Endocrine system

Question 1

what is normal thyroid function dependent on

Answer 1

trophic stimulation by TSH

Question 2

what is TSH produced by

Answer 2

anterior pituitary

Question 3

what is TSH production inhibited and stimulated by

Answer 3

• inhibited by T4 and T3

- stimulated by TRH from hypothalamus

Question 4

how is TRH transported to anterior pituitary

Answer 4

hypophyseal portal system

Question 5

clinical signs of hypothyroidism (9)

Answer 5

• lethargy
• alopecia
• weight gain
• dry hair coat/shedding
• anestrus
• hyperpigmentation
• cold intolerance
• bradycardia
• myxedema

Question 6

clinical lab findings in hypothyroidism (6)

Answer 6

• hypercholesterolemia
• atherosclerosis
• corneal lipidosis
• anemia
• low T4
• abnormal TSH

Question 7

2 causes of hypothyroidism

Answer 7

• lymphatic thyroiditis

- idiopathic thyroid atrophy

Question 8

how much of thyroid tissue must be lost to show signs of hypothyroidism

Answer 8

75%

Question 9

lymphocytic thyroiditis

Answer 9

• hypothyroidism cause
• multifocal to diffuse accumulations of lymphocytes, plasma cells, macrophages in thyroid interstitium
• remaining follicles are smaller
• necrotic epithelial cells, fibrosis
• autoantibodies against thyroglobulin and other thyroid antigens

Question 10

idiopathic thyroid atrophy

Answer 10

• hypothyroidism cause
• loss of thyroid follicles, replacement by adipose tissue
• can have inflammation in end stage
• degenerate follicles are smaller, no colloid
• epithelial cells may be necrotic

Question 11

are all dogs affected with lymphocytic thyroiditis likely to be hypothyroid

Answer 11

no –> need 75% affected to be hypothyroid

Question 12

define: goiter

Answer 12

non-neoplastic and non-inflammatory enlargement of the thyroid glands

Question 13

dietary iodine deficiency

Answer 13

• hypothyroidism
• uncommon in most developed nations
• reduces ability of thyroid to make T3/T4
• goitrogenic plants and drugs can cause
• infant mortality –> alopecia, myxedema, asphyxia from goiter

Question 14

dietary iodine overload

Answer 14

• hypothyroidism
• causes hyperplastic goiter (fed lots of seaweed with iodine)
• inhibition of thyroid peroxidase –> decreases organification of iodine –> decreased thyroxine formation
• protects animal from massive thyroid hormone release

Question 15

congenital dyshormonogenetic goiter

Answer 15

• hypothyroidism
• autosomal recessive condition in sheep, cattle, goats
• unable to synthesize and secrete adequate quantities of thyroid hormones
• hyperplastic goiter develops in response to continued TSH stimulation and lack of T3/T4 negative feedback

Question 16

skin lesions of hypothyroidism

Answer 16

• bilaterally symmetric hair loss
• increased scales
• hyperpigmentation
• endocrine dermatosis (thin epidermis, hyperkeratosis)
• myxedema

Question 17

equine congenital hypothyroidism

Answer 17

• iodine deficient soil
• foals born hypothyroid
• silky coat, delayed bone ossification, lax tendons, mandibular prognathism

Question 18

hyperthyoidism clinical signs (8)

Answer 18

• weight loss
• hyperactivity
• polyphagia
• tachycardia
• PU/PD
• heart murmur
• comiting
• diarrhea

Question 19

hyperthyroidism clinical lab findings

Answer 19

• increased T4/T3

- CBC non-specific

Question 20

thyroid pathology of hyperthyroidism

Answer 20

• contain discreet adenomas

- nodular hyperplasia (one or both lobes) –> benign, non-invasive

Question 21

thyroid glands with nodular hyperplasia

Answer 21

• hyperthyroidism
• may be normal sized or slightly enlarged
• follicles with irregular shapes with varying sizes
• follicles elsewhere in gland are atrophied

Question 22

thyroid glands with adenomas

Answer 22

• hyperthyroidism
• enlarged, may be palpable (thyroid slip)
• adenomas sharply deliniated from surrounding tissue
• variable follicle structure, may be partially collapsed

Question 23

cardiac lesions with hyperthyroidism

Answer 23

• left ventricular concentric hypertrophy
• mild to moderate cardiomegaly
• may progress to left-sided congestive heart failure
• reversible

Question 24

canine hyperthyroidism

Answer 24

• boxers, beagles, goldens
• similar clinical signs
• usually associated with thyroid carcinoma –> only some are functional (owners notice neck mass)
• highly malignant neoplasms

Question 25

canine hyperadrenocorticism basic info

Answer 25

• chronic overproduction of cortisol by hyperactive cells of adrenal cortex
• clinical signs related to effects of glucocorticoid hormone on organs

Question 26

clinical signs of canine cushing’s (8)

Answer 26

• PU/PD
• polyphagia
• abdominal distension
• muscular weakness
• alopecia/acne/calcinosis cutis
• increased panting
• testicular atrophy/anestrus
• myopathy

Question 27

clinical lab findings for cushing’s

Answer 27

• CBC: mature neutrophilia, monocytosis, lymphopenia
• serum chem: elevated ALP ALT, cholesterol, glucose, insulin, lipids - decreased BUN
• ACTH stim is gold standard

Question 28

3 causes of canine cushing’s

Answer 28

• pituitary dependent bilateral adrenal cortical hyperplasia/hypertrophy (85%)
• primary functional adrenocortical adenoma/carcinoma
• iatrogenic

Question 29

pituitary dependent bilateral adrenal cortical hyperplasia/hypertrophy and canine cushing’s

Answer 29

• 85% of spontaneous cushing’s
• associated with corticotrophs of pituitary
• macroadenomas damage hypothalamus
• rarely malignant

Question 30

primary functional adenocortical adenoma/carcinoma and canine cushing’s

Answer 30

• 10-15% of cases

- non-neoplastic remnant adrenal cortical tissue atrophied from negative feedback inhibition

Question 31

liver problems and canine cushings’s

Answer 31

• steroid hepatopathy
• liver is grossly enlarged and pale
• enlarged and vacuolated hepatocytes

Question 32

skin problems and canine cushing’s

Answer 32

• endocrine dermatosis
• calcinosis cutis
• atrophy of sweat glands

Question 33

clinical signs of equine PPID (8)

Answer 33

• chronic lameness and abscesses
• PU/PD
• polyphagia
• muscle weakness/wasting
• somnolence
• hyperpyrexia
• hyperhidrosis
• hirsutism

Question 34

clinical lab findings for equine PPID

Answer 34

• hyperglycemia and glucosuria

- plasma cortisol levels normal to slightly elevated

Question 35

etiology of equine PPID

Answer 35

pituitary tumor of pars intermedia

Question 36

type 1 DM

Answer 36

• immune destruction of pancreatic islet beta cells
• insulin therapy required to prevent ketoacidoss and death
• influx of lymphocytes into pancreatic islets –> beta cell destruction
• small number of canine cases, very rare in cats

Question 37

type 2 DM

Answer 37

• cats and humans, not in dogs
• insufficient insulin secretion relative to metabolic demand
• insulin resistance
• progressive loss of beta cells with concurrent deposition of amyloid (formed from islet amyloid peptide IAPP)

Question 38

secondary DM

Answer 38

• may occur in dogs due to chronic relapsing pancreatitis with secondary (non-specific) destruction of pancreatic islets
• may occur in cases of hyperadrenocorticism or growth hormone excess (acromegaly) due to growth hormone secreting pituitary tumor

Question 39

diabetic ketoacidosis

Answer 39

• insulin deficiency and counter-regulatory hormone excess
• insulin deficiency increases release of FFA from adipose cells –> FFA converted in liver to ketone bodies –> increased entry of FFA into liver –> fatty acid oxidation
• excess ketone bodies lead to acidosis and ketonuria –> osmotic duiresis and dehydration

Question 40

cataracts

Answer 40

• fairly common in diabetic dogs
• due to conversion of glucose to sorbitol and fructose in the lens (aren’t freely permeable)
• osmotic swelling and destruction of lens cells

Question 41

neuropathy

Answer 41

• peripheral demyelinating neuropathy
• diabetic cats with “lameness”
• plantigrade stance on hind limbs due to reduced nerve conduction velocity
• can manifest as megacolon with severe constipation

Question 42

primary hyperparathyroidism hormone info

Answer 42

• not very common
• PTH produced in parathyroid gland, secreted in response to decreased Ca ion concentrations in blood
• PTH promotes increased Ca ions in blood

Question 43

features of primary hyperparathyroidism

Answer 43

• older dogs and cats

- lethargy, hypercalcemia, hyperphosphatemia, increased PTH, PU/PD, demineralization of bone

Question 44

etiology of primary hyperparathyroidism

Answer 44

• parathyroid (chief cell) ademonas: uncommon but most common cause of this (enlargement of one parathyroid gland)
• parathyroid (chief cell) carcinomas: rare cause (invade surrounding tissue)

Question 45

features of humoral hypercalcemia of malignancy (HMM; pseudohyperparathyroidism)

Answer 45

• similar to primary hyperparathyroidism
• milder hypercalcemia
• PTH levels may be within normal range

Question 46

etiology of humoral hypercalcemia of malignancy (HMM; pseudohyperparathyroidism) - basic info

Answer 46

• many (usually malignant) neoplasms

- most often due to secretin of parathyroid hormone-related protein (PTHrP) –> binds to PTH receptor in bone and kidney

Question 47

3 primary mechanisms by which humoral factors can induce hypercalcemia in HMM

Answer 47

• stimulation of osteoclastic bone resorption
• increase in calcium reabsorption from kidney
• increase in calcium reabsorption from intestines

Question 48

tumors associated with pseudohyperparathyroidism

Answer 48

• dogs: apocrine adenocarcinoma or anal sac (95% metastasize), lymphosarcoma (usually T-cell - increased PTHrP), other neoplasms
• horses: squamous cell carcinoma

Question 49

pancreatic endocrine neoplasia - cells affected and products

Answer 49

• beta cells (insulin, IAPP)
• alpha cells (glucagon)
• gamma cells (somatostatin)
• PP-cells (pancreatic polypeptide)
• fetal cells (gastrin)
• other: calcitonin gene-related peptide

Question 50

dogs and pancreatic endocrine neoplasias

Answer 50

• uncommon in all breeds

- carcinomas more common than adenomas

Question 51

other domestic species and pancreatic endocrine neoplasias

Answer 51

• ferrets: relatively common (adrenal cortical adenomas/carcinomas)
• very rarely reported in other domestic species

Question 52

pathology of pancreatic endocrine neoplasias

Answer 52

• firm, dense fibrous texture when cut
• adenomas are well delineated and encapsulated
• carcinomas are poorly delineated and invade surrounding tissues
• polyhederal cells in lobular pattern

Question 53

insulinomas

Answer 53

• hypoglycemia from inappropriate secretion of insulin

- muscle tremors and fasciculation, seizures, coma, death

Question 54

glucagonomas

Answer 54

• rare in dogs

- associated with superficial necrolytic dermatitis

Question 55

gastrinomas

Answer 55

• rare in dogs
• associated with gastrin hypersecretion
• GI issues

Question 56

pheochromocytoma

Answer 56

• neoplasm from chromaffin cell of adrenal medulla
• secretion of catecholamines (norepinephrine)
• dogs and cattle
• 50% show evidence of malognancy (adrenal vein –> caudal vena cava)

Question 57

hypoadrenocorticism (addison’s disease)

Answer 57

• adrenal cortical insufficiency
• causes: idiopathic (all layers affected), adrenitis (bacterial and parasitic agents), adrenocortical hemorrhage (sepsis)

Question 58

pathogenesis of addison’s disease

Answer 58

• less potassium excreted –> hyperkalemia

- less Na/Cl reabsorbed –> hypernatremia, hyperchloriduria

Question 59

clinical signs of addison’s disease

Answer 59

• result of deficient production of corticosteroids
• non-specific symptoms, variety of them
• circulatory collapse, hyporension, emesis, diarrhea, anorexia

Question 60

diabetes insipidus

Answer 60

• inadequate production of ADH (hypophyseal/central form) OR when target cells in kidney fail to respond to ADH (nephrogenic form)
• from compression/destruction of pars nervosa, infundibular stalk, or supraoptic nucleus in hypothalamus
• nephrogenic form: ADH levels normal (body can’t repond)
• produce large volumes of hypotonic/dilute urine –> PU/PD

Question 61

pituitary dwarfism (panhypopituitarism)

Answer 61

• failure of the oropharyngeal ectoderm of rathke’s pouch to differentiate into trophic hormone secreting cells of pars distalis
• result is progressively enlarging, multiloculated cyst and absence of adenohypophysis
• autosomal recessive (german shepherds)