Hypokalemia

Hypokalemia
Classification and external resources

An ECG in a person with a potassium level of 1.1 showing the classical ECG changes of ST segment depression, inverted T waves, large U waves, and a slightly prolonged PR interval.
ICD-10 E87.6
ICD-9 276.8
DiseasesDB 6445
MedlinePlus 000479
eMedicine emerg/273
MeSH D007008

Hypokalemia (American English) or hypokalaemia (British English), also hypopotassemia or hypopotassaemia (ICD-9), refers to the condition in which the concentration of potassium (K+) in the blood is low. The prefix hypo- means "under" (contrast with hyper-, meaning "over"); kal- refers to kalium, the Neo-Latin for potassium, and -emia means "condition of the blood."

Normal serum potassium is 3.5 to 5.5 mEq/L; however, plasma potassium is 0.5 mEq/L lower.[1] Normal plasma potassium levels are between 3.5 to 5.0 mEq/L;[2] at least 95% of the body's potassium is found inside cells, with the remainder in the blood. This concentration gradient is maintained principally by the Na+/K+ pump.

Contents

Signs and symptoms

Mild hypokalemia is often without symptoms, although it may cause a small elevation of blood pressure,[3] and can occasionally provoke cardiac arrhythmias. Moderate hypokalemia, with serum potassium concentrations of 2.5-3 mEq/L (Nl: 3.5-5.0 mEq/L), may cause muscular weakness, myalgia, and muscle cramps (owing to disturbed function of the skeletal muscles), and constipation (from disturbed function of smooth muscles). With more severe hypokalemia, flaccid paralysis and hyporeflexia may result. There are reports of rhabdomyolysis occurring with profound hypokalemia with serum potassium levels less than 2 mEq/L. Respiratory depression from severe impairment of skeletal muscle function is found in many patients.

Some electrocardiographic (ECG) findings associated with hypokalemia include flattened or inverted T waves, a U wave, ST depression and a wide PR interval. Due to prolonged repolarization of ventricular Purkinje fibers, a prominent U wave occurs, that is frequently superimposed upon the T wave and therefore produces the appearance of a prolonged QT interval.[4]

Causes

Hypokalemia can result from one or more of the following medical conditions:

Inadequate potassium intake

Gastrointestinal/integument loss

Urinary loss

Distribution away from ECF

Other/ungrouped

Pseudohypokalemia

Pathophysiology

Potassium is essential for many body functions, including muscle and nerve activity. The electrochemical gradient of potassium between the intracellular and extracellular space is essential for nerve function; in particular, potassium is needed to repolarize the cell membrane to a resting state after an action potential has passed. Decreased potassium levels in the extracellular space will cause hyperpolarization of the resting membrane potential. This hyperpolarization is caused by the effect of the altered potassium gradient on resting membrane potential as defined by the Goldman equation. As a result, a greater than normal stimulus is required for depolarization of the membrane in order to initiate an action potential.

In certain conditions, this will make cells less excitable. However, in the heart, it causes myocytes to become hyperexcitable. Lower membrane potentials in the atrium may cause arrhythmias because of more complete recovery from sodium-channel inactivation, making the triggering of an action potential more likely. In addition, the reduced extracellular potassium (paradoxically) inhibits the activity of the IKr potassium current[13] and delays ventricular repolarization. This delayed repolarization may promote reentrant arrhythmias.

Treatment

The most important treatment in severe hypokalemia is addressing the cause, such as improving the diet, treating diarrhea or stopping an offending medication. Patients without a significant source of potassium loss and who show no symptoms of hypokalemia may not require treatment.

Mild hypokalemia (>3.0 mEq/L) may be treated with oral potassium chloride supplements (Klor-Con, Sando-K, Slow-K). As this is often part of a poor nutritional intake, potassium-containing foods may be recommended, such as leafy green vegetables, tomatoes, citrus fruits, oranges or bananas.[14] Both dietary and pharmaceutical supplements are used for people taking diuretic medications (see Causes, above).

Severe hypokalemia (<3.0 mEq/L) may require intravenous (IV) supplementation. Typically, a saline solution is used, with 20-40 mEq KCl per liter over 3–4 hours. Giving IV potassium at faster rates (20-25 mEq/hr) may predispose to ventricular tachycardias and requires intensive monitoring. A generally safe rate is 10 mEq/hr. Even in severe hypokalemia, oral supplementation is preferred given its safety profile. Sustained release formulations should be avoided in acute settings.

Difficult or resistant cases of hypokalemia may be amenable to a potassium-sparing diuretic, such as amiloride, triamterene, or spironolactone or eplerenone. Concomittant hypomagnesiumemia will inhibit potassium replacement as magnesium is a cofactor for potassium uptake.[15]

When replacing potassium intravenously, infusion via a central line is encouraged to avoid the frequent occurrence of a burning sensation at the site of a peripheral IV, or the rare occurrence of damage to the vein. When peripheral infusions are necessary, the burning can be reduced by diluting the potassium in larger amounts of IV fluid, or mixing 3 ml of 1% lidocaine to each 10 meq of KCl per 50 ml of IV fluid. The practice of adding lidocaine, however, raises the likelihood of serious medical errors.[16]

In other animals

Cats can develop hypokalemia, which may be manifested by abnormal gait and an inability to keep the head elevated. Cats respond well to dietary supplementation of potassium chloride.[17] A feline form of hypokalemic periodic paralysis has been described in Burmese kittens, which appears to be related to an autosomal recessive mutation. Although these kittens are not hypokalemic between episodes, regular supplementation of [KCl] seems effective.[18]

See also

External links

USDA National Nutrient Database for Standard Reference, Release 20

References

  1. ^ "NIH Serum Potassium". http://www.ncbi.nlm.nih.gov/books/NBK307/. 
  2. ^ Kratz, A; Ferraro, M; Sluss, PM; Lewandrowski, KB; Ellender, Stacey M.; Peters, Christine C.; Kratz, Alexander; Ferraro, Maryjane et al. (2004). "Case records of the Massachusetts General Hospital. Weekly clinicopathological exercises. Laboratory reference values". The New England journal of medicine 351 (15): 1548–63. doi:10.1056/NEJMcpc049016. PMID 15470219. 
  3. ^ Krishna, GG; Miller, E; Kapoor, S (1989). "Increased blood pressure during potassium depletion in normotensive men". The New England journal of medicine 320 (18): 1177–82. doi:10.1056/NEJM198905043201804. PMID 2624617. 
  4. ^ Goldman, M.J. (1973). Principles of Clinical Electrocardiography 8th ed.. Los Altos, California: LANGE medical Publications. pp. 293. 
  5. ^ a b Halperin, ML; Kamel, KS (1998). "Potassium". Lancet 352 (9122): 135–40. doi:10.1016/S0140-6736(98)85044-7. PMID 9672294. 
  6. ^ Walmsley RN, White GH (August 1984). "Occult causes of hypokalaemia". Clin. Chem. 30 (8): 1406–8. PMID 6744598. 
  7. ^ Whyte KF, Addis GJ, Whitesmith R, Reid JL (April 1987). "Failure of chronic theophylline therapy to alter circulating catecholamines". Eur J Respir Dis 70 (4): 221–8. PMID 3582518. 
  8. ^ Tsimihodimos V, Kakaidi V, & Elisaf M. (June 2009). "Cola-induced hypokalaemia: pathophysiological mechanisms and clinical implications". International Journal of Clinical Practice 63 (6): 900–2. doi:10.1111/j.1742-1241.2009.02051.x. PMID 19490200. http://www3.interscience.wiley.com/journal/122384349/abstract. free full text
  9. ^ Shirley DG, Walter SJ, Noormohamed FH (November 2002). "Natriuretic effect of caffeine: assessment of segmental sodium reabsorption in humans". Clin. Sci. 103 (5): 461–6. doi:10.1042/CS20020055. PMID 12401118. 
  10. ^ Packer, C.D. (June 2009). "Cola-induced hypokalaemia: a super-sized problem". International Journal of Clinical Practice 63 (6): 833–5. doi:10.1111/j.1742-1241.2009.02066.x. PMID 19490191. http://www3.interscience.wiley.com/journal/122384352/abstract. 
  11. ^ Health.yahoo.com
  12. ^ Sodi R, Davison AS, Holmes E, Hine TJ, Roberts NB (June 2009). "The phenomenon of seasonal pseudohypokalemia: effects of ambient temperature, plasma glucose and role for sodium-potassium-exchanging-ATPase". Clin. Biochem. 42 (9): 813–8. doi:10.1016/j.clinbiochem.2009.01.024. PMID 19232334. 
  13. ^ Sanguinetti MC and Jurkiewicz NK. (1992) Role of external Ca2+ and K+ in gating of cardiac delayed rectifier K+ currents. Pflugers Arch., 420(2):180-6; PMID 1620577.
  14. ^ Umassmed.edu
  15. ^ "New Guidelines for Potassium Replacement in Clinical Practice". http://archinte.ama-assn.org/cgi/content/full/160/16/2429#SEC6. Retrieved 2011-02-16. 
  16. ^ "Safety Issues With Adding Lidocaine to IV Potassium Infustions (Excerpt)". http://www.ismp.org/newsletters/acutecare/articles/20040212_2.asp. Retrieved 2009-05-09. 
  17. ^ Feline Hypokalaemic Polymyopathy. in The Merck Veterinary Manual, 9th edition By Merck & Co. 2006. ISBN 0-911910-50-6
  18. ^ Gaschen F, Jaggy A, Jones B (December 2004). "Congenital diseases of feline muscle and neuromuscular junction". J. Feline Med. Surg. 6 (6): 355–66. doi:10.1016/j.jfms.2004.02.003. PMID 15546767.