A Numerical Study of Crack Penetration and Deflection at the Interface Between Peritubular and Intertubular Dentin.

IF 1.7 4区 医学 Q4 BIOPHYSICS
Min Xu, Zhangying Xu, Bingbing An
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Abstract

Dentin is a biological composite exhibiting multilevel hierarchical structure, which confers excellent damage tolerance to this tissue. Despite the progress in characterization of fracture behavior of dentin, the contribution of composite structure consisting of peritubular dentin (PTD), intertubular dentin (ITD) and tubules to fracture resistance remains elusive. In this study, calculations are carried out for energy release rate associated with crack propagation in the microstructure of dentin. Crack penetration and deflection at the PTD-ITD interface are accounted for in the numerical analyses. It is found that high stiffness of the PTD plays a role in increasing crack driving force, promoting crack growth in the microstructure of dentin. For crack penetration across the PTD-ITD interface, the crack driving force increases with increasing tubule radius; and thick PTD generates amplified crack driving force, thereby leading to weak fracture resistance. The driving force for crack deflection increases with the increase in tubule radius in the case of short cracks, while for long cracks, there is a decrease in driving force with increasing tubule radius. Furthermore, we show that the competition between crack penetration and deflection at the PTD-ITD interface is controlled by the ratio of PTD to ITD elastic modulus, tubule radius and thickness of PTD. High PTD stiffness can increase the propensity of crack deflection. The microstructure of dentin with large tubule radius favors crack deflection and thick PTD is beneficial for crack penetration.

管周牙本质和管间牙本质界面裂缝穿透和变形的数值研究
牙本质是一种生物复合材料,表现出多层次的分层结构,使该组织具有极佳的耐损伤性。尽管在描述牙本质的断裂行为方面取得了进展,但由管周牙本质 (PTD)、管间牙本质 (ITD) 和小管组成的复合结构对断裂抗力的贡献仍然难以确定。本研究对牙本质微观结构中与裂纹扩展相关的能量释放率进行了计算。在数值分析中考虑了 PTD-ITD 界面的裂纹穿透和变形。结果发现,PTD 的高刚度会增加裂纹驱动力,促进牙本质微观结构中的裂纹生长。对于穿过 PTD-ITD 界面的裂纹穿透,裂纹驱动力随着小管半径的增加而增加;厚 PTD 产生的裂纹驱动力被放大,从而导致抗断裂性减弱。对于短裂纹,裂纹挠曲驱动力随小管半径的增大而增大,而对于长裂纹,驱动力则随小管半径的增大而减小。此外,我们还发现 PTD-ITD 界面上裂纹穿透与挠曲之间的竞争受 PTD 与 ITD 弹性模量之比、小管半径和 PTD 厚度的控制。PTD 刚度高会增加裂纹偏转的倾向。小管半径大的牙本质微观结构有利于裂纹偏转,厚的 PTD 有利于裂纹穿透。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
3.40
自引率
5.90%
发文量
169
审稿时长
4-8 weeks
期刊介绍: Artificial Organs and Prostheses; Bioinstrumentation and Measurements; Bioheat Transfer; Biomaterials; Biomechanics; Bioprocess Engineering; Cellular Mechanics; Design and Control of Biological Systems; Physiological Systems.
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