• Adherence to a potassium level 4.0 - 4.5mmol/L [ Time Frame: 7 days ] [ Designated as safety issue: Yes ]
  

• Total quantity of potassium administered [ Time Frame: 7 days ] [ Designated as safety issue: No ]
  
• Incidence of potassium level < 3.0mmol/L and > 5.5mmol/L [ Time Frame: 7 days ] [ Designated as safety issue: Yes ]
  
• Incidence of arrhythmia [ Time Frame: 7 days ] [ Designated as safety issue: Yes ]
  
• Number of arterial blood gases taken [ Time Frame: 7 days ] [ Designated as safety issue: No ]
  

The use of potassium supplementation is commonplace in the critical care environment. Patients often have abnormal serum potassium levels due to active disease processes. Conditions such as acute renal failure and metabolic acidosis precipitate hyperkalaemia, with ileus and insensible losses causing hypokalaemia. Both hypo- and hyperkalaemia can cause life-threatening arrythmias so it is prudent to rectify aberrant levels.

The standard treatment of hypokalaemia in intensive care units is by intravenous administration of potassium chloride. This can be given either as a dilute solution as maintenance intravenous fluid therapy, or as a concentrated solution by intermittent infusion. Alternatively potassium can be given as a concentrated solution by continuous infusion. All techniques require regular monitoring of the patient's serum potassium level with appropriate alterations to the administration regime.

From a theoretical standpoint it would make sense to give potassium by continuous infusion as this allow slow but steady correction of hypokalaemia. A continuous infusion should prevent rapid fluctuations in the serum level that could be caused by intermittent infusions, which may precipitate arrhythmia. However continuous infusions require vigilant monitoring to ensure that hyperkalaemia does not occur and must be given into a central vein to avoid the risk of phlebitis.

The use of intermittent infusions has been used safely in the critical care setting under physician guidance. A retrospective review reported the outcomes of the administration of 495 infusion sets to 190 individuals. While they identified 2 instances of post-infusion hyperkalaemia, neither was associated with any adverse sequelae. Analysis showed a no correlation between serum potassium increase post-infusion and serum creatinine, thus advocating the use of this therapy in patients with renal failure. In light of this valuable safety data, they proceeded with a prospective cohort study involving 40 patients on their Intensive Care Unit. Again the outcomes were favourable with a mean increase of 0.48mmol/L after administration of 20mmol in 100ml of saline over 1 hour. They reported no instances of hyperkalaemia, and data suggested a decreased instance of ectopic beats versus control patients.

The use of a variable dose regime dictated by serum potassium concentration has also been assessed. In a prospective cohort study 20, 30 or 40mmol was administered over 1 hour to 48 patients based on their initial measured potassium level. They only reported 2 instances of hyperkalaemia but neither patient experienced any complications. Usefully they found that patients with oliguric renal failure (creatinine 283 ± 127 micromol/L) had no greater mean increase in potassium level after infusion than patients with normal creatinine clearance.

Two other methods have been suggested. The first, assessed on a paediatric intensive care unit, administered potassium at a rate of 0.25mmol/kg/hr to patients with serum potassium < 3.5mmol/L and ECG abnormalities. The infusion was continued until the ECG abnormalities were corrected. Serum potassium wasn't measured until after completing the infusion, and although the mean increase was only 0.75mmol/L, this method did expose patients to a risk of unmonitored hyperkalaemia. The other involves use of a feedback system with a computer-algorithm driven protocol. This method was not developed into a full production model due to lack of cost-effectiveness.

We were unable to find any trials assessing the efficacy and safety of continuous potassium infusions in the critical care population, so felt it was time this was rectified. Critically ill patients are often hypokalaemic due to insensible losses, inadequate supplementation prior to admission, and use of diuretics and beta-agonists. At the same time they often have acute and/or chronic renal failure or may have a metabolic acidosis that will hamper normal potassium sequestration or excretion. Thus they are at risk of rapidly developing life-threatening hyperkalaemia if supplementation is not carefully titrated against serial monitoring. Continuous infusions administered with due vigilance should allow for correction of hypokalaemia in a safe and precise manner.

Our department used to supplement potassium by intermittent infusion, but after internal discussion we have successfully implemented a continuous infusion protocol. We propose that continuous infusions administered by accredited nurses under physician direction can safely deliver potassium and correct abnormal levels.