Most patients are relatively asymptomatic with mild and even moderate hyperkalemia. Elevated potassium is often discovered on screening labs done in patients with nonspecific complaints or those with suspected electrolyte abnormalities due to infection, dehydration or hypoperfusion. Historical clues include the history of renal disease, diabetes, chemotherapy, major trauma, crush injury, or muscle pain suggestive of rhabdomyolysis. Medications that may predispose to the development of hyperkalemia include digoxin, potassium-sparing diuretics, non-steroidal anti-inflammatory drugs, ace-inhibitors or recent intravenous (IV) potassium, total parenteral nutrition, potassium penicillin or succinylcholine. Patients may complain of weakness, fatigue, palpitations, or syncope.

Physical exam findings may include hypertension and edema in the setting or renal disease. There may also be signs of hypoperfusion. Muscle tenderness may be present in patients with rhabdomyolysis. Jaundice may be seen in patients with hemolytic conditions. Patients may have muscle weakness, flaccid paralysis, or depressed deep tendon reflexes.

The first test that should be ordered in a patient with suspected hyperkalemia is an ECG since the most lethal complication of hyperkalemia is cardiac condition abnormalities which can lead to dysrhythmias and death.[5][6][7][8]

Elevated potassium causes ECG changes in a dose-dependent manner: 

• K = 5.5 to 6.5 mEq/L ECG will show tall, peaked t-waves
• K = 6.5 to 7.5 mEq/L ECG will show loss of p-waves
• K = 7 to 8 ECG mEq/L will show widening of the QRS complex
• K = 8 to 10 mEq/L will produce cardiac arrhythmias, sine wave pattern, and asystole

It should be noted that the rate of rising in serum potassium is a greater factor than the level. Patients with chronic hyperkalemia may have relatively normal EGCs even at high levels, and significant ECG changes may be present at much lower levels in patients with sudden spikes in serum potassium.ECG features of hyperkalemia include:

• Small or absent P wave
• Prolonged PR interval
• Augmented R wave
• Wide QRS
• Peaked T waves

Additional laboratory testing should include serum blood urea nitrogen and creatinine to assess renal function, and urinalysis to screen for the renal disease. Urine potassium, sodium, and osmolality may also be helpful in evaluating the cause. In patients with the renal disease, the serum calcium level should also be checked because hypocalcemia may exacerbate the cardiac effects of hyperkalemia. Complete blood count to screen for leukocytosis or thrombocytosis may also be helpful. Serum glucose and blood gas analysis should be ordered in diabetics and patients with suspected acidosis. Lactate dehydrogenase should be ordered in patients with suspected hemolysis. Creatinine phosphokinases and urine myoglobin should be ordered in patients with suspected rhabdomyolysis. Uric acid and phosphorus should be ordered in patients with suspected tumor lysis syndrome. Digoxin toxicity may cause hyperkalemia so serum levels should be checked in patients on digoxin. If no other cause is found, consider cortisol and aldosterone levels to assess for mineralocorticoid deficiency.

Since pseudohyperkalemia is so common, confirmation should be obtained in asymptomatic patients without typical ECG changes prior to initiating aggressive therapy.

The urgency with which hyperkalemia should be managed depends on how rapidly the condition developed, the absolute serum potassium level, the degree of symptoms, and the cause.[9][10][11]

Patients with neuromuscular weakness, paralysis or ECG changes and elevated potassium of more than 5.5 mEq/L in patients at risk for ongoing hyperkalemia, or confirmed hyperkalemia of 6.5 mEq/L should have aggressive treatment. Exogenous sources of potassium should be immediately discontinued. Calcium therapy will stabilize the cardiac response to hyperkalemia and should be initiated first in the setting of cardiac toxicity. Calcium does not alter the serum concentration of potassium but is first-line therapy in hyperkalemia related arrhythmias and ECG changes.  Calcium chloride contains three times more elemental calcium than calcium gluconate but is more irritating to peripheral vessels and more likely to cause tissue necrosis with extravasation, so it is usually only given through central venous lines or peripherally in cardiac arrest. Thus, calcium gluconate is the usual initial drug of choice in patients with evidence of cardiac toxicity. Insulin and glucose, or insulin alone in hyperglycemic patients, will drive the potassium back into the cells, effectively lowering serum potassium. A common regimen is ten units of regular insulin given with 50 ml of a 50% dextrose solution (D50). Patients should be monitored closely for the development of hypoglycemia. A 10% dextrose infusion at 50-75 ml/hour is associated with less hypoglycemia than bolus dosing with D50. Beta-2 adrenergic agents such as albuterol will also shift potassium intracellularly. To be effective, beta-2 agonists are given in much higher doses than commonly used for bronchodilation. Sodium bicarbonate infusion may be helpful in patients with metabolic acidosis. Bolus dosing of sodium bicarbonate is less effective.

Loop or thiazide diuretics may be helpful in enhancing potassium excretion. They may be used in non-oliguric, volume overloaded patients but should not be used as monotherapy in symptomatic patients. Gastrointestinal cation exchangers such as patiromer may be helpful, particularly in patients with renal insufficiency who cannot receive immediate dialysis. Sodium polystyrene sulfonate, though commonly used, is falling out of favor due to lack of effectiveness and adverse effects, particularly bowel necrosis in elderly patients. If used due to lack of alternatives, it should not be given with sorbitol, which increases toxicity. Hemodialysis should be performed in patients with end-stage renal disease or severe renal impairment.

Complications of Treatment

• Hypokalemia
• Inability to control hyperkalemia
• Hypocalcemia as a result of bicarbonate infusion
• Hypoglycemia due to insulin
• Metabolic alkalosis from bicarbonate therapy
• Volume depletion from diuresis

• Acute tubular necrosis

• Congenital adrenal hyperplasia

• Digitalis toxicity

• Electrical burn injuries

• Head trauma

• Hypocalcemia

• Metabolic acidosis

• Rhabdomyolysis

• Thermal burns

• Tumor lysis syndrome

For patients with mild transient hyperkalemia, the prognosis is excellent if the inciting cause is addressed and treated. Sudden onset, extreme hyperkalemia can cause cardiac arrhythmias that can be lethal in up to two-thirds of cases if not rapidly treated. Hyperkalemia is an independent risk factor for death in hospitalized patients.

• Cardiac arrest
• Weakness
• Arrhythmias

Low salt diet

Avoid medications that cause hyperkalemia

The management of hyperkalemia is an interprofessional because of its potential to induce cardiac arrest and severe weakness. Once hyperkalemia is diagnosed, the primary condition must be treated. Patients with hyperkalemia need cardiac monitoring and nurses should be familiar with ECG features of hyperkalemia, which are often the first to appear. The pharmacist has to ensure that all nephrotoxic medications and agents that raise potassium are discontinued and discuss their findings with the clinical team. Nursing will perform monitoring and followup, watching for signs of worsening hyperkalemia and alerting the clinical staff immediately for corrective action.

If hyperkalemia is severe, the nephrologist should be consulted. If ECG changes are present a cardiology consult should be made. Treatment to lower the high potassium should be ongoing. These patients need cardiac monitoring 24/7 until hyperkalemia has resolved. The dietitian should educate the patient on a low potassium diet. For those with renal dysfunction, continued to follow up with a nephrologist is recommended. Only through open communication between members of the interprofessional team can the morbidity of hyperkalemia be avoided.

Outcomes

The majority of patients have an excellent prognosis. However, patients with chronic disorders like end-stage renal failure may require continual blood work to monitor potassium.[12][13] (Level V)