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Potassium in biology

Potassium is the main intracellular ion for all types of cells, while having a major role in maintenance of fluid and electrolyte balance.[1][2] Potassium is necessary for the function of all living cells, and is thus present in all plant and animal tissues. It is found in especially high concentrations within plant cells, and in a mixed diet, it is most highly concentrated in fruits. The high concentration of potassium in plants, associated with comparatively very low amounts of sodium there, historically resulted in potassium first being isolated from the ashes of plants (potash), which in turn gave the element its modern name. The high concentration of potassium in plants means that heavy crop production rapidly depletes soils of potassium, and agricultural fertilizers consume 93% of the potassium chemical production of the modern world economy.

The functions of potassium and sodium in living organisms are quite different. Animals, in particular, employ sodium and potassium differentially to generate electrical potentials in animal cells, especially in nervous tissue. Potassium depletion in animals, including humans, results in various neurological dysfunctions. Characteristic concentrations of potassium in model organisms are: 30–300mM in E. coli, 300mM in budding yeast, 100mM in mammalian cell and 4mM in blood plasma.[3]

Function in animals[edit]

Potassium is the major cation (K+, a positive ion) inside animal cells, while sodium (Na+) is the major cation outside animal cells. The difference between the concentrations of these charged particles causes a difference in electric potential between the inside and outside of cells, known as the membrane potential. The balance between potassium and sodium is maintained by ion transporters in the cell membrane. All potassium ion channels are tetramers with several conserved secondary structural elements. A number of potassium channel structures have been solved including voltage gated,[6][7][8] ligand gated,[9][10][11][12][13] tandem-pore,[14][15][16] and inwardly rectifying channels,[17][18][19][20][21] from prokaryotes and eukaryotes. The cell membrane potential created by potassium and sodium ions allows the cell to generate an action potential—a "spike" of electrical discharge. The ability of cells to produce electrical discharge is critical for body functions such as neurotransmission, muscle contraction, and heart function.[22]

beans (white beans and others)

dark leafy greens (spinach, Swiss chard, and others)

potatoes

dried fruit (apricots, peaches, prunes, raisins; figs and dates)

squash

yogurt

fish (salmon)

avocado

nuts (pistachios, almonds, walnuts, etc.)

seeds (squash, pumpkin, sunflower)

Eating a variety of foods that contain potassium is the best way to get an adequate amount. Foods with high sources of potassium include kiwifruit, orange juice, potatoes, coconut, avocados, apricots, parsnips and turnips, although many other fruits, vegetables, legumes, and meats contain potassium.


Common foods very high in potassium:[34]


Foods containing the highest concentration:[34]

Deficiency[edit]

High blood pressure/Hypertension[edit]

Diets low in potassium increase risk of hypertension, stroke and cardiovascular disease.[36][37]

Hypokalemia[edit]

A severe shortage of potassium in body fluids may cause a potentially fatal condition known as hypokalemia. Hypokalemia typically results from loss of potassium through diarrhea, diuresis, or vomiting. Symptoms are related to alterations in membrane potential and cellular metabolism. Symptoms include muscle weakness and cramps, paralytic ileus, ECG abnormalities, intestinal paralysis, decreased reflex response and (in severe cases) respiratory paralysis, alkalosis and arrhythmia.


In rare cases, habitual consumption of large amounts of black licorice has resulted in hypokalemia. Licorice contains a compound (Glycyrrhizin) that increases urinary excretion of potassium.[38]

Insufficient intake[edit]

Adult women in the United States consume on average half the AI, for men two-thirds. For all adults, fewer than 5% exceed the AI.[39] Similarly, in the European Union, insufficient potassium intake is widespread.[40]

Side effects and toxicity[edit]

Gastrointestinal symptoms are the most common side effects of potassium supplements, including nausea, vomiting, abdominal discomfort, and diarrhea. Taking potassium with meals or taking a microencapsulated form of potassium may reduce gastrointestinal side effects.


Hyperkalemia is the most serious adverse reaction to potassium. Hyperkalemia occurs when potassium builds up faster than the kidneys can remove it. It is most common in individuals with renal failure. Symptoms of hyperkalemia may include tingling of the hands and feet, muscular weakness, and temporary paralysis. The most serious complication of hyperkalemia is the development of an abnormal heart rhythm (arrhythmia), which can lead to cardiac arrest.


Although hyperkalemia is rare in healthy individuals, oral doses greater than 18 grams taken at one time in individuals not accustomed to high intakes can lead to hyperkalemia.

Biology and pharmacology of chemical elements

 – Neuron communication by electric impulses

Action potential

 – Use of calcium by organisms

Calcium in biology

 – Ionic solids whose dissociation in water frees up ions carrying the electrical current in solution

Electrolyte

 – Use of Iodine by organisms

Iodine in biology

 – Use of Magnesium by organisms

Magnesium in biology

 – Type of physical quantity

Membrane potential

 – Use of Selenium by organisms

Selenium in biology

 – Use of Sodium by organisms

Sodium in biology

. NIH Office of Dietary Supplements. 3 April 2020.

"Potassium Health Professional Fact Sheet"

Brooks/Cole publishers – Sodium Potassium pump

Oregon State University – Micronutrient Information Center

Potassium at

Lab Tests Online

- the Association for Clinical Biochemistry and Laboratory Medicine.

Potassium: analyte monograph