Conduction between isolated rabbit Purkinje and ventricular myocytes coupled by a variable resistance.

Conduction at the Purkinje-ventricular junction (PVJ) demonstrates unidirectional block under both physiological and pathophysiological conditions. Although this block is typically attributed to multidimensional electrotonic interactions, we examined possible membrane-level contributions using single, isolated rabbit Purkinje (P) and ventricular (V) myocytes coupled by an electronic circuit. When we varied the junctional resistance ( R j) between paired V myocytes, conduction block occurred at lower R j values during conduction from the smaller to larger myocyte (115 ± 59 MΩ) than from the larger to smaller myocyte (201 ± 51 MΩ). In Purkinje-ventricular myocyte pairs, however, block occurred at lower R j values during P-to-V conduction (85 ± 39 MΩ) than during V-to-P conduction (912 ± 175 MΩ), although there was little difference in the mean cell size. Companion computer simulations, performed to examine how the early plateau currents affected conduction, showed that P-to-V block occurred at lower R j values when the transient outward current was increased or the calcium current was decreased in the model P cell. These results suggest that intrinsic differences in phase 1 repolarization can contribute to unidirectional block at the PVJ.

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