Changes in Plasma Osmolarity and Control of Serum Calcium/Stone Formation

Question 1

What happens when water intake < excretion?

Answer 1

Plasma osmolarity increases

Question 2

What happens when water intake > excretion?

Answer 2

Plasma osmolarity decreases

Question 3

What happens to the concentration of urine as the amount produced increases?

Answer 3

It decreases

Question 4

What maintains body fluid osmolarity?

Answer 4

Osmoregulation

Question 5

What is body fluid osmolarity maintained at?

Answer 5

275-295mOsm/kg

Question 6

How do disorders of water balance manifest?

Answer 6

As changes in the body fluid osmolarity

Question 7

How do disorders of Na⁺ balance manifest?

Answer 7

Changes in volume

Question 8

Draw a graph showing the relationship between urine output and concentration of urine

Answer 8

Question 9

What detects changes in plasma osmolarity?

Answer 9

The hypothalamic osmoreceptors

Question 10

Where are the hypothalmic osmoreceptors located?

Answer 10

In the Organum Vasculom of the Laminae Terminalis (OVLT)

Question 11

Where is the OVLT situated?

Answer 11

Anterior and ventral to the third ventricle

Question 12

What epithelium does the OVLT have?

Answer 12

Fenestrated, leaky

Question 13

Why does the OVLT have a fenestrated, leaky epithelium?

Answer 13

To exposure it directly to the systemic circulation

Question 14

What happens when a change in plasma osmolarity is sensed?

Answer 14

The OVLT coordinates responses via two different efferent pathways

Question 15

What do the efferent pathways work to do when a change in plasma osmolarity is sensed?

Answer 15

One concentrates urine, and one decreases thirst

Question 16

At what level of dehydration do you feel thirsty?

Answer 16

~10%

Question 17

How does the efferent pathway concentrating urine exert its effect?

Answer 17

It affects ADH, leading to increased renal water secretion

Question 18

What is the effector for the ADH efferent pathway?

Answer 18

The kidney

Question 19

What is the effector for the thirst efferent pathway?

Answer 19

Brain; drinking behaviour

Question 20

What happens if plasma osmolarity increases due to a predominant loss of water?

Answer 20

Osmoreceptors in the hypothalamus (OVLT) initiate the release of ADH from the posterior pituitary

Question 21

At what increase in plasma osmolarity due to a predominant loss in water would osmoreceptors stimulate ADH release?

Answer 21

1% change

Question 22

What affect does decreased osmolarity have on ADH secretion?

Answer 22

It inhibits it

Question 23

Describe an ADH molecule

Answer 23

Small peptide, 99AA’s long

Question 24

What does ADH act on?

Answer 24

The kidney

Question 25

What does ADH act on the kidney to do?

Answer 25

Regulate the volume and osmolarity of the urine

Question 26

How does ADH regulate the volume and osmolarity of the urine?

Answer 26

By increasing the permeability of the kidneys to water and urea

Question 27

How does ADH increase the permeability of the kidney to water?

Answer 27

By the addition of the water channel Aquaporin-2 to the apical membrne of the nephron’s collecting duct

Question 28

What does the ADH driven addition of Aquaporin-2 allow for?

Answer 28

The reabsorption of water to decrease plasma osmolarity

Question 29

Do apical membranes contain Aquaporin 2 in the absence of ADH?

Answer 29

No

Question 30

What happens when ADH is released?

With respect to Aquaporin 2

Answer 30

It is inserted into the membrane

Question 31

What happens to Aquaporin 2 when ADH is removed?

Answer 31

The channel is retrieved from the apical membrane

Question 32

How is Aquaporin 2 retrieved from the apical membrane?

Answer 32

Via endocytosis

Question 33

What does the basolateral membrane always contain?

Answer 33

Aquaporin 3 and 4

Question 34

What is the result of the basolateral membrane always containing Aquaporin 3 and 4?

Answer 34

It is constantly permeable to water

Question 35

What is the result of the basolateral membrane always being permeable to water?

Answer 35

Any water that enters across the apical membrane is able to pass into the peritubular blood

Question 36

What does ADH cause the reabsorption of?

Answer 36

Urea

Question 37

How does ADH cause the reabsorption of urea?

Answer 37

It increases the permeability of the medullary part of the collecting duct to urea

Question 38

What does the reabsorption of urea in the medullary part of the collecting duct cause?

Answer 38

Water to follow

Question 39

What does the rise in urea concentration in the tissues as a result of urea reabsorption in the medullarly part of the collecting duct cause?

Answer 39

It to passively move down its concentration gradient into the ascending limb

Question 40

Is the ascending limb permeable to urea?

Answer 40

Yes

Question 41

Is the ascending limb permeable to water?

Answer 41

No

Question 42

What happens once urea has moved down its concentration gradient into the ascending limb?

Answer 42

It passes back into the collecting duct, where it is reabsorbed into the medullary portion, and more water follows

Question 43

What is the overall effect of ADH on urea?

Answer 43

It causes urea to be recycled

Question 44

What is SIADH?

Answer 44

Syndrome of Inappropriate Anti-Diuretic Hormone Secretion

Question 45

What happens in SIADH?

Answer 45

The secretion of ADH is not inhibited by the lowering of blood osmolarity (negative feedback is removed)

Question 46

What is the result of the secretion of ADH not being inhibited by the lowering of blood osmolarity?

Answer 46

Excessive amounts of water is retained

Question 47

What does excessive water retention cause in SIADH?

Answer 47

• Blood osmolarity drops
• Hyponatremia

Question 48

What is hyponatremia?

Answer 48

Low blood Na⁺ concentration

Question 49

What are the symptoms of hyponatremia?

Answer 49

• Nausea
• Vomiting
• Headache
• Confusion
• Lethargy
• Fatigue
• Appetite loss
• Restlessness
• Irritability
• Muscle weakness
• Spasms
• Cramps
• Seizures
• Decreased consciousness or coma

Question 50

How can hypernatremia be treated if it comes about because of SIADH?

Answer 50

With ADH Receptor Antagonists

Question 51

What is the osmotic gradient at the cortico-medullary border?

Answer 51

None

Question 52

What is the osmotic graient of the medullary intersticium?

Answer 52

Hyperosmotic up to 100mOsmol/Kg at the papilla

Question 53

What happens to the gradient of osmolarity as you descend?

Answer 53

It increases

Question 54

What sets up the osmotic gradient?

Answer 54

The active transport of NaCl out of the TAL and the recycling of urea

Question 55

Why is the action of the TAL crucial?

Answer 55

It removes solute without water, diluting the filtrate and increasing intersticium osmolarity

Question 56

How can NaK2Cl transporters in the TAL be blocked?

Answer 56

With a loop diuretic

Question 57

Give an example of a loop diuretic that can block NaK2Cl transporters in the TAL

Answer 57

Furosemide

Question 58

What happens if you block the NaK2Cl transporters in the TAL?

Answer 58

The medullary intersticium becomes isosmotic and large amounts of dilute urine is produced

Question 59

What does the Loop of Henle act as to set up the osmotic gradient?

Answer 59

A counter current multiplier

Question 60

How does the Loop of Henle act as a counter current multiplier?

Answer 60

1. Tubule filled initially with isotonic fluid
2. Na⁺ ions are pumped out of the ascending loop, raising the osmotic pressure outside the tubule and lowering it inside
3. Fresh fluid enters the glomerulus, and enters the descending limb. As the descending limb is permeable to water, it leaves via osmosis to raise the osmotic pressure inside the descending tubule to 400mOsmol/L
4. More fluid enters from the glomerulus, pushing the concentrated fluid into the ascending limb
5. The Na⁺ pump then produces another 200mOsmol/L gradient across the membrane, but it started with a more concentrated solution (400sOsmol/L), so external osmolarity rises to 500mOsmol/L
6. Fresh fluid again enters; water leaves via osmosis until the osmotic pressure in the descending tubule is 500mOsmol/L
7. This is then pushed into the ascending limb, where the Na⁺ pump produces yet another 200mOsmol/L gradient, raising the interstitial osmolarity to 700mOsmol/L
8. The final gradient will be limited by the diffusion process

Question 61

How are Na⁺ ions pumped out of the ascending loop?

Answer 61

Na/K/Cl co-transporter

Question 62

What is the max concentration difference inside the Loop of Henle and out?

Answer 62

200mOsmol/L

Question 63

Draw a series of diagrams illustrating the Loop of Henle acting as a counter current multiplier

Answer 63

Question 64

What is required to make the concentration gradient that the loop of Henle sets up last long?

Answer 64

The Vasa Recta

Question 65

What are Vasa Recta?

Answer 65

Blood vessels that run alongside the loops, but with opposite flow direction

Question 66

What does the counter current flow between the Loop of Henle and the Vasa Recta allow?

Answer 66

Maintenance of the concentration gradient

Question 67

What happens to isosmotic blood in the descending limb of the vasa reta?

Answer 67

It inters the hyperosmotic milieu of the medulla

Question 68

What is true of the milieu of the medulla?

Answer 68

There is a high concentration of ions (Na⁺, Cl^-, Urea)

Question 69

What happens once the isosmotic blood in the descending limb of the vasa recta enters the hyperosmotic milieu of the medulla?

Answer 69

The ions from the milieu of the medulla diffuse into the vasa recta, and water diffuses out

Question 70

What happens to the osmolarity of the blood in the vasa recta?

Answer 70

It increases as it reaches the tip of the hairpin loop

Question 71

What is true of the blood in the vasa recta as it reaches the tip of the hairpin loop?

Answer 71

It is isosmotic with the medullary intersticium

Question 72

What is true of blood ascending towards the cortex?

Answer 72

It will have a higher solute content than the surrounding intersticium

Question 73

What is the result of the blood ascending towards the cortex having a higher solute content than the surrounding intersticium?

Answer 73

Solute moves back out

Question 74

Where does water move from the descending limb?

Answer 74

To the loop of Henle

Question 75

What is the overall result of the U shape of the vasa recta allowing it to act as a counter current exchanger?

Answer 75

Although there is a large amount of fluid and solute exchange across the vasa recta, there is little net dilution of the concentration of the interstitial fluid

Question 76

What does the U shape of the vasa recta allow?

Answer 76

It to act as a counter current exchanger

Question 77

What is the contribution of the vasa recta to medullary hyperosmolarity?

Answer 77

It does not create it, but prevents it from being dissipated

Question 78

Draw a diagram illustrating how counter current exchange in the vasa recta works

Answer 78

Question 79

What critical roles does calcium play in cellular processes?

Answer 79

• Hormone secretion
• Nerve conduction
• Inactivation/activation of enzymes
• Muscle contraction
• Exocytosis

Question 80

What is the result of calcium playing a critical role in many cellular processes?

Answer 80

The body must very carefully regulate the plasma concentration of free ionised calcium and maintain free plasma [Ca²⁺] within a narrow range

Question 81

What is free ionised calcium?

Answer 81

The physiologically active form of the metal

Question 82

What range must free plasma calcium concentration be maintained at?

Answer 82

1.0 - 1.3mmol/L

Question 83

What % of plasma calcium exists as the free ionised species?

Answer 83

45%

Question 84

What % of plasma calcium exists protein bound?

Answer 84

45%

Question 85

What is plasma calcium protein bound to?

Answer 85

80% bound to albumin

Question 86

What % of plasma calcium exists complexed?

Answer 86

10%

Question 87

What is plasma calcium complexed with?

Answer 87

Citrates, phosphate etc

Question 88

What is the absorption of calcium in the intestines under the control of?

Answer 88

Vitamin D

Question 89

How much dietary calcium is absorbed in the intestines?

Answer 89

20-40% (25mmol)

Question 90

How much calcium is secreted back into the gut?

Answer 90

2-5mmol

Question 91

When does calcium absorption in the intestines increase?

Answer 91

• Growing children
• Pregnancy
• Lactation

Question 92

When does calcium absorption in the intestines decrease?

Answer 92

With advancing age

Question 93

What reduced the absorption of calcium in the intestines?

Answer 93

Complexing calcium

Question 94

What can calcium be complexed with to reduce its absorption?

Answer 94

Oxalates

Question 95

How much calcium to the kidneys filter?

Answer 95

250mmol per day

Question 96

How much calcium is reabsorbed in the kidneys?

Answer 96

95-98%

Question 97

How much calcium is excreted in urine?

Answer 97

<10mmol/day

Question 98

What % of calcium is reabsorbed in the PCT?

Answer 98

65%

Question 99

What is calcium reabsorption in the PCT associated with?

Answer 99

Na⁺ and water uptake

Question 100

What % of calcium is reabsorped in the loop of Henle?

Answer 100

20-25%

Question 101

What % of calcium is reabsorped in the DCT?

Answer 101

10%

Question 102

What is calcium reabsorption in the PCT under the control of?

Answer 102

PTH

Question 103

How does the body obtain vitamin D?

Answer 103

Absorbed in the gut or synthesised in the skin in the presence of sunlight

Question 104

What is vitamin D converted to?

Answer 104

Calciferol

Question 105

Where is vitamin D converte to Calciferol?

Answer 105

In the liver

Question 106

Why is vitamin D converted to Calciferol in the liver?

Answer 106

To increase its short half-life

Question 107

What does parathyroid hormone (PTH) do?

Answer 107

Regulates the conversion of Calciferol in the kidney to its active form, Calcitriol

Question 108

What is Calcitriol?

Answer 108

The active form of vitamin D

Question 109

How does Calcitriol work?

Answer 109

By binding to Calcium in the gut to increase in absorption

Question 110

How does PTH affect calcium levels directly?

Answer 110

By increasing its release from bone and its reabsorption in the PCT of the kidney

Question 111

What does PTH decrease the reabsorption of?

Answer 111

Phosphate and bicarbonate

Question 112

Why does PTH decrease the reabsorption of phosphate and bicarbonate?

Answer 112

If they are present in the blood with Calcium, stones will form

Question 113

What are the types of vitamin D?

Answer 113

• Vitamin D₂
• Vitamin D₃

Question 114

How does vitamin D₂ enter the body?

Answer 114

It is absorbed by the gut

Question 115

What is action of vitamin D₂?

Answer 115

None- prohormone

Question 116

How does vitamin D₃ enter the body?

Answer 116

Skin (UV light)

Question 117

What is the action of vitamin D₃?

Answer 117

None- prohormone

Question 118

Where is Calciferol produced?

Answer 118

Liver

Question 119

What is Calciferol produced from?

Answer 119

The first hydroxylation of vit D

Question 120

What is the action of Calciferol?

Answer 120

None- prohormone

Question 121

Where is Calcitriol formed?

Answer 121

Kidney

Question 122

What is Calcitriol produced from?

Answer 122

2nd Hydroxylation of Vit D

Question 123

What is the action of calcitriol?

Answer 123

Increases Ca²⁺ absorption

Question 124

Where is parathyroid hormone produced?

Answer 124

Parathyroid gland

Question 125

How do calcium levels regulate PTH?

Answer 125

Via negative feedback

Question 126

What are the causes of hypercalcaemia?

Answer 126

• Primary hyperparathyroidism
• Haemotological malignancies
• Non-haemotological malignancies

Question 127

What is the prevalance of primary hyperparathyroidism?

Answer 127

~1/1,000 of the general population

Question 128

What does hypercalcaemia of malignancy come about due to?

Answer 128

The production of Parathyroidhormone-Related Peptide (PTHrP)

Question 129

Why does PTHrP cause hypercalcaemia of malignancy?

Answer 129

Because it has AA homology with the active portion of PTH and works to increase plasma Ca²⁺ concentration

Question 130

What are the categories of symptoms of hypercalcaemia?

Answer 130

• Gastrointestinal
• Cardiovascular
• Central Nervous System

Question 131

What are the gastrointestinal symptoms of hypercalcaemia?

Answer 131

• Anorexia
• Nausea/vomiting
• Constipation
• Acute pancreatitis

Question 132

How commonly does hypercalcaemia cause acute pancreatitis?

Answer 132

Rarely

Question 133

What are the cardiovascular symptoms of hypercalcaemia?

Answer 133

• Hypertension
• Shortened QT interval on ECG
• Enhanced sensitivity to digoxin
• Renal
• Polyuria
• Polydipsia
• Occasional nephrocalcinosis

Question 134

What are the CNS symptoms of hypercalcaemia?

Answer 134

• Cognitive difficulties and apathy
• Depression
• Drowsiness
• Coma

Question 135

What are the general measures in hypercalcaemia management?

Answer 135

• Hydration
• Loop diuretics

Question 136

What is the purpose of hydration and loop diuretics in hypercalcaemia management?

Answer 136

Increase Ca⁺ excretion

Question 137

What are the specific measures in hypercalcaemia management?

Answer 137

• Bisphosphonates
• Calcitonin

Question 138

What is the purpose of bisphosphonates in hypercalcaemia management?

Answer 138

Inhibit the breakdown of bone

Question 139

What is the purpose of Calcitonin in hypercalcaemia management?

Answer 139

Opposes the action of PTH

Question 140

What is important in hypercalcaemia management?

Answer 140

Treat underlying condition

Question 141

What % of men develop renal stones in their lifetime?

Answer 141

20%

Question 142

What % of women develop renal stones in their lifetime?

Answer 142

5-10%

Question 143

What % of all renal tract stones are made of calcium?

Answer 143

70-80%

Question 144

What factors are involved in the formation of calcium renal stones?

Answer 144

• Low urine volume
• Hypercaluria
• Low urine pH

Question 145

At what urine pH to calcium renal stones form?

Answer 145

<5.47

Question 146

What does the mechanism of stone formation involve?

Answer 146

The super-saturation of urine with calcium oxalate

Question 147

What does conservative management of renal stones include?

Answer 147

• Increasing fluid intake
• Restricting dietary oxalate and sodium
• Considering the dietary restriction of calcium and animal protein