How accurately can subject-specific finite element models predict strains and strength of human femora? investigation using full-field measurements

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Grassi, Lorenzo¹; Väänänen, Sami P.²; Ristinmaa, Matti³; Jurvelin, Jukka S.^2,4; Isaksson, Hanna¹

How accurately can subject-specific finite element models predict strains and strength of human femora? investigation using full-field measurements

J Biomech. March 21, 2016;49(5):802-806

©2016 Elsevier Ltd. All rights reserved.

Affiliations

¹Department of Biomedical Engineering, Lund University, Sweden

²Department of Applied Physics, University of Eastern Finland, Finland

³Division of Solid Mechanics, Lund University, Sweden

⁴Diagnostic Imaging Center, Kuopio University Hospital, Finland
Abstract and keywords

Subject-specific finite element models have been proposed as a tool to improve fracture risk assessment in individuals. A thorough laboratory validation against experimental data is required before introducing such models in clinical practice. Results from digital image correlation can provide full-field strain distribution over the specimen surface during in vitro test, instead of at a few pre-defined locations as with strain gauges. The aim of this study was to validate finite element models of human femora against experimental data from three cadaver femora, both in terms of femoral strength and of the full-field strain distribution collected with digital image correlation. The results showed a high accuracy between predicted and measured principal strains (R²=0.93, RMSE=10%, 1600 validated data points per specimen). Femoral strength was predicted using a rate dependent material model with specific strain limit values for yield and failure. This provided an accurate prediction (<2% error) for two out of three specimens. In the third specimen, an accidental change in the boundary conditions occurred during the experiment, which compromised the femoral strength validation. The achieved strain accuracy was comparable to that obtained in state-of-the-art studies which validated their prediction accuracy against 10–16 strain gauge measurements. Fracture force was accurately predicted, with the predicted failure location being very close to the experimental fracture rim. Despite the low sample size and the single loading condition tested, the present combined numerical–experimental method showed that finite element models can predict femoral strength by providing a thorough description of the local bone mechanical response.

Keywords: Finite element; Human femur; Experimental validation; Bone strength
Links

DOI: 10.1016/j.jbiomech.2016.02.032

PubMed: 26944687

WoS: 000374071100025
History

Accepted: 2016-02-12

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Cited By (13)

Year	Entry
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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.
2017	Chen Y, Dall’Ara E, Sales E, Manda K, Wallace R, Pankaj P, Viceconti M. Micro-CT based finite element models of cancellous bone predict accurately displacement once the boundary condition is well replicated: a validation study. J Mech Behav Biomed Mater. January 2017;65:644-651.
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