Assessing the ability of substrate mapping techniques to guide ventricular tachycardia ablation using computational modelling

Fernando O Campos,Michele Orini,Robert Arnold,John Whitaker,Mark O'Neill,Reza Razavi,Gernot Plank,Ben Hanson,Bradley Porter,Christopher Aldo Rinaldi,Jaswinder Gill,Pier D Lambiase,Peter Taggart,Martin J Bishop

doi:10.1016/j.compbiomed.2021.104214

Abstract

BackgroundIdentification of targets for ablation of post-infarction ventricular tachycardias (VTs) remains challenging, often requiring arrhythmia induction to delineate the reentrant circuit. This carries a risk for the patient and may not be feasible. Substrate mapping has emerged as a safer strategy to uncover arrhythmogenic regions. However, VT recurrence remains common. GoalTo use computer simulations to assess the ability of different substrate mapping approaches to identify VT exit sites. MethodsA 3D computational model of the porcine post-infarction heart was constructed to simulate VT and paced rhythm. Electroanatomical maps were constructed based on endocardial electrogram features and the reentry vulnerability index (RVI - a metric combining activation (AT) and repolarization timings to identify tissue susceptibility to reentry). Since scar transmurality in our model was not homogeneous, parameters derived from all signals (including dense scar regions) were used in the analysis. Potential ablation targets obtained from each electroanatomical map during pacing were compared to the exit site detected during VT mapping. ResultsSimulation data showed that voltage cut-offs applied to bipolar electrograms could delineate the scar, but not the VT circuit. Electrogram fractionation had the highest correlation with scar transmurality. The RVI identified regions closest to VT exit site but was outperformed by AT gradients combined with voltage cut-offs. The performance of all metrics was affected by pacing location. ConclusionsSubstrate mapping could provide information about the infarct, but the directional dependency on activation should be considered. Activation-repolarization metrics have utility in safely identifying VT targets, even with non-transmural scars.

Highlights

Recurrent ventricular tachycardias (VTs) are associated with an increased risk of sudden death in patients with ischemic heart disease (IHD) [1,2]
VTs are often associated with circulating electrical wavefronts that are known to be formed at the so-called infarct border zone (BZ)
In-vivo magnetic resonance imaging (MRI) data The geometrical model of the porcine heart was built based on lategadolinium enhanced cardiovascular MRI with an isotropic voxel reso lution of 1 mm obtained seven weeks following myocardial infarction [22]

Summary

Introduction

Recurrent ventricular tachycardias (VTs) are associated with an increased risk of sudden death in patients with ischemic heart disease (IHD) [1,2]. Efficacy of VT ablation in IHD relies on the ability of current mapping systems to identify such isthmuses and deliver adequate lesion sets to the critical arrhythmogenic sites [8]. Identification of targets for ablation of post-infarction ventricular tachycardias (VTs) remains challenging, often requiring arrhythmia induction to delineate the reentrant circuit. This carries a risk for the patient and may not be feasible. Goal: To use computer simulations to assess the ability of different substrate mapping approaches to identify VT exit sites. Activation-repolarization metrics have utility in safely identifying VT targets, even with non-transmural scars

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Conclusion