P321Subthreshold delayed afterdepolarizations form a substrate for conduction block in the infarcted heart

Abstract

Abstract Funding Acknowledgements National Institute for Health Research; British Heart Foundation; and The Wellcome Trust and Engineering and Physical Sciences Research Council. Background Delayed afterdepolarizations (DADs) due to spontaneous calcium (Ca) release (SCR) events from the sarcoplasmic reticulum have been implicated with a variety of arrhythmias. Such SCR events have also been reported in cells that survive in the infarct border zone (BZ). While the potential of Ca-mediated DADs to become suprathreshold and propagate in the form of ectopic beats has been well characterized, the role of subthreshold DADs in arrhythmia formation in the infarcted heart remains to be elucidated. Purpose To use computational modelling to investigate whether subthreshold Ca-mediated DADs may form a substrate for conduction block and reentry in the BZ. Our hypothesis is that subthreshold DADs can hinder local tissue excitability in critical infarct BZ regions by inactivating the fast sodium current (INa), leading to temporary unidirectional conduction block providing a trigger for arrhythmogenesis. Methods We developed an idealized infarct model of the left ventricle. The infarct region consisted of a non-conducting scar transcended by an isthmus of cells that survived myocardial infarction (border zone). These cells were made prone to Ca-mediated DADs described by a phenomenological model of SCR events. The model was pre-paced at the apex followed by a 1500ms-pacing pause to see whether DADs would emerge. An extra beat with a longer coupling interval (CI) was then applied. The following electrophysiological changes resulting from remodeling processes in the isthmus were simulated to assess their contribution to the arrhythmogenic potential of subthreshold DADs: INa loss-of-function due to a (2.5mV and 5mV) negative-shift in the steady-state channel inactivation; 50% reduction in tissue conductivity; and increased levels of fibrosis (up to 50%). Results On average, Ca-mediated DADs reached their maximum value 1065ms after the last paced beat (Fig. A). Despite this, in the default electrophysiological setup, simulations with extra beats with 1000ms > CI > 1100ms did not result in conduction block in any of the experiments. When repeated with combined changes of reduced tissue conductivity and fibrosis, subthreshold DADs were still unable to create a substrate for block. However, when combined with a 5mV-shift in INa inactivation, block at isthmus’ mouth proximal to the stimulus site was detected for extra beats 1010 ms ≥ CI ≥ 1070ms (see Fig. B). The cause of block was due to a subthreshold DAD occurring just prior to the arrival of the extra beat. All blocked beats degenerated into reentry. Conclusions Under most physiological conditions, subthreshold DADs are unlikely to provide a substrate for unidirectional block. However, under conditions of decreased excitability, subthreshold DADs can hinder tissue excitability in the infarcted region leading to conduction block and reentry. Abstract Figure. DAD-mediated conduction block in the BZ