Block of cardiac sodium channels by amiodarone studied by using Vmax of action potential in single ventricular myocytes.

Abstract

1. Acute effects of amiodarone on cardiac sodium channels were investigated in ventricular myocytes isolated from guinea-pig hearts, and compared with those of lignocaine. 2. Transmembrane potential was recorded and controlled by whole-cell current-clamp and voltage-clamp respectively through suction pipette electrodes. The maximum upstroke velocity (Vmax) of the action potential was used as a qualitative index of sodium channel availability. 3. In myocytes treated with amiodarone (1 microM) or lignocaine (40 microM), Vmax of reference action potential elicited at 0.03 Hz was decreased by 6-11%, indicating minimal tonic block of sodium channels. 4. Application of a single conditioning depolarization to those myocytes resulted in a significant decrease in Vmax of a subsequent test action potential. The Vmax reduction was enhanced in a single exponential function as the clamp pulse duration was prolonged. Time constants at 0 mV clamp were 25 ms for amiodarone and 122 ms for lignocaine. 5. Vmax recovery of test action potential following a 1000 ms 0 mV clamp was approximated by a dual exponential function. Time constants for the late slow component (tau R) at the resting potential level were 418 ms for amiodarone and 178 ms for lignocaine. tau R values were shortened in a voltage-dependent manner by hyperpolarization during the coupling interval. 6. These findings suggested that amiodarone, like lignocaine, blocks the sodium channel primarily when it is in the inactivated state. Both onset and offset kinetics of the block are very rapid. Such sodium channel blocking characteristics may contribute to its potent antiarrhythmic activity.