Abstract
PURPOSE: Selective inhibition of atrial proarrhythmicity can be therapeutic for reducing the atrial fibrillation (AF) burden. Atrial-selective K(+)-channel blockade (mainly Kv1.5 and Kv4.3 channels conducting the sustained I(Kur) and transient I(to) outward currents) promises to suppress AF with a favorable benefit-to-harm ratio. The mechanisms underlying the efficacy of K(+) channel blockade under arrhythmic conditions and its association with electrophysiological and contractile remodeling in AF remain to be investigated. METHODS: Using our electromechanically coupled model MBS2023, we have simulated the effects of 4-aminopyridine (4-AP) and AVE0118 at different basic cycle lengths (2-0.25s). We have dissociated the primary and secondary responses to determine the drug's underlying mechanisms of action. We have analyzed the effects of K(+)-channel blockers under arrhythmogenic conditions induced by either forward excitation-contraction coupling (ECC) or mechano-calcium feedback. RESULTS: At the basal rate, the voltage-mediated increase in I(Kr) induced by 4-AP shortens the action potential duration (APD) under sinus rhythm (SR), whereas a surge in I(CaL) prolongs APD under AF. 4-AP can exacerbate the vulnerability to phase 2 early afterdepolarizations (EADs) by slowing repolarization and prolonging myofilament activation. K(+)-channel blockade can decimate the susceptibility of delayed afterdepolarizations (DADs) by eliminating the cytosolic Ca(2+) overload. The slowing of repolarization induced by 4-AP can suppress the reopening of Na(+) channels during phase 3 EADs. CONCLUSION: In both types of EAD, a shorter, Ca(2+)-desensitized sarcomere can reduce the propensity for AF in the model. In general, K(+) channel blockade has anti-arrhythmic potential to suppress phase 3 EADs by slowing repolarization.