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==What is Potassium?==
 
==What is Potassium?==
Potassium is the '''eighth most abundant element in the body and is the second most abundant cation''' (positive ion) after [[Calcium - Nutrition|calcium]]. It is found in greatest amounts in intracellular fluid – about 90% of the body’s potassium is present here and it accounts for about 75% of the cations within the body cells. Smaller quantities are found in bone, plasma, interstitial fluid and connective tissue. It is a very strong reducing metal and therefore not found in its free state in nature but [[Potassium - Nutrition#Dietary Sources|combined with other elements to form salts]].
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Potassium is the '''eighth most abundant element in the body and is the second most abundant cation''' (positive ion) after [[Calcium - Nutrition|calcium]]. It is found in greatest amounts in intracellular fluid – about 90% of the body’s potassium is present here and it accounts for about 75% of the cations within the body cells. Smaller quantities are found in [[Bones - Anatomy & Physiology|bone]], [[plasma]], interstitial fluid and connective tissue. It is a very strong reducing metal and therefore not found in its free state in nature but [[Potassium - Nutrition#Dietary Sources|combined with other elements to form salts]].
    
==Why is it Important?==
 
==Why is it Important?==
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==Roles in the Body==
 
==Roles in the Body==
'''Potassium within cells interacts with sodium outside cells to form a concentration gradient that maintains acid-base balance and facilitates electrical and chemical activity'''. This accounts for its importance in nerve impulses and muscle contraction and its role in normal cardiac function. It is also involved in protein synthesis and the uptake of amino acids. The trans-cellular potassium-sodium gradient is actively maintained by an energy-dependent system that drives cellular pumps responsible for the transport of potassium and sodium ions.
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'''Potassium within cells interacts with [[Sodium - Nutrition|sodium]] outside cells to form a concentration gradient that maintains acid-base balance and facilitates electrical and chemical activity'''. This accounts for its importance in nerve impulses and muscle contraction and its role in normal cardiac function. It is also involved in protein synthesis and the uptake of amino acids. The trans-cellular potassium-sodium gradient is actively maintained by an energy-dependent system that drives cellular pumps responsible for the transport of potassium and sodium ions.
    
==Consequences of Dietary Potassium Deficiency==
 
==Consequences of Dietary Potassium Deficiency==
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====Recognised Syndromes Related to Potassium Deficiency====
 
====Recognised Syndromes Related to Potassium Deficiency====
 
#'''Paralysis and poor growth''': Puppies fed a very low level of potassium (0.01% on a dry matter basis – DM) grew very poorly and within a few weeks developed clinical signs including paralysis of the neck muscles and of the rear legs<ref>Ruegamer, W, Elvehjem, Hart, E (1946). “Potassium deficiency in the dog”. Proc. Soc. Exp. Biol. Med. 61:234-238.</ref>. Increasing the dietary potassium to 0.34% DM ameliorated the adverse effects.   
 
#'''Paralysis and poor growth''': Puppies fed a very low level of potassium (0.01% on a dry matter basis – DM) grew very poorly and within a few weeks developed clinical signs including paralysis of the neck muscles and of the rear legs<ref>Ruegamer, W, Elvehjem, Hart, E (1946). “Potassium deficiency in the dog”. Proc. Soc. Exp. Biol. Med. 61:234-238.</ref>. Increasing the dietary potassium to 0.34% DM ameliorated the adverse effects.   
#'''Hypokalaemia''': Feeding adult bitches a diet containing 0.006% DM potassium did not result in detectable hypokalaemia nor were clinical signs associated with hypokalaemia seen; however, there were decreases in blood pressure, cardiac output, stroke volume and renal blood flow. A dietary potassium of 0.45% DM resulted in no detected abnormality<ref>Abbrecht, P (1972). “Cardiovascular effects of chronic potassium deficiency in the dog”. Am. J. Physiol. 223:555-560.</ref>.
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#'''[[Hypokalaemia]]''': Feeding adult bitches a diet containing 0.006% DM potassium did not result in detectable hypokalaemia nor were clinical signs associated with hypokalaemia seen; however, there were decreases in blood pressure, cardiac output, stroke volume and renal blood flow. A dietary potassium of 0.45% DM resulted in no detected abnormality<ref>Abbrecht, P (1972). “Cardiovascular effects of chronic potassium deficiency in the dog”. Am. J. Physiol. 223:555-560.</ref>.
    
===Cat:===   
 
===Cat:===   
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==Toxicity==
 
==Toxicity==
There is virtually no information on the adverse effects of excessive dietary potassium intake in dogs or cats. As potassium absorption in the intestines is very high (>90%), it would be feasible to see life-threatening hyperkalaemia if excessive amounts of potassium were found in the diet. However, the amount of potassium (in the forms of salts) required to cause toxicity would result in diets that would not be readily consumed by dogs or cats. Additionally, animals with normal kidney function should readily excrete unnecessary potassium. If potassium acts on dogs and cats in a similar way to other non-ruminant mammals, the main symptoms would be increased water intake and urine volume, food aversion and gastroenteritis. Nevertheless it would require intakes many times the recommended level to produce these effects. A tolerable dietary content of at least 1% DM is suggested for non-ruminants including dogs and cats<ref>“Potassium” In: Mineral Tolerance of Animals, 2nd Edition. (2005) National Research Council, National Academy of Sciences. The National Academies Press, Washington DC p 311.</ref>.  
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There is virtually no information on the adverse effects of excessive dietary potassium intake in dogs or cats. As potassium absorption in the [[Small Intestine Overview - Anatomy & Physiology|intestines]] is very high (>90%), it would be feasible to see life-threatening hyperkalaemia if excessive amounts of potassium were found in the diet. However, the amount of potassium (in the forms of salts) required to cause toxicity would result in diets that would not be readily consumed by dogs or cats. Additionally, animals with normal [[Renal Anatomy - Anatomy & Physiology|kidney]] function should readily excrete unnecessary potassium. If potassium acts on dogs and cats in a similar way to other non-ruminant mammals, the main symptoms would be increased water intake and urine volume, food aversion and gastroenteritis. Nevertheless it would require intakes many times the recommended level to produce these effects. A tolerable dietary content of at least 1% DM is suggested for non-ruminants including dogs and cats<ref>“Potassium” In: Mineral Tolerance of Animals, 2nd Edition. (2005) National Research Council, National Academy of Sciences. The National Academies Press, Washington DC p 311.</ref>.  
    
==Dietary Sources==
 
==Dietary Sources==
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[[Category:To Do - Nutrition]]
 
[[Category:To Do - Nutrition]]
[[Category:To Do - Nutrition GGP]]
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[[Category:To Do - Nutrition preMars]]

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