An interface damage model that captures crack propagation at the microscale in cortical bone using XFEM

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Gustafsson, Anna¹; Khayyeri, Hanifeh¹; Wallin, Mathias²; Isaksson, Hanna¹

An interface damage model that captures crack propagation at the microscale in cortical bone using XFEM

J Mech Behav Biomed Mater. February 2019;90:556-565

©2018 Elsevier Ltd. All rights reserved.

Affiliations

¹Department of Biomedical Engineering, Lund University, Box 118, SE-221 00 Lund, Sweden

²Division of Solid Mechanics, Lund University, Box 118, SE-221 00 Lund, Sweden
Abstract and keywords

Reliable tools for fracture risk assessment are necessary to handle the challenge with an aging population and the increasing occurrence of bone fractures. As it is currently difficult to measure local damage parameters experimentally, computational models could be used to provide insight into how cortical bone microstructure and material properties contribute to the fracture resistance. In this study, a model for crack propagation in 2D at the microscale in cortical bone was developed using the extended finite element method (XFEM). By combining the maximum principal strain criterion with an additional interface damage formulation in the cement line, the model could capture crack deflections at the osteon boundaries as observed in experiments. The model was used to analyze how the Haversian canal and the interface strength of the cement line affected the crack trajectory in models depicting osteons with three different orientations in 2D. Weak cement line interfaces were found to reorient the propagating cracks while models with strong interfaces predicted crack trajectories that penetrated the cement line and propagated through the osteons. The presented model is a promising tool that could be used to analyze how local, age-related material changes influence the crack trajectory and fracture resistance in cortical bone.

Keywords: Microstructure; Crack deflection; Cement line; Osteon; Haversian canal
Links

DOI: 10.1016/j.jmbbm.2018.09.045

PubMed: 30472565

WoS: 000457510500061
History

Received: 2018-07-17

Revised: 2018-09-05

Accepted: 2018-09-26

Online: 2018-10-01

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2019	Gustafsson A, Wallin M, Isaksson H. Age-related properties at the microscale affect crack propagation in cortical bone. J Biomech. October 11, 2019;95:109326.
2021	Maghami E, Josephson TO, Moore JP, Rezaee T, Freeman TA, Karim L, Najafi AR. Fracture behavior of human cortical bone: role of advanced glycation end-products and microstructural features. J Biomech. August 26, 2021;125:110600.
2022	Kim S, Baril C, Rudraraju S, Ploeg H-L. Influence of porosity on fracture toughness and fracture behavior of antibiotic-loaded PMMA bone cement. J Biomech Eng. January 2022;144(1):011006.
2022	Gustafsson A, Isaksson H. Phase field models of interface failure for bone application: evaluation of open-source implementations. Theor Appl Fract Mech. October 2022;121:103432.
2020	Moore JP. Mechanical Response and Damage Evolution of Microstructural Cortical Bone Under Compression and Tension [Master's thesis]. Drexel University; June 2020.
2023	Maghami E. Fracture Micromechanics Analyses of Hard Tissues: Study of Increased Glycation Through Diabetes and Age-Related Changes [PhD thesis]. Drexel University; January 2023.
2022	Rahovich P. Effects of Bone Structural Unit (BSU) Geometry and Material Properties on Crack Growth Through Idealized Trabecular Microstructures [Master's thesis]. Sudbury, ON: Laurentian University; 2022.