Calcium Homeostasis

Question 1

what are the roles of calcium in the body?

Answer 1

signalling

blood clotting

apoptosis

skeletal strength

membrane excitability

Question 2

what is the role of calcium in the body in realtion to signalling?

Answer 2

Signalling – Ca2+ important signalling molecules: exocytosis of synaptic vesicles e.g. neurotransmitters/ hormones etc, contraction of muscle fibres, alters enzyme function.

Question 3

what is the role of calcium in the body in realtion to blood clotting?

Answer 3

essential component of clotting cascade

If patient can control muscles then plasma levels of calcium are adequate for blood clotting

Only need little calcium to clot blood and lots to move skeletal muscle so if you can move skeletal muscle you are fine

Question 4

what is the role of calcium in the body in realtion to blood apoptosis?

Answer 4

programmed cell death

Question 5

what is the role of calcium in the body in realtion to blood skeletal strength?

Answer 5

99% of calcium in the body is wrapped up in bone where it gives strength to the skeleton

Question 6

what is the role of calcium in the body in relation to membrane excitability?

Answer 6

Ca2+ decreases Na+ permeability

When calcium rises our permeability for sodium decreases

Most critical in short term homeostasis

Question 7

How does Hypocalcaemia affect Ca2+ and membrane excitability?

Answer 7

Hypocalcaemia increases neuronal Na+ permeability leading to hyperexcitation of neurons. In extreme cases causes tetany, if spreads to larynx and respiratory muscles - asphyxiation

Question 8

How does Hypercalcaemia affect Ca2+ and membrane excitability?

Answer 8

Hypercalcaemia decreases neuronal Na+ permeability which will reduce excitability and depress neuromuscular activity and in extreme cases, trigger cardiac arrhythmias

Question 9

How is calcium distributed in the body?

Answer 9

Bones 99%

Intracellular 0.9% - Mostly stored inside mitochondria and Sarcoplasmic Reticulum. Free [Ca2+]ic very low

Extracellular fluid 0.1% - Nearly half ECF Ca2+ is bound to protein so only 0.05% of the calcium in the body is free in solution and physiologically active

intracellular and extracellular calcium is tightly regulated

Question 10

bone is a big source of calcium to maintain ______ calcium

Answer 10

plasma

Question 11

how much calcium in the body is physiologically active?

Answer 11

only 0.05% of the calcium in the body is free in solution and physiologically active

Question 12

how is calcium stored in the bone?

Answer 12

~1Kg (99%) calcium is stored in the calcified extracellular matrix of bone, mostly in the form of hydroxyapatite (Ca10(PO4)6(OH)2) so phosphate homeostasis is also important in determining calcium balance

Question 13

How much calcium is in plasma?

Answer 13

2.2-2.6mM in plasma (0.1%)

[Ca2+]ECF is maintained within tight limits

Question 14

how is extracellular calcium distributed and stored?

Answer 14

Calcium has a very high affinity for proteins (small positive charge attracted to large negative charge) and in plasma around 40% is bound to plasma proteins

So while [Ca2+]plasma is ~2.4mM, free ionised, and therefore physiologically active [Ca2+] is only about 1.2mM and accounts for ~50% of plasma calcium

The remaining 10% of plasma calcium ions that are neither bound to plasma protein, nor free in solution, bind to plasma anions

Question 15

An important consideration for Ca2+ is that the binding capacity of plasma proteins changes with pH

How does it change with changes in pH?

Answer 15

Binding capacity is increased under alkalotic conditions

So eg if hyperventilate, then plasma pH rises (remember the relationship between CO2 and H+):

CO2 + H2O = H2CO3 = H+ + HCO3-

and plasma proteins bind more Ca2+ causing plasma concentration to fall and therefore may precipitate hypocalcaemic tetany

Opposite occurs with acidosis where binding capacity reduces and free [Ca2+]plasma rises

Increase pH = more protein bound calcium so less free physiologically active calcium

Question 16

Alkalosis _________ protein bound calcium

Answer 16

increases

Increased [H+]plasma dispalces bound Ca2+

Question 17

Total body Ca2+ is determined by what simple principle?

Answer 17

total body calcium = calcium in – calcium out

Question 18

why is the distribution of Ca2+ between bone and ECF crucial?

Answer 18

around 99% of total body Ca2+ is stored in bone and this can be added to or released as required

Bone functions to provide mechanical support for the body but its role in maintaining Ca2+ balance takes precedence over this

Bone will be sacrificed in order to maintain plasma calcium levels

Question 19

There is a continuous turnover of bone, it is continually being deposited and then resorbed

what is this done by?

Answer 19

osteoblasts

osteocytes

osteoclasts

Question 20

what are osteoblasts

Answer 20

Osteoblasts are the bone-building cells

They are highly active cells which lay down a collagen extracellular matrix which they then calcify

Question 21

what are osteocytes?

Answer 21

Osteoblasts differentiate to form osteocytes in established bone. Osteocytes are much less active than osteoblasts but appear to regulate the activity of osteoblasts and osteoclasts

Question 22

what are osteoclasts?

Answer 22

Osteoclasts are the cells that are responsible for mobilizing bone. They secrete H+ ions (around pH 4) to dissolve the calcium salts and also provide proteolytic enzymes to digest the extracellular matrix

Question 23

What two key hormones act to raise [Ca2+]plasma

Answer 23

1. Parathyroid hormone (PTH) polypeptide hormone produced by the parathyroid glands
2. Calcitriol (active form of Vit D3) steroid hormone produced from Vitamin D by the liver and kidneys

Question 24

what is parathyroid hormone?

Answer 24

polypeptide hormone produced by the parathyroid glands

Question 25

What is calcitriol?

Answer 25

active form of Vit D3 - steroid hormone produced from Vitamin D by the liver and kidneys

Question 26

where are the paratyhroid glands?

Answer 26

There are usually 4 lying on the posterior surface of the thyroid gland, although variations in number and location of are common, 1 in 10 people have aberrant distribution, (important if need to remove overactive thyroid gland!). Essential for life!

Question 27

when is PTH released?

Answer 27

Released in response to a decrease in free [Ca2+]plasma

Question 28

How does PTH acts to increase free [Ca2+]plasma?

Answer 28

1. Stimulating osteoclasts to resorption (release) of Ca2+ and phosphate in bone (effects seen within 12-24hrs)
2. Inhibiting osteoblasts to reduce Ca2+ deposition in bone
3. Increasing reabsorption of Ca2+ from the kidney tubules, therefore decreasing its excretion in the urine
4. Increasing renal excretion of phosphate. This elevates free [Ca2+] by preventing it from being deposited back into bone, a process that requires phosphate
5. Stimulates the kidney to synthesise calcitriol from vitamin D which promotes calcium absorption at the gut and kidney

Question 29

what does calcitriol do?

Answer 29

Complements action of PTH - increases [Ca2+]plasma

Question 30

how is calcitriol produced?

Answer 30

A steroid hormone produced in two steps (1. liver, 2. kidneys) from dietary vitamin D or from precursors activated by sunlight on skin. Formation is also stimulated by hormone prolactin in lactating women

Active vitamin D3 is formed from cholesterol derivatives by the action of UV light on the skin, but Vit D can also be gained from the diet

Fat soluble vitamin, dietary sources are fatty fish eg mackerel and tuna, fish liver oils and egg yolks

Question 31

calcitriol binds to receptors in target tissue (intestine, bone and kidney) to cause what effects?

Answer 31

1. Increase absorption of Ca2+ from the gut
2. Facilitates renal absorption of Ca2+
3. Mobilises calcium stores in bone by stimulating osteoclast activity

Question 32

how does calcitriol increase absorption of Ca2+ form the gut?

Answer 32

Unlike many substances, such as water, Na+ and K+ which are completely absorbed from the gut, much of the Ca2+ in the diet passes straight through and is excreted in the faeces

The active transport system which moves Ca2+ from the intestinal lumen to the blood is under the control of calcitriol

In a situation of low plasma [Ca2+]:

increase in PTH = increase­ calcitriol = increase­ in intestinal absorption of Ca2+

Alternatively:

increases levels of plasma Ca2+ inhibit PTH causing a shift to greater osteoblast deposition and less osteoclast resorption.

Question 33

All the actions of calcitriol do what?

Answer 33

Collectively these actions, complement those of PTH and increase [Ca2+]plasma

Question 34

How does prolactin increase plasma Ca2+?

Answer 34

Prolactin stimulates calcitriol synthesis in association with increased demand for Ca2+ for milk production in lactation.

Question 35

summary diagram showing calcium balance in the body

Answer 35

Question 36

Calcitriol only hormone to increase calcium from ______ sources

Answer 36

dietary

Question 37

Circulating level of 1,25(OH)2D (calcitriol) controls proportion of dietary calcium absorbed from the intestine

name A, B and C

Answer 37

A - normal

B - low

C - high

Question 38

when is someone classes as being vitamin D deficient?

Answer 38

Circulating vitamin D levels fall to less than 20ng/ml

Despite Vit D being stored extensively in fat, large proportion of population vitamin D deficient/insufficient.

~75% of Scots are Vit D “insufficient” in summer, rising to 92% in the winter!! Clothing, UVB sunscreen, diet all add to problem of lack of sunlight

More prevalent in >65 years due to reduced gut absorption, reduced Ca2+ mobility

Question 39

what does vitamien D do and what are the effects of someone being vitamin D deficient?

Answer 39

While direct effect of Vit D3 is to release Ca2+ from bone, its effect on Ca2+ absorption from gut/reabsoption at kidneys, means the net Vitamin D3 effect is to increase plasma [Ca2+] and ­mineralization of bone

In Vit D deficiency PTH works hard to maintain plasma [Ca2+] and in doing so continually removes Ca2+ from bone resulting in bones which are soft and, if still growing, become bent. In adults, easily fractured.

In absence of vitamin D you don’t get any phosphate and your bones become weak under the influence of parathyroid hormone

• Rickets in children
• Osteomalacia in adults

Question 40

Vitamin D3 deficiency leads to what?

Answer 40

Ca2+ and phosphate deficiency

Question 41

how does vitamin D3 deficiency cause plasma ca2+ deficiency and bone problems?

Answer 41

Vitamin D3 deficiency = intestinal malabsorption of Ca2+, this decreases [Ca2+]plasma which ­increases PTH which then promotes phosphate deficiency – aggravates Ca2+ loss from bone

Question 42

what people ar emore at risk of vitamin D3 deficiency?

Answer 42

Elderly and Asian populations are the most at risk. Many factors involved:

• Chapatti flour contains phytate which binds dietary Ca2+
• There may be dietary deficiency of vitamin D3
• Pigmented skin is less able to make vitamin D3 in response to UV light

Vit D deficiency implicated in MS, cancer, arthritis, CVD

Question 43

What one key hormone acts to decrease [Ca2+]plasma?

Answer 43

calcitonin

Question 44

what type of hormone is calcitonin?

Answer 44

peptide hormone

Question 45

what is calcitonin made by?

Answer 45

thyroid gland

Question 46

what is the secretion of calcitonin stimulated by?

Answer 46

its secretion is stimulated by ­increased [Ca2+]plasma

Question 47

What is the main action of calcitonin?

Answer 47

Its main actions are to bind to osteoclasts and inhibit bone resorption as well as­ renal excretion so preventing a further ­increase in Ca2+

Question 48

Is calcitonin essential in humans?

Answer 48

there is little evidence that it is important humans. In thyroid disease such as tumours where calcitonin levels are very high, plasma calcium levels are normal and there are no abnormalities of bone structure. So any effect of excess calcitonin is overridden by PTH

Similarly, patients with no calcitonin secretion have normal Ca2+ levels

May be used, rarely, to treat Paget’s disease (overactive osteoclasts)

Question 49

What are other endocrine hormones that alter the Ca2+ balance?

Answer 49

1. Cortisol
2. Insulin
3. Oestrogen
4. Growth Hormone
5. Prolactin

Question 50

how does cortisol alter Ca2+ balance?

Answer 50

Cortisol inhibits osteoblasts, increases renal excretion of Ca2+ and phosphate and reduces intestinal absorption of Ca2+ leading to decreased plasma [Ca2+] causing increased PTH leading to­ bone resorption. This together with the reduced bone formation can, over time, produce osteoporosis

Question 51

how deos insulin alter Ca2+ balance?

Answer 51

Insulin increases bone formation, and antagonises the action of cortisol

Diabetics may have significant bone loss

Question 52

how does oestrogen alter Ca2+ balance?

Answer 52

Oestrogen promotes bone formation via oestrogen receptors on osteoblasts

Post-menopausal osteoporosis a major problem

Question 53

how does growth hormone alter Ca2+ balance?

Answer 53

constant stimulus for bone formation

Question 54

how does prolactin alter Ca2+ balance?

Answer 54

promotes calcium absorption from the gut by stimulating synthesis of calcitriol