| pubmed-article:9160874 | pubmed:abstractText | This study demonstrates the inverse relationship between extracellular free calcium ([Ca(o)]f) and intracellular sodium ([Na(i)]) in isolated perfused rat hearts and thus supports the role of [Na(i)] in the "calcium paradox". It also shows that the extent of the increase in [Na(i)] (delta[Na(i)]), and the extent of the decrease in left ventricular developed pressure (deltaLVDP) in isolated perfused rat hearts, induced by pacing, is modulated by [Ca(o)]f. At low (0.24 mM) as well as normal (1.15 mM) [Ca(o)]f, [Na(i)] increased with pacing, progressively and significantly (P<0.01 and P<0.05, respectively), reaching a maximum of 12.56 +/- 0.46 and 9.22 +/- 0.16 mM at 500 beats/min, respectively. At high [Ca(o)]f (2.2 mM), however, no pacing-induced increase in [Na(i)] was observed. Simultaneously, within the pacing range of 250-500 beats/min, the interval-force relationship was negative for all [Ca(o)]f. With decreasing [Ca(o)]f, a gradually increasing delta[Na(i)] was induced. We hypothesise that a [Ca(o)]f-dependent Na-Ca exchanger activity modulates Na+ uptake, and thus baseline [Na(i)]. During incremental pacing, the increase in pacing rate induces a [Ca(o)]f-dependent delta[Na(i)], which may interact further with the sarcolemmal Na-Ca exchanger activity. As a result, both baseline [Na(i)] and the pacing-induced, [Ca(o)]f-dependent delta[Na(i)] modulate the net Ca2+ uptake, and thus SR Ca, in a manner that results in a modulated left ventricular force development. | lld:pubmed |
