Precision of nanoindentation protocols for measurement of viscoelasticity in cortical and trabecular bone

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Isaksson, Hanna¹; Nagao, Shijo²; MaŁkiewicz, Marta^1,2; Julkunen, Petro³; Nowak, Roman²; Jurvelin, Jukka S.¹

Precision of nanoindentation protocols for measurement of viscoelasticity in cortical and trabecular bone

J Biomech. 2010;43(12):2410-2417

Affiliations

¹Department of Physics and Mathematics, University of Eastern Finland, PO Box 1627, Kuopio 70211, Finland

²The Nordic Hysitron Laboratory, Faculty of Chemistry and Materials Science, Aalto University, FI-00076 Aalto, Finland

³Department of Clinical Neurophysiology, Kuopio University Hospital, Kuopio, Finland
Abstract and keywords

Nanoindentation has recently gained attention as a characterization technique for mechanical properties of biological tissues, such as bone, on the sub-micron level. However, optimal methods to characterize viscoelastic properties of bones are yet to be established. This study aimed to compare the time-dependent viscoelastic properties of bone tissue obtained with different nanoindentation methods. Bovine cortical and trabecular bone samples (n=8) from the distal femur and proximal tibia were dehydrated, embedded and polished. The material properties determined using nanoindentation were hardness and reduced modulus, as well as time-dependent parameters based on creep, loading-rate, dissipated energy and semi-dynamic testing under load control. Each loading protocol was repeated 160 times and the reproducibility was assessed based on the coefficient of variation (CV). Additionally, three well-characterized polymers were tested and CV values were calculated for reference.

The employed methods were able to characterize time-dependent viscoelastic properties of bone. However, their reproducibility varied highly (CV 9–40%). The creep constant increased with increasing dwell time. The reproducibility was best with a 30 s creep period (CV 18%). The dissipated energy was stable after three repeated load cycles, and the reproducibility improved with each cycle (CV 23%). The viscoelastic properties determined with semi-dynamic test increased with increase in frequency. These measurements were most reproducible at high frequencies (CV 9–10%). Our results indicate that several methods are feasible for the determination of viscoelastic properties of bone material. The high frequency semi-dynamic test showed the highest precision within the tested nanoindentation protocols.

Keywords: Nanoindentation; Viscoelastic; Creep; Strain-hardening; Dissipated energy; Semi-dynamic; Bovine
Links

DOI: 10.1016/j.jbiomech.2010.04.017

PubMed: 20478559

WoS: 000282112300024

Cited Works (22)

Year	Entry
2008	Lewis G, Nyman JS. The use of nanoindentation for characterizing the properties of mineralized hard tissues: state-of-the art review. J Biomed Mater Res. October 2008;B87(1):286-301.
1999	Roy ME, Rho J-Y, Tsui TY, Evans ND, Pharr GM. Mechanical and morphological variation of the human lumbar vertebral cortical and trabecular bone. J Biomed Mater Res. February 1999;A44(2):191-197.
2006	Bembey AK, Bushby AJ, Boyde A, Ferguson VL, Oyen ML. Hydration effects on the micro-mechanical properties of bone. J Mater Res. August 2006;21(8):1962-1968.
2007	Tai K, Dao M, Suresh S, Palazoglu A, Ortiz C. Nanoscale heterogeneity promotes energy dissipation in bone. Nat Mater. June 2007;6(6):454-462.
1999	Zysset PK, Guo XE, Hoffler CE, Moore KE, Goldstein SA. Elastic modulus and hardness of cortical and trabecular bone lamellae measured by nanoindentation in the human femur. J Biomech. October 1999;32(10):1005-1012.
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	Fan Z, Rho J-Y. Effects of viscoelasticity and time-dependent plasticity on nanoindentation measurements of human cortical bone. J Biomed Mater Res. October 1, 2003;A67(1):208-214.
2002	Wang X, Shen X, Li X, Agrawal CM. Age-related changes in the collagen network and toughness of bone [published correction appears in Bone. 2003;32(1):107]. Bone. 2002;31(1):1-7.
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.
2001	Wang X, Bank RA, Tekoppele JM, Agrawal CM. The role of collagen in determining bone mechanical properties. J Orthop Res. 2001;19(6):1021-1026.
2006	Bembey AK, Oyen ML, Bushby AJ, Boyde A. Viscoelastic properties of bone as a function of hydration state determined by nanoindentation. Philos Mag. November 21–December 11, 2006;86(33-35):5691-5703.
2008	Zhang J, Niebur GL, Ovaert TC. Mechanical property determination of bone through nano- and micro-indentation testing and finite element simulation. J Biomech. 2008;41(2):267-275.
1992	Oliver WC, Pharr GM. An improved technique for determining hardness and elastic modulus using load and displacement sensing indentation experiments. J Mater Res. 1992;7(6):1564-1583.
2008	Boivin G, Bala Y, Doublier A, Farlay D, Ste-Marie LG, Meunier PJ, Delmas PD. The role of mineralization and organic matrix in the microhardness of bone tissue from controls and osteoporotic patients. Bone. September 2008;43(3):532-538.
1995	Sasaki N, Enyo A. Viscoelastic properties of bone as a function of water content. J Biomech. 1995;28(7):809-815.
2002	Hengsberger S, Kulik A, Zysset P. Nanoindentation discriminates the elastic properties of individual human bone lamellae under dry and physiological conditions. Bone. 2002;30(1):178-184.
2008	Oyen ML, Ferguson VL, Bembey AK, Bushby AJ, Boyde A. Composite bounds on the elastic modulus of bone. J Biomech. August 7, 2008;41(11):2585-2588.
2006	Donnelly E, Baker SP, Boskey AL, van der Meulen MC. Effects of surface roughness and maximum load on the mechanical properties of cancellous bone measured by nanoindentation. J Biomed Mater Res. May 2006;A77(2):426-435.
2006	Mittra E, Akella S, Qin Y-X. The effects of embedding material, loading rate and magnitude, and penetration depth in nanoindentation of trabecular bone. J Biomed Mater Res. October 2006;A79(1):86-93.
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.
2002	Burr DB. The contribution of the organic matrix to bone's material properties. Bone. July 2002;31(1):8-11.
1998	Knott L, Bailey AJ. Collagen cross-links in mineralizing tissues: a review of their chemistry, function, and clinical relevance. Bone. March 1998;22(3):181-187.

Cited By (20)

Year	Entry
2018	Makuch AM, Skalski KR. Human cancellous bone mechanical properties and penetrator geometry in nanoindentation tests. Acta Bioeng Biomech. 2018;20(3):153-164.
2018	Wu D, Isaksson P, Ferguson SJ, Persson C. Young’s modulus of trabecular bone at the tissue level: a review. Acta Biomater. September 15, 2018;78:1.
2020	Chen X, Hughes R, Mullin N, Hawkins RJ, Holen I, Brown NJ, Hobbs JK. Mechanical heterogeneity in the bone microenvironment as characterized by atomic force microscopy. Biophys J. August 4, 2020;119(3):502-513.
2010	Isaksson H, Malkiewicz M, Nowak R, Helminen HJ, Jurvelin JS. Rabbit cortical bone tissue increases its elastic stiffness but becomes less viscoelastic with age. Bone. December 2010;47(6):1030-1038.
2011	Wu Z, Baker TA, Ovaert TC, Niebur GL. The effect of holding time on nanoindentation measurements of creep in bone. J Biomech. April 7, 2011;44(6):2055-2062.
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.
2020	Remache D, Semaan M, Rossi JM, Pithioux M, Milan J. Application of the Johnson-Cook plasticity model in the finite element simulations of the nanoindentation of the cortical bone. J Mech Behav Biomed Mater. January 2020;101:103426.
2015	Chittenden M, Najafi AR, Li J, Jasiuk I. Nanoindentation and ash content study of age dependent changes in porcine cortical bone. J Mech Med Biol. October 2015;15(5):1550074.
2021	Bonicelli A, Zioupos P, Arnold E, Rogers KD, Xhemali B, Kranioti EF. Age related changes of rib cortical bone matrix and the application to forensic age-at-death estimation. Sci Rep. January 22, 2021;11:2086.
2024	Szabo E. Insights Into the Mechanical Behavior of Maturing Cortical Bone: A Porcine Model [PhD thesis]. Cleveland, OH: Case Western Reserve University; May 2024.
2022	Peruzzi CRP. Nanoscale Deformation Mechanisms and Yield Prediction of Lamellar Bone [PhD thesis]. Swiss Federal Institute of Technology Zürich; 2022.
2015	Rodriguez-Florez N. Mechanics of Cortical Bone: Exploring the Micro- and Nano-Scale [PhD thesis]. Imperial College London; January 2015.
2015	Oftadeh R. Hierarchical Analysis and Multiscale Modelling of Cellular Structures: From Meta Materials to Bone Structure [PhD thesis]. Northeastern University; December 2015.
2019	Nobakhti S. Multiscale Characteristics of Bone Toughness [PhD thesis]. Northeastern University; July 2019.
2011	Wu Z. Measures of Bone Quality and Their Relationship to Bone Mechanical Properties [PhD thesis]. University of Notre Dame; December 2011.
2020	O’Sullivan LM. Time-Sequence of Biomechanical Adaption in Trabecular Tissue During Estrogen Deficiency [PhD thesis]. National University of Ireland Galway; March 2020.
2012	Jimenez Palomar I. Mechanical Properties of Bone At the Sub-lamellar Level [PhD thesis]. London, England: Queen Mary University of London; September 2012.
2021	Frank M. Mechanical Characterization of Individual Trabeculae [PhD thesis]. Vienna University of Technology; February 2021.
2017	Tilak K. Finite Element Simulation of Nanoindentation in Lamellar Bone Composites [Master's thesis]. San Antionio, TX: University of Texas at San Antonio; May 2017.
2014	Slane JA. The Use of Micro and Nano Particulate Fillers to Modify the Mechanical and Material Properties of Acrylic Bone Cement [PhD thesis]. University of Wisconsin – Madison; 2014.