posterior
endocrine cells in the adenohypophysis (anterior lobe) and the adenohypophysis (anterior lobe)
lobe) of the pituitary gland:
✔ Releasing hormones (RH) that stimulate
production of one or more hormones
✔ Inhibiting hormones (IH) that prevent the
synthesis and secretion of specific pituitary
hormone
→ acts as an endocrine organ, releasing the
hormones ADH and oxytocin into the circulation at
the neurohypophysis (posterior lobe)
→ contains autonomic centers that have direct neural
control over the endocrine cells of the suprarenal
medulla → sympathetic division is activated →
medulla → hormones
Autonomic centers are either sympathetic
Figure 7.1. Pituitary Gland Structure
or parasympathetic that have direct neural
control over the endocrine cells of the
adrenal or suprarenal gland (on top of the
kidney).
The adrenal or suprarenal gland has
cortex (outer) and medulla (inner). The
medulla releases epinephrine and
norepinephrine.

Figure 7.2. Pituitary Gland Structure

POSTERIOR PITUITARY (NEUROHYPOPHYSIS)

Connected to the hypothalamus through a group of
neurons known as hypothalamic-hypophyseal tract and
releases neurohormones (oxytocin and ADH) (Note: The
term “tract” means or is related to a group of neurons)
Figure 5. Hypothalamic Control over Endocrine Organs
→ Paraventricular neurons in this tract secretes
oxytocin
→ Supraoptic neurons in this tract secretes
antidiuretic hormone (ADH)

ANTERIOR PITUITARY (ADENOHYPOPHYSIS)

Connected to the hypothalamus through hypophyseal
portal system or the bloodstream (Note: The term
“portal” is related to blood)
Secretes releasing and inhibitory hormones
Consists of three areas with indistinct boundaries: pars
distalis, pars intermedia, and pars tuberalis

Figure 6. Hormones of the Hypothalamus

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 PH 131: HUMAN ANATOMY AND PATHOLOGY WITH PATHOPHYSIOLOGY
ENDOCRINE SYSTEM
Prof. Vivien Fe F. Fadrilan-Camacho Trans 2

HORMONES OF THE PITUITARY GLAND → Specialized neurons found in walls of atria of heart,
large veins, carotid arteries, and aortic arch
→ Sense changes in blood pressure
✔ If BP decreases, then ADH secretion is
stimulates

Figure 8.1. Hormones of the Pituitary Gland

Figure 10. Control of ADH Secretion

Figure 8.2. Hormones of the Pituitary Gland

Figure 8.3. Hormones of the Pituitary Gland

Figure 11. Control of Oxytocin Secretion

Propiomelanocortin (POMC)
Prohormone (not totally a hormone )from the anterior
pituitary
Source of ACTH, enkephalin, beta-endorphin, lipotropin
Source of melanocyte-stimulating hormone (CNS
neurotransmitter involved in appetite control)

Melanocyte Stimulating Hormone, Endorphins, Lipotropins
ACTH, MSH, endorphins, and lipotropins all derived
from the same large precursor molecule when
Figure 9. Associated Pathways in the Pituitary Gland stimulated by CRH
Melanocyte Stimulating Hormone (MSH)
HORMONES OF POSTERIOR PITUITARY
→ causes melanocyte to produce more melanin

Antidiuretic Hormone (Vasopressin) Endorphins

Osmoreceptors → act as an analgesic (pain reliever)

→ Specialized neurons of hypothalamus monitor → produced during times of stress
changes in intercellular osmolality (solute Lipotropins
concentration) → Cause adipose cells to catabolize fat
✔ If the concentration of electrolytes increases or
if the concentration of water decreases, then Adrenocorticotrophic Hormone (ACTH)
ADH secretion is stimulated CRH from hypothalamus causes release of ACTH from
Baroreceptors anterior pituitary

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 PH 131: HUMAN ANATOMY AND PATHOLOGY WITH PATHOPHYSIOLOGY
ENDOCRINE SYSTEM
Prof. Vivien Fe F. Fadrilan-Camacho Trans 2

→ Causes cortisol (stress hormone) secretion from the GnRH from hypothalamus stimulates LH and FSH
adrenal cortex (a glucocorticoid from the zona secretion
fasciculata) – against stress Prolactin
→ Causes aldosterone secretion from the adrenal → Role in milk production
cortex (a mineralocorticoid from the zona
→ Regulation of secretion: prolactin-releasing
glomerulosa)
hormone (PRH) and prolactin-inhibiting hormones
→ Binds directly to melanocytes of the skin (PIH)
✔ Causes increase in production of melanin
THYROID GLAND
Growth Hormone (GH or Somatotropin) Highly vascular
Stimulates uptake of amino acids; protein synthesis; Iodine enters follicular cells by active transport
growth in most tissues → Only glands that stores hormone
Stimulates breakdown of fats to be used as an energy Histology
source
→ Composed of follicles (follicular cells surrounding
→ But stimulates synthesis of glycogen (glucose thyroglobulin/thyroid hormones)
sparing)
→ Parafollicular cells: between follicles
Promotes bone and cartilage growth
Follicular cells secrete thyroglobulin into the lumen of
Regulates blood levels of nutrients after a meal and the follicle
during periods of fasting
→ iodine and tyrosine necessary for production of T3
Stimulates glucose synthesis by liver and T4
→ hormones stored here attached to the thyroglobulin
then absorbed into follicular cells
→ hormones disattached from thyroglobulin and
released into circulation
Parafollicular cells -> secrete calcitonin which reduces
[Ca2+] in body fluids when Ca levels

Figure 12. Growth Hormone Effects and Mechanisms

Figure 14. Cellular anatomy of the thyroid gland.

THYROID HORMONES

Only free thyroxine and T3 can enter cell;
→ bound-thyroxine serves as a reservoir of this
hormone
33–40% of T4 converted to T3 in cells
T3 more potent
Bind with intracellular receptor molecules and initiate
Figure 13. Regulation of GH Secretion
new protein synthesis
LH, FSH, Prolactin Normal growth of many tissues dependent on presence
of thyroid hormones
Gonadotropins
→ Glycoprotein hormones that promote growth and Thyrotropin (TSH) and Thyroid Hormones
function of the gonads TRH from hypothalamus causes release of TSH from
LH and FSH anterior pituitary
→ Both hormones regulate production of gametes → Causes secretion and storage of hormones T3 and
and reproductive hormones T4 from and within the thyroid gland
✔ Testosterone in males → T3 and T4 inhibit TRH and TSH secretion
✔ Estrogen and progesterone in females

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 PH 131: HUMAN ANATOMY AND PATHOLOGY WITH PATHOPHYSIOLOGY
ENDOCRINE SYSTEM
Prof. Vivien Fe F. Fadrilan-Camacho Trans 2

Effects of T3 and T4 → regulation depends on calcium levels
Maintain normal rate of metabolism.
Increase the rate at which glucose, fat, and protein are
metabolized
Increase the activity of Na+-K+ pump which increases
body temperature.
Can alter the number and activity of mitochondria
resulting in greater ATP synthesis and heat production.
Normal growth and maturation of bone, hair, teeth, c.t.,
and nervous tissue require thyroid hormone.
Both T3 and T4 play a permissive role for growth
hormone

Figure 17. Effects of parathyroid hormone.

ADRENAL GLANDS
Near superior poles of kidneys; retroperitoneal (area in
the back of the abdomen behind the peritoneum)
Inner medulla; outer cortex
Medulla: Secretes epinephrine and norepinephrine

Figure 15. Hormones of the thyroid and parathyroid glands.

Figure 18. Adrenal layers.
Cortex: three zones from superficial to deep:
1. Zona glomerulosa
Figure 16. Regulation of thyroid hormones.
2. Zona fasciculata
Regulation of Calcitonin Secretion 3. Zona reticularis
Produced by parafollicular cells HORMONES OF ADRENAL CORTEX
Secretion triggered by high Ca2+ concentration in blood;
→ acts to decrease Ca2+ concentration Mineralocorticoids: Zona glomerulosa

Primary target tissue → bone → Aldosterone - rate of sodium reabsorption by
kidneys sodium blood levels
Decreases osteoclast activity, lengthens the life span of
osteoblasts Glucocorticoids: Zona fasciculata
→ Cortisol - fat and protein breakdown,
PARATHYROID GLANDS
h-glucose synthesis, inflammatory response

Secrete PTH: target tissues → bone, kidneys, and Androgens: Zona reticularis
intestines → Weak androgens are secreted and then
→ increases blood calcium and phosphate levels converted to testosterone by peripheral tissues

→ stimulates osteoclasts → Stimulate pubic and axillary hair growth and
sexual drive in females
→ promotes calcium reabsorption by kidneys and
PO4 excretion ADRENAL MEDULLA
→ increases synthesis of vitamin D
Neurohormones: epinephrine and norepinephrine
h-absorption of Ca and PO4 by
Combine with adrenergic membrane-bound receptors
intestines

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 PH 131: HUMAN ANATOMY AND PATHOLOGY WITH PATHOPHYSIOLOGY
ENDOCRINE SYSTEM
Prof. Vivien Fe F. Fadrilan-Camacho Trans 2

All function through G-protein mechanisms
Secretion of hormones prepares the body for physical
activity
Effects are short-lived; hormones rapidly metabolized
Epinephrine:
→ increase blood levels of glucose
→ increase fat breakdown in adipose tissues
→ causes dilation of blood vessels in skeletal
muscles and cardiac muscles
Epinephrine and norepinephrine increase heart rate and
force of contraction; cause blood vessels to constrict in
skin, kidneys, GI tract, and other viscera

Figure 21. The Pancreas

HORMONES OF THE PANCREAS

Glucagon
Major target is the liver
Promotes:
→ Glycogenolysis
✔ Breakdown of glycogen to glucose
Figure 19. Regulation of Adrenal Medullary Secretions → Gluconeogenesis
✔ Synthesis of glucose from lactic acids and
noncarbohydrates
→ Release of glucose to the blood from liver cells

Insulin
Target tissues:
→ Liver
→ Adipose tissue
→ Muscle
→ Satiety center of hypothalamus
Lowers blood glucose levels
Enhances transport of glucose into body cells
Figure 20. Stress and the Adrenal Gland Counters metabolic activity that would enhance blood
glucose levels

PANCREAS PANCREATIC HORMONES

Retroperitoneal Islets Hormone Structure Target tissue Response
Increased
Exocrine gland Liver
uptake and
→ Produces pancreatic and digestive juices Beta Skeletal
Insulin Protein use of
(β) muscle
Endocrine gland glucose and
Fat tissue
amino acid
→ Consists of pancreatic islets
Increased
→ Composed of breakdown of
✔ Alpha cells glycogen
Alpha
Glucagon Polypeptide Liver Release of
Secrete glucagon (ɑ)
glucose into
✔ Beta cells the circulatory
system
Secrete insulin
ɑ and β cells
✔ Delta cells (some
Inhibition of
Secrete somatostatin somatostatin
Delta Somato- insulin &
Peptide is produced
(δ) statin glucagon
in the
secretion
hypothalamu
s)

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 PH 131: HUMAN ANATOMY AND PATHOLOGY WITH PATHOPHYSIOLOGY
ENDOCRINE SYSTEM
Prof. Vivien Fe F. Fadrilan-Camacho Trans 2

→ development and maintenance of male
EFFECT OF INSULIN & GLUCAGON ON TARGET TISSUES
reproductive organs and secondary sex
Target Tissue Response to Insulin Response to Glucagon characteristics
Skeletal muscle
Cardiac muscle
Inhibin
Bone ↑ glucose uptake → Inhibits FSH secretion
Fibroblasts ↑ uptake of certain Little effect
Leukocytes amino acids FEMALE: OVARIES
Mammary
glands
Rapid ↑ in breakdown of Estrogen and Progesterone
glycogen to glucose
Regulates:
(glycogenolysis) and
release of glucose into → Uterine and mammary gland development and
↑ glycogen synthesis the blood function
↑ use of glucose for ↑ glucose formation
Liver
energy (glycolysis) (gluconeogenesis) from → External genitalia structure
amino acids and to
→ Secondary sex characteristics
some degree in fats
↑ metabolism of fatty → Menstrual cycle
acids = ↑ ketones in the
blood Inhibin
↑ glucose uptake, → Inhibits FSH secretion
↑ conc. = breakdown of
glycogen synthesis, fat
fats (lipolysis) Relaxin
Adipose cells synthesis, and fatty
Probably unimportant
acid uptake → Increases flexibility of symphysis pubis
under most conditions
↑ glycolysis
Little effect except to ↑
Nervous system glucose uptake in the No effect
satiety center

Figure 23. Hormones of the Reproductive Organs

PINEAL BODY
In epithalamus
Figure 22. Regulation of Blood Glucose Levels
Produces melatonin
DIABETES MELLITUS (DM)

Results from hyposecretion or hypoactivity of insulin
3 cardinal signs
→ Polyuria
✔ Huge urine output
→ Polydipsia
✔ Excessive thirst
→ Polyphagia
✔ Excessive hunger or food consumption
Hyperinsulinism
→ Excessive insulin secretion
Figure 24. Pineal body
→ Resulting in hypoglycemia

HORMONES OF THE REPRODUCTIVE SYSTEM
THYMUS GLAND, GI TRACT, KIDNEYS

Thymosin
MALE: TESTES
Aids in the developments of the immune system.
Testosterone
GI Tract
Regulates:
Has several hormones that regulate digestion and
→ production of sperm cells enzyme secretion.

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 PH 131: HUMAN ANATOMY AND PATHOLOGY WITH PATHOPHYSIOLOGY
ENDOCRINE SYSTEM
Prof. Vivien Fe F. Fadrilan-Camacho Trans 2

Kidneys Foods such as:
Secrete erythropoietin → Cabbage
→ Signals RBC production → Turnip
→ Soy
Adipose Tissue
→ Kale
Releases leptin
→ Cassava
→ Involved in the sensation of satiety
→ Sweet Potato
→ Stimulates increased energy expenditure.
→ Kale
→ Radish
HORMONE-LIKE SUBSTANCES → Lima Beans
→ Cauliflower
Autocrines
→ Millet
Chemical signals released by a cell that affects the
→ Broccoli
same cell.
→ Brussel Sprouts
Chemical mediators of inflammation which are modified
fatty acids: eicosanoids such as Toxic Goiter
→ Prostaglandins Hyperthyroid condition resulting from hyperactivity of
→ Thromboxanes the thyroid gland due to excessive stimulation by TSH
→ Prostacyclins that produces a large nodular gland.

→ Leukotrienes Goiter Development

Paracrines
Chemical signals released into intercellular fluid that
affects nearby cells.
→ Endorphins (for pain modulation)
→ Enkephalins (for pain modulation)
→ Several growth factors

THYROID DISORDERS

GOITER

Enlargement of the thyroid gland, often visible on the
anterior neck.
Caused by various hypothyroid and hyperthyroid
conditions.
Can be very large, compressing the esophagus and
interfering with swallowing.
Can cause pressure on the trachea.
Figure 25. Endemic Goiter and Hypothyroidism Development
Endemic Goiter HYPERTHYROIDISM (GRAVE’S DISEASE)
May affect large groups of people in a specific
geographical area. Increased T3 and T4 secretion.

Occurs in regions with low iodine levels in the soil and Occurs more frequently in women over 30 years old.
food. Related to an autoimmune factor.
→ Mountainous areas Though there is a risk of developing hypothyroidism or
→ Around the Great Lakes hypoparathyroidism, the following are the treatments:

Iodine is “trapped” by the thyroid gland and used to → Radioactive Iodine
synthesize T3 and thyroxine T4. → Surgical removal of thyroid gland
Leads to low T3 and T4 production and an increase in → Use of antithyroid drugs
TSH from the pituitary gland, produces:
Exophthalmos
→ Hyperplasia
→ Hypertrophy Evident by the presence of protruding, staring eyes and
decreased blink and eye movements
Goitrogens Due to increased tissue mass in the orbit pushing
Foods with elements that block T3 and T4 synthesis but eyeballs forward and from increased sympathetic
increases TSH secretion. stimulation affecting the eyelids.

Lithium and fluoride may be goitrogenic.

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 PH 131: HUMAN ANATOMY AND PATHOLOGY WITH PATHOPHYSIOLOGY
ENDOCRINE SYSTEM
Prof. Vivien Fe F. Fadrilan-Camacho Trans 2

If left untreated, visual impairment may result from optic Primary Prevention
nerve damage or corneal ulceration. No smoking.

Thyrotoxic Crisis or Thyroid Storm → Increases risk of Grave’s disease.

Acute situation of uncontrolled hyperthyroidism, usually Secondary Prevention
precipitated by infection or surgery.
Newborn screening.
Life threatening due to the resulting:
Thyroid disorder medical/surgical management.
→ Hyperthermia
→ Tachycardia
→ Heart Failure
→ Delirium

HYPOTHYROIDISM

Hashimoto’s Thyroiditis
A destructive autoimmune disorder.
Thyroid gland is gradually destroyed due to reactions
made by the immune system against the thyroid gland.

Myxedema
Severe hypothyroidism in adults.
Nonpitting edema manifested as facial puffiness and
thick tongue.
Myxedema coma: acute hypothyroidism resulting in:
→ Hypotension
→ Hypoglycemia
→ Hypothermia
→ Loss of consciousness
→ Life-threatening complications in undiagnosed or
untreated elderly patients.

Cretinism
Untreated congenital hypothyroidism
Either related to iodine deficiency during pregnancy or
developmental defect.
Thyroid gland is nonfunctional or absent.
Neonatal screening aids in early treatment and prevents
mental retardation that accompanies early
hypothyroidism.
Thyroid hormone affects cell metabolism, thus may
affect growth and development due to severe
impairment if left untreated.
Child may be faced with the following:
→ Difficulty feeding
→ Delayed tooth eruption
→ Malocclusion
→ Large protruding tongue
→ Demonstrating stunted skeletal growth
→ Extreme lethargy

PUBLIC HEALTH INTERVENTIONS

Primordial
Iodine Nutrition.
→ Salt iodization
Eliminate thyroid disruptors.
→ Endocrine disrupting chemicals
→ PCBs, cyanide, DDT

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