High-resolution noncontact charge-density mapping of endocardial activation
Andrew Grace, Stephan Willems, Christian Meyer, Atul Verma, Patrick Heck, Min Zhu, Xinwei Shi, Derrick Chou, Lam Dang, Christoph Scharf, Günter Scharf, Graydon Beatty
Andrew Grace, Stephan Willems, Christian Meyer, Atul Verma, Patrick Heck, Min Zhu, Xinwei Shi, Derrick Chou, Lam Dang, Christoph Scharf, Günter Scharf, Graydon Beatty
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Clinical Research and Public Health Cardiology

High-resolution noncontact charge-density mapping of endocardial activation

Abstract

BACKGROUND. Spatial resolution in cardiac activation maps based on voltage measurement is limited by far-field interference. Precise characterization of electrical sources would resolve this limitation; however, practical charge-based cardiac mapping has not been achieved. METHODS. A prototype algorithm, developed from first principles of electrostatic field theory, derives charge density (CD) as a spatial representation of the true sources of the cardiac field. The algorithm processes multiple, simultaneous, noncontact voltage measurements within the cardiac chamber to inversely derive the global distribution of CD sources across the endocardial surface. RESULTS. Comparison of CD to an established computer-simulated model of atrial conduction demonstrated feasibility in terms of spatial, temporal, and morphologic metrics. Inverse reconstruction matched simulation with median spatial errors of 1.73 mm and 2.41 mm for CD and voltage, respectively. Median temporal error was less than 0.96 ms and morphologic correlation was greater than 0.90 for both CD and voltage. Activation patterns observed in human atrial flutter reproduced those established through contact maps, with a 4-fold improvement in resolution noted for CD over voltage. Global activation maps (charge density–based) are reported in atrial fibrillation with confirmed reduction of far-field interference. Arrhythmia cycle-length slowing and termination achieved through ablation of critical points demonstrated in the maps indicates both mechanistic and pathophysiological relevance. CONCLUSION. Global maps of cardiac activation based on CD enable classification of conduction patterns and localized nonpulmonary vein therapeutic targets in atrial fibrillation. The measurement capabilities of the approach have roles spanning deep phenotyping to therapeutic application. TRIAL REGISTRATION. ClinicalTrials.gov NCT01875614. FUNDING. The National Institute for Health Research (NIHR) Translational Research Program at Royal Papworth Hospital and Acutus Medical.

Authors

Andrew Grace, Stephan Willems, Christian Meyer, Atul Verma, Patrick Heck, Min Zhu, Xinwei Shi, Derrick Chou, Lam Dang, Christoph Scharf, Günter Scharf, Graydon Beatty

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Figure 4

System, mapping catheter, and anatomic reconstruction used in clinical studies of human atria.

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System, mapping catheter, and anatomic reconstruction used in clinical s...
(A) The system consists of a console, workstation, and interface unit. Localization and electrical reference electrodes are connected to the system through the patient interface. The AcQMap catheter, ECG electrodes, and auxiliary catheters are connected to the console front panel. Commercially available ablation catheters and generators can be connected through an ablation interface. (B) AcQMap mapping catheter has a 10-F shaft, integral handle (not shown), and deployable distal 25-mm spheroid apparatus that has 6 splines, each populated with 8 ultrasound transducers for anatomy reconstruction and 8 unipolar electrodes for mapping. (C) Radiographic (28° left anterior oblique [LAO]) view of the AcQMap catheter in the left atrium. (D) Ultrasound reconstruction of the left atrium is based on the transit time of sonic reflections between the endocardial surface and the transducers on the catheter splines. Distances calculated from the transit times result in 3D points that represent locations on the endocardial surface and are dynamically triangulated into a surface mesh. Rotation, advancement, and retraction of the catheter during point collection achieves a complete reconstruction throughout the entire chamber, usually over 90–180 seconds (Supplemental Video 1). Postprocessing is performed to establish the final anatomy that is used for navigation and mapping.