John Asta scite author profile

Our objective was to establish a novel model for the study of ventricular fibrillation (VF) in humans. We adopted the established techniques of optical mapping to human ventricles for the first time to determine whether human VF is the result of wave breaks and singularity point formation and is maintained by high-frequency rotors and fibrillatory conduction. We describe the technique of acquiring optical signals in human hearts during VF, their characteristics, and the feasibility of possible analyses that could be performed to elucidate mechanisms of human VF. We used explanted hearts from five cardiomyopathic patients who underwent transplantation. The hearts were Langendorff perfused with Tyrode solution (95% O 2 -5% CO 2 ), and the potentiometric dye di-4-ANEPPS was injected as a bolus into the coronary circulation. Fluorescence was excited at 531 Ϯ 20 nm with a 150-W halogen light source; the emission signal was long-pass filtered at 610 nm and recorded with a mapping camera. Fractional change of fluorescence varied between 2% and 12%. Average signal-to-noise ratio was 40 dB. The mean velocity of VF wave fronts was 0.25 Ϯ 0.04 m/s. Submillimetric spatial resolution (0.65-0.85 mm), activation mapping, and transformation of the data to phase-based analysis revealed reentrant, colliding, and fractionating wave fronts in human VF. On many occasions the VF wave fronts were as large as the entire vertical length (8 cm) of the mapping field, suggesting that there are a limited number of wave fronts on the human heart during VF. Phase transformation of the optical signals allowed the first demonstration ever of phase singularity point, wave breaks, and rotor formation in human VF. This method provides opportunities for potential analyses toward elucidation of the mechanisms of VF and defibrillation in humans.

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Resolving Myocardial Activation With Novel Omnipolar Electrograms

Massé

Magtibay

Jackson

et al. 2016

Circ: Arrhythmia and Electrophysiology

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Resolving Bipolar Electrogram Voltages During Atrial Fibrillation Using Omnipolar Mapping

Haldar

Magtibay

Porta‐Sánchez

et al. 2017

Circ: Arrhythmia and Electrophysiology

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Background: Low-voltage–guided substrate modification is an emerging strategy in atrial fibrillation (AF) ablation. A major limitation to contemporary bipolar electrogram (EGM) analysis in AF is the resultant lower peak-to-peak voltage (V pp ) from variations in wavefront direction relative to electrode orientation and from fractionation and collision events. We aim to compare bipole V pp with novel omnipolar peak-to-peak voltages (V max ) in sinus rhythm (SR) and AF. Methods and Results: A high-density fixed multielectrode plaque was placed on the epicardial surface of the left atrium in dogs. Horizontal and vertical orientation bipolar EGMs, followed by omnipolar EGMs, were obtained and compared in both SR and AF. Bipole orientation has significant impact on bipolar EGM voltages obtained during SR and AF. In SR, vertical values were on average 66±119% larger than horizontal ( P =0.004). In AF, vertical values were on average 31±96% larger than horizontal ( P =0.07). Omnipole V max values were 99.9±125% larger than both horizontal (99.9±125%; P <0.001) and vertical (41±78%; P <0.0001) in SR and larger than both horizontal (76±109%; P <0.001) and vertical (52±70%; P value <0.0001) in AF. Vector field analysis of AF wavefronts demonstrates that omnipolar EGMs can account for collision and fractionation and record EGM voltages unaffected by these events. Conclusions: Omnipolar EGMs can extract maximal voltages from AF signals which are not influenced by directional factors, collision or fractionation, compared with contemporary bipolar techniques.

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John Asta

Optical mapping of Langendorff-perfused human hearts: establishing a model for the study of ventricular fibrillation in humans

Resolving Myocardial Activation With Novel Omnipolar Electrograms

Resolving Bipolar Electrogram Voltages During Atrial Fibrillation Using Omnipolar Mapping

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