The entrainment of action potential duration and contraction amplitude by recapitulation of respiratory sinus arrhythmia in isolated cardiac myocytes

Respiratory sinus arrhythmia (RSA) is the oscillation of heart rate in phase with ventilation and represents the high frequency component of heart rate variability. RSA is prevalent in the young and the endurance-trained and its loss is considered a prognostic indicator for sudden cardiac death. The recapitulation of RSA improves cardiac function in animal models of heart failure1,2. However, the precise mechanisms by which RSA affects cardiac function are unknown.

Hypothesis: We examined the hypothesis that the recapitulation of RSA in isolated ventricular myocytes affects the stimulus interval-dependence of action potential duration (APD) and sarcomere shortening through mechanisms involving sarcoplasmic reticulum (SR) Ca2+ release.

Hearts were excised from adult male guinea pigs under general anaesthesia (140 mg/kg bodyweight euthatal, i.p.) and left ventricular myocytes isolated. Isolated myocytes were superfused with Tyrode’s solution for perforated patch whole-cell current clamp recording and action potentials and sarcomere length measured simultaneously. Sample sizes are presented as n/N (cell/animal number) and nested hierarchical analysis applied using a generalized linear mixed model (P<0.05).

Pacing at a basic cycle length (CL, 350 ms) induced APD, Ca2+ transient amplitude (CaT) and sarcomere shortening alternans. The recapitulation of RSA through oscillatory pacing (OP), in which CL was set to 20% below and 20% above the corresponding basic CL in a 2-short, 2-long stimulus train, reduced the incidence of alternans. Furthermore, OP entrained APD, CaT and sarcomere shortening and this entrainment persisted in voltage clamp experiments with fixed APD. Using a three-step protocol to examine the dependence of APD and sarcomere shortening on both preceding (CLn-1) and anteceding (CLn-2) stimulus intervals, both APD and sarcomere shortening were found to depend directly on the preceding cycle length (CLn-1, P<0.001). In contrast, sarcomere shortening depended inversely on the anteceding CL (CLn-2, P<0.001; n/N = 24/4). Following treatment of the cells with caffeine (50 µM) to sensitise ryanodine receptors, the dependence of APD and sarcomere shortening on CLn-1 was markedly suppressed, and the inverse dependence of sarcomere shortening on CLn-2 was lost (P<0.001, n/N = 6/3). The effects of OP are akin to post-extrasystolic potentiation3 and mathematical simulation4 supports the involvement of changes in the sarcoplasmic reticulum Ca2+ content.

These data are consistent with an obligatory role for the SR in the entrainment of APD, CaT and sarcomere shortening and the suppression of alternans by the recapitulation of RSA. We hypothesise that recapitulation of RSA would be protective against ventricular tachyarrhythmia and further work is required to test this.