Micromechanics modeling of Haversian cortical bone properties

wbldb

Hogan, H. A.¹

Micromechanics modeling of Haversian cortical bone properties

J Biomech. May 1992;25(5):549-556

©1992 Pergamon Press plc

Affiliations

¹Department of Mechanical Engineering, Texas A&M University, College Station, TX 77843-3123, U.S.A.
Abstract

A finite-element micromechanics model for Haversian cortical bone tissue has been developed and studied. The model is an extension of two-dimensional micromechanics techniques for fiber-reinforced composite materials. Haversian systems, or secondary osteons, are considered to be the fiber component, and interstitial lamellar bone the matrix material. The cement line is included as an ‘interphase’ component along the fiber/matrix interface. The model assumes a regular repeatable spacing of the longitudinally aligned continuous fibers and is, therefore, restricted to approximating Haversian cortical bone in its present form. Haversian porosity is modeled explicitly by incorporating a hollow fiber to represent the Haversian canal. Solutions have been obtained by applying uniform macroscopic stresses to the boundaries of the repeating unit cell model. Macroscopic mechanical property predictions correspond reasonably well with the experimental data for cortical bone, but are necessarily dependent on the input properties for each constituent, which are not well established. The predicted variation in the elastic modulus with porosity is not as sensitive as that observed experimentally. Stresses within the constituents can also be modeled with this method and are demonstrated to deviate from the macroscopic applied stress levels.
Links

DOI: 10.1016/0021-9290(92)90095-I

PubMed: 1592860

WoS: A1992HT48000009
History

Revised: 1991-08-16

Cited Works (21)

Year	Entry
1988	Schaffler MB, Burr DB. Stiffness of compact bone: effects of porosity and density. J Biomech. 1988;21(1):13-16.
1987	Schaffler MB, Burr DB, Frederickson RG. Morphology of the osteonal cement line in human bone. Anat Rec. March 1987;217(3):223-228.
1979	Lakes R, Saha S. Cement line motion in bone. Science. May 4, 1979;204(4392):501-503.
1967	Ascenzi A, Bonucci E. The tensile properties of single osteons. Acta Anat. 1967;158(4):375-386.
1969	Currey JD. The relationship between the stiffness and the mineral content of bone. J Biomech. October 1969;2(4):477-480.
1968	Ascenzi A, Bonucci E. The compressive properties of single osteons. Anat Rec. July 1968;161(3):377-392.
1988	Burr DB, Schaffler MB, Frederickson RG. Composition of the cement line and its possible mechanical role as a local interface in human compact bone. J Biomech. 1988;21(11):939-945.
1974	Evans FG, Vincentelli R. Relations of the compressive properties of human cortical bone to histological structure and calcification. J Biomech. January 1974;7(1):1-10.
1973	Piekarski K. Analysis of bone as a composite material. Int J Eng Sci. June 1973;11(6):557-565.
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.
1984	Currey JD. Mechanical Adaptations of Bone. Princeton, NJ: Princeton University Press; 1984.
1984	Yeh C-K, Rodan GA. Tensile forces enhance prostaglandin E synthesis in osteoblastic cells grown on collagen ribbons. Calcif Tiss Int. March 1984;36(1):S67-S71.
1988	Currey JD. The effect of porosity and mineral content on the Young's modulus of elasticity of compact bone. J Biomech. 1988;21(2):131-139.
1964	Currey JD. Three analogies to explain the mechanical properties of bone. Biorheology. 1964;2(1):1-10.
1990	Choi K, Kuhn JL, Ciarelli MJ, Goldstein SA. The elastic moduli of human subchondral, trabecular, and cortical bone tissue and the size-dependency of cortical bone modulus. J Biomech. 1990;23(11):1103-1113.
1974	Black J, Mattson R, Korostoff E. Haversian osteons: size, distribution, internal structure, and orientation. J Biomed Mater Res. September 1974;8(5):299-319.
1989	Martin RB, Ishida J. The relative effects of collagen fiber orientation, porosity, density, and mineralization on bone strength. J Biomech. 1989;22(5):419-426.
1981	Frasca P. Scanning-electron microscopy studies of "ground substance" in the cement lines, resting lines, hypercalcified rings and reversal lines of human cortical bone. Acta Anat. 1981;109(2):115-121.
1989	Martin RB, Burr DB. Structure, Function, and Adaptation of Compact Bone. New York, NY: Raven Press; 1989.
1990	Ascenzi A, Baschieri P, Benvenuti A. The bending properties of single osteons. J Biomech. 1990;23(8):763-771.
1970	McElhaney J, Alem N, Roberts V. A porous block model for cancellous bones. Winter Annual Meeting of the American Society of Mechanical Engineers; November 29–December 3, 1970; New York, NY.1-9. ASME Publication 70-WA/BHF-2.

Cited By (37)

Year	Entry
2017	Ze-dong H, Jing Z, Liang-yu C, Ke L, Jie W. Multilevel finite element analysis on the biological tribology damage of water on bone tissue [in Chinese]. Ch J Tissue Eng Res. March 8, 2017;21(7):1041-1045.
2005	Skedros JG, Holmes JL, Vajda EG, Bloebaum AD. Cement lines of secondary osteons in human bone are not mineral‐deficient: new data in a historical perspective. Anat Rec. September 2005;286A(1):781-803.
1997	Rho J-Y, Tsui TY, Pharr GM. Elastic properties of human cortical and trabecular lamellar bone measured by nanoindentation. Biomaterials. 1997;18(20):1325-1330.
2008	Budyn E, Hoc T, Jonvaux J. Fracture strength assessment and aging signs detection in human cortical bone using an X-FEM multiple scale approach. Comput Mech. September 2008;42(4):579-591.
2013	Ural A, Mischinski S. Multiscale modeling of bone fracture using cohesive finite elements. Eng Fract Mech. May 2013;103:141-152.
2007	Budyn É, Hoc T. Multiple scale modeling for cortical bone fracture in tension using X-FEM. Eur J Comput Mech. 2007;16(2):213-236.
2009	Budyn É, Hoc T. Analysis of micro fracture in human Haversian cortical bone under transverse tension using extended physical imaging. Int J Num Meth Eng. 2009;82(8):940-965.
2011	Mischinski S, Ural A. Finite element modeling of microcrack growth in cortical bone. J Appl Mech. July 2011;78(4):041016.
1997	Braidotti P, Branca FP, Stagni L. Scanning electron microscopy of human cortical bone failure surfaces. J Biomech. February 1997;30(2):155-162.
1999	Arbogast KB, Margulies SS. A fiber-reinforced composite model of the viscoelastic behavior of the brainstem in shear. J Biomech. August 1999;32(8):865-870.
2000	Sevostianov I, Kachanov M. Impact of the porous microstructure on the overall elastic properties of the osteonal cortical bone. J Biomech. July 2000;33(7):881-888.
2004	Dong XN, Guo XE. The dependence of transversely isotropic elasticity of human femoral cortical bone on porosity. J Biomech. August 2004;37(8):1281-1287.
2006	Gibson VA, Stover SM, Gibeling JC, Hazelwood SJ, Martin RB. Osteonal effects on elastic modulus and fatigue life in equine bone. J Biomech. 2006;39(2):217-225.
2006	Bigley RF, Griffin LV, Christensen L, Vandenbosch R. Osteon interfacial strength and histomorphometry of equine cortical bone. J Biomech. 2006;39(9):1629-1640.
1996	Prendergast PJ, Huiskes R. Microdamage and osteocyte-lacuna strain in bone: a microstructural finite element analysis. J Biomech Eng. May 1996;118(2):240-246.
1998	Guo XE, Liang LC, Goldstein SA. Micromechanics of osteonal cortical bone fracture. J Biomech Eng. February 1998;120(1):112-117.
2006	Dong XN, Guo XE. Prediction of cortical bone elastic constants by a two-level micromechanical model using a generalized self-consistent method. J Biomech Eng. June 2006;128(3):309-316.
2022	Gaziano P, Monaldo E, Falcinelli C, Vairo G. Elasto-damage mechanics of osteons: a bottom-up multiscale approach. J Mech Phys Solids. October 2022;167:104962.
2006	Ascenzi M-G, Lomovtsev A. Collagen orientation patterns in human secondary osteons, quantified in the radial direction by confocal microscopy. J Struct Biol. January 2006;153(1):14-30.
2003	Bredbenner TL. Damage Modeling of Vertebral Trabecular Bone [PhD thesis]. Cleveland, OH: Case Western Reserve University; January 2003.
2002	Dong X. Micromechanics of Osteonal Cortical Bone [PhD thesis]. Columbia University; 2002.
2020	Moore JP. Mechanical Response and Damage Evolution of Microstructural Cortical Bone Under Compression and Tension [Master's thesis]. Drexel University; June 2020.
1994	Courtney AC. Mechanical Properties of the Proximal Femur: Changes With Age [PhD thesis]. Cambridge, MA: Harvard University; May 1994.
2017	Bakalova LP. Relating Cortical Bone Mechanics to Intracortical Pore Morphology, Distribution and Remodeling History Within the Fibula Diaphysis [Master's thesis]. Urbana, IL: University of Illinois at Urbana-Champaign; 2017.
2011	Abdel-Wahab AA-GM. Experimental and Numerical Analysis of Deformation and Fracture of Cortical Bone Tissue [PhD thesis]. Loughborough University; August 2011.
2013	Li S. Cutting of Cortical Bone Tissue: Analysis of Deformation and Fracture Process [PhD thesis]. Loughborough University; June 2013.
28	Wang M. Effect of Osteonal Microstructure on Crack Propagation: A Computational Study [PhD thesis]. Loughborough University; October 28.
2002	Egerer AK. The Relationship Between the Osteonal Cement Line and Bone Strength [PhD thesis]. Loma Linda University; June 2002.
2010	Deuerling JM. Effects of Ultrastructural Organization on the Mechanical Properties and Anisotropy of Human Cortical Bone [PhD thesis]. University of Notre Dame; December 2010.
2001	Kim DG. Micromechanical Analysis of Bone At a Bone-Implant Interface [PhD thesis]. Troy, NY: Rensselaer Polytechnic Institute; April 2001.
2011	Wulliamoz PM. Micromechanical Modelling of Normal, Drug Treated and Osteoporotic Bone Using Scanning Acoustic Microsopy and Finite Element Analysis [PhD thesis]. Trinity College Dublin; December 2011.
2011	Reisinger AG. Modeling and Validation of Multiscale Lamellar Bone Elasticity [PhD thesis]. Vienna University of Technology; November 2011.
2007	Bigley RF. Volume Effects on Strength and Fatigue Life of Equine Cortical Bone [PhD thesis]. Davis, University of California; September 2007.
1994	Jepsen KJ. Characterization of the Hierarchical Composite Properties of Cortical Bone: A Transgenic Approach [PhD thesis]. Ann Arbor, MI: University of Michigan; 1994.
2021	Atthapreyangkul A. Multi-Scale Finite Element Modelling of Human Cortical Bone: An Analysis of the Mechanical Properties and Microdamage Onset of Cortical Bone [PhD thesis]. University of New South Wales; April 2021.
1996	Beck BR. The Relationship of Streaming Potential Magnitude to Strain and Periosteal Modeling [PhD thesis]. Eugene, OR: University of Oregon; December 1996.
2016	Arango Villegas C. Study of the Mechanical Behavior of Cortical Bone Microstructure by the Finite Element Method [PhD thesis]. Universität Politècnica de València; May 2016.