A computational assessment of the independent contribution of changes in canine trabecular bone volume fraction and microarchitecture to increased bone strength with suppression of bone turnover

wbldb

Eswaran, Senthil K.¹; Allen, Matthew R.²; Burr, David B.²; Keaveny, Tony M.^1,3

A computational assessment of the independent contribution of changes in canine trabecular bone volume fraction and microarchitecture to increased bone strength with suppression of bone turnover

J Biomech. 2007;40(15):3424-3431

©2007 Elsevier Ltd. All rights reserved.

Affiliations

¹Orthopaedic Biomechanics Laboratory, Department of Mechanical Engineering, University of California, Berkeley, CA 94720, USA

²Department of Anatomy and Cell Biology, Indiana University School of Medicine, Indianapolis, IN 46202, USA

³Department of Bioengineering, University of California, Berkeley, CA 94720, USA
Abstract and keywords

This study addressed the effects of changes in trabecular microarchitecture induced by suppressed bone turnover—including changes to the remodeling space—on the trabecular bone strength–volume fraction characteristics independent of changes in tissue material properties. Twenty female beagle dogs, aged 1–2 years, were treated daily with either oral saline (n=10 control) or high doses of oral risedronate (0.5 mg/kg/day, n=10 suppressed) for a period of 1 year, the latter designed (and confirmed) to substantially suppress bone turnover. High-resolution micro-CT-based finite element models (18-μm voxel size) of canine trabecular bone cores (n=2 per vertebral body) extracted from the T-10 vertebrae were analyzed in both compressive and torsional loading cases. The same tissue-level material properties were used in all models, thus providing measures of tissue-normalized strength due only to changes in the microarchitecture. Suppressed bone turnover resulted in more plate-like architecture with a thicker and more dense trabecular structure, but the relationship between the microarchitectural parameters and volume fraction was unaltered (p>0.05). Though the suppressed group had a greater tissue-normalized strength as compared to the control group (p<0.001) for both compressive and torsional loading, the relationship between tissue-normalized strength and volume fraction was not significantly altered for compression (p>0.13) or torsion (p>0.09). In this high-density, non-osteoporotic animal model, the increases in tissue-normalized strength seen with suppression of bone turnover were entirely commensurate with increases in bone volume fraction and thus, no evidence of microarchitecture-related or "stress-riser" effects which may disproportionately affect strength were found.

Keywords: Trabecular bone; Bone strength; Suppressed bone turnover; Antiresorptive treatment; Microarchitecture; Bone quality; Stress risers
Links

DOI: 10.1016/j.jbiomech.2007.05.013

PubMed: 17618634

WoS: 000251342800016
History

Accepted: 2007-05-15

Cited Works (29)

Year	Entry
1985	Gibson LJ. The mechanical behaviour of cancellous bone. J Biomech. 1985;18(5):317-328.
2000	Boivin GY, Chavassieux PM, Santora AC, Yates J, Meunier PJ. Alendronate increases bone strength by increasing the mean degree of mineralization of bone tissue in osteoporotic women. Bone. November 2000;27(5):687-694.
2003	Burr DB, Miller L, Grynpas M, Li J, Boyde A, Mashiba T, Hirano T, Johnston CC. Tissue mineralization is increased following 1-year treatment with high doses of bisphosphonates in dogs. Bone. December 2003;33(6):960-969.
2006	Hernandez CJ, Keaveny TM. A biomechanical perspective on bone quality. Bone. December 2006;39(6):1173-1181.
2004	Day JS, Ding M, Bednarz P, van der Linden JC, Mashiba T, Hirano T, Johnston CC, Burr DB, Hvid I, Sumner DR, Weinans H. Bisphosphonate treatment affects trabecular bone apparent modulus through micro-architecture rather than matrix properties. J Orthop Res. May 2004;22(3):465-471.
2002	Lill CA, Gerlach UV, Eckhardt C, Goldhahn J, Schneider E. Bone changes due to glucocorticoid application in an ovariectomized animal model for fracture treatment in osteoporosis. Osteoporos Int. May 2002;13(5):407-414.
2002	Parfitt AM. High bone turnover is intrinsically harmful: two paths to a similar conclusion: the Parfitt view. J Bone Miner Res. August 2002;17(8):1558-1559.
2001	Roschger P, Rinnerthaler S, Yates J, Rodan GA, Fratzl P, Klaushofer K. Alendronate increases degree and uniformity of mineralization in cancellous bone and decreases the porosity in cortical bone of osteoporotic women. Bone. August 2001;29(2):185-191.
1996	Ford CM, Keaveny TM. The dependence of shear failure properties of trabecular bone on apparent density and trabecular orientation. J Biomech. 1996;29(10):1309-1317.
2005	Borah B, Ritman EL, Dufresne TE, Jorgensen SM, Liu S, Sacha J, Phipps RJ, Turner RT. The effect of risedronate on bone mineralization as measured by micro-computed tomography with synchrotron radiation: correlation to histomorphometric indices of turnover. Bone. July 2005;37(1):1-9.
2004	Borah B, Dufresne TE, Chmielewski PA, Johnson TD, Chines A, Manhart MD. Risedronate preserves bone architecture in postmenopausal women with osteoporosis as measured by three-dimensional microcomputed tomography. Bone. April 2004;34(4):736-746.
1999	Fenech CM, Keaveny TM. A cellular solid criterion for predicting the axial-shear failure properties of bovine trabecular bone. J Biomech Eng. August 1999;121(4):414-422.
1999	Ulrich D, van Rietbergen B, Laib A, Rüegsegger P. The ability of three-dimensional structural indices to reflect mechanical aspects of trabecular bone. Bone. 1999;25(1):55-60.
2005	Ito M, Nishida A, Aoyagi K, Uetani M, Hayashi K, Kawase M. Effects of risedronate on trabecular microstructure and biomechanical properties in ovariectomized rat tibia. Osteoporos Int. 2005;16(9):1042-1048.
2006	Allen MR, Iwata K, Phipps R, Burr DB. Alterations in canine vertebral bone turnover, microdamage accumulation, and biomechanical properties following 1-year treatment with clinical treatment doses of risedronate or alendronate. Bone. October 2006;39(4):872-879.
2002	Guo XE, Kim CH. Mechanical consequence of trabecular bone loss and its treatment: a three-dimensional model simulation. Bone. February 2002;30(2):404-411.
2003	Ding M, Day JS, Burr DB, Mashiba T, Hirano T, Weinans H, Sumner DR, Hvid I. Canine cancellous bone microarchitecture after one year of high-dose bisphosphonates. Calcif Tiss Int. June 2003;72(6):737-744.
2002	Cummings SR, Karpf DB, Harris F, Genant HK, Ensrud K, LaCroix AZ, Black DM. Improvement in spine bone density and reduction in risk of vertebral fractures during treatment with antiresorptive drugs. Am J Med. March 2002;112(4):281-289.
2001	Mashiba T, Turner CH, Hirano T, Forwood MR, Johnston CC, Burr DB. Effects of suppressed bone turnover by bisphosphonates on microdamage accumulation and biomechanical properties in clinically relevant skeletal sites in beagles. Bone. May 2001;28(5):524-531.
2000	Delmas PD. How does antiresorptive therapy decrease the risk of fracture in women with osteoporosis? Bone. July 2000;27(1):1-3.
2002	Niebur GL, Feldstein MJ, Keaveny TM. Biaxial failure behavior of bovine tibial trabecular bone. J Biomech Eng. December 2002;124(6):699-705.
1988	Harrigan TP, Jasty M, Mann RW, Harris WH. Limitations of the continuum assumption in cancellous bone. J Biomech. 1988;21(4):269-275.
2006	Hernandez CJ, Gupta A, Keaveny TM. A biomechanical analysis of the effects of resorption cavities on cancellous bone strength. J Bone Miner Res. August 2006;21(8):1248-1255.
2006	Allen MR, Iwata K, Sato M, Burr DB. Raloxifene enhances vertebral mechanical properties independent of bone density. Bone. November 2006;39(5):1130-1135.
2004	Adams MF, Bayraktar HH, Keaveny TM, Papadopoulos P. Ultrascalable implicit finite element analyses in solid mechanics with over a half a billion degrees of freedom. In: SC '04: Proceedings of the 2004 ACM/IEEE Conference on Supercomputing. November 6-12, 2004; Pittsburgh, PA.
2006	Bevill G, Eswaran SK, Gupta A, Papadopoulos P, Keaveny TM. Influence of bone volume fraction and architecture on computed large-deformation failure mechanisms in human trabecular bone. Bone. December 2006;39(6):1218-1225.
1999	Hildebrand T, Laib A, Müller R, Dequeker J, Rüegsegger P. Direct three-dimensional morphometric analysis of human cancellous bone: microstructural data from spine, femur, iliac crest, and calcaneus. J Bone Miner Res. July 1999;14(7):1167-1174.
2003	Stölken JS, Kinney JH. On the importance of geometric nonlinearity in finite-element simulations of trabecular bone failure. Bone. October 2003;33(4):494-504.
2002	Riggs BL, Melton LJ III. Bone turnover matters: the raloxifene treatment paradox of dramatic decreases in vertebral fractures without commensurate increases in bone density. J Bone Miner Res. January 2002;17(1):11-14.

Cited By (16)

Year	Entry
2010	Harrison NM, McHugh PE. Comparison of trabecular bone behavior in core and whole bone samples using high-resolution modeling of a vertebral body. Biomech Model Mechanobiol. 2010;9(4):469-480.
2009	Bevill G, Keaveny TM. Trabecular bone strength predictions using finite element analysis of micro-scale images at limited spatial resolution. Bone. April 2009;44(4):579-584.
2009	Tkachenko EV, Slyfield CR, Tomlinson RE, Daggett JR, Wilson DL, Hernandez CJ. Voxel size and measures of individual resorption cavities in three-dimensional images of cancellous bone. Bone. September 2009;45(3):487-492.
2009	Eswaran SK, Bevill G, Nagarathnam P, Allen MR, Burr DB, Keaveny TM. Effects of suppression of bone turnover on cortical and trabecular load sharing in the canine vertebral body. J Biomech. March 11, 2009;42(4):517-523.
2010	Tassani S, Öhman C, Baleani M, Baruffaldi F, Viceconti M. Anisotropy and inhomogeneity of the trabecular structure can describe the mechanical strength of osteoarthritic cancellous bone. J Biomech. April 19, 2010;43(6):1160-1166.
2010	Kadir MRA, Syahrom A, Öchsner A. Finite element analysis of idealised unit cell cancellous structure based on morphological indices of cancellous bone. Med Biol Eng Comput. May 2010;48(5):497-505.
2011	Cotter MM. Gross Morphology, Microarchitecture, Strength and Evolution of the Hominoid Vertebral Body [PhD thesis]. Cleveland, OH: Case Western Reserve University; May 2011.
2011	Kummari SR. Experimental and Computational Evaluation of Microscopic Tissue Damage and Remodeling Cavities in Trabecular Bone [PhD thesis]. Cleveland, OH: Case Western Reserve University; May 2011.
2011	Tkachenko E. Measures of Individual Resorption Cavities in Three-Dimensional Images in Cancellous Bone [Master's thesis]. Cleveland, OH: Case Western Reserve University; May 2011.
2015	Zhou B. Bone Quality Assessment Using High Resolution Peripheral Quantitative Computed Tomography (HR-PQCT) [PhD thesis]. Columbia University; 2015.
2012	Slyfield CR Jr. The Biomechanics of Bone Turnover [PhD thesis]. Ithaca, NY: Cornell University; January 2012.
2018	Torres AM. Fatigue Behavior of Cancellous Bone, Microdamage Accumulation, and Biologically Inspired Cellular Solids [PhD thesis]. Ithaca, NY: Cornell University; August 2018.
2008	Nazarian A. Relative Interaction of Material and Structure in Normal and Pathologic Bone [PhD thesis]. Swiss Federal Institute of Technology Zürich; 2008.
2009	Ozcivici E. Recovery of Trabecular Bone from Disuse Induced Deterioration in Cellular, Morphological and Biomechanical Properties [PhD thesis]. Stony Brook, NY: Stony Brook University; May 2009.
2008	Bevill GR. Micromechanical Modeling of Failure in Trabecular Bone [PhD thesis]. Berkeley, CA: Berkeley, University of California; 2008.
2014	Nawathe S. Micromechanics of the Human Proximal Femur: Role of Microstructure and Tissue-Level Ductility on Femoral Strength [PhD thesis]. Berkeley, CA: Berkeley, University of California; 2014.