OBJECTIVE: Computational models represent a novel framework for understanding the mechanisms behind atrial fibrillation (AF) and offer a pathway for personalizing and optimizing treatment. The characterization of local electrophysiological properties across the atria during procedures remains a challenge. The aim of this work is to characterize the regional properties of the human atrium from multielectrode catheter measurements. METHODS: We propose a novel method that characterizes regional electrophysiology properties by fitting parameters of an ionic model to conduction velocity and effective refractory period restitution curves obtained by a s1-s2 pacing protocol applied through a multielectrode catheter. Using an in-silico dataset we demonstrate that the fitting method can constrain parameters with a mean error of 21.9 ± 16.1% and can replicate conduction velocity and effective refractory curves not used in the original fitting with a relative error of 4.4 ± 6.9%. RESULTS: We demonstrate this parameter estimation approach on five clinical datasets recorded from AF patients. Recordings and parametrization took approx. 5 and 6 min, respectively. Models fitted restitution curves with an error of ~ 5% and identify a unique parameter set. Tissue properties were predicted using a two-dimensional atrial tissue sheet model. Spiral wave stability in each case was predicted using tissue simulations, identifying distinct stable (2/5), meandering and breaking up (2/5), and unstable self-terminating (1/5) spiral tip patterns for different cases. CONCLUSION AND SIGNIFICANCE: We have developed and demonstrated a robust and rapid approach for personalizing local ionic models from a clinically tractable.
OBJECTIVE: Computational models represent a novel framework for understanding the mechanisms behind atrial fibrillation (AF) and offer a pathway for personalizing and optimizing treatment. The characterization of local electrophysiological properties across the atria during procedures remains a challenge. The aim of this work is to characterize the regional properties of the human atrium from multielectrode catheter measurements. METHODS: We propose a novel method that characterizes regional electrophysiology properties by fitting parameters of an ionic model to conduction velocity and effective refractory period restitution curves obtained by a s1-s2 pacing protocol applied through a multielectrode catheter. Using an in-silico dataset we demonstrate that the fitting method can constrain parameters with a mean error of 21.9 ± 16.1% and can replicate conduction velocity and effective refractory curves not used in the original fitting with a relative error of 4.4 ± 6.9%. RESULTS: We demonstrate this parameter estimation approach on five clinical datasets recorded from AF patients. Recordings and parametrization took approx. 5 and 6 min, respectively. Models fitted restitution curves with an error of ~ 5% and identify a unique parameter set. Tissue properties were predicted using a two-dimensional atrial tissue sheet model. Spiral wave stability in each case was predicted using tissue simulations, identifying distinct stable (2/5), meandering and breaking up (2/5), and unstable self-terminating (1/5) spiral tip patterns for different cases. CONCLUSION AND SIGNIFICANCE: We have developed and demonstrated a robust and rapid approach for personalizing local ionic models from a clinically tractable.
Authors: Mark Nothstein; Armin Luik; Amir Jadidi; Jorge Sánchez; Laura A Unger; Eike M Wülfers; Olaf Dössel; Gunnar Seemann; Claus Schmitt; Axel Loewe Journal: Front Physiol Date: 2021-05-24 Impact factor: 4.566
Authors: Sam Coveney; Cesare Corrado; Caroline H Roney; Daniel O'Hare; Steven E Williams; Mark D O'Neill; Steven A Niederer; Richard H Clayton; Jeremy E Oakley; Richard D Wilkinson Journal: Philos Trans A Math Phys Eng Sci Date: 2020-05-25 Impact factor: 4.226
Authors: Dominic G Whittaker; Michael Clerx; Chon Lok Lei; David J Christini; Gary R Mirams Journal: Wiley Interdiscip Rev Syst Biol Med Date: 2020-02-21
Authors: Caroline H Roney; Steven E Williams; Hubert Cochet; Rahul K Mukherjee; Louisa O'Neill; Iain Sim; John Whitaker; Orod Razeghi; George J Klein; Edward J Vigmond; Mark O'Neill; Steven A Niederer Journal: Europace Date: 2018-11-01 Impact factor: 5.214