1B calcium dysregulation

Question 1

Describe the hormonal control in the increase of serum calcium

Answer 1

• Vitamin D
  
  • Synthesised in skin or intake via diet
• Parathyroid Hormone (PTH) (secreted by parathyroid glands)
• Main regulators of calcium (and phosphate) homeostasis via actions on kidney, bone and gut

Question 2

Describe the hormonal control in the decrease of serum calcium

Answer 2

• Calcitonin (secreted by thyroid colloid)

Can reduce calcium acutely, but no negative effect if parafollicular cells are removed eg thyroidectomy

Question 3

What are the 2 types and sources of Vitamin D?

Answer 3

• Vitamin D2 (ergocalciferol) from diet e.g. oily fish
• Vitamin D3 (cholecalciferol) synthesised in skin when exposed to sunlight

Question 4

How is vitamin D3 made and both D2 and D3 metabolised?

Answer 4

Vitamin D becomes activated after undergoing both hydroxylation steps

1,25(OH)2 cholecalciferol is aka calcitriol - the active form of vitamin D

Question 5

What is serum 25-OH cholecalciferol a good indicator of?

Answer 5

Body vitamin D status, as calcitriol is difficult to measure in blood

Question 6

How does calcitriol regulate its own synthesis?

Answer 6

It decreases transcription of 1 alpha hydroxylase - negative feedback

Question 7

What are the effects of calcitriol on the bone?

Answer 7

Increases Ca2+ reabsorption by binding to calcitriol receptors on osteoblasts which release OAFs → Osteoclasts > osteoblasts (ONLY AT LOW SERUM CALCIUM)

• in normal serum calcium, calcitriol works to increase bone formation → osteoblasts > osteoclasts
• n.b. Increase of reabsorption of Ca2+ from the bones itself INTO the blood stream

Question 8

What are the effects of calcitriol on the kidney?

Answer 8

Increases Ca2+ and phosphate reabsorption into blood by kidney from urine

Question 9

What are the effects of calcitriol on the gut?

Answer 9

Increases Ca2+ and phosphate absorption from food into blood

Question 10

What are the effects of PTH on the bone?

Answer 10

Increases reabsorption of calcium from bone

Question 11

What are the effects of PTH on the kidney?

Answer 11

• Increases calcium reabsorption from kidney from urine
• Increases phosphate excretion
• Increases 1-alpha-hydroxylase activity → Increases calcitriol synthesis

Question 12

What are the effects of PTH on the gut?

Answer 12

Through increase in 1-alpha-hydroxylase activity and through increased calcitriol synthesis, there is increase in Ca2+ and phosphate absorption from gut.

So PTH doesn’t directly affect gut

Question 13

What is the overall affect of PTH on plasma calcium levels?

Answer 13

Overall increase

Question 14

What is the overall affect of PTH on plasma phosphate levels?

Answer 14

Net loss → the phosphate loss from the kidney tends to outweigh the phosphate reabsorption from the gut.

Question 15

What specifically happens when PTH interacts with bone?

Answer 15

• PTH binds to PTH receptor on osteoblasts (cells that build bone)
• Stimulates osteoblasts to make osteoclast activating factors (OAFs) e.g. RANKL (receptor activator of nuclear factor kappa-B ligand)
• Osteoclasts (cells that consume bone) are switched on and dissolve bone, releasing calcium into the blood stream

Question 16

How does phosphate reabsorption in kidneys happen?

Answer 16

• Phosphate is reabsorbed via sodium-phosphate co-transporter - this also results in less sodium excretion in urine
• Increased phosphate loss in urine would lower serum phosphate levels

Question 17

How does PTH work in phosphate reabsorption?

Answer 17

• PTH inhibits renal phosphate reabsorption by inhibiting these transporters
• In primary hyperparathyroidism, serum phosphate is low due to increased urine phosphate excretion

Question 18

What is FGF23 and what does it do?

Answer 18

• Fibroblast Growth Factor 23 (hormone) is derived from bone
• Also inhibits phosphate reabsorption in kidneys by inhibiting Na+/PO43- co-transporters
• Also inhibits calcitriol synthesis causing less phosphate absorption from gut from food

Question 19

What is hypocalcaemia?

Answer 19

Low serum calcium

Question 20

How does hypocalcaemia affect action potential generation?

Answer 20

• There’s low extracellular calcium so this enables greater Na+ influx as there’s less competition for Na+ to move across membrane
• Means MORE membrane excitability

Question 21

What are clinical symptoms of hypocalcaemia?

Answer 21

• It sensitises excitable tissues
• Paraesthesia (tingling) of hands, mouth, feet, lips
• Convulsions- fits
• Arrhythmias- unusual heart rhythms
• Tetany- contract muscles but can’t relax again
• Mnemonic- CATs go numb

Question 22

What is Chvostek’s sign?

Answer 22

• You tap facial nerve just below zygomatic arch (cheekbone)
• Since there’s more membrane excitability, you get a positive response of twitching of facial muscles
• Indicates neuromuscular irritability due to hypocalcaemia

Question 23

What is Trousseau’s sign?

Answer 23

• Inflate a BP cuff for several minutes around patient’s arm
• This induces carpopedal (fingers) spasm and muscles contract and can’t relax again (tetany)
• This is due to neuromuscular irritability due to hypocalcaemia

Question 24

What are 2 causes of hypocalcaemia?

Answer 24

• Vitamin D deficiency
• Low PTH levels- hypoparathyroidism

Question 25

What are causes of vitamin D deficiency?

Answer 25

1. Malabsorption or dietary insufficiency
2. Inadequate sun exposure
3. Liver disease
4. Renal disease
5. Vit D receptor defects (rare)

Question 26

What are the consequences of vitamin D deficiency?

Answer 26

• There is a lack of bone mineralisation causing ‘soft bones’
• In children they get rickets (bowing of bones)
• In adults, bones are more formed so they get osteomalacia (predisposed to fractures and proximal myopathy (especially thigh muscles))

Question 27

What are four causes of low PTH levels?

Answer 27

• Surgical- neck surgery could have damaged parathyroid glands
• Auto-immune- one of the most common reasons
• Magnesium deficiency- it’s needed to make PTH
• Congenital (agenesis of parathyroid gland i.e. it doesn’t develop in embryo- rare)

Question 28

What are causes of hypercalcaemia?

Answer 28

• Primary hyperparathyroidism (commonest)
• Malignancy
• Vitamin D excess (rare)

Question 29

How does primary hyperparathyroidism cause hypercalcaemia?

Answer 29

• Too much PTH
• Usually due to a parathyroid gland adenoma
• No negative feedback- high PTH, but high calcium

Question 30

What malignancies can be seen in hypercalcaemia?

Answer 30

• Bony metastases produce local factors to activate osteoclasts
• Certain cancers (e.g. squamous cell carcinomas) secrete PTH-related peptide that acts at PTH receptors

Question 31

What is the relationship between PTH and calcium?

Answer 31

• If calcium falls, parathyroid glands sense this and release more PTH
• If we have too much calcium, there’s negative feedback and parathyroid glands don’t release PTH

Question 32

What happens in primary hyperparathyroidism?

Answer 32

• If we get a parathyroid adenoma it produces too much PTH
• Calcium increases but there’s no negative feedback to PTH due to autonomous PTH secretion from adenoma

Question 33

What is the biochemistry of primary hyperparathyroidism?

Answer 33

• High calcium
• High PTH (not suppressed by hypercalcaemia negative feedback)
• Low phosphate- increased renal phosphate excretion (inhibition of sodium-phosphate transporter in kidney)

Question 34

What is the treatment of primary hyperparathyroidism?

Answer 34

Parathyroidectomy is the main treatment

Question 35

What are the risks of untreated primary hyperparathyroidism?

Answer 35

• Osteoporosis due to osteoclasts constantly breaking down bone
• Renal calculi (stones)
• Psychological impact of hypercalcaemia- mental function, mood

Question 36

What happens in secondary hyperparathyroidism?

Answer 36

• It’s a normal physiological response to hypocalcaemia
• Calcium will be low or normal
• PTH will be high (hyperparathyroidism) secondary to the low calcium
• This is different from primary hyperparathyroidism where calcium is high

Question 37

What are the causes of secondary hyperparathyroidism?

Answer 37

• Most common cause is vitamin D deficiency due to diet, reduced sunlight
• Less common, due to renal failure- can’t make calcitriol in renal failure

Question 38

What is the treatment for secondary hyperparathyroidism in people with and without kidney failure?

Answer 38

Vitamin D replacement

Question 39

What vit D replacement can patients with normal renal function receive?

Answer 39

• 25 hydroxy vitamin D- inactive vit D
• They convert it to 1,25 dihydroxy vitamin D via 1alpha hydroxylase
• Can give ergocalciferol (25 hydroxy vitamin D2) or cholecalciferol (25 hydroxy vitamin D3)
• Can get at chemists/supermarket

Question 40

What vit D replacement can patients with renal failure get?

Answer 40

• There’s inadequate 1alpha hydroxylation, so can’t activate 25 hydroxy vitamin D
• We give them alfacalcidol - 1alpha hydroxycholecalciferol- this is active vitamin D
• Reserved for renal failure patients so needs to be prescribed

Question 41

What happens in tertiary hyperparathyroidism?

Answer 41

• It’s rare
• When you have chronic renal failure you can’t make calcitriol so you have chronic vit D deficiency
• Parathyroid glands start secreting more PTH to make up for drop in calcitriol so calcium doesn’t become low
• One or more of these glands enlarge (hyperplasia) to the point where they can’t be switched off
• Autonomous PTH secretion happens causing hypercalcaemia

Question 42

What is the treatment for tertiary hyperparathyroidism?

Answer 42

Parathyroidectomy

Question 43

What happens in hypercalcaemia due to malignancy?

Answer 43

• There is high calcium
• There is low or suppressed PTH