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Main Authors: Baptiste, Tiffany MG, Rodero, Cristobal, Sillett, Charles P, Strocchi, Marina, Lanyon, Christopher W, Augustin, Christoph M, Lee, Angela WC, Solís-Lemus, José Alonso, Roney, Caroline H, Ennis, Daniel B, Rajani, Ronak, Rinaldi, Christopher A, Plank, Gernot, Wilkinson, Richard D, Williams, Steven E, Niederer, Steven A
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2510.18642
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author Baptiste, Tiffany MG
Rodero, Cristobal
Sillett, Charles P
Strocchi, Marina
Lanyon, Christopher W
Augustin, Christoph M
Lee, Angela WC
Solís-Lemus, José Alonso
Roney, Caroline H
Ennis, Daniel B
Rajani, Ronak
Rinaldi, Christopher A
Plank, Gernot
Wilkinson, Richard D
Williams, Steven E
Niederer, Steven A
author_facet Baptiste, Tiffany MG
Rodero, Cristobal
Sillett, Charles P
Strocchi, Marina
Lanyon, Christopher W
Augustin, Christoph M
Lee, Angela WC
Solís-Lemus, José Alonso
Roney, Caroline H
Ennis, Daniel B
Rajani, Ronak
Rinaldi, Christopher A
Plank, Gernot
Wilkinson, Richard D
Williams, Steven E
Niederer, Steven A
contents The deformation of the left atrium (LA), or its biomechanical function, is closely linked to the health of this cardiac chamber. In atrial fibrillation (AF), atrial biomechanics are significantly altered but the underlying cause of this change is not always clear. Patient-specific models of the LA that replicate patient atrial motion can allow us to understand how factors such as atrial anatomy, myocardial stiffness and physiological constraints are linked to atrial biomechanics. We created patient-specific LA models from CT images. We fitted regional model stiffness to peak CT-derived deformation during the LA reservoir phase ($\pm0.90$ mm) and used the CT deformation transients through the reservoir and conduit phase for model validation (deformation transients fell within $\pm0.38$ mm per unit time of targets). We found that myocardial stiffness varies regionally across the LA. The regional stiffness values were significant factors contributing to regional physiological LA deformation ($p=0.023$) while features of LA anatomy, including regional wall thickness and adipose volume, were less important. These findings provide insight into the underlying causes of altered LA biomechanics in AF.
format Preprint
id arxiv_https___arxiv_org_abs_2510_18642
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Regional heterogeneity in left atrial stiffness impacts passive deformation in a cohort of patient-specific models
Baptiste, Tiffany MG
Rodero, Cristobal
Sillett, Charles P
Strocchi, Marina
Lanyon, Christopher W
Augustin, Christoph M
Lee, Angela WC
Solís-Lemus, José Alonso
Roney, Caroline H
Ennis, Daniel B
Rajani, Ronak
Rinaldi, Christopher A
Plank, Gernot
Wilkinson, Richard D
Williams, Steven E
Niederer, Steven A
Computational Engineering, Finance, and Science
The deformation of the left atrium (LA), or its biomechanical function, is closely linked to the health of this cardiac chamber. In atrial fibrillation (AF), atrial biomechanics are significantly altered but the underlying cause of this change is not always clear. Patient-specific models of the LA that replicate patient atrial motion can allow us to understand how factors such as atrial anatomy, myocardial stiffness and physiological constraints are linked to atrial biomechanics. We created patient-specific LA models from CT images. We fitted regional model stiffness to peak CT-derived deformation during the LA reservoir phase ($\pm0.90$ mm) and used the CT deformation transients through the reservoir and conduit phase for model validation (deformation transients fell within $\pm0.38$ mm per unit time of targets). We found that myocardial stiffness varies regionally across the LA. The regional stiffness values were significant factors contributing to regional physiological LA deformation ($p=0.023$) while features of LA anatomy, including regional wall thickness and adipose volume, were less important. These findings provide insight into the underlying causes of altered LA biomechanics in AF.
title Regional heterogeneity in left atrial stiffness impacts passive deformation in a cohort of patient-specific models
topic Computational Engineering, Finance, and Science
url https://arxiv.org/abs/2510.18642