Postfailure compressive behavior of tibial trabecular bone in three anatomic directions

Keyak, J. H.; Lee, I. Y.; Nath, D. S.; Skinner, H. B.

Affiliations

¹Rehabilitation Research and Development Service, Department of Veterans Afairs Medical Center, San Francisco

²Bioengineering Graduate Group, University of California, San Francisco/Berkeley

³Bioengineering Undergraduate Program, University of California, Berkeley

⁴Department of Orthopaedic Surgery, University of California, Irvine

⁵Department of Orthopaedic Surgery, University of California, San Francisco

⁶Department of Mechanical Engineering, University of California, Berkeley, California

Abstract

To obtain information describing the postfailure behavior of human proximal tibial trabecular bone, cube specimens of bone were mechanically tested in compression beyond the point of failure. Tests were performed in the three anatomic directions, plots of stress versus strain were obtained, and measures to describe the stress‐strain relations before, during, and after failure were defined. These measures included elastic modulus, strength, postfailure slope, strain during maximum stress, and first postfailure minimum stress. For each anatomic direction, analyses were performed to correlate these parameters with ash density.

Each of these measures was significantly correlated with ash density at the p < 0.05 level for all test directions, except for postfailure slope, which was correlated in the mediolateral and superior‐inferior directions, and strain during maximum stress, which was correlated only in the superior‐inferior direction. The data from this study enable trilinear stress‐strain relations to be estimated for proximal tibial trabecular bone of various densities, and can serve as a first step toward modeling the behavior of trabecular bone before, during, and after failure.

Links

DOI: 10.1002/(SICI)1097-4636(199607)31:3<373::AID-JBM11>3.0.CO;2-K

PubMed: 8806063

WoS: A1996UU78600011

History

Received: 1995-08-14

Accepted: 1995-10-19

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Cited By (13)

Year	Entry
2001	Keaveny TM. Strength of trabecular bone. In: Cowin SC, ed. Bone Mechanics Handbook. 2nd ed. Boca Raton, FL: CRC Press; 2001:16-1–16-42.
2013	Keyak JH, Sigurdsson S, Karlsdottir GS, Oskarsdottir D, Sigmarsdottir A, Kornak J, Harris TB, Sigurdsson G, Jonsson BY, Siggeirsdottir K, Eiriksdottir G, Gudnason V, Lang TF. Effect of finite element model loading condition on fracture risk assessment in men and women: the AGES-Reykjavik study. Bone. November 2013;57(1):18-29.
2020	Keyak JH, Kaneko TS, Khosla S, Amin S, Atkinson EJ, Lang TF, Sibonga JD. Hip load capacity and yield load in men and women of all ages. Bone. August 2020;137:115321.
2018	Zhao S, Arnold M, Ma S, Abel RL, Cobb JP, Hansen U, Boughton O. Standardizing compression testing for measuring the stiffness of human bone. Bone Joint Res. August 2018;7(8):524-538.
2005	Keyak JH, Kaneko TS, Tehranzadeh J, Skinner HB. Predicting proximal femoral strength using structural engineering models. Clin Orthop Relat Res. August 2005;437:219-228.
2009	Burgers TA, Lakes RS, García-Rodríguez S, Piller GR, Ploeg H-L. Post-yield relaxation behavior of bovine cancellous bone. J Biomech. 2009;42(16):2728-2733.
2001	Keyak JH. Improved prediction of proximal femoral fracture load using nonlinear finite element models. Med Eng Phys. April 2001;23(3):165-173.
2003	Keyak JH, Falkinstein Y. Comparison of in situ and in vitro CT scan-based finite element model predictions of proximal femoral fracture load. Med Eng Phys. November 2003;25(9):781-787.
1998	Müller R, Gerber SC, Hayes WC. Micro-compression: a novel technique for the nondestructive assessment of local bone failure. Technol Health Care. December 1998;6(5-6):433-444.
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.
2011	Yao H. Microstructure-Based Characterization and Modeling of Trabecular Bone Deformation and Failure [PhD thesis]. Southern Methodist University; August 3, 2011.
2024	Benais R. Computational Modeling of Trabecular Bone Indentation and Development of a New Test Method to Perform Unconstrained Load-Induced Subsidence of an Intervertebral Body Fusion Device [Master's thesis]. University of Waterloo; 2024.
2008	Burgers TA. Press-Fit Fixation and Viscoelastic Response of a Bone-Implant Interface in the Distal Femur [PhD thesis]. University of Wisconsin – Madison; 2008.