Session 11 ILOs - Calcium metabolism and special circumstances for metabolic and endocrine control Flashcards

1
Q

Explain the significance of maintaining serum calcium levels within set limits

A

Calcium plays a critical role in many cellular processes in the body:

  • Muscle contraction
  • Hormone secretion
  • Nerve conduction
  • Exocytosis
  • Blood clotting
  • Activation and inactivation of many enzymes
  • Ca2+ also serves as an intracellular second messenger

Therefore serum calcium is kept within a narrow range

There is significant consequences to serum calcium being outside the range:
Hypocalcaemia - hyper excitability in the nervous system leading to tetany, paralysis or convulsions
Hypercalcaemia - formation of renal calculi, constipation, dehydration, kidney damage, tiredness or depression

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2
Q

Describe the hormonal regulation of serum calcium

A

3 main hormones:

Increase serum calcium:

  1. Parathyroid hormone (PTH) = short term
    - Works quickly, within 1-2 hours
  2. Calcitriol (also called 1,25(OH)2D) = long term
    - Must follow a path of conversion in the skin, liver then kidneys to the active form of Vitamin D (1,25(OH)D)
    - Acts to increase bone resorption, activates Vit D in the intestines and decreases loss in the urine

Decrease serum calcium:

  1. Calcitonin
    - Acts to increase bone building, reduces calcitriol absorption and increases loss in the urine
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3
Q

Explain the regulation of parathyroid hormone and vitamin D

A

Regulation of parathyroid hormone:

  • PTH is continually synthesised but there is little store
  • Low serum calcium up-regulates gene transcription
  • High serum calcium down-regulates gene transcription due to increased binding activates Phospholipase A which then inhibits PTH secretion

Regulation of Vitamin D:

  • Vitamin D is made from the reaction between cholesterol and calcitonin in the skin
  • Vitamin D3 (cholecalciferol) is the precursor, can be taken in supplement form or converted in the skin by UV light
  • Production of active vitamin D in completed in 3 steps, through the skin, the liver then the kidneys
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4
Q

Explain the significance of renal function on calcium metabolism

A

Kidney failure:

  • Kidneys are the site of activation of vitamin D (from 25(OH)D)
  • 3 main effects:
  1. Kidney failure results in decreased production of active Vitamin D, therefore there is increased calcium resaborption (less osteoclasts are inhibited) and more calcium is lost in the gut and therefore serum calcium can decrease
  2. Levels of phosphate in the blood rise, because the kidneys are not excreting excess phosphate into the urine
  3. PTH may be produced in large quantities, stimulated by low levels of calcium in the blood, which can cause bone reabsorption. Eventually the parathyroid glands work so hard that they cause persistently high calcium levels
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5
Q

Describe disorders of calcium metabolism and metabolic bone disease

A

Osteomalacia (adults):

  • Normal structure but under mineralised bone
  • Caused by a lack of Vitamin D in adulthood only

Rickets (osteomalacia in children):

  • Normal structure but under mineralised bone
  • Caused by a lack of Vitamin D in childhood

Osteoporosis:

  • Normal mineralisation but structure is degraded (channels)
  • Usually caused by changes to function of osteoblasts and osteoclasts, as a result of hormone changes
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6
Q

Describe the major metabolic fuels and their sources in the normal individual

A

2 main sources - normally:

  1. Glucose - the preferred fuel source
    - Only small amount of free glucose available, more glucose stored as glycogen
  2. Fatty acids - can be used by most cells except RBCs, brain and CNS
    - A large store of fatty acids in the form of triacylglycerol

3 main sources - in special conditions:

  1. Amino acids - from broken down muscle protein, can be converted to glucose or ketone bodies (2 week supply)
  2. Ketone bodies - mainly from fatty acids, can be used by the brain instead of glucose
  3. Lactate - product of anaerobic metabolism in muscle, liver can convert back to glucose in the Cori cycle
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7
Q

Describe the metabolic responses to feeding and fasting and explain how they are controlled

A

Feeding and fasting affect the fuel source used, in order to provide the body with a continuous supply of glucose for the RBCs and brain/CNS

Timeline:
<2 hours - uses available glucose and fats from gut
2-10 hours - no longer absorption of glucose and fats, uses glycogen stones and may use fatty acid stores
8-10 hours - needs to undertake gluconeogensis and use of fatty acid stores

Effects of feeding:
- The absorption of glucose, amino acids and lipids increases their blood concentration
Stimulates pancreas to release insulin:
- Increases glucose uptake and utilisation by muscle and adipose tissue
- Promotes storage of glucose as glycogen in liver and muscle
- Promotes amino acid uptake and protein synthesis in liver and muscle
- Promotes lipogenesis and storage of fatty acids in adipose tissue

Effects of fasting:
- As the blood glucose concentration falls insulin secretion is depressed
- Reduces the uptake of glucose by adipose tissue and muscle
Falling blood glucose concentration also stimulates glucagon secretion i.e. decreased insulin/anti-insulin ratio:
- Glycogenolysis in the liver to maintain blood glucose for the brain and other glucose dependent tissues.
- Lipolysis in adipose tissue to provide fatty acids for use by tissues.
- Gluconeogenesis to maintain supplies of glucose for the brain

If fasting exceeds 10hr, starvation begins
- Fatty acid metabolism produces ketone bodies (glucose sparing, brain is able to use ketone bodies)

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8
Q

Describe the metabolic responses to starvation and explain how they are controlled

A

Prolonged starvation:
- Reduced blood glucose causes cortisol and glucagon release
- These hormones cause gluconeogenesis, plus breakdown of protein and fat
- Cortisol prevents most cells from using glucose and they use fatty acids instead
- Glycerol can be used for gluconeogenesis (stops proteins from having to be broken down)
- Liver produces ketone bodies for the brain
- Kidneys can contribute to gluconeogenesis
- If fat stores become depleted, then proteins can be used for fuel
= death usually results from loss of muscle mass (lung muscle, leading to infections)

Beware of referring syndrome!!

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9
Q

Describe the metabolic and hormonal response to pregnancy

A

Pregnancy is split into 2 metabolic phases:

Phase 1 - anabolic phase

  • Preparatory phase
  • Increases in maternal fat stores
  • Small increase in level of insulin sensitivity (insulin has more of an effect to increase storage)
  • Nutrients are stored to meet the future demands of rapid fatal growth

Phase 2 - metabolic phase

  • Decreased insulin sensitivity (insulin has less of an effect to prevent storage)
  • Increased insulin resistance results increased maternal glucose and free fatty acids (more substrates available for foetal growth)

Most substances transfers by simple diffusion across the placenta - glucose is the principal fuel for the foetus and is facilitated by GLUT1

The foetus secretes a wide range of proteins that control the maternal hypothalamic pituitary axis

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10
Q

Explain the hormonal basis of gestational diabetes

A

Increased appetite in pregnancy results in increased glucose ingestion, if the beta cells do not respond with insulin secretion, then gestational diabetes can occur

  • Oestrogen and progesterone increase the sensitivity of the maternal beta cells to glucose
  • You then get more beta cells and bigger beta cells
  • This results in increased insulin secretion to lower blood glucose
    = IF beta cells do not respond normally, then gestational diabetes can occur

3 known underlying causes:

  1. Autoantibodies, similar to T1DM
  2. Genertic susceptibility
  3. B cell dysfunction in setting of obesity and chronic insulin resistance (i.e pre-diabetes waiting to happen!) - a starting point in terms of insulin resistance before pregnancy is crucial
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11
Q

Describe the metabolic and hormonal responses to various types of exercise

A

Metabolic response needs to adapt in order to ensure:

  • Increased energy requirements are met
  • Minimal disruption to metabolic homeostasis
  • Glucose supply to the brain is maintained
  • Waste produces are removed promptly

Response depends on the type of exercise (muscles used), duration and intensity and the physical condition of the individual

Initial burst - muscle creatine phosphate (~ 5 seconds)
Additional intensive exercise (anaerobic) - muscle glycogen breakdown (~2 minutes, up to 60 mins if aerobic)
Longer additional exercise (MUST be aerobic) - fatty acid breakdown but is slow release and can only be used in aerobic conditions (~48 hours of low intensity)

Hormonal changes:

  • Insulin levels fall slowly (inhibited by adrenaline)
  • Glucagon levels rise (energy release)
  • Adrenaline and growth hormone rise (energy release)
  • Cortisol rises slowly (energy release)
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12
Q

Explain the benefits of exercise

A
  • Reduced adipose, increased muscle
  • Improved glucose tolerance
  • Improved insulin sensitivity
  • Reduced blood triacylglycerol
  • Reduced blood pressure
  • Psychological effect
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