Endocrine Flashcards

Question 1

Q

What is the main pancreatic disease?

Answer

A

Diabetes Mellitus (DM)

Question 2

Q

What are the two types of DM?

Answer

A

Type 1 (Autoimmune destruction of pancreatic B cells, resulting in lack of insulin secretion).
Type 2 (decrease in insulin sensitivity).

Question 3

Q

What is diabetes mellitus?

Answer

A

Chronic hyperglycaemia due to insulin dysfunction.

- Glucose cannot be moved from bloodstream into cells effectively, leading to them being starved of energy.

Question 4

Q

What is the clinical presentation of type 1 diabetes?

Answer

A

Hyperglycaemia
Polydipsia
Polyuria
Weight loss
Blurred vision
Nausea and vomiting
Usually diagnosed in the young.
Can present with diabetic ketoacidosis.

Question 5

Q

What is the clinical presentation of type 2 diabetes?

Answer

A

Usually asymptomatic, and picked up by screening.

- Screening should be carried out when risk factors are present.

Question 6

Q

What is the pathophysiology of type 1 diabetes?

Answer

A

Hyperglycaemia due to insulin deficiency.
Insulin deficiency occurs as a result of pancreatic B-cell destruction (usually caused by autoimmune mechanisms)
If no evidence of autoimmune destruction, the disease is referred to as idiopathic type 1 DM.

Question 7

Q

What is the pathophysiology of type 2 diabetes?

Answer

A

Multifactorial disorder
Increase in insulin resistance, often accompanied by deficit in insulin secretion.
Leads to chronic hyperglycaemia.

Question 8

Q

What is the aetiology of type 1 diabetes?

Answer

A

HLA-DR3/4 (human leukocyte antigen) is affected in >90% of type 1 diabetic patients.
This abnormality causes autoimmune disease, often including the attack of islet cells (mainly B cells) of the pancreas.

Question 9

Q

What is the aetiology of type 2 DM?

Answer

A

Multifactorial
There is an element of genetic susceptibility, but not as strong as in type 1 DM.
No HLA link established.

Question 10

Q

What is the epidemiology of type 1 DM?

Answer

A

Onset younger (<30)

- Usually patients will be skinny.

Question 11

Q

What is the epidemiology of type 2 DM?

Answer

A

Onset older (>30)
Patients are usually overweight.
More common than type 1 DM generally speaking.

Question 12

Q

What are the diagnostic tests for type 1 DM?

Answer

A

Plasma glucose test (random, fasted, 2 hour etc.).
HbA1c. This will provide a measurement of the average plasma glucose over the last 2-3 months.
C peptide. This will go down in type 1 DM and remain the same/increase in type 2 DM.

Question 13

Q

What are the diagnostic tests for type 2 DM?

Answer

A

Plasma glucose test (random, fasted, 2 hours etc.).
HbA1c. This will provide a measurement of the average plasma glucose over the last 2-3 months to see if it is chronically raised.

Question 14

Q

What clinical test can be done to tell the difference between type 1 and type 2 DM?

Answer

A

C peptide test.
C pep will be low in type 1 DM
C pep will be normal/raised in type 2 DM.

Question 15

Q

What is the treatment for type 1 DM?

Answer

A

1st line:

Basal-bolus insulin
Pre-meal insulin IF NEEDED
Metformin (a biguanide) IF NEEDED.

Question 16

Q

What is the treatment for type 2 DM?

Answer

A

First line: Diet and exercise changes.
If no change, prescribe metformin (biguanide).
Add SGLT2 inhibitor if CV risk is high (canagliflozin)
Potentially use sulfonylurea (glimepiride) if metformin not tolerated.
Give aspirin (non-selective COX inhibitor) or clopidogrel (P2Y12 antagonist) to reduce risk of CVD. Both aspirin and clopidogrel are antiplatelet drugs.

Question 17

Q

What are the potential complications of type 1 and 2 DM?

Answer

A

Diabetic ketoacidosis (body cannot use glucose as fuel due to lack of insulin, so begins to use lipids and peptides instead. This produces ketones, which are released into the blood. High levels of ketones are toxic.)
Diabetic nephropathy (chronically high glucose levels do damage to kidneys).
Diabetic neuropathy (high glucose levels -> neurological damage, causing lack of sensation in feet/hands.)
Diabetic retinopathy (damage to retinal blood vessels, which if severe enough can lead to vision defects.)
Hyperosmolar hyperglycaemic nonketotic coma (caused by extremely high glucose levels, similar to ketoacidosis, but with the absence of high ketone levels).

Question 18

Q

What are the 4 main thyroid disorders I need to be aware of?

Answer

A

Graves disease
Hashimoto’s thyroiditis
Hypothyroidism
Thyroid cancer/ malignancies.

Question 19

Q

What is Grave’s disease?

Answer

A

HYPERthyroidism due to the pathological stimulation (immune system disorder) of TSH receptors.

Question 20

Q

What is the difference between primary and secondary hyperthyroidism?

Answer

A

Primary hyperparathyroidism - Disease is directly within the thyroid, leading to increased T3/T4 secretion (unrelated to TSH levels)

Secondary hyperparathyroidism - Thyroid gland is being overstimulated by excessive TSH hormones.

Question 21

Q

How will a person with Grave’s syndrome present clinically?

Answer

A

Rapid heart beat
Tremor
Diffuse palpable goitre (swollen thyroid gland).
Audible bruit over thyroid gland (audible pulse over thyroid due to vascular proliferation).
Eye problems: Bulging eyes, and lid retraction.

Question 22

Q

What is the pathophysiology of Grave’s disease?

Answer

A

Thyroid stimulating immunoglobulins bind to TSH receptors on the thyroid, leading to excess T3 and T4 (thyroxine) production.
T4 receptors on the pituitary are stimulated due to elevated T4 levels, leading to suppression of TSH secretion.
Therefore, Grave’s disease causes high thyroid hormone levels, with low TSH.

Question 23

Q

What is the aetiology of Grave’s disease?

Answer

A

Unclear.
There is an element of genetic influence.
It is an autoimmune disease, and associated with other autoimmune diseases such as parnicious anaemia and myasthenia gravis.

Question 24

Q

What is the epidemiology of Grave’s disease?

Answer

A

The most common cause of hyperthyroidism.

Question 25

Q

What are the diagnostic tests for Grave’s?

Answer

A

Thyroid hormone tests. High T3 and T4

- TSH test. Lower than normal TSH.

Question 26

Q

What are the potential treatments for Grave’s disease?

Answer

A

Antithyroid drugs (carbimazole usually, else propylthiouracil). These will be taken in one of two ways:
Block and replace. Prolonged treatment using the drug, along with levothyroxine to replace the lost thyroid hormone.
Titration. Gradual reduction in the dose of anti-thyroid, until the naturally produced thyoid hormones are at the right level again.
Also give a B blocker (atenolol or propanolol) to treat symptoms such as tachycardia, tremor and anxiety. If contraindicated give CCB (verapamil).
Thyoidectomy (partial or complete)
Radioactive iodine. Taken up by thyroid, and will subsequently kill some of the thyroid, reducing hormone production.

Question 27

Q

What is the most common complication of grave’s disease?

Answer

A

Thyroid storm (same as thyrotoxic crisis).

This is a hypermetabolic state induced by the presence of excessive thyroid hormones.

Hyperthyroidism can also cause atrial fibrillation, and a subsequent irregularly irregular heartbeat.

Question 28

Q

What is Hashimoto’s thyroiditis?

Answer

A

HYPOthyroidism due to aggressive destruction of thyroid cells.

Question 29

Q

How will a person with Hashimoto’s disease present clinically?

Answer

A

Rapid enlargement of the thyroid gland, which can cause dyspnoea and/or dysphagia due to pressure changes.
The hypothyroidism will cause fatigue, cold intolerance, slowed movement, decreased sweating. (decreased metabolic activity).

Question 30

Q

What is the pathophysiology of Hashimoto’s disease?

Answer

A

Autoimmune disease.

- Causes aggressive destruction of thyroid cells, and thyroid fibrosis.

Question 31

Q

What is the aetiology of Hashimoto’s disease?

Answer

A

Unknown
Autoimmune, with some genetic relation.
Can be triggered by iodine insufficiency, infection, smoking and stress.

Question 32

Q

What is the epidemiology of Hashimoto’s disease?

Answer

A

More common in places with lower iodine intake/ iodine deficiency in diet.
Approx. 15x more likely in women.
The most common cause of HYPOthyroidism.

Question 33

Q

What investigations are required for diagnosis of Hashimoto’s thyroiditis?

Answer

A

TSH levels will usually be raised (negative feedback).

- Thyroid antibodies will be present.

Question 34

Q

What treatments are available for Hashimoto’s disease?

Answer

A

Thyroid hormone replacement (levothyroxine).

- Resection of obstructive goitre to relieve symptoms (dyspnoea and dysphagia.)

Question 35

Q

What are the potential complications of hypothyroidism?

Answer

A

Hyperlipidemia. (Blood contains too many lipids, such as cholesterol and triglycerides.). This can increase risk of cardiovascular disease over time.
Myxoedema coma. A form of endocrine emergency (20-50% mortality), usually caused by extreme (and untreated) hypothyroidism. Treated with thyroid replacement (levothyroxine) and hydrocortisone (to protect against potential adrenal insufficiency).

Question 36

Q

What is Hashimoto’s encephalopathy?

Answer

A

Effects brain function

- Associated with Hashimoto’s thyroiditis, but relationship unclear.

Question 37

Q

Other than Hashimoto’s disease, what are the 3 broad categories of hypothyroid disease?

Answer

A

Primary
Secondary
Transient

Question 38

Q

What is the clinical presentation of hypothyroidism?

Answer

A

Symptoms relate to reduced metabolic activity.

Insidious (slow) onset.
Tiredness/ lethargy
Intolerance of cold
goitre (swelling of thyroid gland)
Slowing of intellectual activity.
Constipation
Deep hoarse voice
Puffy face, hands and feet.

Question 39

Q

What do the different classifications of thyroid disease mean?

Answer

A

Primary. Means disease directly associated with the thyroid gland.
Secondary. Means disease associated with the pituitary or hypothalamus.
Transient. Means it is temporary hypothyroidism (eg after birth, or after withdrawing from treatment for a short time.)

Question 40

Q

What is the pathophysiology of primary hypothyroidism?

Answer

A

Aggressive destruction of the thyroid cells due to cellular/antibody mediated immune processes.
Antibodies bind and block TSH receptors on thyroid, leading to inadequate T3/4 production and secretion.

Question 41

Q

What is the pathophysiology of secondary hypothyroidism?

Answer

A

Reduced release or production of TSH due to issues with either the hypothalamus (TRH) or the pituitary (TSH).
This results in reduced T3/4 release from the thyroid.

Question 42

Q

What is the pathophysiology of transient hypothyroidism?

Answer

A

Sudden deficit of T3/4 leading to raised TSH levels (-ve feedback) as the thyroid tries to re-establish normal T3/4 levels.

Question 43

Q

What is the aetiology of hypothyroidism?

Answer

A

Primary:

Hashimotos thyroiditis (autoimmune)
Iodine deficiency
Congenital defects

Secondary:

Isolated TSH deficiency
Hypopituitarism (due to neoplastic infection/tumour of pituitary).
Hypothalamic disorder (neoplasm, severe head trauma).

Transient:
- Caused by withdrawal from thyroid therapies., such as iodine supplementation withdrawal.

Question 44

Q

What are the diagnostic tests used to diagnose hypothyroidism?

Answer

A

Low free serum T4 levels.
TSH will be normal/high in primary hypothyroidism.
TSH will be low in secondary hypothyroidism.

Question 45

Q

What treatments are given for primary and secondary hypothyroidism?

Answer

A

Primary - Thyroid hormone replacement therapy (Levothyroxine), and potential resection of the obstructive goitre.

Secondary - Still give thyroid hormone replacement (levothyroxine) but also treat the underlying cause.

Transient - Will often resolve on its own. If due to treatment withdrawal, consider restarting treatment/ re-establishing a higher dose.

Question 46

Q

What are the 5 common classifications of thyroid cancer?

Answer

A

Papillary
Follicular
Anaplastic
Lymphoma
Medullary

Question 47

Q

What thyroid cancers usually present as asymptomatic thyroid nodules (hard and fixed)?

Answer

A

Papillary thyroid cancer
Follicular thyroid cancer
Anaplastic thyroid cancer

Question 48

Q

What thyroid cancer presents as a rapidly growing mass in the neck?

Answer

A

Thyroid lymphoma

Question 49

Q

What thyroid cancer causes diarrhoea, flushing episodes and itching?

Answer

A

Medullary thyroid cancer.

Question 50

Q

What is a papillary thyroid cancer?

Answer

A

A cancer of the thyroid gland which exhibits papillae (small rounded processes) amongst it’s cells histologically.

Question 51

Q

What is a follicular thyroid cancer?

Answer

A

Cancer of the follicular cells of the thyroid (cells responsible for T3/4 production and secretion.

Question 52

Q

What is an anaplastic thyroid cancer?

Answer

A

A very aggressive, rapidly proliferating cancer.

- Consists of cells that have little to no resemblance to normal cells.

Question 53

Q

What is a thyroid lymphoma?

Answer

A

Cancer of the thyroid originating from leukocytic cells.

Question 54

Q

What is a medullary thyroid cancer?

Answer

A

Cancer that starts in the “C” cells of the thyroid. These are the cells that produce calcitonin (related to calcium management in the body).

Question 55

Q

What is the pathophysiology of a papillary thyroid cancer?

Answer

A

Tends to spread locally within the neck.

- Could compress the trachea.

Question 56

Q

What is the pathophysiology of a follicular thyroid cancer?

Answer

A

Greater likelihood to metastasise and spread to the lungs and bones than a papillary thyroid cancer.
Still may infiltrate neck

Question 57

Q

What is the pathophysiology of an anaplastic thyroid cancer?

Answer

A

Dedifferentiation of follicular thyroid cells, and rapid proliferation of those cells.
Dedifferentiation means that these cancer cells no longer uptake iodine or contribute to T3/4 synthesis.

Question 58

Q

What is the pathophysiology of thyroid lymphoma?

Answer

A

Originates from leukocytic cells.

- Almost always will be non-hodgkins (Reed-Sternberg cells are NOT present in non-hodgkins).

Question 59

Q

What is the pathophysiology of medullary thyroid cancer?

Answer

A

Cancer of the parafollicular calcitonin producing cells (“C-cells”).
Medullary cancer results in large amounts of calcitonin production (affects calcium regulation - hypocalcaemia).

Question 60

Q

What is the epidemiology of thyroid cancers?

Answer

A

70% of thyroid cancer is papillary, and this is 3x more common in women. Also more likely to occur in young people.
20% of thyroid cancer is follicular. Occurs in middle ages and more common for people with iodine deficiency.
Lymphoma, anaplastic and medullary thyroid cancers are far less common.
Thyroid lymphoma is associated with Hashimoto’s thyroiditis (an inflammatory hypothyroid disease, so makes sense!).

Question 61

Q

What investigations are conducted to diagnose thyroid cancers?

Answer

A

Fine needle aspiration, then histological assessment of the biopsy.
Calcitonin can be measured by blood test. If serum calcitonin is high, probably medullary cancer.

Question 62

Q

What are the treatment options for thyroid cancer?

Answer

A

Total thyroidectomy
Radioactive iodine administration.
External radiotherapy. (Palliative care to reduce symptoms).
Prophylactic central lymph node dissection (a preventative measure to reduce chance of cancer spreading).

Question 63

Q

What is the main disease of hypercortisolism?

Answer

A

Cushing’s syndrome

Question 64

Q

What is Cushing’s syndrome?

Answer

A

Persistently and inappropriately elevated circulating glucocorticoid (cortisol).

Answer 65

A

Obesity (with fat distribution being central “pot belly”)
Plethoric complexion (red faced)
Rounded “moon face”
Thin skin
Bruising
Striae (around abdomen especially)
Hypertension
Pathological fractures.

Answer 66

A

When the elevated glucocorticoid levels are attributed to inappropriate ACTH secretion from the pituitary (secondary hyperglucocorticoid disease).
Caused by presence of a benign adenoma of the pituitary gland.
Cushing’s disease is a subtype of cushing’s syndrome.

Answer 67

A

Many features occur due to the catabolic effect cortisol has on protein. (Such as thin skin, easy bruising, striae).
Excessive alcohol intake can mimic the clinical and biochemical signs of Cushing’s syndrome. However, these symptoms will resolve when alcohol intake is reduced. (Pseudo-cushing’s).

Answer 68

A

ACTH-dependant Cushing’s (secondary):

Excessive ACTH from pituitary (Cushing’s disease).
ACTH producing tumour
Too much ACTH being administered to patient.

ACTH-independent Cushing’s (primary):

Excess glucocorticoid administration (MOST COMMON CAUSE)
Adrenal adenomas
Adrenal carcinomas

Answer 69

A

(AdrenoCorticoTrophic Hormone)

Answer 70

A

1/100,000
Higher incidence in patients with diabetes.
2/3 of Cushing’s cases are Cushing’s disease (secondary hyperglucocorticoid) rather than Cushing’s syndrome.

Answer 71

A

CONFIRM RAISED CORTISOL LEVELS:

48 hour low dose dexamethasone. For a normal patient, this will result in less ACTH being released (-ve feedback) by the pituitary, and as a result less cortisol will be released by the adrenal glands.
However, a cushing’s syndrome patient will have raised cortisol levels, as the increased level of cortisol will not impact upon their cortisol production.

This is established by monitoring the cortisol levels.

ESTABLISHING THE CAUSE OF CUSHINGS SYNDROME:

Carry out an MRI of both the renal system (adrenal glands for primary disease/ACTH-independent disease) and the pituitary.(for secondary disease/ ACTH dependant disease).

Answer 72

A

For tumours, surgical removal. This is first line for all types of Cushing syndrome where it is possible.
Otherwise, cortisol synthesis inhibition. (Drugs include metyrapone and ketoconazole).

Answer 73

A

Hypertension
Obesity (Increase in circulating FFA (free fatty acids) leading to lipid accumulation in both the liver and skeletal muscle).
Potential death

Answer 74

A

No, rarely enters remission.

Answer 75

A

Overgrowth of all organ systems due to excess GH.

Answer 76

A

Slow onset (timeline only usually established by using old photos).
Larger hands/feet.
Large tongue
Prognathism (protruding jaw).
Interdental separation
Spade-like hands (widened fingers).

Answer 77

A

Gigantism occurs when GH secretion is high in younger people whose long bone epiphyses have not yet fused. This leads to them having tall stature along with large hands and feet.
Acromegaly occurs when GH secretion is high in older people after their long bone epiphyses have already fused. As a result there is no change in stature, just an increase in hand and feet size.

Answer 78

A

GH acts directly upon many tissues such as the liver, muscle, bone and fat.
GH also acts indirectly, as it affects the levels of insulin-like growth factor (IGF-1) which also contributes to managing growth and development.
Excess of either hormone causes excess growth of many different organ systems.

Answer 79

A

Normally as a result of excessive GH secretion by a pituitary tumour.
GH can be secreted by other tumours too such as hypothalamic and specific lung cancers, but this is far rarer.

Answer 80

A

1/200,000
Average age of DIAGNOSIS is 40, but disease has often been present long before then due to the insidious progression pattern.

Answer 81

A

2 Components:

Glucose tolerance test (GOLD STANDARD)x:

Patient is given a high glucose content drink
Normally, GH would drop in response to this. If it doesn’t drop sufficiently, person has acromegaly.

IGF-1 test:
- IGF-1 stays a lot more constant throughout the day than GH does, so provides a much better average to go off when trying to determine whether a person has too much GF/IGF-1 or not than GH alone.

Answer 82

A

Transsphenoidal resection surgery (removal of pituitary tumour). IF POSSIBLE THIS IS 1ST LINE.
IF SURGERY NOT POSSIBLE SOMATOSTATIN ANALOGUES ARE FIRST LINE (Again, somatostatin inhibits GH production). 2 examples of SSA are Octreotide and Ianreotide.
Dopamine agonists (Bind to D2 receptors and restrict GH secretion). Often given as dual therapy with SSAs.

2nd line:
- GH receptor antagonists (Due to -ve feedback loops, suppress GH secretion) For example, pegvisomant.

Answer 83

A

Hypertension
Diabetes
Untreated adenoma can impact optic chiasm (Blindness/ vision impairment).
Acromegaly patients are at a significantly higher risk of colorectal cancer.

Answer 84

A

Same thing as primary hyperaldosteronism.

- Means that aldosterone levels are high INDEPENDENTLY of the RAAS system.

Answer 85

A

Hypertension (possibly low urine output)

- Hypokalaemia (aldosterone increases K excretion, but increases Na and water retention).

Answer 86

A

This is where aldosterone levels are high due to high renin levels (so DEPENDANT on the RAAS system).

Answer 87

A

Aldosterone stimulates sodium reabsorption and potassium excretion in the distal tubules.
Therefore, hyperaldosteronism will cause increased sodium reabsorption, and increased potassium excretion.
If sodium reabsorption increases, so does water reabsorption.

Answer 88

A

Potentially an adrenal adenoma secreting excess aldosterone.

Answer 89

A

Plasma aldosterone (high)

- Renin (should be low - if normal or high suggests secondary hyperaldosteronism).

Answer 90

A

For an adenoma:
- Surgical removal

For adrenal hyperplasia:
- Aldosterone antagonist (usually spironolactone).

Answer 91

A

The adrenal glands do not produce adequate levels of adrenal hormones.

Answer 92

A

Primary adrenal insufficiency.

Answer 93

A

Autoimmune destruction of the adrenal cortex, leading to less cortical products (cortisol AND aldosterone).
Negative feedback stimulates excess ACTH, leading to melanocyte stimulation and HYPER PIGMENTATION (differentiates Addison’s from secondary hypoadrenalism).

Answer 94

A

Insidious onset.
Non-specific symptoms (lethargy, depression, anorexia, weight loss, weakness, fatigue).
Postural hypertensions

The 4 T’s:

Thin
Tanned (hyperpigmentation)
Tired
Tearful

Answer 95

A

Organ specific autoantibodies in 90% of cases.

Answer 96

A

Morning serum cortisol, and ACTH levels should be taken at the same time.
Raised ACTH with low serum cortisol is a strong indicator of Addison’s disease (primary adrenal insufficiency).

Answer 97

A

Hormone replacement (hydrocortisone) and mineralocorticoid (fludrocortisone).

Answer 98

A

Acute medical emergency caused by a lack of cortisol.
IV hydrocortisone immediately if suspected.
Saline for hypotension/ dehydration if required. If glucose is low, 5% dextrose.
Treat underlying cause if possible.

Answer 99

A

Reduction of adrenal cortex stimulation.
Less cortisol (but not less aldosterone) due to low ACTH.
Low ACTH means there is NO PIGMENTATION (differentiates this disease from Addison’s).

Answer 100

A

Same as Addison’s but without the pigmentation:
Tired
Teary
Thin
NOT Tanned

Answer 101

A

Hypothalamic-pituitary disease.

- Long-term steroid therapy. This can lead to suppression of the HPA (hypothalamic-pituitary-adrenal) axis.

Answer 102

A

Serum cortisol + ACTH.

- Both cortisol and ACTH being low will indicate secondary adrenal insufficiency.

Answer 103

A

Hormone replacement (just hydrocortisone, as aldosterone has not been affected).
Try to taper off the hydrocortisone if condition improves.

Answer 104

A

“MURDER”

M-Muscle weakness
U-Urine- oliguria, anuria
R-Respiratory distress
D-Decreased cardiac contractility
E-ECG changes (Tall, tented T waves and prolonged PR interval)
R-Reflexes- hyperreflexia, or areflexia (flaccid)

Answer 105

A

Tall, tented T waves

- Sometimes loss of P waves

Answer 106

A

Renal impairment (most common). Leads to potassium retention in the nephron.
Can also caused by use of potassium sparing diuretics (drugs that increase water loss but not potassium loss).

Answer 107

A

Usually, routine blood test that finds raised potassium.

- Sometimes, ECG. Will show tall, tented T waves and sometimes absence of P waves.

Answer 108

A

Restriction of dietary potassium.

- Loop diuretics.

Answer 109

A

MI causing death.

Answer 110

A

Usually asymptomatic
Muscle weakness
Increased risk of arrhythmia
Polyuria

Answer 111

A

T wave flattening/ inversion.

- Presence of a U wave (wave after T, representing repolarisation of the purkinjee fibres.

Answer 112

A

Excessive loss of potassium through the kidneys in response to aldosterone therapy or diuretic therapy.
Aldosterone directly inhibits potassium reabsorption in the kidneys (due to Na K pumps being up-regulated).

Answer 113

A

Routine bloods show low K

- ECG. Flat/ inverted T waves and potentially prominent U waves.

Answer 114

A

Treat underlying cause

Withdrawal of harmful medication.
Increase dietary potassium/ give a potassium supplement if required.
Check magnesium levels, as these are closely related.

Answer 115

A

Cardiac arrhythmia and sudden death.

Answer 116

A

Continued secretion of ADH despite:

plasma hypotonicity (less solute concentration than cells).
normal plasma volume.

Answer 117

A

If mild:

Nausea
Headache
Irritability
Mild hyponatraemia

If severe:

Fits
Coma
Severe hyponatraemia

Answer 118

A

Impaired free water excretion secondary to inappropriate secretion of ADH.

Answer 119

A

Disordered hypothalamic-pituitary secretion of ADH.
Ectopic ADH production.

Neurological:

Trauma
Tumour
Infection

Pulmonary:

Small cell cancer
Mesothelioma
CF

Answer 120

A

FBC (low osmolality of electrolytes)

- Check how concentrated urine is (often still highly concentrated despite low osmolality of serum electrolytes).

Answer 121

A

1st line:

Reduce fluid intake.
Treat underlying cause.

2nd line or if disease is more severe:
- Tolvaptan (ADH receptor antagonist).

Answer 122

A

The hyposecretion of or insensitivity to ADH.

Answer 123

A

Cranial diabetes insipidus.

Answer 124

A

Nephrogenic diabetes insipidus.

Answer 125

A

Polyuria

- Compensatory polydipsia

Answer 126

A

Disease of the hypothalamus (site of ADH production) resulting in insufficient ADH production.

Answer 127

A

Depends on the aetiology

- Can be disruption of channels/damage to the kidneys, resulting in reduced response to ADH.

Answer 128

A

Neurosurgery.
Trauma.
Tumour.
Infiltrative disease of the hypothalamus.
Idiopathic.

Answer 129

A

Hypokalaemia
Hypercalcaemia
Drugs
Renal tubular acidosis
Sickle cell
Prolonged polyuria
CKD

Answer 130

A

Urine volume
- Confirm there is polyuria (>3L every 24 hours)

Water deprivation test:

Deprive patient of fluid for 8 hours.
Measure serum and urine osmolality, and urine volume hourly.
For a patient with DI, the urine will remain dilute despite dehydration.

Answer 131

A

Administer desmopressin (synthetic ADH).
If the patient responds normally to the desmopressin, DI is central/cranial and to do with ADH production.
If there is little to no change in the patients urine and it remains dilute, DI is nephrogenic and to do with ADH insensitivity.

Answer 132

A

Central DI:
- Desmopressin

Nephrogenic DI:

Treat underlying cause (often renal disease)
Maintain adequate fluid intake to prevent dehydration.
Can use hydrochlorothiazide or sodium restriction in diet to reduce urine output.

Answer 133

A

Excessive secretion of PTH

Answer 134

A

Primary hyperparathyroidism:
- One parathyroid gland produces excess PTH, due to adenoma or hyperplasia of the gland.

Secondary hyperparathyroidism:
- Increased secretion of PTH to compensate for hypocalcaemia.

Tertiary hyperparathyroidism:
- Autonomous secretion of PTH due to chronically high levels of calcium.

Answer 135

A

70-80% asymptomatic.
Bone pain (osteoporosis or osteopenia)
Renal calculi
Nausea
Neuropsychiatric

“Bones, stones, abdominal groans and psychic moans”.

Answer 136

A

CKD signs
Muscle cramps
Bone pain

Answer 137

A

Single parathyroid adenoma or hyperplasia.

Answer 138

A

CKD usually, but can be any condition with hypocalcaemia (e.g. vitamin D deficiency)
Tertiary hyperparathyroidism develops from secondary if hypersecretion of PTH is chronic.

Answer 139

A

Third most common endocrine disorder.

Answer 140

A

All through blood tests:

Primary - Hypercalcaemia and raised PTH
Secondary - Hypocalcaemia and raised PTH.
Tertiary - Hypercalcaemia and chronically high PTH

To tell the difference between primary and tertiary look at course of disease and symptoms (is there any CKD?).

Answer 141

A

Surgical removal of adenoma.
Vit. D supplementation (increase gut absorption of calcium, otherwise this will be down-regulated due to high levels of calcium already in the blood).
If osteoporosis is present, consider biphosphonates (alendronic acid).

Answer 142

A

Vit D and calcium supplementation always.
If malabsorption related, treat the GI cause.
If CKD related, treat the CKD.

Answer 143

A

Partial or total parathyroidectomy with close calcium monitoring afterwards.

Answer 144

A

Caused by reduction or absence of PTH, leading to low calcium (hypocalcaemia) and elevated phosphate (hyperphosphataemia).

Answer 145

A

Increased excitability of muscles and nerves.
Numbness around the mouth/extremities.
Cramps/convulsions
Positive Trousseau sign (occlude blood flow to hand, leading to flexion at the wrist and MCP joints - this is a sign of hypocalcaemia).
Positive Chvostek sign (tap the mandible of an individual - their facial muscles twitch. Another sign of hypocalcaemia).

Answer 146

A

Normally, PTH stimulates vitamin D activation, which facilitates:

intestinal calcium absorption.
renal reabsorption of calcium.
calcium release from bone.

PTH also inhibits phosphate reabsorption.

ALL OF THESE PROCESSES ARE INHIBITED IN HYPOPARATHYRODISIM.

Answer 147

A

Can be transient.

- Most commonly follows anterior neck surgery.

Answer 148

A

Calcium low
PTH low
Phosphate high

Answer 149

A

Calcium

- Calcitrol (biologically active form of vitamin D).

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Endocrine Flashcards

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