Imaging Dispersion of Myocardial Repolarization, II: Noninvasive Reconstruction of Epicardial Measures Raja N. Ghanem, John E. Burnes, Albert L. Waldo.

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Imaging Dispersion of Myocardial Repolarization, II: Noninvasive Reconstruction of Epicardial Measures Raja N. Ghanem, John E. Burnes, Albert L. Waldo & Yoram Rudy Circulation 2001;104: Abstract: Current noninvasive approaches for detecting substrates with increased dispersion based on ECG measures (eg, QT dispersion) have shown limited success and inconsistencies. In this study, epicardial potentials were recorded with a 224-electrode sock from an open-chest dog during regional warming and cooling to induce localized regions of increased dispersion. Body-surface potentials were generated from these epicardial potentials in a human torso model. Realistic geometric errors and measurement noise were added to the torso data to simulate the clinical environment. The data were then used to reconstruct noninvasively repolarization properties (ARI: activation-recovery intervals; QRST integral maps) on the heart using electrocardiographic imaging (ECGI). ECGI can reconstruct repolarization properties accurately and localize areas of increased dispersion of repolarization in the heart noninvasively. Introduction Dispersion of repolarization results in regional variation in refractoriness, which can be highly arrhythmogenic. Conventional ECG is not sensitive to increased dispersion of repolarization. Epicardial potentials determined here using noninvasive ECGI accurately reflect spatial heterogeneities of myocardial repolarization. The activation-recovery interval (ARI) is the difference between activation and recovery times and has been shown to correlate with local action potential duration. QRST integrals reflect intrinsic spatial heterogeneity of repolarization independently of the activation sequence. Measured (top) and noninvasively reconstructed (bottom) epicardial ARI maps during control (left column) regional LV warming (second column; region corresponds to orange area), regional LV cooling (third column; blue area) and simultaneous warming and cooling (right column). Colors provide ARI values in milliseconds. Note uniform ARI in control (green). Warming introduces Measured (top) and noninvasively reconstructed using ECGI (middle) QRST- integral maps on the heart surface. Note high values of QRST-integral in warmed region (red) and low values in cooled region (dark green and blue), capturing local repolarization changes and dispersion. The body surface QRST-integral (bottom) is similar between control and the various interventions that affect repolarization, demonstrating that the body surface ECG is not sensitive to dispersion of repolarization in the heart. This observation highlights the importance of ECGI in detecting arrhythmogenic substrate associated with repolarization abnormalities. dispersion by shortening ARI (orange) while cooling prolongs ARI (blue). When applied together, a steep repolarization gradient develops between the warm and cool regions (from orange to blue, right column). These repolarization changes and the associated dispersion are captured noninvasively by ECGI (bottom).