Heart rate changes and myocardial sodium.

Historic studies with sodium ion (Na ) micropipettes and first-generation fluorescent probes suggested that an increase in heart rate results in higher intracellular Na -levels. Using a dual fluorescence indicator approach, we simultaneously assessed the dynamic changes in intracellular Na and calcium (Ca ) with measures of force development in isolated excitable myocardial strip preparations from rat and human left ventricular myocardium at different stimulation rates and modeled the Na -effects on the sodium-calcium exchanger (NCX). To gain further insight into the effects of heart rate on intracellular Na -regulation and sodium/potassium ATPase (NKA) function, Na , and potassium ion (K ) levels were assessed in the coronary effluent (CE) of paced human subjects. Increasing the stimulation rate from 60/min to 180/min led to a transient Na -peak followed by a lower Na -level, whereas the return to 60/min had the opposite effect leading to a transient Na -trough followed by a higher Na -level. The presence of the Na -peak and trough suggests a delayed regulation of NKA activity in response to changes in heart rate. This was clinically confirmed in the pacing study where CE-K levels were raised above steady-state levels with rapid pacing and reduced after pacing cessation. Despite an initial Na peak that is due to a delayed increase in NKA activity, an increase in heart rate was associated with lower, and not higher, Na -levels in the myocardium. The dynamic changes in Na unveil the adaptive role of NKA to maintain Na and K -gradients that preserve membrane potential and cellular Ca -hemostasis.