Patient-specific finite-element analyses of the proximal femur with orthotropic material properties validated by experiments

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Trabelsi, Nir¹; Yosibash, Zohar¹

Patient-specific finite-element analyses of the proximal femur with orthotropic material properties validated by experiments

J Biomech Eng. June 2011;133(6):061001

©2011 ASME

Affiliations

¹Department of Mechanical Engineering, Ben-Gurion University of the Negev, Beer-Sheva, 84105, Israel
Abstract and keywords

Patient-specific high order finite-element (FE) models of human femurs based on quantitative computer tomography (QCT) with inhomogeneous orthotropic and isotropic material properties are addressed. The point-wise orthotropic properties are determined by a micromechanics (MM) based approach in conjunction with experimental observations at the osteon level, and two methods for determining the material trajectories are proposed (along organs outer surface, or along principal strains). QCT scans on four fresh-frozen human femurs were performed and high-order FE models were generated with either inhomogeneous MM-based orthotropic or empirically determined isotropic properties. In vitro experiments were conducted on the femurs by applying a simple stance position load on their head, recording strains on femurs’ surface and head’s displacements. After verifying the FE linear elastic analyses that mimic the experimental setting for numerical accuracy, we compared the FE results to the experimental observations to identify the influence of material properties on models’ predictions. The strains and displacements computed by FE models having MM-based inhomogeneous orthotropic properties match the FE-results having empirically based isotropic properties well, and both are in close agreement with the experimental results. When only the strains in the femoral neck are being compared a more pronounced difference is noticed between the isotropic and orthotropic FE result. These results lay the foundation for applying more realistic inhomogeneous orthotropic material properties in FEA of femurs.

Keywords: Proximal femur; Finite element analysis; p-FEM; Computed tomography (CT); Micromechanics; Anisotropic materials; Bone biomechanics
Links

DOI: 10.1115/1.4004180

PubMed: 21744921

WoS: 000292515300001
History

Received: 2010-11-29

Revised: 2011-03-30

Online: 2011-06-14

Cited Works (38)

Year	Entry
2003	Wirtz DC, Pandorf T, Portheine F, Radermacher K, Schiffers N, Prescher A, Weichert D, Niethard FU. Concept and development of an orthotropic FE model of the proximal femur. J Biomech. February 2003;36(2):289-293.
2002	Rho JY, Zioupos P, Currey JD, Pharr GM. Microstructural elasticity and regional heterogeneity in human femoral bone of various ages examined by nano-indentation. J Biomech. February 2002;35(2):189-198.
2000	Wirtz DC, Schiffers N, Pandorf T, Radermacher K, Weichert D, Forst R. Critical evaluation of known bone material properties to realize anisotropic fe-simulation of the proximal femur. J Biomech. October 2000;33(10):1325-1330.
2007	Taddei F, Schileo E, Helgason B, Cristofolini L, Viceconti M. The material mapping strategy influences the accuracy of ct-based finite element models of bones: an evaluation against experimental measurements. Med Eng Phys. 2007;29(9):973-979.
1986	Wolff J. The Law of Bone Remodelling. Maquet P, Furlong R, trans. New York, NY: Springer; 1986.
1990	Keyak JH, Meagher JM, Skinner HB, Mote CD Jr. Automated three-dimensional finite element modelling of bone: a new method. J Biomed Eng. 1990;12(5):389-397.
1984	Ashman RB, Cowin SC, Van Buskirk WC, Rice JC. A continuous wave technique for the measurement of the elastic properties of cortical bone. J Biomech. 1984;17(5):349-361.
2002	Fan Z, Swadener JG, Rho JY, Roy ME, Pharr GM. Anisotropic properties of human tibial cortical bone as measured by nanoindentation. J Orthop Res. July 2002;20(4):806-810.
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.
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	Heřt J, Fiala P, Petrtýl M. Osteon orientation of the diaphysis of the long bones in man. Bone. May–June 1994;15(3):269-277.
1995	Rho JY, Hobatho MC, Ashman RB. Relations of mechanical properties to density and CT numbers in human bone. Med Eng Phys. July 1995;17(5):347-355.
2008	Schileo E, Dall’Ara E, Taddei F, Malandrino A, Schotkamp T, Baleani M, Viceconti M. An accurate estimation of bone density improves the accuracy of subject-specific finite element models. J Biomech. August 7, 2008;41(11):2483-2491.
2007	Yosibash Z, Padan R, Joskowicz L, Milgrom C. A CT-based high-order finite element analysis of the human proximal femur compared to in-vitro experiments. J Biomech Eng. June 2007;129(3):297-309.
1994	Keller TS. Predicting the compressive mechanical behavior of bone. J Biomech. September 1994;27(9):1159-1168.
2007	Schileo E, Taddei F, Malandrino A, Cristofolini L, Viceconti M. Subject-specific finite element models can accurately predict strain levels in long bones. J Biomech. 2007;40(13):2982-2989.
1998	Viceconti M, Bellingeri L, Cristofolini L, Toni A. A comparative study on different methods of automatic mesh generation of human femurs. Med Eng Phys. January 1998;20(1):1-10.
2001	Bergmann G, Deuretzbacher G, Heller M, Graichen F, Rohlmann A, Strauss J, Duda GN. Hip contact forces and gait patterns from routine activities. J Biomech. July 2001;34(7):859-871.
2007	Shahar R, Zaslansky P, Barak M, Friesem AA, Currey JD, Weiner S. Anisotropic Poisson's ratio and compression modulus of cortical bone determined by speckle interferometry. J Biomech. 2007;40(2):252-264.
1990	Lotz JC, Gerhart TN, Hayes WC. Mechanical properties of trabecular bone from the proximal femur: a quantitative CT study. J Comput Assist Tomogr. January–February 1990;14(1):107-114.
2000	Cody DD, Hou FJ, Divine GW, Fyhrie DP. Short term in vivo precision of proximal femoral finite element modeling. Ann Biomed Eng. April 2000;28(4):408-414.
2007	Öhman C, Baleani M, Perilli E, Dall’Ara E, Tassani S, Baruffaldi F, Viceconti M. Mechanical testing of cancellous bone from the femoral head: experimental errors due to off-axis measurements. J Biomech. 2007;40(11):2426-2433.
2001	Heller MO, Bergmann G, Deuretzbacher G, Dürselen L, Pohl M, Claes L, Haas NP, Duda GN. Musculo-skeletal loading conditions at the hip during walking and stair climbing. J Biomech. July 2001;34(7):883-893.
2007	Yosibash Z, Trabelsi N, Milgrom C. Reliable simulations of the human proximal femur by high-order finite element analysis validated by experimental observations. J Biomech. 2007;40(16):3688-3699.
2002	Taylor WR, Roland E, Ploeg H, Hertig D, Klabunde R, Warner MD, Hobatho MC, Rakotomanana L, Clift SE. Determination of orthotropic bone elastic constants using FEA and modal analysis. J Biomech. June 2002;35(6):767-773.
2009	Cristofolini L, Juszczyk M, Taddei F, Viceconti M. Strain distribution in the proximal human femoral metaphysis. Proc Inst Mech Eng Part H-J Eng Med. April 2009;2223(3):273-288.
2009	Trabelsi N, Yosibash Z, Milgrom C. Validation of subject-specific automated p-FE analysis of the proximal femur. J Biomech. February 9, 2009;42(3):234-241.
2004	Viceconti M, Davinelli M, Taddei F, Cappello A. Automatic generation of accurate subject-specific bone finite element models to be used in clinical studies. J Biomech. 2004;37(10):1597-1605.
2008	Helgason B, Taddei F, Pálsson H, Schileo E, Cristofolini L, Viceconti M, Brynjolfsson S. A modified method for assigning material properties to FE models of bones. Med Eng Phys. May 2008;30(4):444-453.
2006	Peng L, Bai J, Zeng X, Zhou Y. Comparison of isotropic and orthotropic material property assignments on femoral finite element models under two loading conditions. Med Eng Phys. April 2006;28(3):227-233.
2007	Fritsch A, Hellmich C. "Universal" microstructural patterns in bone: micromechanics-based prediction of anisotropic material behavior. J Theo Biol. February 21, 2007;244(4):597-620.
1991	Lotz JC, Gerhart TN, Hayes WC. Mechanical properties of metaphyseal bone in the proximal femur. J Biomech. 1991;24(5):317-329.
2008	Yoon YJ, Cowin SC. The estimated elastic constants for a single bone osteonal lamella. Biomech Model Mechanobiol. February 2008;7(1):1-11.
2009	Franzoso G, Zysset PK. Elastic anisotropy of human cortical bone secondary osteons measured by nanoindentation. J Biomech Eng. February 2009;131(2):021001.
2003	Morgan EF, Bayraktar HH, Keaveny TM. Trabecular bone modulus–density relationships depend on anatomic site. J Biomech. July 2003;36(7):897-904.
1996	Rho J-Y. An ultrasonic method for measuring the elastic properties of human tibial cortical and cancellous bone. Ultrasonics. December 1996;34(8):777-783.
1985	Cowin SC. The relationship between the elasticity tensor and the fabric tensor. Mech Mater. 1985;4(2):137-147.
2009	Chevalier Y, Pahr D, Zysset PK. The role of cortical shell and trabecular fabric in finite element analysis of the human vertebral body. J Biomech Eng. November 2009;131(11):111003.

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Year	Entry
2013	Dall'Ara E, Luisier B, Schmidt R, Kainberger F, Zysset P, Pahr D. A nonlinear QCT-based finite element model validation study for the human femur tested in two configurations in vitro. Bone. January 2013;52(1):27-38.
2020	Toniolo I, Salmaso C, Bruno G, De Stefani A, Stefanini C, Gracco ALT, Carniel EL. Anisotropic computational modelling of bony structures from CT data: an almost automatic procedure. Comput Methods Prog Biomed. June 2020;189:105319.
2012	Grassi L, Schileo E, Taddei F, Zani L, Juszczyk M, Cristofolini L, Viceconti M. Accuracy of finite element predictions in sideways load configurations for the proximal human femur. J Biomech. January 10, 2012;45(2):394-399.
2012	Wille H, Rank E, Yosibash Z. Prediction of the mechanical response of the femur with uncertain elastic properties. J Biomech. April 30, 2012;45(7):1140-1148.
2013	Kersh ME, Zysset PK, Pahr DH, Wolfram U, Larsson D, Pandy MG. Measurement of structural anisotropy in femoral trabecular bone using clinical-resolution CT images. J Biomech. October 18, 2013;46(15):2659-2666.
2014	Dall’Ara E, Barber D, Viceconti M. About the inevitable compromise between spatial resolution and accuracy of strain measurement for bone tissue: a 3D zero-strain study. J Biomech. September 22, 2014;47(12):2956-2963.
2019	Knowles NK, Langohr GDG, Faieghi M, Nelson A, Ferreira LM. Development of a validated glenoid trabecular density-modulus relationship. J Mech Behav Biomed Mater. February 2019;90:140-145.
2020	Ruiz Wills C, Tassani S, Di Gregorio S, Martínez S, González Ballester MA, Humbert L, Noailly J, Del Río LM. Relative fragility of osteoporotic femurs assessed with DXA and simulation of finite element falls guided by emergency X-rays. Rev Osteoporos Metab Miner. April–June 2020;12(2):62-70.
2020	Lewandowski K. Numerical Investigation of Bone Adaptation to Exercise and Fracture in Thoroughbred Racehorses [PhD thesis]. Glasgow, UK: University of Glasgow; February 2020.
2015	Gargac J. Evaluation of Bone Healing, Damage, and Adaptation Using Computational Modeling and Image Processing Techniques [PhD thesis]. University of Notre Dame; July 2015.
2012	Dall'Ara E. QCT Based Finite Element Models of the Human Vertebra and Femur: Validation With Experiments and Comparison With Bone Densitometry [PhD thesis]. Vienna University of Technology; October 2012.
2017	Fung A. Experimental Validation of Finite Element Predicted Bone Strain in the Human Metatarsal [Master's thesis]. Calgary, AB: University of Calgary; April 2017.
2018	Hosseini Kalajahi SM. Addressing Partial Volume Artifacts With Quantitative Computed Tomography-Based Finite Element Modeling of the Human Proximal Tibia [Master's thesis]. University of Saskatchewan; April 2018.
2019	Knowles NK. Improving Material Mapping in Glenohumeral Finite Element Models: A Multi-Level Evaluation [PhD thesis]. University of Western Ontario; 2019.