Experimental validation of a finite element model of the proximal femur using digital image correlation and a composite bone model
Experimental validation of a finite element model of the proximal femur using digital image correlation and a composite bone model
Computational biomechanical models are useful tools for supporting orthopaedic implant design and surgical decision making, but because they are a simplification of the clinical scenario they must be carefully validated to ensure that they are still representative. The goal of this study was to assess the validity of the generation process of a structural Finite Element model of the proximal femur, employing the Digital Image Correlation (DIC) strain measurement technique. A finite element analysis model of the proximal femur subjected to gait loading was generated from a CT scan of an analogue composite femur, and its predicted mechanical behaviour was compared to an experimental model. Where previous studies have employed strain gauging to obtain discreet point data for validation, in this study DIC was used for full field quantified comparison of the predicted and experimentally measured strains. The strain predicted by the computational model was in good agreement with experimental measurements, with R-Squared correlation values from 0.83 to 0.92 between the simulation and the tests. The sensitivity and repeatability of the strain measurements were comparable to or better than values reported in the literature for other DIC tests on tissue specimens. The experimental-model correlation was in the same range as values obtained from strain gauging, but the DIC technique produced more detailed, full field data and is potentially easier to use. As such, the findings supported the validity of the model generation process, giving greater confidence in the model’s predictions, and Digital Image Correlation was demonstrated as a useful tool for validation of biomechanical models.
biomechanics, biomedical imaging, bone, computerised tomography, finite element analysis, physiological models
014504-[6pp]
Dickinson, Alexander
10151972-c1b5-4f7d-bc12-6482b5870cad
Taylor, Andrew
39974814-4868-4c73-a3fa-2adfa4be3e46
Ozturk, H.
df54e623-5468-4214-97a6-68ba5f4964e7
Browne, Martin
6578cc37-7bd6-43b9-ae5c-77ccb7726397
January 2011
Dickinson, Alexander
10151972-c1b5-4f7d-bc12-6482b5870cad
Taylor, Andrew
39974814-4868-4c73-a3fa-2adfa4be3e46
Ozturk, H.
df54e623-5468-4214-97a6-68ba5f4964e7
Browne, Martin
6578cc37-7bd6-43b9-ae5c-77ccb7726397
Dickinson, Alexander, Taylor, Andrew, Ozturk, H. and Browne, Martin
(2011)
Experimental validation of a finite element model of the proximal femur using digital image correlation and a composite bone model.
Journal of Biomechanical Engineering, 133 (1), .
(doi:10.1115/1.4003129).
(PMID:21186906)
Abstract
Computational biomechanical models are useful tools for supporting orthopaedic implant design and surgical decision making, but because they are a simplification of the clinical scenario they must be carefully validated to ensure that they are still representative. The goal of this study was to assess the validity of the generation process of a structural Finite Element model of the proximal femur, employing the Digital Image Correlation (DIC) strain measurement technique. A finite element analysis model of the proximal femur subjected to gait loading was generated from a CT scan of an analogue composite femur, and its predicted mechanical behaviour was compared to an experimental model. Where previous studies have employed strain gauging to obtain discreet point data for validation, in this study DIC was used for full field quantified comparison of the predicted and experimentally measured strains. The strain predicted by the computational model was in good agreement with experimental measurements, with R-Squared correlation values from 0.83 to 0.92 between the simulation and the tests. The sensitivity and repeatability of the strain measurements were comparable to or better than values reported in the literature for other DIC tests on tissue specimens. The experimental-model correlation was in the same range as values obtained from strain gauging, but the DIC technique produced more detailed, full field data and is potentially easier to use. As such, the findings supported the validity of the model generation process, giving greater confidence in the model’s predictions, and Digital Image Correlation was demonstrated as a useful tool for validation of biomechanical models.
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e-pub ahead of print date: 23 December 2010
Published date: January 2011
Keywords:
biomechanics, biomedical imaging, bone, computerised tomography, finite element analysis, physiological models
Organisations:
Bioengineering Sciences
Identifiers
Local EPrints ID: 170133
URI: http://eprints.soton.ac.uk/id/eprint/170133
ISSN: 0148-0731
PURE UUID: 02c9d129-841a-4f81-be56-0b55f09a0ddf
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Date deposited: 04 Jan 2011 10:02
Last modified: 14 Mar 2024 02:52
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Author:
Andrew Taylor
Author:
H. Ozturk
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