TY - JOUR
T1 - Constructing bilayer and volumetric atrial models at scale
AU - Roney, Caroline H.
AU - Solis Lemus, Jose Alonso
AU - Lopez Barrera, Carlos
AU - Zolotarev, Alexander
AU - Ulgen, Onur
AU - Kerfoot, Eric
AU - Bevis, Laura
AU - Misghina, Semhar
AU - Vidal Horrach, Caterina
AU - Jaffery, Ovais A.
AU - Ehnesh, Mahmoud
AU - Rodero, Cristobal
AU - Dharmaprani, Dhani
AU - Ríos-Muñoz, Gonzalo R.
AU - Ganesan, Anand
AU - Good, Wilson W.
AU - Neic, Aurel
AU - Plank, Gernot
AU - Hopman, Luuk H. G. A.
AU - Götte, Marco J. W.
AU - Honarbakhsh, Shohreh
AU - Narayan, Sanjiv M.
AU - Vigmond, Edward
AU - Niederer, Steven
N1 - Funding Information: C.H.R. acknowledges support from a UKRI Future Leaders Fellowship (grant no. MR/W004720/1). The team acknowledge Archer2 simulation funding. O.A.J. acknowledges funding for his PhD studentship from Acutus Medical. W.W.G. is an employee and shareholder of Acutus Medical. The research described herein was not influenced by this employment and no conflict of interest exists. C.R. receives funding from the British Heart Foundation (grant no. RG/20/4/34 803). This work was also supported by the Wellcome ESPRC Centre for Medical Engineering at King’s College London (grant no. WT 203148/Z/16/Z). G.P. received financial support from the Austrian Science Fund (FWF) grant no. I6476-B. C.L.B. acknowledges CONACYT for a research scholarship. D.D. and A.G. acknowledge funding as follows: Cardiovascular Health Mission Grant from the Medical Research Future Fund, and Heart Health Innovation Grant from The Hospital Research Foundation of South Australia. G.R.R.-M. acknowledges support from the Instituto de Salud Carlos III, Madrid, Spain (grant nos. PI18/01895, DTS21/00064 and PI22/01619). E.V. received financial support from the French Government as part of the ‘Investments of the Future’ programme managed by the National Research Agency (ANR), grant reference ANR-10-IAHU-04. Publisher Copyright: © 2023 The Authors.
PY - 2023/12/15
Y1 - 2023/12/15
N2 - To enable large in silico trials and personalized model predictions on clinical timescales, it is imperative that models can be constructed quickly and reproducibly. First, we aimed to overcome the challenges of constructing cardiac models at scale through developing a robust, open-source pipeline for bilayer and volumetric atrial models. Second, we aimed to investigate the effects of fibres, fibrosis and model representation on fibrillatory dynamics. To construct bilayer and volumetric models, we extended our previously developed coordinate system to incorporate transmurality, atrial regions and fibres (rule-based or data driven diffusion tensor magnetic resonance imaging (MRI)). We created a cohort of 1000 biatrial bilayer and volumetric models derived from computed tomography (CT) data, as well as models from MRI, and electroanatomical mapping. Fibrillatory dynamics diverged between bilayer and volumetric simulations across the CT cohort (correlation coefficient for phase singularity maps: left atrial (LA) 0.27 ± 0.19, right atrial (RA) 0.41 ± 0.14). Adding fibrotic remodelling stabilized re-entries and reduced the impact of model type (LA: 0.52 ± 0.20, RA: 0.36 ± 0.18). The choice of fibre field has a small effect on paced activation data (less than 12 ms), but a larger effect on fibrillatory dynamics. Overall, we developed an open-source user-friendly pipeline for generating atrial models from imaging or electroanatomical mapping data enabling in silico clinical trials at scale (https://github.com/pcmlab/atrialmtk).
AB - To enable large in silico trials and personalized model predictions on clinical timescales, it is imperative that models can be constructed quickly and reproducibly. First, we aimed to overcome the challenges of constructing cardiac models at scale through developing a robust, open-source pipeline for bilayer and volumetric atrial models. Second, we aimed to investigate the effects of fibres, fibrosis and model representation on fibrillatory dynamics. To construct bilayer and volumetric models, we extended our previously developed coordinate system to incorporate transmurality, atrial regions and fibres (rule-based or data driven diffusion tensor magnetic resonance imaging (MRI)). We created a cohort of 1000 biatrial bilayer and volumetric models derived from computed tomography (CT) data, as well as models from MRI, and electroanatomical mapping. Fibrillatory dynamics diverged between bilayer and volumetric simulations across the CT cohort (correlation coefficient for phase singularity maps: left atrial (LA) 0.27 ± 0.19, right atrial (RA) 0.41 ± 0.14). Adding fibrotic remodelling stabilized re-entries and reduced the impact of model type (LA: 0.52 ± 0.20, RA: 0.36 ± 0.18). The choice of fibre field has a small effect on paced activation data (less than 12 ms), but a larger effect on fibrillatory dynamics. Overall, we developed an open-source user-friendly pipeline for generating atrial models from imaging or electroanatomical mapping data enabling in silico clinical trials at scale (https://github.com/pcmlab/atrialmtk).
KW - cardiac arrhythmia
KW - computational model
KW - digital twin
KW - in silico trial
KW - patient-specific cardiac model
UR - http://www.scopus.com/inward/record.url?scp=85180156568&partnerID=8YFLogxK
U2 - https://doi.org/10.1098/rsfs.2023.0038
DO - https://doi.org/10.1098/rsfs.2023.0038
M3 - Article
C2 - 38106921
SN - 2042-8898
VL - 13
JO - Interface focus
JF - Interface focus
IS - 6
M1 - 20230038
ER -