A morphological model of vertebral trabecular bone

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Kim, H. S.¹; Al-Hassan, S. T. S.²

A morphological model of vertebral trabecular bone

J Biomech. August 2002;35(8):1101-1114

©2002 Elsevier Science Ltd. All rights reserved.

Affiliations

¹Institute for Advanced Engineering, Yongin, P.O. Box 25, Kyonggi-Do 449-860, South Korea

²Department of Mechanical Engineering, UMIST, P.O. Box 88, Sackville St., Manchester M60 1QD, UK
Abstract and keywords

In their micro-structures, typical natural cellular materials such as vertebral trabecular bone have a network of doubly tapered struts, thickening near the strut joints. However, past analytical models for vertebral trabecular bone do not take account of the effect of strut taper on the mechanical properties.

This paper presents an analytical cell model comprised of doubly tapered struts to predict the global mechanical properties of vertebral trabecular bone. The predicted results for male, female, and both sexes fit the experimental data well. By considering several strut taper geometries, it is shown that the horizontal Young's modulus and the horizontal uniaxial collapse stress are, in some cases, approximately 1.8- and 2.2-fold higher, respectively, than those of the uniform strut model. This finding illustrates the importance of increased trabecular thickening near the strut joints (i) for improving the accuracy of calculating the mechanical properties and (ii) for the effective treatment of aged bone using drug therapy. It also highlights the need to combine trabecular architecture measurements with information about the morphology near the strut joints.

Keywords: Vertebral trabecular bone; Doubly tapered strut; Morphological model; Effective Young’s modulus; Uniaxial collapse stress
Links

DOI: 10.1016/S0021-9290(02)00053-2

PubMed: 12126669

WoS: 000177318000010
History

Accepted: 2002-03-05

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2004	Hellmich C, Ulm F-J, Dormieux L. Can the diverse elastic properties of trabecular and cortical bone be attributed to only a few tissue-independent phase properties and their interactions? arguments from a multiscale approach. Biomech Model Mechanobiol. June 2004;2(4):219-238.
2015	Goda I, Ganghoffer J-F. 3D plastic collapse and brittle fracture surface models of trabecular bone from asymptotic homogenization method. Int J Eng Sci. February 2015;87:58-82.
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