3.3 - Disorders of vasopressin

Question 1

How does the posterior pituitary gland work?

Answer 1

• anatomically continuous with hypothalamus
• hypothalamic magnocellular neurons containing arginine vasopressin (AVP) or oxytocin
• neurons are long, originate in supraoptic and paraventricular hypothalamic nuclei
• nuclei –> stalk –> posterior pituitary

Question 2

What is diuresis?

Answer 2

Production of urine

Question 3

What is the physiological action of vasopressin (ADH)? (3)

Answer 3

• stimulation of water reabsorption in renal collecting duct - acts through V2 receptor
• also a vasoconstrictor via V1 receptor
• stimulates ACTH release from anterior pituitary

Question 4

How does AVP concentrate urine?

Answer 4

1. AVP from pituitary enters bloodstream and binds to V2 receptor on kidney tubule cell
2. cascade
3. aquaporin-2 inserted into apical membrane of kidney tubule cell
4. water enters the kidney tubule cell from the tubular lumen
5. water leaves the kidney tubule into the blood via aquaporin-3

Question 5

How does the posterior pituitary come up on MRI?

Answer 5

• as a bright spot
• not visualised in all healthy individuals, so absence may be normal

Question 6

What is the stimuli for vasopressin release?

Answer 6

• increase in plasma osmolality (concentration) sensed by osmoreceptors
• osmoreceptors are special sensory receptors in the hypothalamus

Question 7

How do osmoreceptors regulate vasopressin?

Answer 7

1. increase in plasma osmolality (e.g. increase in extracellular Na+, due to dehydration)
2. water moves out of the osmoreceptor via osmosis
3. osmoreceptor shrinks
4. stimulates increased osmoreceptor firing
5. AVP release from hypothalamic neurons

Question 8

What is the physiological response to water deprivation?

Answer 8

1. increased plasma osmolality
2. stimulation of osmoreceptors
3. leads to increased thirst AND increased AVP release
4. increased AVP release leads to increased water reabsorption from renal collecting ducts
5. reduced urine volume, increase in urine osmolality
6. reduction in plasma osmolality as more water reabsorbed

Question 9

What is arginine vasopressin deficiency (AVP-D)?

Answer 9

• previously known as cranial (central) diabetes insipidus
• problem with hypothalamus and/or posterior pituitary
• unable to make AVP

Question 10

What is arginine vasopressin resistance (AVP-R)?

Answer 10

• previously known as nephrogenic diabetes insipidus
• can make AVP (normal hypothalamus and posterior pituitary)
• kidney (collecting duct) unable to respond to AVP (e.g. damaged receptors)

Question 11

Why do the symptoms of AVP deficiency/resistance occur?

Answer 11

1. AVP problem - deficiency/resistance
2. impaired concentration of urine in renal collecting duct
3. large volumes of dilute (hypotonic) urine
4. increase in plasma osmolality (and sodium)
5. stimulation of osmoreceptors
6. thirst - polydipsia
7. maintains circulating volume as long as patient has access to water

Question 12

How can AVP deficiency/resistance lead to death?

Answer 12

When there is no access to water, the patient dehydrates and dies (since water cannot be reabsorbed from urine therefore rely on drinking water)

Question 13

Why have we moved away from using the term diabetes insipidus?

Answer 13

• diabetes insipidus is not the same as diabetes mellitus
• preventing a patient with DI from drinking / not giving fluids if unable to drink can cause death
• moved away from DI due to this reason
• AVP deficiency = cranial DI
• AVP resistance = nephrogenic DI

Question 14

What are the symptoms of AVP deficiency/resistance? (3)

Answer 14

• polyuria
• nocturia
• polydipsia - extreme thirst

Question 15

Why do the symptoms occur differently in diabetes mellitus vs AVP deficiency/resistance?

Answer 15

• in DM (hyperglycaemia), these symptoms are due to osmotic diuresis (high glucose conc in urine = large volumes)
• in AVP deficiency/resistance, these symptoms are due to a problem with AVP

Question 16

Which is more common out of diabetes mellitus vs insipidus for these symptoms?

Answer 16

• diabetes mellitus
• if you see someone with these symptoms, check their BGC first

Question 17

What are the two types of causes of AVP deficiency?

Answer 17

• acquired (more common)
• congenital (rare)

Question 18

What are examples of acquired causes of AVP deficiency? (6)

Answer 18

• traumatic brain injury
• pituitary surgery
• pituitary tumours
• metastasis to pituitary gland e.g. breast
• granulomatous infiltration of pituitary stalk e.g. TB, sarcoidosis
• autoimmune

Question 19

What are the causes of AVP resistance?

Answer 19

• much less common than AVP-deficiency
• congenital - rare e.g. mutation in gene encoding V2 receptor, aquaporin-2 type water channel
• acquired - drugs e.g. lithium

Question 20

What happens to urine in AVP deficiency / resistance?

Answer 20

• very dilute (hypo-osmolar)
• large volumes

Question 21

What happens to plasma in AVP deficiency / resistance?

Answer 21

• increased concentration (hyper-osmolar) as patient becomes dehydrated and cannot reabsorb water
• increased sodium (hypernatraemia)
• glucose normal - always check this in a patient with these symptoms

Question 22

What is psychogenic polydipsia?

Answer 22

• similar presentation to AVP-deficiency/resistance
• polydipsia, polyuria and nocturia
• no problem with AVP
• problem is that patient drinks all the time, so passes large volumes of dilute urine

Question 23

How does increased drinking lead to the symptoms of psychogenic polydipsia?

Answer 23

1. increased drinking (polydipsia)
2. plasma osmolality and sodium falls
3. less AVP secreted by posterior pituitary
4. large volumes of dilute (hypotonic) urine
5. plasma osmolality returns to normal

Question 24

How do we distinguish between AVP deficiency/resistance and psychogenic polydipsia?

Answer 24

• water deprivation test - no access to anything to drink
• over time, measure urine volumes, urine concentration (osmolality) and plasma concentration (osmolality)
• weigh regularly - stop test if patient loses >3% body weight (marker of significant dehydration which can occur with AVP-D/R)

Question 25

What do the graphs of urine osmolality against hours of water deprivation for
normal vs psychogenic polydipsia vs AVP-deficiency/resistance look like?

Answer 25

• normal = increases and levels off at highest
• psychogenic polydipsia = lower than normal
• AVP deficiency/resistance = flat line from start

Question 26

How do we distinguish between AVP-deficiency and resistance?

Answer 26

• give desmopressin (ddAVP) during water deprivation test - works like AVP
• AVP deficiency - response to desmopressin, urine osmolality increases
• AVP resistance - no increase in urine osmolality as kidneys cannot respond

Question 27

How do we treat AVP deficiency?

Answer 27

• want to replace vasopressin with something selective for V2 receptor (V1 activation would be unhelpful) and a longer half life
• desmopressin
• different preparations - tablets and intranasal (preferred as tablet requires high doses)

Question 28

How is AVP resistance treated?

Answer 28

• very rare disease - difficult to treat
• thiazide diuretics e.g. bendofluazide work

Question 29

What is syndrome of inappropriate anti-diuretic hormone (SIADH)? (6)

Answer 29

• too much AVP
• reduced urine output
• water retention
• high urine osmolality
• low plasma osmolality
• dilutional hyponatraemia - makes you feel confused

Question 30

What are the causes of SIADH? (5)

Answer 30

• CNS - head injury, stroke, tumour
• pulmonary disease (lung cells release ADH) - pneumonia, bronchiectasis
• malignancy - lung cancer (small cell)
• drug-related - carbamazepine, SSRIs
• idiopathic (we do not know)

Question 31

How is SIADH managed?

Answer 31

• common cause of prolonged hospital stay
• fluid restrict
• can use a vasopressin antagonist (vaptan) - binds to V2 receptors in kidney, very expensive