Approach to hyperkalemia: Clinical sciences

Last updated: January 30, 2025

Approach to hyperkalemia: Clinical sciences

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Decision-Making Tree

Questions

USMLE® Step 2 style questions USMLE

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A 65-year-old man presents to his primary care PA to follow up on abnormal laboratory results. He previously had a potassium level of 5.6 mEq/L. His past medical history includes type 2 diabetes mellitus and stage 3 chronic kidney disease. The patient’s laboratory studies are listed below. Which of the following is the most likely cause of the previous hyperkalemia and the current laboratory results?  

Laboratory study
Result
Reference
Potassium
5.7 mEq/L
3.5-5.0 mEq/L
Bicarbonate
22 mEq/L
22-28 mEq/L
Glucose
202 mg/dL
70-110 mg/dL (fasting)
eGFR
35 mL/min/1.73m2
>60mL/min/1.73m2
Creatine kinase
60 units/L
25-90 units/L
Aldosterone
8 ng/dL (supine)
2-5 ng/dL (supine)
Serum osmolality
290 mOsm/kg H2O
275–295 mOsm/kg H2O

Transcript

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Hyperkalemia refers to an elevated serum potassium level, usually above 5.5 milliequivalents per liter. Mild hyperkalemia can be asymptomatic, while severe hyperkalemia can cause life-threatening symptoms like paralysis and cardiac arrhythmias.

Some common causes of hyperkalemia include increased potassium intake and conditions associated with transcellular potassium shifts, like medication-induced hyperkalemia, metabolic acidosis, tumor lysis, rhabdomyolysis, or due to decreased effective arterial blood volume. Another very important cause is reduced renal function, or renal failure. Lastly, other causes include tubular resistance to aldosterone, hyporeninemic hypoaldosteronism, and adrenal insufficiency.

Now, if you suspect hyperkalemia, you should first perform an ABCDE assessment to determine if your patient is unstable or stable. If the patient is unstable, stabilize the airway, breathing, and circulation. Next, obtain IV access and put your patient on cardiac telemetry. This is important because extreme elevations in serum potassium can lead to myocardial instability and dangerous cardiac arrhythmias, such as ventricular fibrillation. You should also monitor vital signs and provide supplemental oxygen, if needed.

Now that we're done with unstable patients, let’s go back to the ABCDE assessment and discuss the stable ones. If your patient is stable, first obtain a focused history and physical examination. Next, obtain labs, including a comprehensive metabolic panel or CMP, and an arterial or venous blood gas, as well as a 12-lead ECG. History typically reveals palpitations, paresthesias, muscle weakness, or even ascending paralysis in extreme cases. Additionally, there might be a known history of acute or chronic kidney disease. On the flip side, physical examination usually reveals generalized weakness or a strength deficit, but you could also see fasciculations, or involuntary muscle twitching, as well as flaccid paralysis.

Lab findings will reveal a potassium above 5.5 milliequivalents per liter, and the ECG might demonstrate characteristic changes as the degree of hyperkalemia progresses. The earliest manifestation is tall-peaked T waves, followed by p wave flattening, and prolongation of the PR interval. In severe cases, you might even see disappearance of P waves, widening of the QRS complex and the eventual development of a sine-wave appearance. At this point, you can diagnose hyperkalemia!

Now, here’s a clinical pearl to keep in mind! Laboratory processing of blood specimens can affect your interpretation of potassium levels. If hemolysis or blood clotting occurs during blood collection and storage, intracellular potassium might be released into the extracellular fluid, causing a falsely elevated potassium level, or pseudohyperkalemia. Alternatively, transfusing packed red blood cells can cause a true hyperkalemia. During storage, potassium can diffuse from the cellular layer to the plasma layer of donor blood. So after transfusion, the potassium in the donor plasma causes a true, but generally brief, elevation in the recipient's serum potassium level. If you suspect any of these scenarios, be sure to repeat the blood draw.

Okay, now that you’ve diagnosed hyperkalemia, the first thing you should do is treat it. The treatment options can be remembered with the mnemonic C BIG K Drop. This stands for Calcium gluconate, Beta-agonists or Bicarbonate, Insulin, Glucose, K-binders, and Diuretics or Dialysis.

Calcium gluconate helps stabilize the cardiac cell membrane, so it should be immediately given to patients with ECG changes or cardiac arrhythmia in the setting of severe hyperkalemia above 6.5 milliequivalents per liter.

Beta-agonists like albuterol, Bicarbonate, or Insulin help rapidly shift potassium into cells, decreasing its serum levels. Keep in mind that the effect of medications that shift potassium into cells is only temporary, so they’re usually used while waiting for another treatment option to take effect.

Additionally, Glucose is given with insulin to prevent hypoglycemia, since insulin will also shift glucose into cells. Next, K-binders, like Sodium sulfonate, can be used prevent gastrointestinal absorption of potassium, increasing its fecal excretion; while Diuretics like furosemide in addition to IV saline infusion are given to help increase urinary excretion of potassium.

Lastly, Dialysis can be used to remove potassium from the body, but it’s typically reserved for refractory cases who don’t respond to any other treatment options, and for patients with renal failure.

Ok, now that you’ve treated your patient’s hyperkalemia, let’s look for the cause. First, consider increased potassium load. If your patient has a high dietary potassium intake, either through potassium rich foods or supplements, you can diagnose hyperkalemia due to increased potassium load. On the other hand, if the history suggests a normal potassium load, you should consider conditions associated with transcellular shift of potassium, which actually refers to the movement of potassium from the intracellular to the extracellular space.

If your patient has received medications such as beta blockers, digoxin, or succinylcholine, consider medication-induced hyperkalemia as the cause. Alternatively, if your patient's labs reveal a pH below 7.35, a low serum bicarbonate, and a normal anion gap, diagnose hyperkalemia due to metabolic acidosis with a normal anion gap. This occurs due to a compensatory mechanism involving the exchange of intracellular potassium ions for extracellular hydrogen ions.

Sources

  1. "Emergency management of severe hyperkalemia: Guideline for best practice and opportunities for the future" Pharmacol Res (2016)
  2. "Guidelines for the Management of Pediatric and Adult Tumor Lysis Syndrome: An Evidence-Based Review" J Clin Oncol. (2008)
  3. "Harrison's Principles of Internal Medicine, 20e. " McGraw Hill (2018)
  4. "Diagnosis and treatment of hyperkalemia" Cleve Clin J Med. (2017)
  5. "Potassium Disorders: Hypokalemia and Hyperkalemia" Am Fam Physician (2015)