High-density and high-coverage composite atrial activation maps: an in-silico validation study

Ozan Ozgul*, Victor G. Marques, Ben JM Hermans, Arne van Hunnik, Sander Verheule, Ali Gharaviri, Simone Pezzuto, Angelo Auricchio, Ulrich Schotten, Pietro Bonizzi, Stef Zeemering

*Corresponding author for this work

Research output: Contribution to journalArticleAcademicpeer-review

Abstract

Objective: Repetitive atrial activation patterns (RAAPs) during complex atrial tachycardia could be associated with localized mechanisms that can be targeted. Clinically available electroanatomical mapping systems are limited by either the spatial coverage or electrode density of the mapping catheters, preventing the adequate visualization of transiently occurring RAAPs. This work proposes a technique to overcome this shortcoming by stitching spatially overlapping conduction patterns together to a larger image- called a composite map. Methods: Simulated stable mechanisms and meandering reentries are sequentially mapped (4x4 grid, 3mm spacing) and then reconstructed back to the original sizes with the proposed recurrence plot-based algorithm. Results: The reconstruction of single linear waves presents minimal errors (local activation time (LAT) difference: 3.2 [1.6-4.9] ms, conduction direction difference: 5.2 [2.3-8.0] degrees). Errors significantly increase (p&lt;0.05) for more complex patterns, being the highest with unstable reentries (LAT difference: 10.3 [3.5-16.2] ms, conduction direction difference: 18.2 [6.7-29.7] deg). In a second part of the analysis, 111 meandering reentries are reconstructed. Mapping 30 locations overlappingly around each reentry core was found to be the optimal mapping strategy. For this optimal setting, LAT, conduction direction, and core localization errors are low (6.1 [4.2-8.6] ms, 11.2 [8.6-15.5] deg and 4.1 [2.9-4.9] mm, respectively) and are weakly correlated with the degree of the meander (<inline-formula><tex-math notation="LaTeX">$\rho$</tex-math></inline-formula>=0.41, <inline-formula><tex-math notation="LaTeX">$\rho$</tex-math></inline-formula>=0.40 and <inline-formula><tex-math notation="LaTeX">$\rho$</tex-math></inline-formula>=0.20, respectively). Conclusion: Our findings underline the feasibility of generating composite maps by stitching spatially overlapping recordings. Significance: Composite maps can be instrumental in personalized ablation strategies.

Original languageEnglish
Number of pages10
JournalIeee Transactions on Biomedical Engineering
DOIs
Publication statusE-pub ahead of print - 1 Jan 2024

Keywords

  • Arrhythmia
  • Atrial arrhythmias
  • Biomedical engineering
  • Catheter ablation
  • Catheters
  • Conduction patterns
  • Electrodes
  • High-density atrial mapping
  • Image reconstruction
  • Recording
  • Recurrence plots
  • Repetitive activation patterns
  • Sequential mapping
  • Visualization

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