Hyperkalemia
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American Roentgen Ray Society Images of Hyperkalemia |
Editor-In-Chief: C. Michael Gibson, M.S., M.D. [1]; Associate Editor(s)-In-Chief: Priyamvada Singh, M.B.B.S. [2]; Raviteja Guddeti, M.B.B.S. [3];Mahmoud Sakr, M.D. [4]
Synonyms and keywords: Hyperkalaemia.
Overview
Hyperkalemia (AE) or Hyperkalaemia (BE) is an elevated blood level (above 5.0 mmol/L) of the electrolyte potassium. The prefix hyper- means high (contrast with hypo-, meaning low). The middle kal refers to kalium, which is Latin for potassium. The end portion of the word, -emia, means "in the blood". Extreme degrees of hyperkalemia are considered a medical emergency due to the risk of potentially fatal arrhythmias
Pathophysiology
Potassium is the most abundant intracellular cation. It is critically important for many physiologic processes, including maintenance of cellular membrane potential, homeostasis of cell volume, and transmission of action potentials in nerve cells. Its main dietary sources are vegetables (tomato and potato), fruits (orange and banana) and meat. Elimination is through the gastrointestinal tract and the kidney.
The renal elimination of potassium is passive (through the glomeruli), and resorption is active in the proximal tubule and the ascending limb of the loop of Henle. There is active excretion of potassium in the distal tubule and the collecting duct; both are controlled by aldosterone.
Hyperkalemia develops when there is excessive production (oral intake, tissue breakdown) or ineffective elimination of potassium. Ineffective elimination can be hormonal (inaldosterone deficiency) or due to causes in the renal parenchyma that impair excretion.
Increased extracellular potassium levels result in depolarization of the membrane potentials of cells. This depolarization opens some voltage-gated sodium channels, but not enough to generate an action potential. After a short while, the open sodium channels inactivate and become refractory, increasing the threshold to generate an action potential. This leads to the impairment of neuromuscular, cardiac, and gastrointestinal organ systems. Of most concern is the impairment of cardiac conduction which can result in ventricular fibrillation or asystole.
Patients with the rare hereditary condition of hyperkalemic periodic paralysis appear to have a heightened sensitivity of muscular symptoms that are associated with transient elevation of potassium levels. Episodes of muscle weakness and spasms can be precipitated by exercise or fasting in these subjects.==[[Hyperkalemia ==Risk factors
Risk Factors
The kidneys normally remove excess potassium from the body. Most cases of hyperkalemia are caused by disorders that reduce the kidneys' ability to get rid of potassium. This may result from disorders such as:
- Acute kidney failure
- Chronic kidney failure
- Glomerulonephritis
- Obstructive uropathy
- Rejection of a kidney transplant
The hormone aldosterone regulates kidney removal of sodium and potassium. Lack of aldosterone can result in hyperkalemia with an increase in total body potassium.Addison's disease is one disorder that causes reduced aldosterone production.
Any time potassium is released from the cells, it may build up in the fluid outside the cells and in the bloodstream. Acidosis leads to the movement of potassium from inside the cells to the fluid outside the cells. Tissue injury can cause the cells to release potassium. Such injury includes:
- Burns
- Disorders that cause blood cells to burst (hemolytic conditions)
- Gastrointestinal bleeding
- Rhabdomyolysis from drugs, alcoholism, coma, or certain infections
- Surgery
- Traumatic injury
- Tumors
If the kidney is working properly, and there is enough aldosterone, tissue trauma alone rarely leads to hyperkalemia. A normally functioning kidney will remove the excess potassium that has been released from the cells.
Increased intake of potassium can cause hyperkalemia if kidney function is poor. Salt substitutes often contain potassium, as do many "low-salt" packaged foods.
Hyperkalemia may be caused by medications, including medications that affect kidney function (potassium sparing diuretics, such as spironolactone, amiloride, ortriamterene) and potassium supplements (especially intravenous potassium).
Causes
Common Causes
- ACE inhibitors
- Acidosis
- Addisonian crisis
- Beta blockers
- Blood transfusion and complications
- Cirrhosis
- Diabetic nephropathy
- Increased ingestion of high potassium foods
- Malnutrition
- Renal tubular acidosis
- Renal failure
Causes by Organ System
Causes in Alphabetical Order
Diagnosis
History
A detailed history taking is very helpful in diagnosing the cause of hyperkalemia.
- Dietary history (diets with low sodium and rich in potassium)
- Diets recommended for patients with cardiac disease, hypertension, and diabetes mellitus
- Potassium supplements in herbal supplements, salt substitutes
- Fruits, dried fruits, juices, banana and vegetables
- Medications history (drugs causing a decreased excretion of potassium)
- Nonsteroidal anti-inflammatory drugs
- Angiotensin-converting enzyme inhibitors
- Angiotensin receptor blockers (potassium-sparing diuretics, especially popular in the treatment of cirrhosis and congestive heart failure)
- Cyclosporine or tacrolimus
- Antibiotics, such as pentamidine or trimethoprim/sulfamethoxazole
- Medical history
- Renal failure
- Diabetes mellitus
- Sickle cell disease or trait
- Urinary tract obstruction - Type IV renal tubular acidosis, also called hyperkalemic renal tubular acidosis. It can be seen with polycystic kidney disease,amyloidosis and diabetes mellitus.
- The combination of abdominal pain, hypoglycemia and hyperpigmentation, often in the context of a history of other autoimmune disorders, may be signs of Addison's disease, itself a medical emergency.
Symptoms
Hyperkalemia often has no symptoms and the problem may be detected during screening blood tests for another medical disorder, or it may only come to medical attention after complications have developed, such as cardiac arrhythmia or sudden death. Patients may present with the symptoms such as, irregular heartbeat, nausea, slow, weak, or absent pulse. Extreme degrees of hyperkalemia are considered a medical emergency due to the risk of potentially fatalarrhythmias. Symptoms are fairly nonspecific and may include:
- Malaise
- Palpitations
- Muscle weakness
- Mild breathlessness may indicate metabolic acidosis, one of the settings in which hyperkalemia may occur.
Physical Examination
Vitals
Pulse
- Bradycardia (heart block)
Respiratory Rate
- Tachypnea (respiratory muscle weakness)
Neurologic
- Muscle weakness
- Flaccid paralysis
- Depressed or absent deep tendon reflexes
- Muscle tenderness associated with muscle weakness (rhabdomyolysis)
Laboratory Findings
Initial
- Calcium
- Phosphate
- Magnesium
- Blood urea nitrogen (BUN)/creatinine
Extensive Evaluation
- Cortisol
- Renin
- Aldosterone levels
- Transtubular potassium gradient (by assessing potassium+ secretion)
Electrocardiogram
There appears to be a direct effect of elevated potassium on some of the potassium channels that increases their activity and speeds membrane repolarization. Hyperkalemia causes an overall membrane depolarization that inactivates many sodium channels. The faster repolarization of the cardiac action potential causes the tenting of the T waves, and the inactivation of sodium channels causes a sluggish conduction of the electrical wave around the heart, which leads to smaller P waves and widening of the QRS complex.
Moderate Hyperkalemia
With moderate hyperkalemia, there is reduction of the size of the P wave and development of tent-shaped T waves.
Severe Hyperkalemia
Further hyperkalemia will lead to widening of the QRS complex, and the QRS complex may ultimately become sinusoidal in shape (sine wave pattern).
EKG Examples
The EKG below demonstrates Peaked T waves of hyperkalemia.
The EKG below demonstrates characteristics of hyperkalemia including: Broad QRS complexes circled in green; fusion of the QRS complex and the Twave as circled in blue; and tall peaked T waves as circled in red.
Tall, Narrow, and Peaked T waves
- Earliest sign of hyperkalemia
- Occurs with K > 5.5 meq/li
- Differential diagnosis of this EKG change includes the T wave changes of bradycardia or stroke.
- Prominent U waves and QTc prolongation are more consistent with stroke than hyperkalemia.
Shown below is the EKG demonstrating Tall, narrow and peaked T waves:
Shown below is the EKG demonstrating Tall, narrow and peaked T waves:
Intraventricular Conduction Defect
- Observed when K > 6.5 meq/li
- There is a modest correlation of the QRS duration with serum K
- As the K rises, the QRS complexes may resemble sine waves
- Generally the widening is diffuse and usually there is no resemblance of the morphology to that of either LBBB or RBBB
Intraventricular Conduction Defect on EKG Before and After Treatment for Hyperkalemia
Shown below are the series of EKG images before, during and after treatment:
- Before Treatment
- During Treatment
- After Treatment
Decrease of the Amplitude of the P wave or an Absent P Wave
- Decreased P wave amplitude occurs when the K is > 7.0 meq/li
- P waves may be absent when the K is > 8.8 meq/li
- The impulses are still being generated in the SA node and are conducted to the ventricles through specialized atrial fibers without depolarizing the atrial muscle
- Moderate or sever hyperkalemia can cause sinus arrest [4]
ST Segment Changes Simulating Current of Injury
- Have been labeled the dialyzable current of injury
Cardiac arrhythmias: bradyarrhythmias, tachyarrhythmias, atrioventricular conduction defects
- Occurs with severe hyperkalemia, not mild to moderate hyperkalemia
Treatment
Medical Therapy
- Calcium supplementation (calcium gluconate 10% (10ml), preferably through a central venous catheter as the calcium may cause phlebitis) does not lower potassium but decreases myocardial excitability, protecting against life threatening arrhythmias.
- Insulin (e.g. intravenous injection of 10-15u of (short acting) insulin (e.g. Actrapid) {along with 50ml of 50% dextrose to prevent hypoglycemia}) will lead to a shift of potassium ions into cells, secondary to increased activity of the sodium-potassium ATPase.
- Bicarbonate therapy (e.g. 1 ampule (45mEq) infused over 5 minutes) is effective in cases of metabolic acidosis. The bicarbonate ion will stimulate an exchange of cellular H+ for Na+, thus leading to stimulation of the sodium-potassium ATPase.
- Salbutamol (albuterol, Ventolin®) is a β2-selective catacholamine that is administered by nebuliser (e.g. 10-20 mg). This drug promotes movement of K into cells, lowering the blood levels.
- Polystyrene sulfonate (Calcium Resonium, Kayexalate) is a binding resin that binds K within the intestine and removes it from the body by defecation. Calcium Resonium (15g three times a day in water) can be given by mouth. Kayexelate can be given by mouth or as an enema. In both cases, the resin absorbs K within the intestine and carries it out of the body by defecation. This medication may cause diarrhea.
- Refractory or severe cases may need dialysis to remove the potassium from the circulation.
- Preventing recurrence of hyperkalemia typically involves reduction of dietary potassium, removal of an offending medication, and/or the addition of a diuretic (such asfurosemide (Lasix®) or hydrochlorothiazide).
References
- ↑ Sevastos N et al. (2006) Pseudohyperkalemia in serum: the phenomenon and its clinical magnitude. J Lab Clin Med, 147(3):139-44; PMID 16503244.
- ↑ Don BR et al. (1990) Pseudohyperkalemia caused by fist clenching during phlebotomy. N Engl J Med, 322(18):1290-2; PMID 2325722.
- ↑ Iolascon A et al. (1999) Familial pseudohyperkalemia maps to the same locus as dehydrated hereditary stomatocytosis. Blood, 93(9):3120-3; PMID 10216110.
- ↑ Bonvini RF, Hendiri T, Anwar A (2006). "Sinus arrest and moderate hyperkalemia". Annales De Cardiologie Et D'angéiologie. 55 (3): 161–3. PMID 16792034. Unknown parameter
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