Multiple factors influence the morphology of the bipolar electrogram: An in silico modeling study

Multiple factors influence the morphology of the bipolar electrogram: An in silico modeling study

Although bipolar electrograms (Bi-egms) are commonly used for catheter mapping and ablation of cardiac arrhythmias, the accuracy and reproducibility of Bi-egms have not been evaluated. We aimed to clarify the influence of the catheter orientation (CO), catheter contact angle (CA), local conduction v...

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Bibliographic Details
Published in:PLoS computational biology Vol. 15; no. 4; p. e1006765
Main Authors: Hwang, Minki, Kim, Jaehyuk, Lim, Byounghyun, Song, Jun-Seop, Joung, Boyoung, Shim, Eun Bo, Pak, Hui-Nam
Format: Journal Article
Language:English
Published: United States Public Library of Science 05-04-2019
Public Library of Science (PLoS)
Subjects:
Ablation
Ablation (Surgery)
Amplitudes
Arrhythmia
Atrial fibrillation
Biology and Life Sciences
Cardiac arrhythmia
Cardiology
Catheters
Computer and Information Sciences
Conduction
Contact angle
Electric potential
Electrodes
Electroencephalography
Engineering and Technology
Fibrillation
Heart
Mapping
Medical instruments
Medicine and Health Sciences
Methods
Morphology
Physical Sciences
Simulation
Sinuses
Substrates
Three dimensional models
Voltage
Wave direction
Wave propagation
South Korea
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Summary:Although bipolar electrograms (Bi-egms) are commonly used for catheter mapping and ablation of cardiac arrhythmias, the accuracy and reproducibility of Bi-egms have not been evaluated. We aimed to clarify the influence of the catheter orientation (CO), catheter contact angle (CA), local conduction velocity (CV), scar size, and catheter type on the Bi-egm morphology using an in silico 3-dimensional realistic model of atrial fibrillation. We constructed a 3-dimensional, realistic, in silico left atrial model with activation wave propagation including bipolar catheter models. Bi-egms were obtained by computing the extracellular potentials from the distal and proximal electrodes. The amplitude and width were measured on virtual Bi-egms obtained under different conditions created by changing the CO according to the wave direction, catheter-atrial wall CA, local CV, size of the non-conductive area, and catheter type. Bipolar voltages were also compared between virtual and clinically acquired Bi-egms. Bi-egm amplitudes were lower for a perpendicular than parallel CO relative to the wave direction (p<0.001), lower for a 90° than 0° CA (p<0.001), and lower for a CV of 0.13m/s than 0.48m/s (p<0.001). Larger sized non-conductive areas were associated with a decreased bipolar amplitude (p<0.001) and increased bipolar width (p<0.001). Among three commercially available catheters (Orion, Pentaray, and Thermocool), those with more narrowly spaced and smaller electrodes produced higher voltages on the virtual Bi-egms (p<0.001). Multiple factors including the CO, CA, CV, and catheter design significantly influence the Bi-egm morphology. Universal voltage cut-off values may not be appropriate for bipolar voltage-guided substrate mapping.
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The authors have declared that no competing interests exist.
ISSN:1553-7358
1553-734X
1553-7358
DOI:10.1371/journal.pcbi.1006765