Development of a balanced experimental-computational approach to understanding the mechanics of proximal femur fractures

Helgason, B.; Gilchrist, Seth; Ariza, O.; Chak, J. D.; Zheng, G.; Widmer, R. P.; Ferguson, S. J.; Guy, P.; Cripton, Peter A.

doi:10.1016/j.medengphy.2014.02.019

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Development of a balanced experimental-computational approach to understanding the mechanics of proximal femur fractures
Citation	Helgason B, Gilchrist S, Ariza O, Chak JD, Zheng G, Widmer RP, Ferguson SJ, Guy P, Cripton PA. Med. Eng. Phys. 2014; 36(6): 793-799.
Affiliation	Orthopaedic and Injury Biomechanics Group, University of British Columbia, Vancouver, Canada; Centre for Hip Health and Mobility, University of British Columbia, Vancouver, Canada; Department of Mechanical Engineering, University of British Columbia, Vancouver, Canada; Department of Orthopedics, University of British Columbia, Vancouver, Canada.
Copyright	(Copyright © 2014, Institute of Physics and Engineering in Medicine, Publisher Elsevier Publishing)
DOI	10.1016/j.medengphy.2014.02.019
PMID	24629624
Abstract	The majority of people who sustain hip fractures after a fall to the side would not have been identified using current screening techniques such as areal bone mineral density. Identifying them, however, is essential so that appropriate pharmacological or lifestyle interventions can be implemented. A protocol, demonstrated on a single specimen, is introduced, comprising the following components; in vitro biofidelic drop tower testing of a proximal femur; high-speed image analysis through digital image correlation; detailed accounting of the energy present during the drop tower test; organ level finite element simulations of the drop tower test; micro level finite element simulations of critical volumes of interest in the trabecular bone. Fracture in the femoral specimen initiated in the superior part of the neck. Measured fracture load was 3760N, compared to 4871N predicted based on the finite element analysis. Digital image correlation showed compressive surface strains as high as 7.1% prior to fracture. Voxel level results were consistent with high-speed video data and helped identify hidden local structural weaknesses. We found using a drop tower test protocol that a femoral neck fracture can be created with a fall velocity and energy representative of a sideways fall from standing. Additionally, we found that the nested explicit finite element method used allowed us to identify local structural weaknesses associated with femur fracture initiation. Language: en