A whole bone-lacunocanalicular network-osteocyte model examining bone adaptation to distinct loading parameters

IF 7.1 1区工程技术 Q1 ENGINEERING, MECHANICAL

International Journal of Mechanical Sciences Pub Date : 2025-01-15 DOI:10.1016/j.ijmecsci.2025.109931

Ruisen Fu, Chenlu Wang, Nusrat Shahneela, Rahman Ud Din, Haisheng Yang

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Abstract

The mechanical adaptive responses of bone are affected by various parameters of the loading, such as magnitude, rate, frequency, number of cycles, and recovery time. However, the precise relationships between different loading parameters and bone adaptation as well as their governing mechanism remain unclear. Here, we developed a novel multi-scale model of whole bone-lacunocanalicular network (LCN)-osteocyte characterizing whole-bone deformation-produced fluid flow within a large LCN as well as responses of osteocytes to fluid shear stress (FSS) via opening, closing, or inactivating mechanosensitive ion channels (MSIC). The model was next used to examine the effects of loading magnitude, frequency, cycle numbers, and recovery time on the responses of osteocytes. Results showed that the load magnitude and frequency mainly affected the proportion of open MSIC by changing FSS on the osteocytes. When the load-induced FSS increased, the proportion of open osteocyte MSIC was enhanced. With an increase in the cycle number, MSIC transformed gradually from an open state into an inactivated state, resulting in saturation in response to continuous FSS. Interestingly, a short-term recovery time restored the MSIC to a closed state which could turn into an open state following subsequent loading, while a long-term recovery time was helpful for recovering the mechanical sensitivity of the osteocytes. These computational results largely replicated the mechanical responses of bone as observed in in vivo animal loading experiments, suggesting the importance of osteocyte MSIC in response to different loading parameters. This multi-scale model considering osteocyte MSIC could provide mechanistic insights into bone adaptation to distinct mechanical stimuli.

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整个骨-腔隙网络-骨细胞模型研究骨对不同载荷参数的适应性

载荷的大小、速率、频率、循环次数和恢复时间等参数对骨的力学自适应反应有影响。然而，不同载荷参数与骨适应之间的确切关系及其调控机制尚不清楚。在这里，我们开发了一种新的全骨-腔隙管网络(LCN)-骨细胞的多尺度模型，该模型表征了大LCN内全骨变形产生的流体流动，以及骨细胞通过打开、关闭或失活机械敏感离子通道（MSIC）对流体剪切应力（FSS）的反应。该模型随后被用于检测加载强度、频率、周期数和恢复时间对骨细胞反应的影响。结果表明，载荷大小和频率主要通过改变骨细胞的FSS来影响开放MSIC的比例。当负载诱导的FSS增加时，开放骨细胞MSIC的比例增加。随着循环数的增加，MSIC逐渐从开放状态转变为失活状态，导致对连续FSS的响应饱和。有趣的是，短期恢复时间将MSIC恢复到闭合状态，并在随后的加载中变为开放状态，而长期恢复时间有助于恢复骨细胞的机械敏感性。这些计算结果在很大程度上复制了在体内动物加载实验中观察到的骨的力学响应，表明骨细胞MSIC在响应不同加载参数中的重要性。这个考虑骨细胞MSIC的多尺度模型可以提供骨适应不同机械刺激的机制见解。

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

International Journal of Mechanical Sciences 工程技术-工程：机械

CiteScore

12.80

自引率

17.80%

发文量

769

审稿时长

19 days

期刊介绍： The International Journal of Mechanical Sciences (IJMS) serves as a global platform for the publication and dissemination of original research that contributes to a deeper scientific understanding of the fundamental disciplines within mechanical, civil, and material engineering. The primary focus of IJMS is to showcase innovative and ground-breaking work that utilizes analytical and computational modeling techniques, such as Finite Element Method (FEM), Boundary Element Method (BEM), and mesh-free methods, among others. These modeling methods are applied to diverse fields including rigid-body mechanics (e.g., dynamics, vibration, stability), structural mechanics, metal forming, advanced materials (e.g., metals, composites, cellular, smart) behavior and applications, impact mechanics, strain localization, and other nonlinear effects (e.g., large deflections, plasticity, fracture). Additionally, IJMS covers the realms of fluid mechanics (both external and internal flows), tribology, thermodynamics, and materials processing. These subjects collectively form the core of the journal's content. In summary, IJMS provides a prestigious platform for researchers to present their original contributions, shedding light on analytical and computational modeling methods in various areas of mechanical engineering, as well as exploring the behavior and application of advanced materials, fluid mechanics, thermodynamics, and materials processing.