Alkalosis and digoxin effects on plasma potassium, ionic homeostasis and exercise performance in healthy humans
TL;DRAbstract
Muscle contractions induce cellular potassium (K+) efflux which may contribute to impaired muscle cell membrane excitability and fatigue. The magnitude of K+ changes are dependent on the size of contracting muscle mass, duration and intensity of exercise, and health and fitness status of participants. Activation of the sarcolemmal and t-tubular bound sodium-potassium adenosine 5’ triphosphatase enzyme (Na+,K+ATPase, NKA) mediates muscle cell K+ and Na+ active exchange, and is instrumental in the maintenance of muscle cellular and plasma K+ homeostasis during exercise. Therefore modulations of NKA function might enhance or impair exercise induced K+ disturbances, and theoretically can have a profound effect on muscle excitability and exercise performance. This thesis examined the effects of two interventions designed to induce acute or short term upregulation and downregulation of NKA activity on K+ homeostasis and exercise performance in healthy humans. Study 1 investigated the effects
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Muscle contractions induce cellular potassium (K+) efflux which may contribute to impaired muscle cell membrane excitability and fatigue. The magnitude of K+ changes are dependent on the size of contracting muscle mass, duration and intensity of exercise, and health and fitness status of participants. Activation of the sarcolemmal and t-tubular bound sodium-potassium adenosine 5’ triphosphatase enzyme (Na+,K+ATPase, NKA) mediates muscle cell K+ and Na+ active exchange, and is instrumental in the maintenance of muscle cellular and plasma K+ homeostasis during exercise. Therefore modulations of NKA function might enhance or impair exercise induced K+ disturbances, and theoretically can have a profound effect on muscle excitability and exercise performance. This thesis examined the effects of two interventions designed to induce acute or short term upregulation and downregulation of NKA activity on K+ homeostasis and exercise performance in healthy humans. Study 1 investigated the effects
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