Quantifying trabecular bone material anisotropy and orientation using low resolution clinical CT images: A feasibility study. Issue 9 (September 2016)
- Record Type:
- Journal Article
- Title:
- Quantifying trabecular bone material anisotropy and orientation using low resolution clinical CT images: A feasibility study. Issue 9 (September 2016)
- Main Title:
- Quantifying trabecular bone material anisotropy and orientation using low resolution clinical CT images: A feasibility study
- Authors:
- Nazemi, S. Majid
Cooper, David M.L.
Johnston, James D. - Abstract:
- Highlights: Quantified fabric using grey-level structure tensor in upsized micro-CT images. Derived anisotropic stiffness entries and main orientation using micro finite element. Fabric explained 94% of the variance in anisotropic stiffness entries. Fabric predicted main orientation with 4.8° mean error. It is possible to estimate anisotropy in clinical CT images. Abstract: Accounting for spatial variation of trabecular material anisotropy and orientation can improve the accuracy of quantitative computed tomography-based finite element (FE) modeling of bone. The objective of this study was to investigate the feasibility of quantifying trabecular material anisotropy and orientation using clinical computed tomography (CT). Forty four cubic volumes of interest were obtained from micro-CT images of the human radius. Micro-FE modeling was performed on the samples to obtain orthotropic stiffness entries as well as trabecular orientation. Simulated computed tomography images (0.32, 0.37, and 0.5 mm isotropic voxel sizes) were created by resampling micro-CT images with added image noise. The gray-level structure tensor was used to derive fabric eigenvalues and eigenvectors in simulated CT images. For 'best case' comparison purposes, Mean Intercept Length was used to define fabric from micro-CT images. Regression was used in combination with eigenvalues, imaged density and FE to inversely derive the constants used in Cowin and Zysset–Curnier fabric-elasticity equations, and forHighlights: Quantified fabric using grey-level structure tensor in upsized micro-CT images. Derived anisotropic stiffness entries and main orientation using micro finite element. Fabric explained 94% of the variance in anisotropic stiffness entries. Fabric predicted main orientation with 4.8° mean error. It is possible to estimate anisotropy in clinical CT images. Abstract: Accounting for spatial variation of trabecular material anisotropy and orientation can improve the accuracy of quantitative computed tomography-based finite element (FE) modeling of bone. The objective of this study was to investigate the feasibility of quantifying trabecular material anisotropy and orientation using clinical computed tomography (CT). Forty four cubic volumes of interest were obtained from micro-CT images of the human radius. Micro-FE modeling was performed on the samples to obtain orthotropic stiffness entries as well as trabecular orientation. Simulated computed tomography images (0.32, 0.37, and 0.5 mm isotropic voxel sizes) were created by resampling micro-CT images with added image noise. The gray-level structure tensor was used to derive fabric eigenvalues and eigenvectors in simulated CT images. For 'best case' comparison purposes, Mean Intercept Length was used to define fabric from micro-CT images. Regression was used in combination with eigenvalues, imaged density and FE to inversely derive the constants used in Cowin and Zysset–Curnier fabric-elasticity equations, and for comparing image derived fabric-elasticity stiffness entries to those obtained using micro-FE. Image derived eigenvectors (which indicated trabecular orientation) were then compared to orientation derived using micro-FE. When using clinically available voxel sizes, gray-level structure tensor derived fabric combined with Cowin's equations was able to explain 94–97% of the variance in orthotropic stiffness entries while Zysset–Curnier equations explained 82–88% of the variance in stiffness. Image derived orientation deviated by 4.4–10.8° from micro-FE derived orientation. Our results indicate potential to account for spatial variation of trabecular material anisotropy and orientation in subject-specific finite element modeling of bone using clinically available CT. … (more)
- Is Part Of:
- Medical engineering & physics. Volume 38:Issue 9(2016:Sep.)
- Journal:
- Medical engineering & physics
- Issue:
- Volume 38:Issue 9(2016:Sep.)
- Issue Display:
- Volume 38, Issue 9 (2016)
- Year:
- 2016
- Volume:
- 38
- Issue:
- 9
- Issue Sort Value:
- 2016-0038-0009-0000
- Page Start:
- 978
- Page End:
- 987
- Publication Date:
- 2016-09
- Subjects:
- Trabecular bone main orientation -- Trabecular bone anisotropic elastic properties -- Fabric-elasticity equations -- Clinical CT images
Biomedical engineering -- Periodicals
Biomedical Engineering -- Periodicals
Physics -- Periodicals
Génie biomédical -- Périodiques
Biomedical engineering
Electronic journals
Periodicals
610.28 - Journal URLs:
- http://www.medengphys.com ↗
http://www.sciencedirect.com/science/journal/13504533 ↗
http://www.clinicalkey.com/dura/browse/journalIssue/13504533 ↗
http://www.clinicalkey.com.au/dura/browse/journalIssue/13504533 ↗
http://www.elsevier.com/journals ↗ - DOI:
- 10.1016/j.medengphy.2016.06.011 ↗
- Languages:
- English
- ISSNs:
- 1350-4533
- Deposit Type:
- Legaldeposit
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- Available online (eLD content is only available in our Reading Rooms) ↗
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- British Library DSC - 5527.323000
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