Potassium
Pathophysiology
[edit | edit source]- 98% of total body potassium is located inside cells - but we monitor potassium by measuring the 2% (actually we measure the intravascular potassium, which is only 0.4%!)
- Total body potassium about 50mEq / kg
- Daily requirement 50mmol
Hyperkalaemia
[edit | edit source]- Much worse-tolerated than hypokalaemia - can be life-threatening
- Aetiology
- Trans-cellular shift - potassium release from cells - high urine K (>30mEq/L)
- Acidosis - although a causal link has not been firmly established
- Tumour lysis syndrome - appears within 7 days of cytotoxic chemotherapy - AKI, hyperkalaemia, hyperphosphataemia, hypocalcaemia, hyperuricaemia
- Drugs - beta blockers, digitalis, succinylcholine
- Insulin deficiency
- Impaired renal excretion - urine K < 30mEq/L
- Drugs that inhibit RAAS - ACE inhibitors, ARBs, K+-sparing diuretics, NSAIDs, heparin, Bactrim
- Renal failure - usually doesn't occur until eGFR<10, but can appear earlier in interstitial nephritis
- Adrenal insufficiency - only seen in chronic adrenal insufficiency
- Pseudohyperkalaemia - present ex vivo but not in vivo. Repeat the venipuncture when suspected.
- Mostly potassium release from traumatic haemolysis during venipuncture
- K+ release from fist muscles during clenching
- K+ release from clot formation in the tube in patients with severe leucocytosis (>50) or thrombocytosis (1,000)
- Excessive supplementation
- Blood transfusion - begins to appear after 7 units
- Trans-cellular shift - potassium release from cells - high urine K (>30mEq/L)
- Clinical manifestations
- Slowed impulse transmission, which can progress to heart block and bradycardic arrest
- ECG changes usually start at K=7
- Tall, tapering T wave in V2 and V3
- P wave amplitude decreases and PR interval lengthens
- P waves disappear and QRS widens
- VF/asystole
- Severity
- Approach
- Hyperkalaemia is actually quite tricky to treat in some post-op patients
- Assess and stabilise cardiac membrane
- Calcium gluconate 10% in 10mL over 3 minutes; repeat after 5 minutes if necessary; effects last 30-60 minutes; opposes the cardiac depolarisation produced by hyperkalaemia
- Use calcium chloride 10mL of 10% for circulatory shock
- Treat hyperkalaemia - both trans-cellular shift and removal of K from body
- Reduce intake
- Stop fluids containing K+
- Stop supplements
- Low-potassium diet
- Shift intracellular
- Insulin 10 units actrapid in 50mL of 50% dextrose over 5 minutes, with close BSL monitoring, with highest risk after 60 mins. Takes 30-60 minutes. Should decrease K by 0.6mEq/L.
- 10mg salbutamol neb over 30 mins, or 5mg if IHD history. Causes tachycardia as high doses are needed to do anything.
- Increase excretion
- Resonium 30g in 50mL of 20% sorbitol (oral - preferred) or 50g in 200mL of 20% sorbitol (retention enema). Onset at 2 hours, peak at 6 hours.
- Don't use resonium in post-op patients or those with ileus - it can cause intestinal necrosis in rare case reports. It also takes 1-2 hours to work, and has minimal effect if just one dose.
- Frusemide (only if normal renal function, otherwise talk to ICU)
- Dialysis - very effective
- Resonium 30g in 50mL of 20% sorbitol (oral - preferred) or 50g in 200mL of 20% sorbitol (retention enema). Onset at 2 hours, peak at 6 hours.
- Reduce intake
- Identify aetiology
- Management
- Urgent repeat - do a VBG + UEC + CMP
- ECG
- If any ECG changes, manage as per severe hyperkalaemia
Hypokalaemia
[edit | edit source]- Aetiology
- Trans-cellular shift - potassium movement into cells
- Alkalosis (variable and unpredictable)
- Hypothermia (transient)
- Insulin
- Inhaled beta-2 agonist bronchodilators in combination with diuretics
- Decrease in total body potassium
- Urine loss - diuretics, NGT (loss of volume and H+), alkalosis, magnesium depletion (impairs potassium reabsorption in renal tubules). Urine chloride levels are low with NGT and alkalosis, and high with diuretics and magnesium depletion.
- GIT loss - diarrhoea
- Trans-cellular shift - potassium movement into cells
- Clinical manifestations
- Mostly asymptomatic
- Symptoms <2.5
- ECG abnormalities - prominent U waves, flattening and inversion of T waves, prolongation of QT interval. Hypokalaemia alone is not a risk factor for severe arrhythmias, but can add to others
- Diffuse muscle weakness
- Management
- Eliminate or treat any condition leading to trans-cellular shifts
- Identify and correct hypomagnesaemia
- Estimate potassium deficits (mEq and mmol are 1:1 for potassium)
- Replace
- IV if potassium <3.3 or questionable GIT absorption. Reasonable to give both in many cases.
- Check again in 12 hours if K < 3, otherwise check again 24 hours
- Potassium chloride (best option in most)
- 600mg PO tablets contain 8mmol potassium
- Slow-K is modified release
- Span-K is immediate release
- Chlorvescent contains 14mmol potassium (not good for patients with ileus or struggling with fluid intake)
- Can put 10mmol potassium chloride in 100mL normal saline
- 600mg PO tablets contain 8mmol potassium
- Potassium phosphate - can be used in concomitant hypophosphataemia, best choice in DKA because of phosphate depletion
- Potassium bicarbonate - good in hypokalaemia and combined metabolic acidosis
- Serum K can be slow to rise, as explained by the total body K/serum K curve above, and the large total estimated deficits for near-normal serum levels
- Don't need to give calcium gluconate