Pointwise characterization of the elastic properties of planar soft tissues: application to ascending thoracic aneurysms
Pointwise characterization of the elastic properties of planar soft tissues: application to ascending thoracic aneurysms
In this manuscript, we present a combined experimental and computational technique that can identify the heterogeneous elastic properties of planar soft tissues. By combining inverse membrane analysis, digital image correlation, and bulge inflation tests, we are able to identify a tissue's mechanical properties locally. To show how the proposed method could be implemented, we quantified the heterogeneous material properties of a human ascending thoracic aortic aneurysm (ATAA). The ATAA was inflated at a constant rate using a bulge inflation device until it ruptured. Every 3 kPa images were taken using a stereo digital image correlation system. From the images, the three-dimensional displacement of the sample surface was determined. A deforming NURBS mesh was derived from the displacement data, and the local strains were computed. The wall stresses at each pressure increment were determined using inverse membrane analysis. The local material properties of the ATAA were then identified using the pointwise stress and strain data. To show that it is necessary to consider the heterogeneous distribution of the mechanical properties in the ATAA, three different forward finite element simulations using pointwise, elementwise, and homogeneous material properties were compared. The forward finite element predictions revealed that heterogeneous nature of the ATAA must be accounted for to accurately reproduce the stress-strain response
bulge inflation test, digital image correlation, heterogeneous material properties, inverse elastostatic analysis, thoracic aneurysm
967-978
Davis, Frances M.
20f89066-bbac-42dc-908d-d89a747dc399
Luo, Yuanming
88b5368e-09df-48a4-99b4-680902dc947a
Avril, Stephane
2a04eeed-db32-41eb-90fe-c21674b4496f
Duprey, Ambroise
ec5b5eac-34f2-4197-8be5-eaaa5575e1ff
Lu, Jia
08c1272f-b20c-4154-84f8-63b9c34ecb7f
October 2015
Davis, Frances M.
20f89066-bbac-42dc-908d-d89a747dc399
Luo, Yuanming
88b5368e-09df-48a4-99b4-680902dc947a
Avril, Stephane
2a04eeed-db32-41eb-90fe-c21674b4496f
Duprey, Ambroise
ec5b5eac-34f2-4197-8be5-eaaa5575e1ff
Lu, Jia
08c1272f-b20c-4154-84f8-63b9c34ecb7f
Davis, Frances M., Luo, Yuanming, Avril, Stephane, Duprey, Ambroise and Lu, Jia
(2015)
Pointwise characterization of the elastic properties of planar soft tissues: application to ascending thoracic aneurysms.
Biomechanics and Modeling in Mechanobiology, 14 (5), .
(doi:10.1007/s10237-014-0646-9).
Abstract
In this manuscript, we present a combined experimental and computational technique that can identify the heterogeneous elastic properties of planar soft tissues. By combining inverse membrane analysis, digital image correlation, and bulge inflation tests, we are able to identify a tissue's mechanical properties locally. To show how the proposed method could be implemented, we quantified the heterogeneous material properties of a human ascending thoracic aortic aneurysm (ATAA). The ATAA was inflated at a constant rate using a bulge inflation device until it ruptured. Every 3 kPa images were taken using a stereo digital image correlation system. From the images, the three-dimensional displacement of the sample surface was determined. A deforming NURBS mesh was derived from the displacement data, and the local strains were computed. The wall stresses at each pressure increment were determined using inverse membrane analysis. The local material properties of the ATAA were then identified using the pointwise stress and strain data. To show that it is necessary to consider the heterogeneous distribution of the mechanical properties in the ATAA, three different forward finite element simulations using pointwise, elementwise, and homogeneous material properties were compared. The forward finite element predictions revealed that heterogeneous nature of the ATAA must be accounted for to accurately reproduce the stress-strain response
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More information
Accepted/In Press date: December 2014
e-pub ahead of print date: 10 January 2015
Published date: October 2015
Keywords:
bulge inflation test, digital image correlation, heterogeneous material properties, inverse elastostatic analysis, thoracic aneurysm
Organisations:
Engineering Science Unit
Identifiers
Local EPrints ID: 382226
URI: http://eprints.soton.ac.uk/id/eprint/382226
ISSN: 1617-7959
PURE UUID: 159f0518-c7b1-41ee-903d-975c0d12a842
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Date deposited: 22 Oct 2015 13:23
Last modified: 14 Mar 2024 21:26
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Contributors
Author:
Frances M. Davis
Author:
Yuanming Luo
Author:
Stephane Avril
Author:
Ambroise Duprey
Author:
Jia Lu
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