Jana M Schwarzl1, Ruben Schleberger1, Ann-Kathrin Kahle1, Alexandra Höller2, Michael Schwarzl1,3, Benjamin N Schaeffer1, Paula Münkler1,3, Julia Moser1, Ruken Ö Akbulak4, Christian Eickholt4, Leon Dinshaw1, Jannis Dickow1, Philippe Maury5, Frederic Sacher6, Claire A Martin7, Tom Wong8, Heidi L Estner9, Pierre Jaïs6, Stephan Willems3,4, Christian Meyer3,10,11. 1. Department of Cardiology, University Heart and Vascular Center Hamburg, University Medical Center Hamburg-Eppendorf, Hamburg, Germany. 2. Institute of Medical Biometry and Epidemiology, Center of Experimental Medicine, University Medical Center Hamburg-Eppendorf, Hamburg, Germany. 3. DZHK (German Center for Cardiovascular Research), Berlin, Germany. 4. Department of Cardiology, Asklepios Hospital St. Georg, Hamburg, Germany. 5. Department of Cardiology, University Hospital Rangueil, Toulouse, France. 6. Department of Cardiac Electrophysiology, LIRYC Institute, Bordeaux University Hospital, Bordeaux, France. 7. Department of Cardiology, Royal Papworth Hospital, National Health Service Foundation Trust, Cambridge, UK. 8. Heart Rhythm Center, Imperial College London, The Royal Brompton and Harefield NHS Foundation Trust, London, UK. 9. Department of Internal Medicine I - Cardiology, University Hospital Munich, Ludwig-Maximilian University Munich, Munich, Germany. 10. Division of Cardiology, cardiac Neuro- and Electrophysiology Research Consortium (cNEP), EVK Düsseldorf, Düsseldorf, Germany. 11. Institute for Neural and Sensory Physiology, Cardiac Neuro- and Electrophysiology Research Consortium (cNEP), Medical Faculty, Heinrich Heine University Düsseldorf, Düsseldorf, Germany.
Abstract
INTRODUCTION: Substrate-based catheter ablation approaches to ventricular tachycardia (VT) focus on low-voltage areas and abnormal electrograms. However, specific electrogram characteristics in sinus rhythm are not clearly defined and can be subject to variable interpretation. We analyzed the potential ablation target size using automatic abnormal electrogram detection and studied findings during substrate mapping in the VT isthmus area. METHODS AND RESULTS: Electrogram characteristics in 61 patients undergoing scar-related VT ablation using ultrahigh-density 3D-mapping with a 64-electrode mini-basket catheter were analyzed retrospectively. Forty-four complete substrate maps with a mean number of 10319 ± 889 points were acquired. Fractionated potentials detected by automated annotation and manual review were present in 43 ± 21% of the entire low-voltage area (<1.0 mV), highly fractionated potentials in 7 ± 8%, late potentials in 13 ± 15%, fractionated late potentials in 7 ± 9% and isolated late potentials in 2 ± 4%, respectively. Highly fractionated potentials (>10 ± 1 fractionations) were found in all isthmus areas of identified VT during substrate mapping, while isolated late potentials were distant from the critical isthmus area in 29%. CONCLUSION: The ablation target area varies enormously in size, depending on the definition of abnormal electrograms. Clear linking of abnormal electrograms with critical VT isthmus areas during substrate mapping remains difficult due to a lack of specificity rather than sensitivity. However, highly fractionated, low-voltage electrograms were found to be present in all critical VT isthmus sites.
INTRODUCTION: Substrate-based catheter ablation approaches to ventricular tachycardia (VT) focus on low-voltage areas and abnormal electrograms. However, specific electrogram characteristics in sinus rhythm are not clearly defined and can be subject to variable interpretation. We analyzed the potential ablation target size using automatic abnormal electrogram detection and studied findings during substrate mapping in the VT isthmus area. METHODS AND RESULTS: Electrogram characteristics in 61 patients undergoing scar-related VT ablation using ultrahigh-density 3D-mapping with a 64-electrode mini-basket catheter were analyzed retrospectively. Forty-four complete substrate maps with a mean number of 10319 ± 889 points were acquired. Fractionated potentials detected by automated annotation and manual review were present in 43 ± 21% of the entire low-voltage area (<1.0 mV), highly fractionated potentials in 7 ± 8%, late potentials in 13 ± 15%, fractionated late potentials in 7 ± 9% and isolated late potentials in 2 ± 4%, respectively. Highly fractionated potentials (>10 ± 1 fractionations) were found in all isthmus areas of identified VT during substrate mapping, while isolated late potentials were distant from the critical isthmus area in 29%. CONCLUSION: The ablation target area varies enormously in size, depending on the definition of abnormal electrograms. Clear linking of abnormal electrograms with critical VT isthmus areas during substrate mapping remains difficult due to a lack of specificity rather than sensitivity. However, highly fractionated, low-voltage electrograms were found to be present in all critical VT isthmus sites.
Authors: Ruben Schleberger; Jana M Schwarzl; Julia Moser; Moritz Nies; Alexandra Höller; Paula Münkler; Leon Dinshaw; Christiane Jungen; Marc D Lemoine; Philippe Maury; Frederic Sacher; Claire A Martin; Tom Wong; Heidi L Estner; Pierre Jaïs; Stephan Willems; Christian Eickholt; Christian Meyer Journal: Sci Rep Date: 2022-06-01 Impact factor: 4.996
Authors: Ann-Kathrin Kahle; Rebekka Güde; Jana M Schwarzl; Paula Münkler; Ruken Ö Akbulak; Charlotte Jahnke; Sebastian Bohnen; Tilman Würger; Michael Schwarzl; Stephan Willems; Ulf K Radunski; Christian Meyer Journal: J Cardiovasc Dev Dis Date: 2022-07-29