Understanding Repolarization in the Intracardiac Unipolar Electrogram: A Long-lasting Controversy Revisited

Overview

Journal Front Physiol

Date 2023 Apr 24

PMID 37089414

Authors

Job Stoks

Laura R Bear

Johan Vijgen

Paul Dendale

Ralf Peeters

Paul G A Volders

Matthijs J M Cluitmans

Affiliations

Soon will be listed here.

Abstract

The optimal way to determine repolarization time (RT) from the intracardiac unipolar electrogram (UEG) has been a topic of debate for decades. RT is typically determined by either the Wyatt method or the "alternative method," which both consider UEG T-wave slope, but differently. To determine the optimal method to measure RT on the UEG. Seven pig hearts surrounded by an epicardial sock with 100 electrodes were Langendorff-perfused with selective cannulation of the left anterior descending (LAD) coronary artery and submersed in a torso-shaped tank containing 256 electrodes on the torso surface. Repolarization was prolonged in the non-LAD-regions by infusing dofetilide and shortened in the LAD-region using pinacidil. RT was determined by the Wyatt (t) and alternative (t) methods, in both invasive (recorded with epicardial electrodes) and in non-invasive UEGs (reconstructed with electrocardiographic imaging). t and t were compared to local effective refractory period (ERP). With contact mapping, mean absolute error (MAE) of t and t vs. ERP were 21 ms and 71 ms, respectively. Positive T-waves typically had an earlier ERP than negative T-waves, in line with theory. t -but not t-shortened by local infusion of pinacidil. Similar results were found for the non-invasive UEGs (MAE of t and t vs. ERP were 30 ms and 92 ms, respectively). The Wyatt method is the most accurate to determine RT from (non) invasive UEGs, based on novel and historical analyses. Using it to determine RT could unify and facilitate repolarization assessment and amplify its role in cardiac electrophysiology.

Citing Articles

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