Predicting trabecular bone microdamage initiation and accumulation using a non-linear perfect damage model

Kosmopoulos, Victor; Keller, Tony S.

Affiliations

¹Hôpital Orthopédique de la Suisse Romande, Avenue Pierre-Decker 4, CH-1005 Lausanne, Switzerland

²Musculoskeletal Research Foundation, Tampa, FL, United States

Abstract and keywords

Studies evaluating the mechanical behavior of the trabecular microstructure play an important role in our understanding of pathologies such as osteoporosis, and in increasing our understanding of bone fracture and bone adaptation. Understanding of such behavior in bone is important for predicting and providing early treatment of fractures. The objective of this study is to present a numerical model for studying the initiation and accumulation of trabecular bone microdamage in both the pre- and post-yield regions. A sub-region of human vertebral trabecular bone was analyzed using a uniformly loaded anatomically accurate microstructural three-dimensional finite element model. The evolution of trabecular bone microdamage was governed using a non-linear, modulus reduction, perfect damage approach derived from a generalized plasticity stress–strain law. The model introduced in this paper establishes a history of microdamage evolution in both the pre- and post-yield regions.

Keywords: Trabecular bone; Perfect damage; Finite element method; Microstructural deformation; Microdamage initiation

Links

DOI: 10.1016/j.medengphy.2007.02.011

PubMed: 17881275

WoS: 000258588700008

History

Received: 2006-11-13

Revised: 2007-02-16

Accepted: 2007-02-16

Online: 2007-09-18

Cited Works (20)

Year	Entry
1973	Pugh JW, Rose RM, Radin EL. A possible mechanism of Wolff's Law: trabecular microfractures. Arch Int Physiol Biochim. February 1973;81(1):27-40.
2001	Jepsen KJ, Davy DT, Akkus O. Observations of damage in bone. In: Cowin SC, ed. Bone Mechanics Handbook. 2nd ed. Boca Raton, FL: CRC Press; 2001:17-1–17-18.
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.
1994	Guo X-DE, McMahon TA, Keaveny TM, Hayes WC, Gibson LJ. Finite element modeling of damage accumulation in trabecular bone under cyclic loading. J Biomech. February 1994;27(2):145-155.
1998	Bentolila V, Boyce TM, Fyhrie DP, Drumb R, Skerry TM, Schaffler MB. Intracortical remodeling in adult rat long bones after fatigue loading. Bone. September 1998;23(3):275-281.
2004	Bayraktar HH, Keaveny TM. Mechanisms of uniformity of yield strains for trabecular bone. J Biomech. November 2004;37(11):1671-1678.
2000	Niebur GL, Feldstein MJ, Yuen JC, Chen TJ, Keaveny TM. High-resolution finite element models with tissue strength asymmetry accurately predict failure of trabecular bone. J Biomech. December 2000;33(12):1575-1583.
2004	Morgan E, Bayraktar H, Yeh O, Majumdar S, Burghardt A, Keaveny T. Contribution of inter-site variations in architecture to trabecular bone apparent yield strains. J Biomech. 2004;37(9):1413-1420.
1985	Burr DB, Martin RB, Schaffler MB, Radin EL. Bone remodeling in response to in vivo fatigue microdamage. J Biomech. 1985;18(3):189-200.
1999	Turner CH, Rho J, Takano Y, Tsui TY, Pharr GM. The elastic properties of trabecular and cortical bone tissues are similar: results from two microscopic measurement techniques. J Biomech. April 1999;32(4):437-441.
1997	Burr DB, Forwood MR, Fyhrie DP, Martin RB, Schaffler MB, Turner CH. Bone microdamage and skeletal fragility in osteoporotic and stress fractures. J Bone Miner Res. January 1997;12(1):6-15.
1999	Kopperdahl DL, Roberts AD, Keaveny TM. Localized damage in vertebral bone is most detrimental in regions of high strain energy density. J Biomech Eng. December 1999;121(6):622-628.
1977	Carter DR, Hayes WC. The compressive behavior of bone as a two-phase porous structure. J Bone Joint Surg. 1977;59A(7):954-962.
1994	Keller TS. Predicting the compressive mechanical behavior of bone. J Biomech. September 1994;27(9):1159-1168.
1995	Martin B. Mathematical model for repair of fatigue damage and stress fracture in osteonal bone. J Orthop Res. May 1995;13(3):309-316.
1982	Martin RB, Burr DB. A hypothetical mechanism for the stimulation of osteonal remodelling by fatigue damage. J Biomech. 1982;15(3):137-139.
1997	Jepsen KJ, Davy DT. Comparison of damage accumulation measures in human cortical bone. J Biomech. September 1997;30(9):891-894.
1997	Wachtel EF, Keaveny TM. Dependence of trabecular damage on mechanical strain. J Orthop Res. September 1997;15(5):781-787.
2002	Makiyama AM, Vajjhala S, Gibson LJ. Analysis of crack growth in a 3D Voronoi structure: a model for fatigue in low density trabecular bone. J Biomech Eng. October 2002;124(4):512-520.
2004	Bourne BC, van der Meulen MCH. Finite element models predict cancellous apparent modulus when tissue modulus is scaled from specimen CT-attenuation. J Biomech. May 2004;37(5):613-621.

Cited By (15)

Year	Entry
2018	Nelms MD, Hodo WD, Rajendran AM. Bioinspired layered composite principles of biomineralized fish scale. In: Gopalakrishnan S, Rajapaks Y, eds. Blast Mitigation Strategies in Marine Composite and Sandwich Structures. Springer Singapore; 2018:397-421. Springer Transactions in Civil and Environmental Engineering.
2013	Harrison NM, McDonnell P, Mullins L, Wilson N, O’Mahoney D, McHugh PE. Failure modelling of trabecular bone using a non-linear combined damage and fracture voxel finite element approach. Biomech Model Mechanobiol. April 2013;12(2):225-241.
2010	Fang G, Ji B, Liu XS, Guo XE. Quantification of trabecular bone microdamage using the virtual internal bond model and the individual trabeculae segmentation technique. Comput Methods Biomech Biomed Eng. October 2010;13(5):605-15.
2013	Nawathe S, Juillard F, Keaveny TM. Theoretical bounds for the influence of tissue-level ductility on the apparent-level strength of human trabecular bone. J Biomech. April 26, 2013;46(7):1293-1299.
2013	Hardisty MR, Zauel R, Stover SM, Fyhrie DP. The importance of intrinsic damage properties to bone fragility: a finite element study. J Biomech Eng. January 2013;135(1):011004.
2011	Karim L, Vashishth D. Role of trabecular microarchitecture in the formation, accumulation, and morphology of microdamage in human cancellous bone. J Orthop Res. November 2011;29(11):1739-1744.
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.
2014	Carretta R. Post-Yield Mechanics and Material Composition of Single Trabeculae: A Combined Experimental and Modelling Approach [PhD thesis]. Swiss Federal Institute of Technology Zürich; 2014.
2010	Wang JL. Effects of Aging and Remodeling on Bone Microdamage Formation [Master's thesis]. Atlanta, GA: Georgia Institute of Technology; December 2010.
2012	Hamed E. Multiscale Modeling of Elastic Moduli and Strength of Bone [PhD thesis]. University of Illinois at Urbana-Champaign; 2012.
2009	Lievers WB. Effects of Geometric and Material Property Changes on the Apparent Elastic Properties of Cancellous Bone [PhD thesis]. Queen's University; April 2009.
2011	Karim L. The Biomolecular Basis of Bone Fracture [PhD thesis]. Troy, NY: Rensselaer Polytechnic Institute; November 2011.
2014	Gross T. Development and Application of 3d CT Image-Based Micro and Macro Finite Element Models for Human Bones and Orthopedic Implant Systems [PhD thesis]. Vienna University of Technology; 2014.
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.
2012	Hardisty MR. Not Tough Enough: Why Bone Turns Pale When it Feels Stressed [PhD thesis]. Davis, CA: Davis, University of California; 2012.