STRETCH-INDUCED DEPOLARIZATIONS AS A TRIGGER OF ARRHYTHMIAS IN ISOLATED CANINE LEFT-VENTRICLES

Transient diastolic stretch of the left ventricle predictably elicits arrhythmias. To investigate the mechanism of such stretch-induced arrhythmias, monophasic action potentials were recorded from six blood-perfused isolated canine left ventricles with an epicardial contact electrode. Stretch-induced arrhythmias were elicited using a computerized servo-pump system that increased left ventricular volume for 250 ms during early diastole. Depolarizations that coincided with the onset of stretch were observed that always preceded the stretch-induced arrhythmia. As stretch volume (DELTA-V) increased from 10 to 30 ml, the amplitude of the stretch-induced depolarization increased progressively and the probability of eliciting an arrhythmia rose from 30 to 94%. To exclude motion artifact, additional recordings were made after the heart was depolarized by increasing the perfusate K+ concentration to 154 mM (K arrest). After K arrest, the stretch-induced depolarizations were reduced by 95% or more (P < 0.05) at all stretch volumes. Thus the change in monophasic action potential signal during transient diastolic stretch reflects actual depolarization of the myocardium with negligible motion artifact. When the stretch-activated channel blocker, Gd3+ (10-mu-M), was administered, which produces potent inhibition of stretch-induced arrhythmias in our model, the stretch-induced depolarizations were substantially reduced in magnitude. Our results show that as diastolic stretch increases, stretch-induced depolarizations become larger and reach threshold potential more often; consequently, the probability of eliciting a stretch-induced arrhythmia increases. This mechanism of arrhythmogenesis may be particularly important in patients with regionally or globally dilated left ventricles.