Application of the Tsai–Wu quadratic multiaxial failure criterion to bovine trabecular bone

wbldb

Keaveny, T. M.^1,2; Wachtel, E. F.¹; Zadesky, S. P.¹; Arramon, Y. P.¹

Application of the Tsai–Wu quadratic multiaxial failure criterion to bovine trabecular bone

J Biomech Eng. February 1999;121(1):99-107

Affiliations

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

²Department of Orthopaedic Surgery, University of California, San Francisco, CA 94143
Abstract

As a first step toward development of a multiaxial failure criterion for human trabecular bone, the Tsai–Wu quadratic failure criterion was modified as a function of apparent density and applied to bovine tibial trabecular bone. Previous data from uniaxial compressive, tensile, and torsion tests (n = 139 total) were combined with those from new triaxial tests (n = 17) to calibrate and then verify the criterion. Combinations of axial compression and radial pressure were used to produce the triaxial compressive stress states. All tests were performed with minimal end artifacts in the principal material coordinate system of the trabecular network. Results indicated that the stress interaction term F₁₂ exhibited a strong nonlinear dependence on apparent density (r² > 0.99), ranging from −0.126 MPa⁫⁻²⁫ at low densities (0.29 g/cm³) to 0.005 MPa⁫⁻²⁫ at high densities (0.63 g/cm³). After calibration and when used to predict behavior of new specimens without any curve-fitting, the Tsai–Wu criterion had a mean (± SD) error of −32.6 ± 10.6 percent. Except for the highest density triaxial specimens, most (15/17 specimens) failed at axial stresses close to their predicted uniaxial values, and some reinforcement for transverse loading was observed. We conclude that the Tsai–Wu quadratic criterion, as formulated here, is at best only a reasonable predictor of the multiaxial failure behavior of trabecular bone, and further work is required before it can be confidently applied to human bone.
Links

DOI: 10.1115/1.2798051

PubMed: 10080095

WoS: 000078831700015
History

Received: 1997-12-10

Revised: 1998-08-20

Cited Works (37)

Year	Entry
1986	Cowin SC. Fabric dependence of an anisotropic strength criterion. Mech Mater. September 1986;5(3):251-260.
1994	Keaveny TM, Guo XE, Wachtel EF, McMahon TA, Hayes WC. Trabecular bone exhibits fully linear elastic behavior and yields at low strains. J Biomech. 1994;27(9):1127-1136.
1997	Silva MJ, Gibson LJ. Modeling the mechanical behavior of vertebral trabecular bone: effects of age-related changes in microstructure. Bone. 1997;21(2):191-199.
1983	Stone JL, Beaupre GS, Hayes WC. Multiaxial strength characteristics of trabecular bone. J Biomech. 1983;16(9):743-752.
1978	Hayes WC, Swenson LW Jr, Schurman DJ. Axisymmetric finite element analysis of the lateral tibial plateau. J Biomech. 1978;11(1-2):21-33.
1990	Fyhrie DP, Carter DR. Femoral head apparent density distribution predicted from bone stresses. J Biomech. 1990;23(1):1-10.
1997	Keaveny TM, Pinilla TP, Crawford RP, Kopperdahl DL, Lou A. Systematic and random errors in compression testing of trabecular bone [published correction appears in J Orthop Res. 1995;17(1):151]. J Orthop Res. 1997;15(1):101-110.
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.
1994	Goulet RW, Goldstein SA, Ciarelli MJ, Kuhn JL, Brown MB, Feldkamp LA. The relationship between the structural and orthogonal compressive properties of trabecular bone. J Biomech. April 1994;27(4):375-389.
1983	Bensusan JS, Davy DT, Heiple KG, Verdin KG. Tensile, compressive and torsional testing of cancellous bone. In: Transacation of the 29th Annual Meeting of the Orthopaedic Research Society. March 8-10, 1983; Anaheim, CA.132.
1997	Silva MJ, Gibson LJ. The effects of non-periodic microstructure and defects on the compressive strength of two-dimensional cellular solids. Int J Mech Sci. May 1997;39(5):549-563.
1983	Neil JL, Demos TC, Stone JL, Hayes WC. Tensile and compressive properties of vertebral trabecular bone. In: Transacation of the 29th Annual Meeting of the Orthopaedic Research Society. March 8-10, 1983; Anaheim, CA.344.
1991	Ciarelli MJ, Goldstein SA, Kuhn JL, Cody DD, Brown MB. Evaluation of orthogonal mechanical properties and density of human trabecular bone from the major metaphyseal regions with materials testing and computed tomography. J Orthop Res. May 1991;9(5):674-682.
1969	Patel MR. The Deformation and Fracture of Rigid Cellular Plastics Under Multiaxial Stress [PhD thesis]. Berkeley, CA: Berkeley, University of California; 1969.
1994	Keaveny TM, Wachtel EF, Ford CM, Hayes WC. Differences between the tensile and compressive strengths of bovine tibial trabecular bone depend on modulus. J Biomech. 1994;27(9):1137-1146.
1985	Cezayirlioglu H, Bahniuk E, Davy DT, Heiple KG. Anisotropic yield behavior of bone under combined axial force and torque. J Biomech. 1985;18(1):61-69.
1988	Rice JC, Cowin SC, Bowman JA. On the dependence of the elasticity and strength of cancellous bone on apparent density. J Biomech. 1988;21(2):155-168.
1990	Turner CH, Cowin SC, Rho JY, Ashman RB, Rice JC. The fabric dependence of the orthotropic elastic constants of cancellous bone. J Biomech. 1990;23(6):549-561.
1987	Goldstein SA. The mechanical properties of trabecular bone: dependence on anatomic location and function. J Biomech. 1987;20(11-12):1055-1061.
1991	Lotz JC, Cheal EJ, Hayes WC. Fracture prediction for the proximal femur using finite element models, I: linear analysis. J Biomech Eng. 1991;113(4):353-360.
1971	Tsai SW, Wu EM. A general theory of strength for anisotropic materials. J Compos Mater. January 1971;5(1):58-80.
1987	Vahey JW, Lewis JL, Vanderby R Jr. Elastic moduli, yield stress, and ultimate stress of cancellous bone in the canine proximal femur. J Biomech. 1987;20(1):29-33.
1989	Carter DR, Orr TE, Fyhrie DP. Relationships between loading history and femoral cancellous bone architecture. J Biomech. 1989;22(3):231-244.
1997	Simmons CA, Hipp JA. Method-based differences in the automated analysis of the three-dimensional morphology of trabecular bone. J Bone Miner Res. June 1997;12(6):942-947.
1980	Carter DR, Schwab GH, Spengler DM. Tensile fracture of cancellous bone. Acta Orthop Scand. 1980;51(5):733-741.
1975	Townsend PR, Raux P, Rose RM, Miegel RE, Radin EL. The distribution and anisotropy of the stiffness of cancellous bone in the human patella. J Biomech. 1975;8(6):363-367.
1985	Kaplan SJ, Hayes WC, Stone JL, Beaupré GS. Tensile strength of bovine trabecular bone. J Biomech. 1985;18(9):723-727.
1988	Yahia LH, Drouin G, Duval P. A methodology for mechanical measurements of technical constants of trabecular bone. Eng Med. October 1988;17(4):169-173.
1990	Jensen KS, Mosekilde L, Mosekilde L. A model of vertebral trabecular bone architecture and its mechanical properties. Bone. 1990;11(6):417-423.
1995	van Rietbergen B, Weinans H, Huiskes R, Odgaard A. A new method to determine trabecular bone elastic properties and loading using micromechanical finite-element models. J Biomech. January 1995;28(1):69-81.
1982	Brown TD, Mutschler TA, Ferguson AB. A non-linear finite element analysis of some early collapse processes in femoral head osteonecrosis. J Biomech. 1982;15(9):705-715.
1991	Lotz JC, Cheal EJ, Hayes WC. Fracture prediction for the proximal femur using finite element models, II: nonlinear analysis. J Biomech Eng. 1991;113(4):361-364.
1986	Cowin SC. Wolff’s law of trabecular architecture at remodeling equilibrium. J Biomech Eng. February 1986;108(1):83-88.
1997	Bagi CM, Wilkie D, Georgelos K, Williams D, Bertolini D. Morphological and structural characteristics of the proximal femur in human and rat. Bone. September 1997;21(3):261-267.
1980	Brown TD, Ferguson AB Jr. Mechanical property distributions in the cancellous bone of the human proximal femur. Acta Orthop Scand. 1980;51(1):429-437.
1987	Cheal EJ, Snyder BD, Nunamaker DM, Hayes WC. Trabecular bone remodeling around smooth and porous implants in an equine patellar model. J Biomech. 1987;20(11-12):1121-1134.
1985	Cheal EJ, Hayes WC, Lee CH, Snyder BD, Miller J. Stress analysis of a condylar knee tibial component: influence of metaphyseal shell properties and cement injection depth. J Orthop Res. 1985;3(4):424-434.

Cited By (35)

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.
2005	Iwamoto M, Miki K, Tanaka E. Ankle skeletal injury predictions using anisotropic inelastic constitutive model of cortical bone taking into account damage evolution. Stapp Car Crash J. 2005;49:133-156. SAE 2005-22-0007.
2001	Keaveny TM, Morgan EF, Niebur GL, Yeh OC. Biomechanics of trabecular bone. Annu Rev Biomed Eng. 2001;3:307-333.
2009	Rincón-Kohli L, Zysset PK. Multi-axial mechanical properties of human trabecular bone. Biomech Model Mechanobiol. June 2009;8(3):195-208.
2008	Nazarian A, von Stechow D, Zurakowski D, Müller R, Snyder BD. Bone volume fraction explains the variation in strength and stiffness of cancellous bone affected by metastatic cancer and osteoporosis. Calcif Tiss Int. December 2008;83(6):368-379.
2004	Doblaré M, García JM, Gomez MJ. Modelling bone tissue fracture and healing: a review. Eng Fract Mech. September 2004;71(13-14):1809-1840.
2020	Mirzaali MJ, Libonati F, Böhm C, Rinaudo L, Cesana BM, Ulivieri FM, Vergani L. Fatigue-caused damage in trabecular bone from clinical, morphological and mechanical perspectives. Int J Fatigue. April 2020;133:105451.
2005	Shim VPW, Yang LM, Liu JF, Lee VS. Characterisation of the dynamic compressive mechanical properties of cancellous bone from the human cervical spine. Int J Impact Eng. December 2005;32(1-4):525-540.
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.
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.
2002	Niebur GL, Feldstein MJ, Keaveny TM. Biaxial failure behavior of bovine tibial trabecular bone. J Biomech Eng. December 2002;124(6):699-705.
2004	Bayraktar HH, Gupta A, Kwon RY, Papadopoulos P, Keaveny TM. The modified super-ellipsoid yield criterion for human trabecular bone. J Biomech Eng. 2004;126(6):677-684.
2015	Oftadeh R, Perez-Viloria M, Villa-Camacho JC, Vaziri A, Nazarian A. Biomechanics and mechanobiology of trabecular bone: a review. J Biomech Eng. January 2015;137(1):010802.
2012	Wolfram U, Gross T, Pahr DH, Schwiedrzik J, Wilke H-J, Zysset PK. Fabric-based Tsai-Wu yield criteria for vertebral trabecular bone in stress and strain space. J Mech Behav Biomed Mater. November 2012;15:218-228.
2007	Skedros JG, Baucomb SL. Mathematical analysis of trabecular "trajectories" in apparent trajectorial structures: the unfortunate historical emphasis on the human proximal femur. J Theo Biol. January 7, 2007;244(1):15-45.
2020	Aguirre TG, Ingrole A, Fuller L, Seek TW, Fiorillo AR, Sertich JJW, Donahue SW. Differing trabecular bone architecture in dinosaurs and mammals contribute to stiffness and limits on bone strain. PLoS One. August 19, 2020;15(8):e0237042.
2003	Bredbenner TL. Damage Modeling of Vertebral Trabecular Bone [PhD thesis]. Cleveland, OH: Case Western Reserve University; January 2003.
2020	Aguirre TG. Bio-Inspired Design for Engineering Applications: Empirical and Finite Element Studies of Biomechanically Adapted Porous Bone Architectures [PhD thesis]. Colorado State University; Summer 2020.
2012	Slyfield CR Jr. The Biomechanics of Bone Turnover [PhD thesis]. Ithaca, NY: Cornell University; January 2012.
2013	Souzanchi MF. The Effect of Microarchitecture and Fabric Anisotropy of Trabecular Bone on Its Mechanical Behavior [PhD thesis]. New York, NY: The City University of New York; 2013.
2008	Nazarian A. Relative Interaction of Material and Structure in Normal and Pathologic Bone [PhD thesis]. Swiss Federal Institute of Technology Zürich; 2008.
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.
2006	Nagaraja S. Microstructural Stresses and Strains Associated With Trabecular Bone Microdamage [PhD thesis]. Atlanta, GA: Georgia Institute of Technology; December 2006.
2012	Rennick JA. Bone Fracture Prediction Using Computed Tomography Based Rigidity Analysis and the Finite Element Method [Master's thesis]. Northeastern University; April 2012.
2015	Oftadeh R. Hierarchical Analysis and Multiscale Modelling of Cellular Structures: From Meta Materials to Bone Structure [PhD thesis]. Northeastern University; December 2015.
2004	Wang X. Measurement and Analysis of Microdamage in Bone [PhD thesis]. University of Notre Dame; December 2004.
2012	Kelly N. An Experimental and Computational Investigation of the Inelastic Behaviour of Trabecular Bone [PhD thesis]. Galway, Ireland: National University of Ireland Galway; September 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.
2006	Verhulp E. Analyses of Trabecular Bone Failure [PhD thesis]. Eindhoven, The Netherlands: Eindhoven University of Technology; 2006.
2004	Greaves CY. Spinal Cord Injury Mechanisms: A Finite Element Study [Master's thesis]. Vancouver, BC: University of British Columbia; May 2004.
2007	MacNeil JAM. Clinical Assessment of Bone Quality [PhD thesis]. Calgary, AB: University of Calgary; June 2007.
2000	Niebur GL. A Computational Investigation of Multiaxial Failure in Trabecular Bone [PhD thesis]. Berkeley, CA: University of California; 2000.
2003	Bayraktar HH. Multiaxial Strength and Micromechanics of Human Bone [PhD thesis]. Berkeley, CA: Berkeley, University of California; 2003.
2013	Sanyal A. Bone Strength Multi-Axial Behavior: Volume Fraction, Anisotropy and Microarchitecture [PhD thesis]. Berkeley, CA: Berkeley, University of California; 2013.
2011	Aiyangar AK. Physical and Computational Modeling of Subsidence of Anterior Interbody Fusion Devices [PhD thesis]. University of Wisconsin – Madison; 2011.