Abstract
The recent studies have shown that long-term bisphosphonate use may result in a number of mechanical alterations in the bone tissue including a reduction in compositional heterogeneity and an increase in microcrack density. There are limited number of experimental and computational studies in the literature that evaluated how these modifications affect crack initiation and propagation in cortical bone. Therefore, in this study, the entire crack growth process including initiation and propagation was simulated at the microscale by using the cohesive extended finite element method. Models with homogeneous and heterogeneous material properties (represented at the microscale capturing the variability in material property values and their distribution) as well as different microcrack density and microstructure were compared. The results showed that initiation fracture resistance was higher in models with homogeneous material properties compared to heterogeneous ones, whereas an opposite trend was observed in propagation fracture resistance. The increase in material heterogeneity level up to 10 different material property sets increased the propagation fracture resistance beyond which a decrease was observed while still remaining higher than the homogeneous material distribution. The simulation results also showed that the total osteonal area influenced crack propagation and the local osteonal area near the initial crack affected the crack initiation behavior. In addition, the initiation fracture resistance was higher in models representing bisphosphonate treated bone (low material heterogeneity, high microcrack density) compared to untreated bone models (high material heterogeneity, low microcrack density), whereas an opposite trend was observed at later stages of crack growth. In summary, the results demonstrated that tissue material heterogeneity, microstructure, and microcrack density influenced crack initiation and propagation differently. The findings also elucidate how possible modifications in material heterogeneity and microcrack density due to bisphosphonate treatment may influence the initiation and propagation fracture resistance of cortical bone.
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References
Acevedo C et al (2015) Alendronate treatment alters bone tissues at multiple structural levels in healthy canine cortical bone. Bone 81:352–363
Akkus O, Rimnac CM (2001) Cortical bone tissue resists fatigue fracture by deceleration and arrest of microcrack growth. J Biomech 34:757–764
Allen MR, Burr DB (2007) Mineralization, microdamage, and matrix: how bisphosphonates influence material properties of bone. BoneKEy-Osteovision 4:49–60
Allen MR, Burr DB (2011) Bisphosphonate effects on bone turnover, microdamage, and mechanical properties: what we think we know and what we know that we don’t know. Bone 49:56–65. https://doi.org/10.1016/j.bone.2010.10.159
Allen MR, Iwata K, Phipps R, Burr DB (2006) Alterations in canine vertebral bone turnover, microdamage accumulation, and biomechanical properties following 1-year treatment with clinical treatment doses of risedronate or alendronate. Bone 39:872–879
Allen MR, Reinwald S, Burr DB (2008) Alendronate reduces bone toughness of ribs without significantly increasing microdamage accumulation in dogs following 3 years of daily treatment. Calcif Tissue Int 82:354–360
ASTM E399 (2012) ASTM Standard E399 standard test method for linear-elastic plane-strain fracture toughness KIc of metallic materials. https://doi.org/10.1520/E0399
Bajaj D, Geissler JR, Allen MR, Burr DB, Fritton J (2014) The resistance of cortical bone tissue to failure under cyclic loading is reduced with alendronate. Bone 64:57–64
Bala Y et al (2012) Bone micromechanical properties are compromised during long-term alendronate therapy independently of mineralization. J Bone Miner Res 27:825–834. https://doi.org/10.1002/jbmr.1501
Boskey AL (2013) Bone composition: relationship to bone fragility and antiosteoporotic drug effects. BoneKEy Rep. https://doi.org/10.1038/bonekey.2013.181
Boskey AL et al (2016) Examining the relationships between bone tissue composition, compositional heterogeneity, and fragility fracture: a matched case-controlled FTIRI study. J Bone Miner Res 31:1070–1081. https://doi.org/10.1002/jbmr.2759
Boskey AL, Spevak L, Weinstein RS (2009) Spectroscopic markers of bone quality in alendronate-treated postmenopausal women. Osteoporos Int 20:793–800. https://doi.org/10.1007/s00198-008-0725-9
Bousson V, Bergot C, Wu Y, Jolivet E, Zhou LQ, Laredo J-D (2011) Greater tissue mineralization heterogeneity in femoral neck cortex from hip-fractured females than controls. A microradiographic study. Bone 48:1252–1259
Brock GR, Chen JT, Ingraffea AR, MacLeay J, Pluhar GE, Boskey AL, van der Meulen MC (2015) The effect of osteoporosis treatments on fatigue properties of cortical bone tissue. Bone Rep 2:8–13
Camanho PP, Davila CG, de Moura MF (2003) Numerical simulation of mixed-mode progressive delamination in composite materials. J Compos Mater 37:1415–1438. https://doi.org/10.1177/0021998303034505
Chapurlat RD, Arlot M, Burt-Pichat B, Chavassieux P, Roux JP, Portero-Muzy N, Delmas PD (2007) Microcrack frequency and bone remodeling in postmenopausal osteoporotic women on long-term bisphosphonates: a bone biopsy study. J Bone Miner Res 22:1502–1509. https://doi.org/10.1359/jbmr.070609
Chapurlat RD, Delmas PD (2009) Bone microdamage: a clinical perspective. Osteoporos Int 20:1299–1308. https://doi.org/10.1007/s00198-009-0899-9
Ciarelli TE, Tjhia C, Rao DS, Qiu S, Parfitt AM, Fyhrie DP (2009) Trabecular packet-level lamellar density patterns differ by fracture status and bone formation rate in white females. Bone 45:903–908
Demirtas A, Curran E, Ural A (2016) Assessment of the effect of reduced compositional heterogeneity on fracture resistance of human cortical bone using finite element modeling. Bone 91:92–101. https://doi.org/10.1016/j.bone.2016.07.015
Dong XN, Zhang X, Guo XE (2005) Interfacial strength of cement lines in human cortical bone. Mech Chem Biosyst 2:63–68
Donnelly E et al (2012) Reduced cortical bone compositional heterogeneity with bisphosphonate treatment in postmenopausal women with intertrochanteric and subtrochanteric fractures. J Bone Miner Res 27:672–678. https://doi.org/10.1002/jbmr.560
Ettinger B, Burr DB, Ritchie RO (2013) Proposed pathogenesis for atypical femoral fractures: lessons from materials research. Bone 55:495–500. https://doi.org/10.1016/j.bone.2013.02.004
Forwood MR, Burr DB, Takano Y, Eastman DF, Smith PN, Schwardt JD (1995) Risedronate treatment does not increase microdamage in the canine femoral neck. Bone 16:643–650
Gourion-Arsiquaud S, Lukashova L, Power J, Loveridge N, Reeve J, Boskey AL (2013) Fourier transform infrared imaging of femoral neck bone: reduced heterogeneity of mineral-to-matrix and carbonate-to-phosphate and more variable crystallinity in treatment-naive fracture cases compared with fracture-free controls. J Bone Miner Res 28:150–161
Granke M, Makowski AJ, Uppuganti S, Nyman JS (2016) Prevalent role of porosity and osteonal area over mineralization heterogeneity in the fracture toughness of human cortical bone. J Biomech 49:2748–2755
Iwata K, Mashiba T, Hitora T, Yamagami Y, Yamamoto T (2014) A large amount of microdamages in the cortical bone around fracture site in a patient of atypical femoral fracture after long-term bisphosphonate therapy. Bone 64:183–186. https://doi.org/10.1016/j.bone.2014.04.012
Khosla S, Shane E (2016) A crisis in the treatment of osteoporosis. J Bone Miner Res 31:1485–1487
Koester KJ, Ager J, Ritchie R (2008) The true toughness of human cortical bone measured with realistically short cracks. Nat Mater 7:672–677
Komatsubara S et al (2004) Suppressed bone turnover by long-term bisphosphonate treatment accumulates microdamage but maintains intrinsic material properties in cortical bone of dog rib. J Bone Miner Res 19:999–1005. https://doi.org/10.1359/JBMR.040126
Lloyd AA et al (2017) Atypical fracture with long-term bisphosphonate therapy is associated with altered cortical composition and reduced fracture resistance Proc Natl Acad Sci 114:8722–8727
Ma S et al (2017) Long-term effects of bisphosphonate therapy: perforations, microcracks and mechanical properties. Sci Rep 7:43399. https://doi.org/10.1038/srep43399
Mashiba T, Hirano T, Turner CH, Forwood MR, Johnston CC, Burr DB (2000) Suppressed bone turnover by bisphosphonates increases microdamage accumulation and reduces some biomechanical properties in dog rib. J Bone Miner Res 15:613–620. https://doi.org/10.1359/jbmr.2000.15.4.613
Mashiba T, Turner CH, Hirano T, Forwood MR, Johnston CC, Burr DB (2001) Effects of suppressed bone turnover by bisphosphonates on microdamage accumulation and biomechanical properties in clinically relevant skeletal sites in beagles. Bone 28:524–531. https://doi.org/10.1016/S8756-3282(01)00414-8
Mast P, Nash G, Michopoulos J, Thomas R, Badaliance R, Wolock I (1995) Characterization of strain-induced damage in composites based on the dissipated energy density part I. Basic scheme and formulation. Theor Appl Fract Mech 22:71–96
McCalden RW, McGeough JA, Barker MB, Court-Brown CM (1993a) Age-related changes in the tensile properties of cortical bone. The relative importance of changes in porosity, mineralization, and microstructure. J Bone Joint Surg Am 75:1193–1205
McCalden RW, McGeough JA, Barker MB, Court-Brown CM (1993b) Age-related changes in the tensile properties of cortical bone. The relative importance of changes in porosity, mineralization, and microstructure. J Bone Joint Surg Am 75:1193–1205
Mischinski S, Ural A (2013) Interaction of microstructure and microcrack growth in cortical bone: a finite element study. Comput Methods Biomech Biomed Eng 16:81–94. https://doi.org/10.1080/10255842.2011.607444
Moës N, Belytschko T (2002) Extended finite element method for cohesive crack growth. Eng Fract Mech 69:813–833
Monier-Faugere M-C et al (1999) Intermittent and continuous administration of the bisphosphonate ibandronate in ovariohysterectomized beagle dogs: effects on bone morphometry and mineral properties. J Bone Miner Res 14:1768–1778. https://doi.org/10.1359/jbmr.1999.14.10.1768
Nalla RK, Kinney JH, Ritchie RO (2003) Mechanistic fracture criteria for the failure of human cortical bone. Nat Mater 2:164–168. https://doi.org/10.1038/nmat832
Norman TL, Yeni Y, Brown C, Wang Z (1998) Influence of microdamage on fracture toughness of the human femur and tibia. Bone 23:303–306
O’Brien FJ, Taylor D, Lee TC (2003) Microcrack accumulation at different intervals during fatigue testing of compact bone. J Biomech 36:973–980
O’Brien FJ, Taylor D, Clive Lee T (2007) Bone as a composite material: the role of osteons as barriers to crack growth in compact bone. Int J Fatigue 29:1051–1056. https://doi.org/10.1016/j.ijfatigue.2006.09.017
Ortiz M, Pandolfi A (1999) Finite-deformation irreversible cohesive elements for three-dimensional crack-propagation analysis. Int J Numer Methods Eng 44:1267–1282. https://doi.org/10.1002/(SICI)1097-0207(19990330)44:9%3c1267::AID-NME486%3e3.0.CO;2-7
Phelps J, Hubbard G, Wang X, Agrawal C (2000) Microstructural heterogeneity and the fracture toughness of bone. J Biomed Mater Res Part A 51:735–741
Reilly DT, Burstein AH (1975) The elastic and ultimate properties of compact bone tissue. J Biomech 8:393–405
Rho JY, Tsui TY, Pharr GM (1997) Elastic properties of human cortical and trabecular lamellar bone measured by nanoindentation. Biomaterials 18:1325–1330
Roschger P, Rinnerthaler S, Yates J, Rodan GA, Fratzl P, Klaushofer K (2001) Alendronate increases degree and uniformity of mineralization in cancellous bone and decreases the porosity in cortical bone of osteoporotic women. Bone 29:185–191. https://doi.org/10.1016/S8756-3282(01)00485-9
Schaffler MB, Choi K, Milgrom C (1995) Aging and matrix microdamage accumulation in human compact bone. Bone 17:521–525
Shane E et al (2010) Atypical subtrochanteric and diaphyseal femoral fractures: report of a task force of the American Society for Bone and Mineral Research. J Bone Miner Res 25:2267–2294. https://doi.org/10.1002/jbmr.253
Stepan JJ et al (2007) Low bone mineral density is associated with bone microdamage accumulation in postmenopausal women with osteoporosis. Bone 41:378–385. https://doi.org/10.1016/j.bone.2007.04.198
Tai K, Dao M, Suresh S, Palazoglu A, Ortiz C (2007) Nanoscale heterogeneity promotes energy dissipation in bone. Nat Mater 6:454–462
Tamminen IS et al (2014) Increased heterogeneity of bone matrix mineralization in pediatric patients prone to fractures: a biopsy study. J Bone Miner Res 29:1110–1117
Tjhia CK, Odvina CV, Rao DS, Stover SM, Wang X, Fyhrie DP (2011) Mechanical property and tissue mineral density differences among severely suppressed bone turnover (SSBT) patients, osteoporotic patients, and normal subjects. Bone 49:1279–1289. https://doi.org/10.1016/j.bone.2011.09.042
Ural A, Vashishth D (2006) Cohesive finite element modeling of age-related toughness loss in human cortical bone. J Biomech 39:2974–2982. https://doi.org/10.1016/j.jbiomech.2005.10.018
Vashishth D, Behiri JC, Bonfield W (1997) Crack growth resistance in cortical bone: concept of microcrack toughening. J Biomech 30:763–769
Vashishth D, Gibson GJ, Khoury JI, Schaffler MB, Kimura J, Fyhrie DP (2001) Influence of nonenzymatic glycation on biomechanical properties of cortical bone. Bone 28:195–201. https://doi.org/10.1016/S8756-3282(00)00434-8
Vennin S, Desyatova A, Turner JA, Watson PA, Lappe JM, Recker RR, Akhter MP (2017) Intrinsic material property differences in bone tissue from patients suffering low-trauma osteoporotic fractures, compared to matched non-fracturing women. Bone 97:233–242. https://doi.org/10.1016/j.bone.2017.01.031
Wang X, Shen X, Li X, Mauli Agrawal C (2002) Age-related changes in the collagen network and toughness of bone. Bone 31:1–7. https://doi.org/10.1016/S8756-3282(01)00697-4
Yao H, Dao M, Carnelli D, Tai K, Ortiz C (2011) Size-dependent heterogeneity benefits the mechanical performance of bone. J Mech Phys Solids 59:64–74
Zioupos P (2001) Accumulation of in-vivo fatigue microdamage and its relation to biomechanical properties in ageing human cortical bone. J Microsc 201:270–278
Zioupos P, Currey JD (1998) Changes in the stiffness, strength, and toughness of human cortical bone with age. Bone 22:57–66
Acknowledgements
This study was funded by National Science Foundation Award No. CMMI-1434412. The computational resources for this study were supported by XSEDE Award No. MSS-160001.
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Demirtas, A., Ural, A. Material heterogeneity, microstructure, and microcracks demonstrate differential influence on crack initiation and propagation in cortical bone. Biomech Model Mechanobiol 17, 1415–1428 (2018). https://doi.org/10.1007/s10237-018-1035-6
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DOI: https://doi.org/10.1007/s10237-018-1035-6