Abstract
Mechanisms of ventricular tachycardia induced by local application of a properly timed premature stimulus were studied with routine microelectrode technique and extracellular recordings on a ventricular sheet. Thinly sliced preparations obtained from subepicardial muscle of the canine ventricle were used as an approximation of a two-dimensional model. On these preparations, spontaneously sustained tachycardia easily induced by a single premature stimulus. Since delayed after-depolarizations were never evoked by frequent stimulations even in the K+-free and high-Ca++ media, these tachycardias seemed to be induced by re-entrant and circus movement mechanisms. To analyse the re-entrant mechanisms, action potentials generated by normal driving stimuli were recorded from multiple points (40 approximately 50 points) and the spreads of the depolarization and repolarization phases of the action potentials were mapped. The depolarizing wave front on the map always showed a circular or elliptical pattern. Whenever the pattern of spread of the repolarizing wave was similar to that of the depolarizing wave, sustained tachycardia was never brought about by any premature stimulus. On the other hand, when the map of the spread of the repolarizing wave was very complicated and mixed with that of the depolarizing wave, sustained tachycardia was frequently induced. From the above results, it is suggested that the nonuniform recovery of excitability plays a role in the generation of sustained tachycardia. Moreover, a portion of the unidirectional block of the premature impulse was determined by calculated using the conduction velocity of the premature impulse and the effective refractory period in each cell; then a route of re-entry for the premature impulse was simulated.(ABSTRACT TRUNCATED AT 250 WORDS)
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