D J Huelsing1, A E Pollard, K W Spitzer. 1. Cardiac Rhythm Management Lab and Department of Biomedical Engineering, University of Alabama-Birmingham, Volker Hall B140, 1670 University Blvd., Birmingham, AL 35294, USA. djh@crml.uab.edu
Abstract
OBJECTIVE: While several studies have demonstrated that the L-type calcium current maintains discontinuous conduction, the contribution of the transient outward current (I(to)) to conduction remains unclear. This study evaluated the effects of I(to) inhibition on conduction between ventricular myocytes. METHODS: An electronic circuit with a variable resistance (R(j)) was used to electrically couple single epicardial myocytes isolated from rabbit right ventricle. We inhibited I(to) with 4-aminopyridine superfusion, rate-acceleration, or premature stimulation to evaluate the subsequent effects on conduction delay and the critical R(j), which was quantified as the highest R(j) that could be imposed before conduction failed. RESULTS: I(to) inhibition significantly enhanced conduction in all cell pairs (n=23). Pharmacologic inhibition of I(to) resulted in a 32+/-5% decrease in conduction delay and a 36+/-7% increase in critical R(j). Similarly, reduction of the basic cycle length from 2 to 0.5 s resulted in a 31+/-3% decrease in conduction delay and a 31+/-3% increase in critical R(j). Finally, premature action potentials conducted with a 41+/-4% shorter conduction delay and a 73+/-24% higher critical R(j) than basic action potentials. CONCLUSIONS: I(to) inhibition significantly enhanced conduction across high R(j). These results suggest I(to) may contribute to rate-dependent conduction abnormalities.
OBJECTIVE: While several studies have demonstrated that the L-type calcium current maintains discontinuous conduction, the contribution of the transient outward current (I(to)) to conduction remains unclear. This study evaluated the effects of I(to) inhibition on conduction between ventricular myocytes. METHODS: An electronic circuit with a variable resistance (R(j)) was used to electrically couple single epicardial myocytes isolated from rabbit right ventricle. We inhibited I(to) with 4-aminopyridine superfusion, rate-acceleration, or premature stimulation to evaluate the subsequent effects on conduction delay and the critical R(j), which was quantified as the highest R(j) that could be imposed before conduction failed. RESULTS: I(to) inhibition significantly enhanced conduction in all cell pairs (n=23). Pharmacologic inhibition of I(to) resulted in a 32+/-5% decrease in conduction delay and a 36+/-7% increase in critical R(j). Similarly, reduction of the basic cycle length from 2 to 0.5 s resulted in a 31+/-3% decrease in conduction delay and a 31+/-3% increase in critical R(j). Finally, premature action potentials conducted with a 41+/-4% shorter conduction delay and a 73+/-24% higher critical R(j) than basic action potentials. CONCLUSIONS: I(to) inhibition significantly enhanced conduction across high R(j). These results suggest I(to) may contribute to rate-dependent conduction abnormalities.
Authors: Keith F Decker; Jordi Heijman; Jonathan R Silva; Thomas J Hund; Yoram Rudy Journal: Am J Physiol Heart Circ Physiol Date: 2009-01-23 Impact factor: 4.733
Authors: Arie O Verkerk; Ronald Wilders; Jan G Zegers; Marcel M G J van Borren; Jan H Ravesloot; E Etienne Verheijck Journal: J Physiol Date: 2002-04-01 Impact factor: 5.182