1b Sodium and Potassium Balance

Question 1

What is the osmolarity?

Answer 1

measure of the amount of solute dissolved in a solution (osmoles/Litre)

Question 2

What is meant by osmole?

Answer 2

1 mole of dissolved solute per litre

Question 3

Describe how there is a constant osmolarity?

Answer 3

water and salt are inter-related

When there is increased salt, there will be increased water as water follows salt, resulting in an increased volume

Question 4

During water deprivation, how does the change in urine osmolarity compare to that of plasma osmolarity?

Answer 4

Urine concentrates = as the osmolality increases
Plasma = remains at the homeostatic set point

Question 5

What allows the homeostatic set point of plasma osmolarity?

Answer 5

The semi permeable cell membrane allows the movement of water across the cell

Question 6

What is the normal plasma osmolarity?

Answer 6

285-295 mosm/L

Question 7

What is the most important and prevalent solute in the ECF?

Answer 7

Sodium - 140 mmol/L

Question 8

What effect does increasing dietary sodium have on blood volume and pressure and how does it do this?

Answer 8

Increased dietary sodium → Increased total body sodium → Increased osmolarity (but this can’t happen - because of the semi permeable membrane, water will always follow) → Increased water intake and retention → Increased ECF volume → Increased blood volume and pressure

Question 9

At euvolemia, what effect is had on Na+ intake and through what nucleus does this occur in?

Answer 9

Inhibition of sodium intake

Lateral parabrachial nucleus

Question 10

Which neurotransmitters are working to inhibit sodium intake?

Answer 10

Seretonin and glutamate

Question 11

Which neurotransmitters are working to increase a persons appetite for sodium?

Answer 11

GABA, Opiods

Question 12

What is the peripheral control of sodium intake?

Answer 12

Taste, small amounts of Na+ is desirable, but as this increases it becomes aversive

Question 13

How much sodium is absorbed into each part of the nephron?

Answer 13

Proximal - 67%
Thick ascending limb - 25%
Distal convoluted tubule - 5%
Collecting duct - 3%

Question 14

What is GFR proportional to?

Answer 14

Renal Plasma Flow

Question 15

Why do GFR and RPF eventually plateau?

Answer 15

We don’t want to excrete more sodium than is needed

Question 16

What percent of renal plasma enters the tubular system and therefore how do you calculate GFR from renal plasma flow?

Answer 16

20%

GFR = RPF * 20

Question 17

How is increased tubular sodium levels reacted to by the macula densa and how does this affect perfusion pressure and GFR?

Answer 17

1. High tubular sodium
2. Increased uptake of sodium from the macula dense (via the triple transporter)
3. This triggers ADENOSINE release
4. This is detected by the extraglomerular mesangial cells
5. Renin production is reduced, which promotes smooth muscle cell contraction
6. This reduced perfusion pressure so GFR decreases

Question 18

What is the best way to retain sodium?

Answer 18

Filter less sodium

Question 19

How can you filter less sodium?

Answer 19

Reducing efferent arteriole pressure to increase pressure gradient and so more blood flow from afferent arteriole rather than being filtered out

So more retention of both sodium and water

-

Question 20

What are 3 main physiological mechanisms that increase Na+ reabsorption and retention?

Answer 20

1. Increased sympathetic activity
2. Angiotensin II
3. Aldosterone

Question 21

How does increased sympathetic activity lead to more sodium retention?

Answer 21

• Causes SMC of afferent arteriole to contract so less is filtered
• Stimulates sodium uptake in the proximal convoluted tubule
• Stimulates juxtaglomerular apparatus to release Renin which forms angiotensin II (This further stimulates sodium reabsorption in the proximal convoluted tubule)

Question 22

How does angiotensin effect sodium retention?

Answer 22

Stimulates sodium uptake from cells of PCT

Question 23

how does aldosterone affect sodium reabsorption?

Answer 23

Stimulates sodium reabsorption in the DCT and collecting duct

Question 24

How does the juxtaglomerular apparatus respond to low tubular sodium?

Answer 24

Causes the stimulation of renin production which makes angiotensin and aldosterone

Question 25

What is the main protein involved in decreasing sodium reabsorption?

Answer 25

Atrial naturietic peptide

Question 26

Describe the mechanism of action of ANP in order to decreased sodium reabsorption?

Answer 26

Vasodilator - reduces afferent arteriolar pressure so more is filtered to be excreted

ANP

Decreases uptake of Na+ from PCT, DCT, CT

Reduces renin secretion from Juxtaglomerular apparatus

Question 27

What happens to blood pressure and volume when there is low sodium?

Answer 27

Decreases blood pressure and blood volume
This increases beta sympathetic activity

Question 28

What does decreased Beta1 sympathetic activity cause when there is low sodium?

Answer 28

Atrial-Naturietic Protein production

Question 29

Where is aldosterone synthesized and released?

Answer 29

The adrenal cortex - zona glomerulosa

Question 30

When is aldosterone released?

Answer 30

released in response to angiotensin II
or a decrease in blood pressure which is detected by the baroreceptors

Question 31

What effect does aldosterone have on blood pressure?

Answer 31

increases blood pressure

Question 32

How is aldosterone release triggered by increased sympathetic activity?

Answer 32

Increased sympathetic activity stimulates the cells of the juxtaglomerular apparatus to release renin

Renin activity cleaves angiotensinogen to angiotensin I

Angiotensin I is cleaved by angiotensin converting enzyme to produce angiotensin II

Angiotensin II stimulates the synthesis of aldosterone synthase in the zona glomerulosa to increase the synthesis of aldosterone.

Question 33

What effect does aldosterone have in the distal convoluted tubule and the collecting duct?

Answer 33

Increases sodium reabsorption
Increases potassium secretion
Increases H+ secretion

Question 34

What does aldosterone excess lead to?

Answer 34

Hypokalaemic alkalosis

Question 35

Can aldosterone pass through the lipid membrane?

Answer 35

Yes - it is lipid soluble

Question 36

Describe the mechanism by which aldosterone works?

Answer 36

Passes through cell membrane - steroid hormone

Binds mineralocorticoid receptor

Binds another and becomes a dimer

Translocates into the nucleus

Binds and enables transcription of genes and mRNA of proteins which help it carry out its function

Question 37

Transcription of what proteins are increased by Aldosterone?

Answer 37

ENaC (Epithelial sodium channels)
Na+ K+ ATPase
regulatory proteins needed for the channels

Resulting in more sodium and more active sodium channels

Question 38

What are the symptoms of hypoaldosteronism?

Answer 38

Dizziness, low blood pressure, salt craving and palpitations

Question 39

Describe the pathophysiology of hypoaldosteronism?

Answer 39

• Less aldosterone
• Less reabsorption of sodium in the distal convoluted tubule
• More sodium is lost in the urine, and more loss of water
• ECF falls

Increases Renin, Angiotensin II and ADH to try and compensate

Question 40

Describe the pathophysiology of hyperaldosteronism?

Answer 40

• Too much Aldosterone
• Reabsorption of sodium in the distal nephron is increased
• Less urinary loss of sodium, more water retention, ECF increases

reduced renin, Ang II and ADH

Question 41

In states of hyperaldosteronism which two proteins are raised?

Answer 41

ANP and BNP

ANP - tries to decreases sodium reabsorption to compensate for the increase which the hyperaldosterone is causing

Question 42

what are the symptoms of hyperaldosteronism?

Answer 42

high blood pressure
Muscle weakness
Polyuria
Thirst

Question 43

What is Liddle’s syndrome?

Answer 43

An inherited disease of high blood pressure = where there is a mutation in the aldosterone activated sodium channel meaning it is always on, resulting in constant sodium retention = hypertension

Question 44

Describe the pathway involving the kidney though which increased sympathetic stimulation increases aldosterone levels

Answer 44

Increased sympathetic activity stimulates the cells of the juxtaglomerular apparatus (0.5 mark) to release renin (0.5 mark). Renin activity cleaves angiotensinogen to angiotensin I (0.5 mark). Angiotensin I is cleaved by angiotensin converting enzyme (0.5 mark) to produce angiotensin II (0.5 mark). Angiotensin II stimulates the synthesis of aldosterone synthase (0.5 mark) in the zona glomerulosa (0.5 mark) to increase the synthesis (0.5 mark) of aldosterone.

Question 45

What would be the expected effect of spironolactone treatment on the blood pressure of a person with Liddle’s Syndrome?

Answer 45

No effect (1 mark). The mutation in Liddle’s syndrome is in the aldosterone sensitive ENaC sodium channel. This mutation means that the channel is always on so that there will be minimal effect on sodium reuptake (1 mark).

Question 46

When hypertension is resistant to diuretics, what is then used?

Answer 46

potassium sparing diuretics e.g. spironolactone

Question 47

In the heart where are the baroreceptors that respond to low pressure?

Answer 47

Atria
Right ventricle

Question 48

In the heart, where are the baroreceptors which respond to high pressure?

Answer 48

Carotid sinus
Aortic Arch

Question 49

In the low pressure side, how is low pressure dealt with?

Answer 49

Low pressure → Reduced baroreceptor firing → Signal through Afferent fibres to brainstem → Sympathetic activity & ADH Release which promotes Water retention to try and increase pressure again

Question 50

In the low pressure side, how is high pressure dealt with?

Answer 50

High pressure → Atrial stretch → ANP, BNP released

Stop sodium retention, therefore more sodium excreted

Question 51

On the high pressure side, how is low pressure dealt with? (2 ways)

Answer 51

Low pressure → Reduced baroreceptor firing → Signal through Afferent fibres to brainstem → Sympathetic activity and ADH Release

Low pressure → Reduced baroreceptor firing → JGA cells → Renin released

Question 52

When is ANP released?

Answer 52

In response to atrial stretch

Question 53

What are the four actions of ANP?

Answer 53

1. Vasodilation of renal blood vessels
2. Inhibition of sodium reabsorption in th PCT and CD
3. Inhibits renin and aldosterone
4. Reduces blood pressure

Question 54

Which protein kinase does ANP stimulate?

Answer 54

Protein Kinase G

Question 55

Describe the physiology which occurs in response to volume expansion?

Answer 55

Volume expansion = decreased sympathetic activity ===

1. Reduces renin → reduced Angiotensin I → reduced angiotensin II → reduced aldosterone
2. Increases ANP & BNP → Reduces GFR and Na+ uptake in the DCT and CT and also DECREASES AVP from the brain, reduces renin, Reduces aldosterone production from adrenal gland, Reduces AVP → Decreased aquaporins into the epithelial wall in the CT

Question 56

Describe the physiology which occurs in response to volume contraction?

Answer 56

Volume contraction = increased sympathetic activity

1. Increases renin -> increases angiotensin 1 -> increases angiotensin II -> increases aldosterone so increased sodium reabsorption
2. Decreases ANP and BNP
3. Increased AVP from brain = increased sodium reabsorption in collecting duct

Question 57

Where does angiotensin II cause increased sodium reabsorption?

Answer 57

Distal convoluted tubule

Question 58

What would be the effect on water reabsorption of increased sodium levels reaching the collecting duct and why?

Answer 58

Increased Na+ in the collecting duct means there is increased osmolarity and so it is more difficult to reabsorb water since water will migrate via osmosis into the collecting duct since there is a higher osmolarity here

Question 59

How does sodium excretion relate to ECF volume?

Answer 59

reducing sodium reabsorption reduces total Na+ levels, ECF volume and therefore blood pressure

Question 60

What are the vascular effects of ACE Inhibitors?

Answer 60

Vasodilation -> Increased vascular volume -> Lower blood pressure

Question 61

What are the renal effects of ACEi?

Answer 61

decreased sodium reuptake in the proximal PCT-> increased Na+ in distal nephron → decreased water reabsorption → decreased blood pressure

Question 62

What are the adrenal effects of ACEi?

Answer 62

Reduced aldosterone resulting in the following indirect renal effects:

• Lower Na+ reabsorption in the collecting duct
• Therefore more sodium in the distal nephron, therefore more water retention, so blood volume is higher, blood pressure higher

Question 63

Which part of the nephron do osmotic diuretics and carbonic anhydrase inhibitors work on?

Answer 63

PCT

Question 64

Which part of the nephron do Loop Diuretics work on?

Answer 64

Thick Ascending Limb

Question 65

Which part of the nephron do Thiazides work on?

Answer 65

Distal CT

Question 66

Which part of the nephron do K+ sparing diuretics work on?

Answer 66

CCD

Question 67

How do carbonic anhydrase inhibitors work?

Answer 67

• Less bicarbonate produced
• Therefore less H+, so less H+ Na+ exchange, so less Na+ to exchange with K+ into the blood, therefore less sodium reuptake

Therefore LESS Na+ reabsorption in the PCT and reduced water reabsorption

Question 68

what is an example of a loop diuretic?

Answer 68

Furosemide

Question 69

How do loop diuretics work?

Answer 69

They are triple transporter inhibitors

Therefore less Na+ Reuptake in the LOH
Increased Na+ in the distal nephron

Question 70

How do thiazides work?

Answer 70

Inhibit the Na+ Cl- transporter on the apical side of the distal collecting duct

• Therefore reduced reuptake of Na+ in the DCT, and reduced water reabsorption

Question 71

Why does calcium reabsorption increase when on thiazides?

Answer 71

The basolateral Na+ K+ ATPase is unaffected
Therefore since more sodium is entering into the cell, the gradient is going to increase

Therefore the 3Na+ Ca2+ transporter is going to becomes more active so more Ca2+ pumped back into the blood

Question 72

How do potassium sparing diuretics work?

Answer 72

They bind to the MR receptor and cause an inhibition of aldosterone function

Question 73

What is the main intracellular ion?

Answer 73

Potassium

Question 74

How does high extracellular potassium effect the membrane?

Answer 74

Depolarises the membrane = action potentials leading to heart arrhythmias

Question 75

What condition does low potassium lead to?

Answer 75

Abnormal heart rhythms

Question 76

Describe how dietary potassium is absorbed?

Answer 76

Meal = increased potassium absorption = increased plasma K+ = increased tissue uptake

Question 77

What stimulates an increased tissue uptake of potassium?

Answer 77

Insulin, aldosterone and adrenaline

Question 78

How does insulin stimulate K+ uptake after dietary intake?

Answer 78

Indirectly

Insulin stimulates basolateral sodium proton exchanger

This increases intracellular Na+ so to decrease this, the Na+K+ ATPase is stimulated to increase uptake of K+

Question 79

Where is most of the K+ reabsorbed from in the nephron?

Answer 79

PCT

Question 80

What 4 factors stimulate K+ secretion from CCD and DCT?

Answer 80

Increased Plasma [K+]

Increased aldosterone

Increased tubular flow rate

Increased plasma pH

Question 81

Which cells in the kidney are involved in potassium secretion?

Answer 81

Principal cells

Question 82

In K+ depletion, how does the reabsorption of K+ change?

Answer 82

Instead of being secreted, in the DCT and CCD, it is reabsorbed from the tubular fluid

This leads to less K+ being excreted

Question 83

How does potassium secretion (back into urine) by principal cells in the DCT and CCD occur, in response to increased plasma [K+]?

Answer 83

Activity of basolateral Na+/K+ATPase increases intracellular K+ which is then removed into the tubular fluid by K+ channels on the apical side

Therefore more K+ excreted in the urine to counteract the increased K+ the blood

Question 84

How does potassium secretion occur in the DCT and CCD as a result of increased tubular flow?

Answer 84

Increased tubular flow stimulates the primary cilium present on the distal cells in the nephron

This activates PDK1 which increases calcium concentrations in the cell

This stimulates the ‘openness’ of the K+ channels on the apical side of the cell so K+ can leave the cell & enter tubule since there is a higher K+ intracellularly due to the Na+/K+ATPase

Question 85

What are some causes of hypokalemia?

Answer 85

Inadequate dietary intake

Diuretics - increased tubular flow rate

Surreptitious vomiting - reduced intake

Diarrhoea - reduced intake

Genetics

Gitelman’s syndrome - Mutation in the Na+/Cl- transporter in the distal nephron

Question 86

What are some causes of hyperkalaemia?

Answer 86

Seen in resonse to K+ sparing diuretics - Blocks aldosterone

ACE inhibitors

Seen in elderly

Severe diabetes

Chronic Kidney disease

Question 87

Describe how Potassium Sparing Diuretics are potassium Sparing?

Answer 87

They are inhibitors of Aldosterone

This means, there is less Sodium reabsorption in the DCT, so the basolateral 3 Na+ 2 K+ Channels are not needing to work as much, therefore less potassium is taken from the blood into the principal cells and therefore the lumen