Journal article
Computed Tomography–Based Stiffness Measures of Trabecular Bone Microstructure: Cadaveric Validation and In Vivo Application
JBMR plus, Vol.6(6), p.n/a
06/2022
DOI: 10.1002/jbm4.10627
PMCID: PMC9189917
PMID: 35720662
Abstract
ABSTRACT
Osteoporosis causes bone fragility and elevates fracture risk. Applications of finite element (FE) analysis (FEA) for assessment of trabecular bone (Tb) microstructural strength at whole‐body computed tomography (CT) imaging are limited due to challenges with Tb microstructural segmentation. We present a nonlinear FEA method for distal tibia CT scans evading binary segmentation of Tb microstructure, while accounting for bone microstructural distribution. First, the tibial axis in a CT scan was aligned with the FE loading axis. FE cubic mesh elements were modeled using image voxels, and CT intensity values were calibrated to ash density defining mechanical properties at individual elements. For FEA of an upright volume of interest (VOI), the bottom surface was fixed, and a constant displacement was applied at each vertex on the top surface simulating different loading conditions. The method was implemented and optimized using the ANSYS software. CT‐derived computational modulus values were repeat scan reproducible (intraclass correlation coefficient [ICC] ≥ 0.97) and highly correlated (r ≥ 0.86) with the micro‐CT (μCT)‐derived values. FEA‐derived von Mises stresses over the segmented Tb microregion were significantly higher (p < 1 × 10−11) than that over the marrow space. In vivo results showed that both shear and compressive modulus for males were higher (p < 0.01) than for females. Effect sizes for different modulus measures between males and females were moderate‐to‐high (≥0.55) and reduced to small‐to‐negligible (<0.40) when adjusted for pure lean mass. Among body size and composition attributes, pure lean mass and height showed highest (r ∈ [0.45 0.56]) and lowest (r ∈ [0.25 0.39]) linear correlation, respectively, with FE‐derived modulus measures. In summary, CT‐based nonlinear FEA provides an effective surrogate measure of Tb microstructural stiffness, and the relaxation of binary segmentation will extend the scope for FEA in human studies using in vivo imaging at relatively low‐resolution. © 2022 The Authors. JBMR Plus published by Wiley Periodicals LLC on behalf of American Society for Bone and Mineral Research.
Details
- Title: Subtitle
- Computed Tomography–Based Stiffness Measures of Trabecular Bone Microstructure: Cadaveric Validation and In Vivo Application
- Creators
- Indranil Guha - University of IowaXialiou Zhang - University of IowaChamith S. Rajapakse - University of PennsylvaniaElena M. Letuchy - University of IowaGregory Chang - New York UniversityKathleen F. Janz - University of IowaJames C. Torner - University of IowaSteven M. Levy - University of IowaPunam K. Saha - University of Iowa
- Resource Type
- Journal article
- Publication Details
- JBMR plus, Vol.6(6), p.n/a
- DOI
- 10.1002/jbm4.10627
- PMID
- 35720662
- PMCID
- PMC9189917
- NLM abbreviation
- JBMR Plus
- ISSN
- 2473-4039
- eISSN
- 2473-4039
- Publisher
- John Wiley & Sons, Inc
- Number of pages
- 13
- Grant note
- National Institute of Dental and Craniofacial Research (R01‐DE09551; R01‐DE12101) National Heart, Lung, and Blood Institute (R01‐HL142042) Wright;Bush‐Shreves Endowed Professor Fund at the University of Iowa General Clinical Research Program Grant (M01‐RR00059) Clinical and Translational Science Award (UL1‐RR024979)
- Language
- English
- Date published
- 06/2022
- Academic Unit
- Preventive and Community Dentistry; Neurology; Radiology; Electrical and Computer Engineering; Epidemiology; Injury Prevention Research Center; Neurosurgery; Health, Sport, and Human Physiology
- Record Identifier
- 9984266621602771
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