Strain rate dependency of bovine trabecular bone under impact loading at sideways fall velocity

There is currently a knowledge gap in scientific literature concerning the strain rate dependent properties of trabecular bone at intermediate strain rates. Meanwhile, strain rates between 10 and 200/s have been observed in previous dynamic finite element models of the proximal femur loaded at reali...

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Bibliographic Details
Published in:Journal of biomechanics 2018-06, Vol.75, p.46-52
Main Authors: Enns-Bray, William S., Ferguson, Stephen J., Helgason, Benedikt
Format: Article
Language:English
Subjects:
Accidental Falls
Animals
Anisotropy
Bone marrow
Bone strength
Bulk density
Cancellous bone
Cancellous Bone - physiology
Cattle
Compression
Compression tests
Computer simulation
Dependence
Drop tower
Drop towers
Elastic Modulus
Experiment
Experiments
Femur
Femur - diagnostic imaging
Femur - physiology
Finite Element Analysis
Finite element method
Hip
Hip - physiology
Impact
Impact loads
Impact tests
Kinetic energy
Material properties
Mathematical models
Mechanical loading
Mechanical Phenomena
Mechanical properties
Mechanics
Modulus of elasticity
Morphology
Piezoelectricity
Porous materials
Regression analysis
Regression models
Strain rate
Stress, Mechanical
Tensile stress
Tibia - diagnostic imaging
Tibia - physiology
Trabecular bone
Video compression
X-Ray Microtomography
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Summary:There is currently a knowledge gap in scientific literature concerning the strain rate dependent properties of trabecular bone at intermediate strain rates. Meanwhile, strain rates between 10 and 200/s have been observed in previous dynamic finite element models of the proximal femur loaded at realistic sideways fall speeds. This study aimed to quantify the effect of strain rate (ε̇) on modulus of elasticity (E), ultimate stress (σu), failure energy (Uf), and minimum stress (σm) of trabecular bone in order to improve the biofidelity of material properties used in dynamic simulations of sideways fall loading on the hip. Cylindrical cores of trabecular bone (D = 8 mm, Lgauge = 16 mm, n = 34) from bovine proximal tibiae and distal femurs were scanned in µCT (10 µm), quantifying apparent density (ρapp) and degree of anisotropy (DA), and subsequently impacted within a miniature drop tower. Force of impact was measured using a piezoelectric load cell (400 kHz), while displacement during compression was measured from high speed video (50,000 frames/s). Four groups, with similar density distributions, were loaded at different impact velocities (0.84, 1.33, 1.75, and 2.16 m/s) with constant kinetic energy (0.4 J) by adjusting the impact mass. The mean strain rates of each group were significantly different (p 
ISSN:0021-9290
1873-2380
DOI:10.1016/j.jbiomech.2018.04.042