Development of a 50th percentile female femur model

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Schubert, A.¹; Erlinger, N.¹; Leo, C.¹; Iraeus, J.²; John, J.²; Klug, C.¹

Development of a 50th percentile female femur model

Proceedings of the 2021 International IRCOBI Conference on the Biomechanics of Injury

Affiliations

¹Vehicle Safety Institute at Graz University of Technology, Austria

²Chalmers University of Technology, Gothenburg, Sweden
Abstract and keywords

This study illustrates the development of a generic femur model representative of a 50th percentile female in terms of geometry, material data, and injury risk curve.

A female femur model consisting of 14,520 hexahedral elements was developed, calibrated, and validated. The outer shape and cortical thickness of the femur shaft were adjusted to meet a regression model reported in literature for an average 50 year old female. For the proximal femur, five computed tomography scans were morphed to the target geometry and the mean thickness of the cortical bone was calculated. Material properties for the cortical bone were calculated from experimental data for both tension and compression loading. To validate the proximal femur mode and calibrate an injury risk curve, 15 dynamic drop-tower tests were reproduced. For the validation of the femur shaft, 16 bending tests were simulated. The characteristics of the experimental curves were generally well captured for experiments with normal bone density. Maximum principal strains and 99th percentile strains of the cortical bone at the time of fracture were used to develop risk curves for fractures of the proximal femur and the femur shaft, which were identified as the most relevant femoral injuries in an accident analysis. The model as well as the post-processing scripts are openly available and can be applied or further enhanced by other researchers.

Keywords: Female; femur; human body model; injury risk; sex-specific; VIVA+
Links

URL: http://www.ircobi.org/wordpress/downloads/irc21/pdf-files/2138.pdf

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