A new method for laboratory testing of human proximal femora in conditions simulating a sideways fall was developed. Additionally, in order to analyze the strain state in future cadaveric tests, digital image correlation (DIC) was validated as a tool for strain field measurement on the bone of the femoral neck. A fall simulator which included models for the body mass, combined lateral femur and pelvis mass, pelvis stiffness, and trochanteric soft tissue was designed. The characteristics of each element were derived and developed based on human data from the literature. The simulator was verified by loading a state-of-the-art surrogate femur and comparing the resulting force-time trace to published, human volunteer experiments. To validate the DIC, 20 human proximal femora were prepared with a strain rosette and speckle paint pattern, and loaded to 50% of their predicted failure load at a low compression rate. Strain rosettes were taken as the gold standard, and minimum principal strains from the DIC and the rosettes were compared using descriptive statistics. The initial slope of the force-time curve obtained in the fall simulator matched published human volunteer data, with local peaks superimposed in the model due to internal vibrations of the spring used to model the pelvis stiffness. Global force magnitude and temporal characteristics were within 2% of published volunteer experiments. The DIC minimum principal strains were found to be accurate to . These tools will allow more biofidelic laboratory simulation of falls to the side, and more detailed analysis of proximal femur failure mechanisms using human cadaver specimens.
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December 2013
Research-Article
Development of an Inertia-Driven Model of Sideways Fall for Detailed Study of Femur Fracture Mechanics
Seth Gilchrist,
Seth Gilchrist
Department of Mechanical Engineering,
e-mail: seth@mech.ubc.ca
University of British Columbia
,Vancouver, BC V6T-1Z4
, Canada
e-mail: seth@mech.ubc.ca
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Pierre Guy,
Pierre Guy
Department of Orthopeadics,
e-mail: pierre.guy@ubc.ca
University of British Columbia
,Vancouver, BC V5Z-1M9
, Canada
e-mail: pierre.guy@ubc.ca
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Peter A Cripton
Peter A Cripton
Department of Mechanical Engineering,
e-mail: cripton@mech.ubc.ca
University of British Columbia
,Vancouver, BC V6T-1Z4
, Canada
e-mail: cripton@mech.ubc.ca
Search for other works by this author on:
Seth Gilchrist
Department of Mechanical Engineering,
e-mail: seth@mech.ubc.ca
University of British Columbia
,Vancouver, BC V6T-1Z4
, Canada
e-mail: seth@mech.ubc.ca
Pierre Guy
Department of Orthopeadics,
e-mail: pierre.guy@ubc.ca
University of British Columbia
,Vancouver, BC V5Z-1M9
, Canada
e-mail: pierre.guy@ubc.ca
Peter A Cripton
Department of Mechanical Engineering,
e-mail: cripton@mech.ubc.ca
University of British Columbia
,Vancouver, BC V6T-1Z4
, Canada
e-mail: cripton@mech.ubc.ca
Contributed by the Bioengineering Division of ASME for publication in the JOURNAL OF BIOMECHANICAL ENGINEERING. Manuscript received April 10, 2013; final manuscript received August 9, 2013; accepted manuscript posted September 12, 2013; published online October 4, 2013. Assoc. Editor: Tammy Haut Donahue.
J Biomech Eng. Dec 2013, 135(12): 121001 (8 pages)
Published Online: October 4, 2013
Article history
Received:
April 10, 2013
Revision Received:
August 9, 2013
Accepted:
September 12, 2013
Citation
Gilchrist, S., Guy, P., and Cripton, P. A. (October 4, 2013). "Development of an Inertia-Driven Model of Sideways Fall for Detailed Study of Femur Fracture Mechanics." ASME. J Biomech Eng. December 2013; 135(12): 121001. https://doi.org/10.1115/1.4025390
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