9.2 - Sodium and potassium balance

Question 1

Define osmolarity.

Answer 1

The measure of the solute (particle) concentration in a solution (osmoles/litre)

Question 2

What is 1 osmole?

Answer 2

1 osmole = 1 mole of dissolved particles per litre (1 mole of NaCl = 2 moles of particles in solution = 2 osm/l)

Question 3

What does osmolarity depend on?

Answer 3

The number of dissolved particles - the greater the number of dissolved particles, the greater the osmolarity

Question 4

How does our osmolarity remain constant?

Answer 4

• by water moving around through semi-permeable membranes
• increased salt = osmolarity increases = increased water moves into that area = increased volume + osmolarity back to normal
• reduced salt = osmolarity decreases = water moves out = decreased volume + osmolarity back to normal

Question 5

How does our osmolarity remain constant - put this in terms of ECF mosmoles, concentration and ECF volume?

Answer 5

• mosmoles 2900, conc 290mosm/L, volume 10L
• mosmoles 3190 (increased by 290), conc 290mosm/L, volume 11L
• mosmoles 2610 (decreased by 290), conc 290mosm/L, volume 9L

Question 6

What is normal plasma osmolarity?

Answer 6

285-295 mosmol/L

Question 7

What is normal plasma osmolarity made up of? (7)

Answer 7

• sodium ~140 mmol/L
• chloride ~105 mmol/L
• bicarbonate ~24 mmol/L
• potassium ~4 mmol/L
• glucose ~3-8 mmol/L
• calcium ~2 mmol/L
• protein ~1 mmol/L

Question 8

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

Answer 8

Sodium

Question 9

How does dietary sodium affect weight and blood pressure?

Answer 9

• increased dietary sodium –> increased total body sodium –> increased osmolarity (body does not allow) –> increased water intake and retention –> increased ECF volume –> increased blood volume and pressure + increased body weight
• decreased dietary sodium –> decreased total body sodium –> decreased osmolarity (body does not allow) –> decreased water intake and retention –> decreased ECF volume –> decreased blood volume and pressure + decreased body weight

Question 10

What part of the brain centrally controls regulation of sodium intake?

Answer 10

Lateral parabrachial nucleus (junction of midbrain and pons)

Question 11

How is sodium intake centrally regulated under normal conditions of euvolemia (normal sodium levels)?

Answer 11

• lateral parabrachial nucleus inhibits Na+ intake - suppresses our desire to intake sodium
• driven by: serotonin and glutamate (a set of cells in parabrachial nucleus that respond to these)

Question 12

How is sodium intake centrally regulated under conditions of Na+ deprivation?

Answer 12

• lateral parabrachial nucleus increases appetite for Na+
• driven by GABA and opioids

Question 13

What is the peripheral mechanism for regulating sodium intake?

Answer 13

• taste - food with no salt tastes unpleasant
• salt in low concentrations makes food appetising = we want to eat it
• as Na+ concentration increases, it becomes more aversive for us so we do not want to eat it

Question 14

How much (%) sodium is reabsorbed in different parts of the nephron?

Answer 14

• PCT - 67% (therefore 67% of water too)
• thick ascending LoH - 25%
• DCT - 5%
• collecting duct - 3%
• overall <1% excreted

Question 15

How does GFR change sodium excretion?

Answer 15

Sodium reabsorption values are % not amounts so if we increase GFR, more sodium is excreted

Question 16

How is GFR linked to renal plasma flow rate and blood pressure?

Answer 16

• RPF proportional to mean arterial pressure
• approximately 20% of renal plasma enters tubular system
• GFR = RPF x 0.2
• therefore GFR is also proportional to MAP

Question 17

What happens to GFR and RPF at a certain threshold of high blood pressure?

Answer 17

RPF and GFR both plateau at high blood pressures e.g. when exercising, as we do not want to excrete more sodium than is needed

Question 18

Describe the nephron’s system to limit sodium loss through kidney excretion.

Answer 18

• high Na+ in filtrate = higher than normal amounts of Na+ passing through DCT
• DCT in tight association with glomerulus, and JGA contains macula densa cells which detect high tubular Na+
• increased Na+/Cl- uptake via triple transporter
• macula densa cells release adenosine which is detected by extraglomerular mesangial cells which interact with smooth muscle cells in afferent arteriole
• this reduces blood flow into glomerulus, thus reducing perfusion pressure and GFR (reducing Na+ excretion)
• adenosine release also leads to reduction in renin production (short-term, does not affect renin production over long period)

Question 19

What various systems in the nephron can increase Na+ reabsorption/retention? (3)

Answer 19

• sympathetic activity
• angiotensin II (and aldosterone)
• low tubular Na+ itself will stimulate production of renin from JGA and therefore AT-II

Question 20

How can sympathetic activity increase Na+ reabsorption/retention in the nephron? (3)

Answer 20

• contracts SMC of afferent arteriole (which reduces blood flow and therefore Na+ loss)
• stimulates Na+ uptake by PCT cells
• stimulates JGA cells to produce renin –> angiotensin II

Question 21

How can angiotensin II increase Na+ reabsorption/retention in the nephron? (3)

Answer 21

• stimulates PCT cells to take up Na+
• stimulates adrenal glands to produce aldosterone which stimulates Na+ uptake in distal part of DCT and collecting duct
• vasoconstriction

Question 22

Describe the system in the nephron for decreasing Na+ reabsorption.

Answer 22

Atrial natriuretic peptide:

• acts as a vasodilator
• reduces Na+ uptake in PCT, DCT and collecting duct
• suppresses production of renin by JGA

Question 23

How does the body react to low sodium levels?

Answer 23

1. low Na+ = lower BP and fluid volume
2. this increases beta-1 sympathetic activity which stimulates afferent arteriole SMC to contract and reduce glomerular filtration pressure
3. stimulates renin production = cleaves angiotensinogen into angiotensin I = cleaved by ACE into angiotensin II
4. angiotensin II stimulates zona glomerulosa of adrenal gland to release aldosterone which increases Na+ reabsorption
5. angiotensin II also promotes vasoconstriction and Na+ reabsorption
6. this causes increased Na+ reabsorption and reduces water output

Question 24

How does the body react to high sodium levels?

Answer 24

1. high Na+ = higher BP and fluid volume
2. this reduces beta-1 sympathetic activity and causes production of ANP
3. reduced renin production = reduced angiotensin II
4. reduced aldosterone which reduces Na+ reabsorption
5. vasodilation and decreased Na+ reabsorption and increased water output

Question 25

What is aldosterone and when is it released?

Answer 25

• steroid hormone synthesised and released from adrenal cortex (zona glomerulosa)
• released in response to angiotensin II
• also released in response to decrease in blood pressure (via baroreceptors)

Question 26

How is aldosterone released in response to angiotensin II?

Answer 26

Angiotensin II promotes synthesis of aldosterone synthase, which causes the last two enzymatic steps in production of aldosterone from cholesterol

Question 27

What does aldosterone do in the kidney? (3)

Answer 27

• increased sodium reabsorption (35g per day)
• increased K+ secretion
• increased H+ secretion

Question 28

What can excess aldosterone lead to?

Answer 28

Hypokalaemic alkalosis

Question 29

How does aldosterone work at a cellular level in collecting duct cells?

Answer 29

1. lipid-soluble steroid hormone so passes through cell membrane
2. binds to a mineralocorticoid receptor sitting in cytoplasm bound to protein called HSP90
3. once aldosterone is bound, HSP90 is removed and the mineralocorticoid receptor dimerises
4. translocates into nucleus and binds to DNA and stimulates production of mRNA for genes for epithelial Na+ channel (ENaC) and Na+K+ATPase, which go to their respective membranes
5. also increases transcription of regulatory proteins that stimulate activity of those two transporters, so both more sodium channels and more active sodium channels

Question 30

What happens in hypoaldosteronism?

Answer 30

Reabsorption of sodium in distal nephron is reduced –> increased urinary loss of sodium –> ECF falls because water moves out with sodium

Question 31

What does the body do to try and compensate for hypoaldosteronism?

Answer 31

Increases renin, angiotensin II and ADH (and other sodium-reabsorbing mechanisms) to try and increase reabsorption

Question 32

What are the symptoms of hypoaldosteronism? (4)

Answer 32

• low blood pressure
• dizziness (due to low BP)
• salt craving
• palpitations (due to change in membrane potential)

Question 33

What happens in hyperaldosteronism?

Answer 33

• increased reabsorption of sodium in distal nephron –> reduced urinary loss of sodium –> increased total body sodium –> ECF volume increases as lots of water is absorbed (hypertension)
• this reduces renin, angiotensin II and ADH production, and increases ANP and BNP

Question 34

What are the symptoms of hyperaldosteronism? (4)

Answer 34

• high blood pressure
• muscle weakness
• polyuria (try to get rid of excess water)
• thirst (since our body thinks there is insufficient water in system)

Question 35

What is Liddle’s syndrome?

Answer 35

An inherited disease of high blood pressure

Question 36

What causes Liddle’s syndrome?

Answer 36

• mutation in the aldosterone activated sodium channel means the channel is always on (increased ENaC activity)
• this leads to increased sodium reabsorption and therefore hypertension

Question 37

What does Liddle’s syndrome look like?

Answer 37

Like hyperaldosteronism but with normal/low aldosterone

Question 38

Where do we have low pressure baroreceptors? (3)

Answer 38

• atria (heart)
• right ventricle (heart)
• pulmonary vasculature (vascular system)

Question 39

What is the response to low pressure from the low pressure baroreceptors?

Answer 39

Low pressure –> reduced baroreceptor firing –> signal through afferent fibres to brainstem –> sympathetic activity and ADH release for water retention

Question 40

What is the response to high pressure from the low pressure baroreceptors?

Answer 40

High pressure –> atrial stretch –> ANP and BNP released for greater water loss

Question 41

What is ANP?

Answer 41

Atrial natriuretic peptide = small peptide made in the atria (also makes BNP)

Question 42

Describe the mechanism of ANP after release?

Answer 42

1. released in response to atrial stretch
2. binds to guanylyl cyclase (receptor)
3. this converts GTP to cyclic GMP (cGMP)
4. this activates protein kinase G
5. leads to cellular responses

Question 43

What are the actions of ANP? (4)

Answer 43

• vasodilation of renal (and other systemic) blood vessels
• inhibition of sodium reabsorption in proximal tubule and collecting ducts
• inhibits release of renin and aldosterone
• reduces blood pressure

Question 44

What high pressure baroreceptors do we have? (3)

Answer 44

• carotid sinus (vascular system)
• aortic arch (vascular system)
• juxtaglomerular apparatus (vascular system)

Question 45

How do high pressure baroreceptors respond to low pressure?

Answer 45

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 46

How does the body react in response to volume expansion? (4)

Answer 46

• reduction in sympathetic activity leading to reduced Na+ reuptake in PCT
• reduction in renin production so less angiotensin II and aldosterone production –> more Na+ excretion as less reabsorption
• more ANP and BNP - affects GFR and promotes Na+ excretion
• reduction in AVP in brain

Question 47

How does the body react in response to volume contraction?

Answer 47

• increase in sympathetic activity leading to increased Na+ reuptake in PCT
• increase in renin production so more angiotensin II and aldosterone production –> more Na+ (and therefore water) reabsorption in collecting duct
• less ANP and BNP
• more AVP production in brain - promote water reabsorption by inserting aquaporins in collecting duct cells

Question 48

What is the effect of increased sodium levels in the tubular fluid on water secretion in nephron?

Answer 48

• water reabsorbed in nephron because medulla has gradient of osmolarity throughout, which we match with the osmolarity in tubular fluid
• increased Na+ in tubular fluid reduces gradient from tubular fluid to medulla, so less water moves into medulla = less water reabsorbed
• more solute arriving in later part of nephron, less water we reabsorb

Question 49

What is the effect of reducing Na+ reabsorption (Na+ excretion) on Na+ levels, ECF volume and BP?

Answer 49

• reducing Na+ reabsorption reduces total Na+ levels, ECF volume and blood pressure
• this is because Na+ levels determine ECF volume, and reducing ECF volume reduces BP

Question 50

What do ACE inhibitors primarily do?

Answer 50

Reduce angiotensin II production

Question 51

What are the vascular effects of ACE inhibitors?

Answer 51

• vasodilation (less angiotensin II which contracts blood vessels)
• this increases vascular volume, which decreases blood pressure

Question 52

What direct renal effects do ACE inhibitors have? (3)

Answer 52

• reduced Na+ reuptake in PCT
• increased Na+ in distal nephron (reduces gradients from tubular fluid into interstitium, reducing water reabsorption)
• less water reabsorption = lower blood pressure

Question 53

What adrenal effects does reduced angiotensin II from ACE inhibitors have?

Answer 53

• reduced aldosterone
• leads to reduced Na+ reuptake in cortical collecting duct
• also increases Na+ in distal nephron (region of nephron with the highest osmolarity) - reduces water reabsorption due to reduction in osmotic gradient across tubular wall
• reduced water reabsorption = lower blood pressure

Question 54

What type of drug are ACE inhibitors?

Answer 54

Diuretics - reduce water reabsorption

Question 55

What are some types of diuretics other than ACE inhibitors? (5)

Answer 55

• osmotic diuretics (PCT)
• carbonic anhydrase inhibitors (PCT)
• loop diuretics (thick asc LoH)
• thiazide diuretics (DCT)
• K+ sparing diuretics (CD)

Question 56

What do osmotic diuretics do?

Answer 56

• put something un-reabsorbable into PCT
• since it cannot be reabsorbed, it stays in PCT and increases osmolarity
• this means less water will be reabsorbed from PCT (usually where most water is reabsorbed so will see greatest effect here)

Question 57

Where do carbonic anhydrase inhibitors work?

Answer 57

Carbonic anhydrase enzymes are most active in PCT where these inhibitors work

Question 58

How do carbonic anhydrase inhibitors work?

Answer 58

1. block carbonic anhydrase, so cannot convert HCO3- into H2CO3 then H2O + CO2
2. CO2 cannot go into cell and react with H2O to make H2CO3 using another carbonic anhydrase
3. no H2CO3 is split into H+ + HCO3- = H+ cannot be used to move Na+ into cell using Na+/H+ exchanger so net sodium uptake decreases and reduction in urinary acidity

Question 59

What are the effects of carbonic anhydrase inhibitors? (3)

Answer 59

• reduced Na+ reuptake in PCT
• increased Na+ in distal nephron
• reduced water reabsorption

Question 60

Where do loop diuretics work?

Answer 60

Thick ascending loop of Henle

Question 61

What is an example of a loop diuretic?

Answer 61

Furosemide

Question 62

What do loop diuretics do?

Answer 62

• block Na+/2Cl-/K+ triple transporter
• reduces Na+ reuptake in LoH
• increased Na+ in distal nephron
• decreases osmotic gradient across tubular wall into interstitium so reduced water reabsorption

Question 63

Where do thiazide diuretics work?

Answer 63

DCT

Question 64

What do thiazide diuretics do?

Answer 64

• block NaCl transporter in DCT
• reduced Na+ reuptake in DCT, increasing Na+ in DCT
• leads to increased Na+ in distal nephron
• reduced water reabsorption due to reduced osmotic gradient across tubular wall

Question 65

What other effects do thiazide diuretics have?

Answer 65

• increase Ca2+ reabsorption - because Na+K+ATPase is not affected so pumps Na+ into blood from cell
• but NaCl transporter in DCT is blocked so Na+ cannot move into cell from tubular fluid
• therefore decrease in Na+ in cell, so Na+ moves from blood into cell via Na+/Ca2+ antiporter, so Ca2+ builds up in blood

Increased Ca2+ reabsorption = symptoms of hypercalcaemia!!!

Question 66

Where do K+ sparing diuretics work?

Answer 66

Collecting duct

Question 67

What is an example of a K+ sparing diuretic?

Answer 67

Spironolactone

Question 68

What do K+ sparing diuretics do?

Answer 68

• inhibitors of aldosterone function e.g. spironolactone
• bind MR and block its function
• aldosterone usually increases production of Na+ channel and Na+/K+ATPase to increase Na+ reuptake and K+ secretion and H+ excretion, so an excess of aldosterone can lead to hypokalaemic alkalosis
• if this is blocked, activity of this uptake system reduces, so Na+ reuptake in distal nephron reduces, reducing water reabsorption

Question 69

How are K+ sparing diuretics K+ sparing?

Answer 69

Since Na+K+ATPase pumps K+ out of blood into cell and then K+ moves into lumen, if we block it then K+ remains in blood (spared)

K+ sparing diuretics block aldosterone, which is involved in K+ excretion (so blocking = reduced excretion)

Question 70

How important is K+ extracellularly vs intracellularly?

Answer 70

• main intracellular ion (150 mmol/L)
• extracellular K+ much lower at 3-5 mmol/L

Question 71

What are the effects of extracellular K+?

Answer 71

• has effects on excitable membranes (of nerve and muscle)
• high K+ depolarises membranes –> action potentials and heart arrhythmias
• low K+ makes depolarisation more difficult –> arrhythmias and asystole (flatline with no ventricular depolarisation)

Question 72

What happens to potassium when we eat a meal?

Answer 72

• potassium is present in most/all foods
• eating a meal leads to K+ absorption - especially unprocessed foods with a lot of K+
• this increases plasma K+ concentration
• this needs to be reduced which happens via tissue uptake

Question 73

What stimulates tissue uptake of potassium? (3)

Answer 73

• insulin
• aldosterone
• adrenaline

Question 74

How does insulin stimulate tissue uptake of potassium?

Answer 74

• indirect - stimulates Na+/H+ exchanger which increases Na+ coming into tissue cells
• this increases intracellular Na+ which needs to be reduced
• achieved via Na+K+ATPase which moves Na+ back into blood and K+ into cell

Question 75

Under normal conditions, how is K+ excreted and reabsorbed through the nephron?

Answer 75

• 67% of K+ is reabsorbed in PCT
• 20% is reabsorbed in thick ascending limb of LoH through Na+2Cl-K+ triple transporter
• 10-50% of K+ is secreted in DCT and up to 30% secreted in collecting duct
• leads to 15-80% of K+ from glomerular filtrate being excreted

Question 76

What stimulates K+ secretion? (4)

Answer 76

• high plasma K+
• increased aldosterone
• increased tubular flow rate
• increased plasma pH

Question 77

How does high plasma K+ cause K+ secretion by principal cells?

Answer 77

• increased activity of Na+/K+ exchanger means more K+ moves into cell
• more K+ in the cell means more K+ leaves cell in tubular fluid
• also an effect on membrane potential which helps stimulate K+ secretion

Question 78

How does increased tubular flow rate cause K+ secretion?

Answer 78

• distal cells have primary cilia
• increased tubular flow = cilia stimulate PDK1 which increases Ca2+ in cell
• this stimulates openness of K+ channels, allowing K+ to move out of cell into tubular fluid after being pumped into cell from blood via Na+K+ATPase

Question 79

How much K+ is excreted when there is low K+ (instead of normal K+)?

Answer 79

• instead of secretion and DCT and collecting duct, K+ is reabsorbed as well similar to earlier parts of the nephron
• 3% reabsorbed in DCT and 9% reabsorbed in collecting duct

Question 80

How common is hypokalaemia?

Answer 80

One of the most common electrolyte imbalances (seen in up to 20% of hospitalised patients)

Question 81

What causes hypokalaemia? (4)

Answer 81

• inadequate dietary intake (too much processed food)
• diuretics (increased tubular flow rates –> K+ secretion via PDK1 mechanism)
• surreptitious vomiting (reduced K+ intake)
• diarrhoea (reduced K+ intake)

Question 82

What genetic conditions can lead to hypokalaemia?

Answer 82

Gitelman’s syndrome (mutation in NaCl transporter in distal nephron) leads to increased K+ loss

Question 83

How common is hyperkalaemia?

Answer 83

Common electrolyte imbalance seen in 1-10% of hospitalised patients

Question 84

What causes hyperkalaemia? (5)

Answer 84

• K+ sparing diuretics
• ACE inhibitors
• elderly
• severe diabetes
• kidney disease