Control Of Potassium

Question 1

Where is most potassium?

Answer 1

Inside cells (98% of K) -mostly in skeletal muscles

[K+] = 120-150mmol/L

ECF = only 2% (3-5mmol/L)

This means that a shift of 1% of ICF K+ to ECF would raise ECF [K+] by 50%.

Question 2

How is the difference between ECF and ICF maintained?

Answer 2

NaKATPase - maintaining it is critical

Question 3

Why is maintaining ECF [K+] so critical?

Answer 3

Because of its effect on the resting membrane potential.

Hence its effect on excitability of cardiac tissue.

Hence the risk of life threatening arrhythmias with hyperkalaemia and hypokalaemia

Question 4

How is ECF K+ regulated?

Answer 4

Immediate control - by internal balance - moves K+ between ECF and ICF

Longer term, overall K+ balance - by external balance (match input with output) adjusting renal secretions.

Question 5

List some foods that are rich in potassium

Answer 5

Raisins 
Honey dew melon 
Banana 
Orange 
Tomato 
Potato chips 
Baked potato 
Milk

Question 6

How does your body control potassium following a meal?

Answer 6

The intestines and colon absorb dietary K+ - This means ECF K+ will increase a little bit.

BUT, 4/5th moves into cells within minutes to stop [K+] increasing my too much.

After a slight delay kidneys begin to excrete K+ -excretion is complete in 6-12 hours.

New research also suggest that the gut has some influence in controlling after meal K+ secretion

Question 7

How does potassium enter and leave cells?

Answer 7

Internal balance is the net result of the movement of K+ into and out of cells.

K+ moves from ECF into cells via NaKATPase

K+ moves out of cells into ECF via K+ channels (channels which determine the K+ permeability of the cell membrane)

Question 8

What factors increase the K+ uptake by cells?

Answer 8

Hormones

• Insulin (rises anyway with a meal)
• Aldosterone (secreted from suprarenal gland -stimulated by RAAS)
• Catecholamines (B2 agonist)

Increased [K+] in ECF

Alkalosis pH - low ECF [H+] - K+ shift into cells.

Question 9

What factors provost the K+ shift out of cells?

Answer 9

Exercise

Cel lysis

Increase in ECF osmolality (e.g. diabetes)

Low ECF [K+]

Acidosis - increase in ECF [H+] camisoles a K+ shift and movement out of the cells.

Question 10

How does insulin cause an increase in K+ uptake?

Answer 10

K+ in splanchnic blood stimulates insulin secretion by pancreas

Insulin increases Na-K-ATPase activity - increases K+ uptake by muscle cells and liver.

I.V insulin + Dextrose is used to treat hyperkalaemia

Question 11

How does aldosterone cause an increase in K+ uptake?

Answer 11

K+ in blood stimulates aldosterone secretion which stimulates the uptake of K+ via NaKATPase.

Question 12

How do catecholamines stimulate the uptake of K+?

Answer 12

Act via B2 adrenoreceptors which stimulate Na-K-ATPase and cellular uptake of K+

Question 13

What happens to the K+ concentration in exercise?

Answer 13

Net release of K+ during recovery phase of action potential, K+ exits the cell.

Also skeletal muscle damage during exercise releases K+.

This means that the increase plasma [K+] is proportional to the intensity of the exercise.

Uptake by non-contracting tissues prevents dangerously high hyperkalaemia.

Exercise and trauma also increases catecholamines, high offset ECF [K+] rise by increasing K+ uptake by other cells.

Cessation of exercise results in a rapid decrease in plasma [K+], often to under 3mmol/L.

Question 14

How does acidosis lead to hyperkalaemia?

Answer 14

In acidosis, H+ shift into cells and there is a reciprocal shift of K+ out of the cells.

The opposite can occur and hyperkalaemia can cause acidosis.

Question 15

How does alkalosis lead to hypokalaemia?

Answer 15

Alkalosis causes a shift of H+ out of the cells.

This means there is a reciprocal shift of K+ Ito the cells.

The opposite can occur and hypokalaemia can cause alkalosis.

Question 16

Where abouts in the nephron is potassium mainly regulated?

Answer 16

Late distal tubule an cortical collecting duct

Question 17

How does the kidney handle potassium?

Answer 17

Most of the K+ is reabsorbed.

• 67% in PCT
• 20% in Thick ascending limb of LoH
• Rest in DT and collecting duct

Some K+ is secreted into the distal tubule and cortical collecting duct - this can be varied and controlled so it is this K that will appear in the urine and not that which is reabsorbed.

Question 18

How will K+ reabsorbtion / secretion change if you have a low K+ diet?

Answer 18

The reabsorbtion mainly stays the same.

The secretion in the principle cells of DCT and cortical collecting duct will be minimised.

Question 19

How is K+ secreted in the distal tubule and collecting duct?

Answer 19

It is secreted by principle cells.

NaKATPase activity in the basolateral membrane increase [K+] and decrease [Na+].

High intracellular K+ creates a chemical gradient for secretion.

Na+ moves from lumen into cell down its concentration gradient (via apical ENaC) creating an electrical gradient.

Together create a favourable electrochemical gradient for K+ secretion via apical K+ channels.

Question 20

What tubular factors affect K+ secretion by principle cells?

Answer 20

ECF [K+]

• Directly stimulates NaKATPase and increases permeability of apical K+ channels.
• Also stimulates aldosterone secretion

Aldosterone 
-Increases: 
transcription of relevant proteins 
K+ channels 
ENaC in apical membrane 

Acid base status
-Acidosis - decreases K+ secretion, inhibits NaKATPase and decrease K+ channel permeability. Alkalosis does the opposite.

Question 21

What luminal factors affect K+ secretion by principle cells?

Answer 21

Increased distal tubular flow rate - washes away luminal K+ and increases K+ loss.

Increases Na delivery to distal tubule - more Na absorbed which results in more Na absorbed and therefore more K+ loss. (E.g. diuretic - ferosimide bocks Na absorption in thcika spending limb so more available downstream)

Question 22

What cells absorb K+ in the DT and CD?

Answer 22

Intercalated cells.

This is an active process that is mediated by the HKATPase in the apical membrane.

Question 23

What are some of the effects of changes in ECF [K+]?

Answer 23

Alter cell membrane resting potential

Alter neuro muscular excitability

• Problems with cardiac conduction and pacemaker automaticity
• Alter neuronal function
• Alter skeletal muscle function
• Alter smooth muscle function

Results in arrhythmias, cardiac arrest, muscle paralysis.

BUT, usually pick it up quite late so need to know situations that this is likely to occur.

Question 24

What could cause hyperkalaemia?

Answer 24

Increased intake (unlikely) - only if renal dysfunction is also present. Unless inappropriate dose of IV K+

Decreased renal excretion (more likely)

• Acute of chronic kidney injury
• Drugs that block K+ excretion (most frequent) - ACE inhibitors, K+ sparing diuretics
• Low aldosterone state (addison’s disease).

Also internal shift.

Question 25

What could cause an internal shift in K+ (Start leaving cells)?

Answer 25

Diabetic ketoacidosis
-No insulin and plasma hyperosmolarity and metabolic acidosis

Cell lysis
-Muscle crush injury , tumour cell lysis

Metabolic acidosis

Exercise

Question 26

What are the clinical features of hyperkalaemia?

Answer 26

Heart - altered excitability (arrhythmias, heart block)

GI - neuromuscular dysfunction, paralytic lieus

Acidosis

Question 27

Describe the ECG of hyperkalaemia

Answer 27

7mmol/L - High T wave

8mmol/L - Prolonged PR interval, depressed ST segment, high T wave

9mmol/L - Atrial standstill (no P waves), intraventricular block

10mmol/L - Ventricular fibrillation

Question 28

How do you treat hyperkalaemia (short term)?

Answer 28

1. IV calcium gluconate to prevent arrhythmias (works immediately for half an hour)
2. IV glucoses and insulin (works in about 30 mins) pushes K+ back into cells.
   Also give nebuliser beta agonist (salbultamol)
   -Lasts 3-4 hours
3. Dialysis to remove express K+

Question 29

How do you treat hyperkalaemia (long term)?

Answer 29

1. Treat cause - stop meds, treat DKA
2. Reduce K+ intake
3. Measures to remove excess K+ -Dialisis or oral K+ biding resins to bind K+ in gut.

Question 30

What could cause hypokalaemia?

Answer 30

1. External balance
   -Excessive loss
   GI - diarrhoea/ vomiting / bulimia
   Renal losses of K+ - Diuretics, osmotic diuresis (diabetes), high aldosterone levels.
2. Problems with internal balance - shift of K+ into ICF e.g. metabolic alkalosis.

Question 31

What are the clinical features of hypokalaemia?

Answer 31

1. Heart - altered excitability causing arrhythmias.
2. GI - neuromuscular dysfunction causing paralytic lieus (more likely in low than high K)
3. Skeletal muscle - neuromuscular dysfunction causing muscle weakness.
4. Renal - unresponsive to ADH - nephrogenic DI (polyuria and polydipsia).

Question 32

What ECG changes occur in hypokalaemia?

Answer 32

3.5 - low T ave

3 - low T wave, high U wave

2.5 - Low T wave, high U wave, Low ST segment.

Question 33

How do you treat hypokalaemia?

Answer 33

Treat cause

Potassium replacement - IV / oral

If due to increased mineralcorticoid activity - K sparing diuretics which block the action of aldosterone on principle cells.