Characterizing the clinical implementation of a novel activation-repolarization metric to identify targets for catheter ablation of ventricular tachycardias using computational models

Fernando O Campos,Michele Orini,Peter Taggart,Ben Hanson,Pier D Lambiase,Bradley Porter,Christopher Aldo Rinaldi,Jaswinder Gill,Martin J Bishop

doi:10.1016/j.compbiomed.2019.03.018

Abstract

Identification of targets for catheter ablation of ventricular tachycardias (VTs) remains a significant challenge. VTs are often driven by re-entrant circuits resulting from a complex interaction between the front (activation) and tail (repolarization) of the electrical wavefront. Most mapping techniques do not take into account the tissue repolarization which may hinder the detection of ablation targets. The re-entry vulnerability index (RVI), a recently proposed mapping procedure, incorporates both activation and repolarization times to uncover VT circuits. The method showed potential in a series of experiments, but it still requires further development to enable its incorporation into a clinical protocol. Here, in-silico experiments were conducted to thoroughly assess RVI maps constructed under clinically-relevant mapping conditions. Within idealized as well as anatomically realistic infarct models, we show that parameters of the algorithm such as the search radius can significantly alter the specificity and sensitivity of the RVI maps. When constructed on sparse grids obtained following various placements of clinical recording catheters, RVI maps can identify vulnerable regions as long as two electrodes were placed on both sides of the line of block. Moreover, maps computed during pacing without inducing VT can reveal areas of abnormal repolarization and slow conduction but not directly vulnerability. In conclusion, the RVI algorithm can detect re-entrant circuits during VT from low resolution mapping grids resembling the clinical setting. Furthermore, RVI maps may provide information about the underlying tissue electrophysiology to guide catheter ablation without the need of inducing potentially harmful VT during the clinical procedure. Finally, the ability of the RVI maps to identify vulnerable regions with specificity in high resolution computer models could potentially improve the prediction of optimal ablation targets of simulation-based strategies.

Highlights

Ventricular tachycardias (VTs) carry the greatest risk of sudden death in patients with ischemic heart disease [1]
Activation and repolarization sequences resulting from the premature S2 wavefront were used to construct re-entry vulnerability index (RVI) maps and assess their ability to locate scar-related re-entrant circuits. 3.1.1. 2D Idealized Model
Within an idealized 2D infarct model as well as in a realistic BiV model we showed that for small search radii, all interpolation methods can identify with high specificity and varying sensitivity the isthmus maintaining the ventricular tachycardias (VTs)

Summary

Introduction

Ventricular tachycardias (VTs) carry the greatest risk of sudden death in patients with ischemic heart disease [1]. Identification of the re-entrant entry/exit points often requires VT-induction to delineate isthmuses from activation mapping. Inducibility may be neither possible nor desired as it increases the risk of the procedure. In this case, voltage-mapping is performed to uncover abnormal substrates within the scar [3], regions of local abnormal ventricular activity [5, 6, 7], discrete slow conducting channels [8, 9, 10, 11], or areas with abnormal signal amplitude during either sinus or paced rhythm [4]. Repolarization, a key factor in the formation of a re-entrant circuit, is often neglected during mapping techniques hindering the identification of critical sites and increasing the risk of later recurrence of VT

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