Role of apamin-sensitive small conductance calcium-activated potassium currents in long-term cardiac memory in rabbits

Abstract

Background: Apamin-sensitive small conductance calcium-activated K current (I_KAS) is up-regulated during ventricular pacing and masks short-term cardiac memory (CM).

Objective: The purpose of this study was to determine the role of I_KAS in long-term CM.

Methods: CM was created with 3-5 weeks of ventricular pacing and defined by a flat or inverted T wave off pacing. Epicardial optical mapping was performed in both paced and normal ventricles. Action potential duration (APD₈₀) was determined during right atrial pacing. Ventricular stability was tested before and after I_KAS blockade. Four paced hearts and 4 normal hearts were used for western blotting and histology.

Results: There were no significant differences in either echocardiographic parameters or fibrosis levels between groups. Apamin induced more APD₈₀ prolongation in CM than in normal ventricles (mean [95% confidence interval]: 9.6% [8.8%-10.5%] vs 3.1% [1.9%-4.3%]; P <.001). Apamin significantly lengthened APD₈₀ in the CM model at late activation sites, indicating significant I_KAS up-regulation at those sites. The CM model also had altered Ca²⁺ handling, with the 50% Ca²⁺ transient duration and amplitude increased at distal sites compared to a proximal site (near the pacing site). After apamin, the CM model had increased ventricular fibrillation (VF) inducibility (paced vs control: 33/40 (82.5%) vs 7/20 (35%); P <.001) and longer VF durations (124 vs 26 seconds; P <.001).

Conclusion: Chronic ventricular pacing increases Ca²⁺ transients at late activation sites, which activates I_KAS to maintain repolarization reserve. I_KAS blockade increases VF vulnerability in chronically paced rabbit ventricles.

Keywords: Cardiac memory; Electrophysiology; Ion channel; Ventricular fibrillation.