Renal insufficiency: hyperkalemia
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Introduction to Potassium
K+ outflow is responsible for phase III (repolarization) of the cardiac cycle. Insulin and beta agonists promote the influx of K+. Total body stores include 4200 mEq intracellularly, versus only 12 mEq in the plasma. Potassium excretion of K+ is determined primarily by [K+] and aldosterone levels
Causes of Hyperkalemia in Renal Failure
Decreased excretion (lowered GFR, K+ sparing diuretics, ACE-inhibitors, heparin [decreased aldosterone efficacy], and constipation), intracellular release (metabolic acidosis, beta blockers, insulin deficiency), and increased intake (blood transfusion, increased dietary intake)
Hyperkalemia in Renal Failure: Anesthetic Concerns
Time Course of Hyperkalemia
Potassium balance usually maintained in early renal failure, thus hyperkalemia is a late sign (a GFR of 8 cc/min is adequate to clear potassium)
Hyperkalemia and Induction
In non-renal failure patients, induction with SCh increased [K+] by 0.4 mEq/L [Manninen PH et al. Anesth Analg 70: 172, 1990] and by 0.09 mEq/L [Stacey MR et al. Anaesthesia 50: 933, 1995]. Schow et al. reviewed 40,000 anesthetics at Duke University Medical Center, and found 38 cases in which SCh was used with a starting potassium > 5.5 mEq/L. No fatalities or arrhythmias occurred, and the authors estimated that the maximal risk of an event was 7.9% or less [Schow AJ et al. Anesth Analg 95: 119, 2002; FREE Full-text at Anesthesia & Analgesia]
Duration of Neuromuscular Blockade
Despite the fact that muscle weakness is a sign of hyperkalemia (at > 7 mEq/L), Miller at al. showed that the prolongation of neuromuscular blockade following paralysis in renal failure patients is not related to potassium levels, but rather to the relative inability of the kidneys to excrete NMBDs or their metabolites
Signs of Hyperkalemia
(> 6 mEq/L): peaked T waves, prolonged PR interval (ex. AV block), flattened P wave, QRS widened to sine wave; (> 7 mEq/L): musculoskeletal weakness; Note that these effects are worsened by hyponatremia, hypocalcemia, and acidosis, all of which are present in the setting of renal failure
Acute Treatment of Hyperkalemia
1g CaCl2, 50g glucose, 10 U insulin, furosemide, 100 mEq bicarbonate (controversial)
Renal Failure: Hyperkalemia
- Causes: decreased excretion (lowered GRF, ACE-inhibitors), intracellular release (metabolic acidosis), increased intake (transfusion)
- Signs: peaked T waves, prolonged PR interval, flattened P wave, QRS widened to sine wave, musculoskeletal weakness
- Acute Treatment: 1g CaCl2, 50g glucose, 10 U insulin, furosemide, 100 mEq bicarbonate (controversial)
- Anesthesia Concerns: very real but may be overstated; increase in non-renal failure patients < 0.5 mEq/L with SCh. Affect on paralysis not related to K+
Other Electrolyte Abnormalities in Renal Failure
(see also Renal failure: electrolytes and Renal Failure)
Sources: Duerksen DR and Papineau N. Journal of Parenteral and Enteral Nutrition 22: 102, 1998; Miller's Anesthesia, 7th Edition. p 2112; Barash, PG. Clinical Anesthesia, 5th ed. (Philadelphia), p. 1020, 2006; Manninen PH et al. Anesth Analg 70: 172, 1990; Stacey MR et al. Anaesthesia 50: 933, 1995; Schow AJ et al. Can Succinylcholine Be Used Safely in Hyperkalemic Patients? Anesth Analg 95: 119, 2002; FREE Full-text at Anesthesia & Analgesia
