No data available.
Please log in to see this content.
You have no subscription access to this content.
No metrics data to plot.
The attempt to load metrics for this article has failed.
The attempt to plot a graph for these metrics has failed.
The effect of voxel size on high-resolution peripheral computed tomography measurements of trabecular and cortical bone microstructure
1. NIH Consensus Development Panel on Osteoporosis Prevention, Diagnosis, and Therapy, “Osteoporosis prevention, diagnosis, and therapy,” J. Am.MA 285, 785–795 (2001).
2. Y. Jiang, J. Zhao, E. Y. Liao, R. C. Dai, X. P. Wu, and H. K. Genant, “Application of micro-CT assessment of 3-D bone microstructure in preclinical and clinical studies,” J. Bone Miner. Metab. 23 Suppl, 122–131 (2005).
4. A. Laib, H. J. Hauselmann, and P. Ruegsegger, “In vivo high resolution 3D-QCT of the human forearm,” Technol. Health Care 6, 329–337 (1998).
5. A. Laib and P. Ruegsegger, “Calibration of trabecular bone structure measurements of in vivo three-dimensional peripheral quantitative computed tomography with 28-microm-resolution microcomputed tomography,” Bone 24, 35–39 (1999).
6. A. J. Burghardt, G. J. Kazakia, and S. Majumdar, “A local adaptive threshold strategy for high resolution peripheral quantitative computed tomography of trabecular bone,” Ann. Biomed. Eng. 35, 1678–1686 (2007).
7. A. J. Burghardt, G. J. Kazakia, S. Ramachandran, T. M. Link, and S. Majumdar, “Age- and gender-related differences in the geometric properties and biomechanical significance of intracortical porosity in the distal radius and tibia,” J. Bone Miner. Res. 25, 983–993 (2010).
8. A. J. Burghardt, H. R. Buie, A. Laib, S. Majumdar, and S. K. Boyd, “Reproducibility of direct quantitative measures of cortical bone microarchitecture of the distal radius and tibia by HR-pQCT,” Bone 47, 519–528 (2010).
9. H. R. Buie, G. M. Campbell, R. J. Klinck, J. A. MacNeil, and S. K. Boyd, “Automatic segmentation of cortical and trabecular compartments based on a dual threshold technique for in vivo micro-CT bone analysis,” Bone 41, 505–515 (2007).
10. T. Hildebrand, A. Laib, R. Muller, J. Dequeker, and P. Ruegsegger, “Direct three-dimensional morphometric analysis of human cancellous bone: microstructural data from spine, femur, iliac crest, and calcaneus,” J. Bone Miner. Res. 14, 1167–1174 (1999).
11. K. K. Nishiyama, H. M. Macdonald, H. R. Buie, D. A. Hanley, and S. K. Boyd, “Postmenopausal women with osteopenia have higher cortical porosity and thinner cortices at the distal radius and tibia than women with normal aBMD: An in vivo HR-pQCT study,” J. Bone Miner. Res. 25, 882–890 (2010).
12. X. S. Liu, X. H. Zhang, K. K. Sekhon, M. F. Adams, D. J. McMahon, J. P. Bilezikian, E. Shane, and X. E. Guo, “High-resolution peripheral quantitative computed tomography can assess microstructural and mechanical properties of human distal tibial bone,” J. Bone Miner. Res. 25, 746–756 (2010).
14. G. J. Kazakia, B. Hyun, A. J. Burghardt, R. Krug, D. C. Newitt, A. E. de Papp, T. M. Link, and S. Majumdar, “In vivo determination of bone structure in postmenopausal women: A comparison of HR-pQCT and high-field MR imaging,” J. Bone Miner. Res. 23, 463–474 (2008).
15. A. L. Kwan, J. M. Boone, K. Yang, and S. Y. Huang, “Evaluation of the spatial resolution characteristics of a cone-beam breast CT scanner,” Med. Phys. 34, 275–281 (2007).
17. A. M. Parfitt, C. H. E. Mathews, A. R. Villanueva, M. Kleerekoper, B. Frame, and D. S. Rao, “Relationships between surface, volume, and thickness of iliac trabecular bone in aging and in osteoporosis—Implications for the microanatomic and cellular mechanisms of bone loss,” J. Clin. Invest. 72, 1396–1409 (1983).
19. P. K. Saha, Y. Xu, H. Duan, A. Heiner, and G. Y. Liang, “Volumetric topological analysis: A novel approach for trabecular bone classification on the continuum between plates and rods,” IEEE Trans. Med. Imaging 29, 1821–1838 (2010).
20. X. S. Liu, P. Sajda, P. K. Saha, F. W. Wehrli, G. Bevill, T. M. Keaveny, and X. E. Guo, “Complete volumetric decomposition of individual trabecular plates and rods and its morphological correlations with anisotropic elastic moduli in human trabecular bone,” J. Bone Miner. Res. 23, 223–235 (2008).
22. D. Cooper, A. Turinsky, C. Sensen, and B. Hallgrimsson, “Effect of voxel size on 3D micro-CT analysis of cortical bone porosity,” Calcif. Tissue Int. 80, 211–219 (2007).
23. N. J. Wachter, P. Augat, G. D. Krischak, M. Mentzel, L. Kinzl, and L. Claes, “Prediction of cortical bone porosity in vitro by microcomputed tomography,” Calcif. Tissue Int. 68, 38–42 (2001).
24. K. Raum, I. Leguerney, F. Chandelier, M. Talmant, A. Saied, F. Peyrin, and P. Laugier, “Site-matched assessment of structural and tissue properties of cortical bone using scanning acoustic microscopy and synchrotron radiation mu CT,” Phys. Med. Biol. 51, 733–746 (2006).
25. R. J. Fajardo, E. Cory, N. D. Patel, A. Nazarian, A. Laib, R. K. Manoharan, J. E. Schmitz, J. M. Desilva, L. M. Maclatchy, B. D. Snyder, and M. L. Bouxsein, “Specimen size and porosity can introduce error into muCT-based tissue mineral density measurements,” Bone 44, 176–184 (2009).
26. K. Sekhon, G. J. Kazakia, A. J. Burghardt, B. Hermannsson, and S. Majumdar, “Accuracy of volumetric bone mineral density measurement in high-resolution peripheral quantitative computed tomography,” Bone 45, 473–479 (2009).
27. J. B. Pialat, A. J. Burghardt, M. Sode, T. M. Link, and S. Majumdar, “Visual grading of motion induced image degradation in high resolution peripheral computed tomography: Impact of image quality on measures of bone density and micro-architecture,” Bone 50, 111–118 (2011).
28. S. Boutroy, M. L. Bouxsein, F. Munoz, and P. D. Delmas, “In vivo assessment of trabecular bone microarchitecture by high-resolution peripheral quantitative computed tomography,” J. Clin. Endocrinol. Metab. 90, 6508–6515 (2005).
Article metrics loading...
Full text loading...
Most read this month