Nonlinear changes of transmembrane potential during defibrillation shocks: role of Ca(2+) current.

Defibrillation shocks induce complex nonlinear changes of transmembrane potential (DeltaV(m)). To elucidate the ionic mechanisms of nonlinear DeltaV(m), we studied the effects of ionic channel blockers on DeltaV(m) in geometrically defined myocyte cultures. Experiments were carried out in cell strands with widths of 0.2 mm (narrow strands) and 0.8 mm (wide strands) produced using a technique of directed cell growth. Uniform-field shocks were applied across strands during the action potential (AP) plateau, and the distribution of shock-induced DeltaV(m) was measured using an optical mapping technique. Nifedipine and 4-aminopyridine were applied to inhibit the L-type calcium current (I:(Ca)) and the transient outward current (I:(to)), respectively. In control conditions, the distribution of DeltaV(m) across cell strands was highly asymmetrical with a large ratio of negative to positive DeltaV(m) (DeltaV(-)(m)/DeltaV(+)(m)) measured at the opposite strand borders. Application of nifedipine caused a large increase of DeltaV(+)(m) and a decrease of DeltaV(-)(m)/DeltaV(+)(m), indicating involvement of I:(Ca) in the asymmetrical DeltaV(m), likely as a result of the outward flow of I:(Ca) when V(m) exceeded the I:(Ca) reversal potential. DeltaV(-)(m) decreased in the narrow strands but remained unchanged in the wide strands, indicating that the changes of DeltaV(-)(m) were caused by electrotonic interaction with an area of depolarization. 4-Aminopyridine did not change DeltaV(-)(m)/DeltaV(+)(m). These results provide evidence that (1) the asymmetry of shock-induced DeltaV(m) during the AP plateau is due to outward flow of I:(Ca) in the depolarized portions of the strands, (2) I:(to) is not involved in the mechanism of DeltaV(m) asymmetry, and (3) the effects of drugs on DeltaV(m) are modulated by the tissue geometry.