Simplified boundary conditions alter cortical-trabecular load sharing at the distal radius; A multiscale finite element analysis

High-resolution peripheral quantitative computed tomography (HR-pQCT) derived micro-finite element (FE) modeling is used to evaluate mechanical behavior at the distal radius microstructure. However, these analyses typically simulate non-physiologic simplified platen-compression boundary conditions o...

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Bibliographic Details
Published in:Journal of biomechanics 2018-01, Vol.66, p.180-185
Main Authors: Johnson, Joshua E., Troy, Karen L.
Format: Article
Language:English
Subjects:
Aged
Aged, 80 and over
Boundary conditions
Cadavers
Cancellous Bone - physiology
Compartments
Compression
Compressive strength
Computed tomography
Computer simulation
Cooperation
Cortical Bone - physiology
Cortical-trabecular microstructure
Data compression
Female
Finite Element Analysis
Finite element method
Forearm
Forearm - physiology
High resolution
Humans
Image acquisition
Image resolution
Load
Load sharing
Loads (forces)
Male
Mathematical analysis
Mathematical models
Mechanical properties
Microstructure
Middle Aged
Models, Biological
Multiscale
Multiscale analysis
Osteoporosis
Radius
Radius - diagnostic imaging
Radius - physiology
Simulation
Stress, Mechanical
Tomography
Tomography, X-Ray Computed - methods
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Description
Summary:High-resolution peripheral quantitative computed tomography (HR-pQCT) derived micro-finite element (FE) modeling is used to evaluate mechanical behavior at the distal radius microstructure. However, these analyses typically simulate non-physiologic simplified platen-compression boundary conditions on a small section of the distal radius. Cortical and trabecular regions contribute uniquely to distal radius mechanical behavior, and various factors affect these regions distinctly. Generalized strength predictions from standardized platen-compression analyses may not adequately capture region specific responses in bone. Our goal was to compare load sharing within the cortical-trabecular compartments between the standardized platen-compression BC simulations, and physiologic BC simulations using a validated multiscale approach. Clinical- and high-resolution images were acquired from nine cadaveric forearm specimens using an HR-pQCT scanner. Multiscale FE models simulating physiologic BCs, and micro-FE only models simulating platen-compression BCs were created for each specimen. Cortical and trabecular loads (N) along the length of the distal radius micro-FE section were compared between BCs using correlations. Principal strain distributions were also compared quantitatively. Cortical and trabecular loads from the platen-compression BC simulations were strongly correlated to the physiologic BC simulations. However, a 30% difference in cortical loads distally, and a 53% difference in trabecular loads proximally was observed under platen BC simulations. Also, distribution of principal strains was clearly different. Our data indicated that platen-compression BC simulations alter cortical-trabecular load sharing. Therefore, results from these analyses should be interpreted in the appropriate mechanical context for clinical evaluations of normal and pathologic mechanical behavior at the distal radius.
ISSN:0021-9290
1873-2380
DOI:10.1016/j.jbiomech.2017.10.036