Grid-patterned mapping catheters may overcome the directional sensitivity limitations of conventional bipolar voltage mapping, allowing for more accurate detection of atrial fibrillation substrate.
This review discusses the limitations of standard bipolar voltage mapping for atrial substrate evaluation, particularly regarding directionality, and introduces a grid-pattern mapping catheter to improve mapping reliability.
The relationship between atrial fibrosis and atrial fibrillation (AF) has been proven. Patient specific substrate ablation targeting fibrotic tissue estimated by bipolar voltage mapping has emerged as an alternative strategy for additional substrate modification beyond pulmonary vein isolation. The primary mechanism of a low-voltage electrogram has been suggested to be atrial fibrosis, however, no direct correlation between histological fibrosis and low-voltage zone has been confirmed. Furthermore, the definition of low-voltage zone is still controversial, and bipolar voltage amplitudes depend on multiple variables including electrodes orientation relative to direction of wavefront, electrode length, interelectrode spacing, and tissue contact. The aim of this article is to review the role and limitation of voltage mapping, and to share our initial experience of a newly released grid-pattern designed mapping catheter to make the voltage mapping more reliable to guide patient specific AF ablation.
Takanori Yamaguchi (Fri,) conducted a review in Atrial Fibrillation. Grid-patterned mapping catheter (Advisor HD Grid) vs. Conventional circular mapping catheter was evaluated. Grid-patterned mapping catheters may overcome the directional sensitivity limitations of conventional bipolar voltage mapping, allowing for more accurate detection of atrial fibrillation substrate.
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