Modelling the micro-damage process zone during cortical bone fracture

Dapaah, Daniel<sup>1</sup>; Badaoui, Raphael<sup>1,2</sup>; Bahmani, Aram<sup>3</sup>; Montesano, John<sup>1,3</sup>; Willett, Thomas<sup>1,3</sup>

Affiliations

¹Systems Design Engineering, University of Waterloo, 200 University Ave. W., Waterloo, Canada

²Bio-Mechanics and Bio-Engineering, Université de Technologie Compiègne, rue Roger Coutolenc, 60205 Compiègne, France

³Mechanical and Mechatronics Engineering, University of Waterloo, 200 University Ave. W., Waterloo, Canada

Abstract and keywords

Cortical bone employs intrinsic toughening mechanisms to delay crack growth initiation and propagation hence increasing its fracture toughness. Computational models of the bone fracture process though do not explicitly capture these intrinsic local toughening mechanisms. Such models could provide insights into possible sub-microscale mechanisms involved in the bone fracture process. Therefore, in this study, the intrinsic toughening mechanism referred to as the micro-damage process zone (MDPZ) was modelled using a bi-linear continuum damage law. This model was then experimentally validated using single edge notch bending specimens and digital image correlation for strain field measurements. The size and shape of the micro-damage process zone as well as the load-deflection curves generated by the model reasonably replicated those measured experimentally. The results indicate that the continuum damage mechanics approach is a robust means of modelling the MDPZ at the continuum level and with further development of the model can provide a useful tool for studies of the fracture process in cortical bone.

Keywords: Cortical bone; Fracture energy; Micro-damage; Process zone; Continuum damage mechanics

Links

DOI: 10.1016/j.engfracmech.2019.106811

WoS: 000504452100031

History

Received: 2019-07-20

Revised: 2019-12-3

Accepted: 2019-12-3

Online: 2019-12-7

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Year	Entry
2022	Dai X, Fan R, Wu H, Jia Z. Investigation on the differences in the failure processes of the cortical bone under different loading conditions. Appl Bionics Biomech. 2022;2022:3406984.
2022	Buccino F, Bagherifard S, D'Amico L, Zagra L, Banfi G, Tromba G, Vergani LM. Assessing the intimate mechanobiological link between human bone micro-scale trabecular architecture and micro-damages. Eng Fract Mech. July 2022;270:108582.
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.