Role of localized repolarization and conduction heterogeneities in ventricular arrhythmias and sudden cardiac death

Abstract

Recent clinical studies have indicated the presence of localized tissue abnormalities in sudden cardiac death (SCD) survivors without apparent structural heart disease, including idiopathic ventricular fibrillation (VF) and J-wave Syndromes. The origin of these abnormalities, showing distinct electrical features on contact mapping, and mechanisms of associated arrhythmias are still a matter of debate. To determine the respective role of localized repolarization and conduction heterogeneities in vulnerability to arrhythmias and SCD, and to characterize their specific electrical signatures. Optical mapping was performed on porcine right ventricular models of either local (i) repolarization shortening, (ii) conduction slowing, or (iii) micro-structural heterogeneity which were created by locally perfusing (i) pinacidil (20 μM n = 13) or (ii) flecainide (2 μM n = 13) via an epicardial catheter (branch of right coronary artery), or (iii) by local epicardial tissue destruction through radiofrequency application (9 micro lesions 30W 1 sec n = 13). Pseudo-ECG were assessed and the number of induced and spontaneous arrhythmias were quantified and mapped in each preparation. An HD grid mapping catheter was used to record bipolar electrograms (n = 5 in each group). Electrograms were normal in model (i), but showed local fragmentation in 40% of preparations in model (ii) with greater effects observed at high pacing frequencies (3 Hz). In model (iii), the structural substrate alone increased the width and number of peaks in the electrograms, and addition of flecainide (2 μM) in this model induced pronounced fragmentation (≥ 3 peaks and ≥ 70ms duration) in 100% of the cases. Arrhythmogenicity was significantly increased in models (i) and (ii) which presented 82% and 45% more spontaneous arrhythmias (P < 0.0001 and 0.05 vs. baseline) and a reduced pacing frequency threshold to induce arrhythmias (−69% and −50%, P < 0.001 vs. baseline). In these models, the frequency of spontaneous activity was increased (+411% P < 0.01 and +181% P < 0.05 vs. baseline) and originated near the heterogeneous area. Microstructural substrates have the most pronounced impact on electrograms, especially when combined with sodium channel blockers, while repolarization heterogeneities do not lead to electrogram fragmentation but are associated with the highest prevalence of spontaneous arrhythmias. Both heterogeneities show increased ectopic activity.