Experimental validation of a finite element model of the proximal femur using digital image correlation and a composite bone model

Dickinson, A. S.<sup>1</sup>; Taylor, A. C.<sup>2</sup>; Ozturk, H.<sup>1</sup>; Browne, M.<sup>1</sup>

Affiliations

¹Bioengineering Research Group, University of Southampton, Highfield, Southampton, Hants SO17 1BJ, UK

²Finsbury Development Limited, 13 Mole Business Park, Randalls Road, Leatherhead, Surrey KT22 0BA, UK

Abstract and keywords

Computational biomechanical models are useful tools for supporting orthopedic 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 analog composite femur, and its predicted mechanical behavior was compared with an experimental model. Whereas 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 R² 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 the validation of biomechanical models.

Keywords: digital image correlation (DIC); finite element analysis (FEA); experimental validation

Links

DOI: 10.1115/1.4003129

PubMed: 21186906

WoS: 000285767600016

History

Received: 2010-05-24

Revised: 2010-11-15

Accepted: 2010-11-29

Online: 2010-12-23

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Cited By (15)

Year	Entry
2013	Gustafson HM, Cripton PA. Use of digital image correlation for validation of surface strain in specimen-specific vertebral finite element models. In: Proceedings of the 9th Ohio State University Injury Biomechanics Symposium. May 19-21, 2013; Columbus, OH.
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2020	Katz Y, Yosibash Z. New insights on the proximal femur biomechanics using digital image correlation. J Biomech. March 5, 2020;101:109599.
2020	Grassi L, Kok J, Gustafsson A, Zheng Y, Väänänen SP, Jurvelin JS, Isaksson H. Elucidating failure mechanisms in human femurs during a fall to the side using bilateral digital image correlation. J Biomech. June 9, 2020;106:109826.
2013	Gilchrist S, Guy P, Cripton PA. Development of an inertia-driven model of sideways fall for detailed study of femur fracture mechanics. J Biomech Eng. December 2013;135(12):121001.
2014	Grassi L, Väänänen SP, Yavari SA, Jurvelin JS, Weinans H, Ristinmaa M, Zadpoor AA, Isaksson H. Full-field strain measurement during mechanical testing of the human femur at physiologically relevant strain rates. J Biomech Eng. November 2014;136(11):111010.
2012	Shah S, Bougherara H, Schemitsch EH, Zdero R. Biomechanical stress maps of an artificial femur obtained using a new infrared thermography technique validated by strain gages. Med Eng Phys. December 2012;34(10):1496-1502.
2016	Chen Y. Verification and Validation of MicroCT-Based Finite Element Models of Bone Tissue Biomechanics [PhD thesis]. Sheffield, UK: University of Sheffield; July 2016.
2015	Nazeri H. An Investigation of the Strain Field and Inter-Fragmentary Movement of a Broken Hemi-Pelvis [Master's thesis]. Edmonton, AB: University of Alberta; 2015.
2019	Jee CC-B. Biomechanical Experimental Simulation of Pelvic Fracture [Master's thesis]. Edmonton, AB: University of Alberta; 2019.
2014	Gilchrist SM. Comparison of Proximal Femur Deformations, Failures and Fractures in Quasi-Static and Inertially-Driven Simulations of a Sideways Fall from Standing: An Experimental Study Utilizing Novel Fall Simulation, Digital Image Correlation, and Development of Digital Volume Correlation Techniques [PhD thesis]. Vancouver, BC: University of British Columbia; January 2014.
2016	Gustafson HM. Quantifying the Response of Vertebral Bodies to Compressive Loading Using Digital Image Correlation [PhD thesis]. Vancouver, BC: University of British Columbia; October 2016.
2017	Palanca M. In Vitro Full-Field Methods for the Biomechanical Characterization of Spine Segments [PhD thesis]. University of Bologna; March 2017.
2021	Kusins J. A Multi-Level Mechanical Assessment of the Shoulder Coupled With Evaluation of Upper Extremity Predictive Finite Element Models [PhD thesis]. University of Western Ontario; 2021.