Manipulating load-induced fluid flow in vivo to promote bone adaptation.

Bone Pub Date : 2022-09-01 DOI:10.2139/ssrn.4168547

Quentin Meslier, Nicole DiMauro, Priya Somanchi, Sarah Nano, S. Shefelbine

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引用次数: 2

Abstract

Mechanical stimulation is critical to maintaining bone mass and strength. Strain has been commonly thought of as the mechanical stimulus driving bone adaptation. However, numerous studies have hypothesized that fluid flow in the lacunar-canalicular system plays a role in mechanoadaptation. The role of fluid flow compared to strain magnitude on bone remodeling has yet to be characterized. This study aimed to determine the contribution of fluid flow velocity compared to strain on bone adaptation. We used finite element modeling to design in vivo experiments, manipulating strain and fluid flow contributions. Using a uniaxial compression tibia model in mice, we demonstrated that high fluid flow velocity results in significant bone adaptation even under low strain magnitude. In contrast, high strain magnitude paired with low fluid velocity does not trigger a bone response. These findings support previous hypotheses stating that fluid flow is the principal mechanical stimulus driving bone adaptation. Moreover, they give new insights regarding bone adaptative response and provide new pathways toward treatment against age-related mechanosensitivity loss in bone.

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控制体内负荷诱导的流体流动以促进骨适应。

机械刺激对维持骨量和强度至关重要。应变通常被认为是驱动骨适应的机械刺激。然而，许多研究假设腔隙-管系统中的流体流动在机械适应中起作用。与应变量级相比，流体流量对骨重塑的作用尚未得到表征。本研究旨在确定流体流速相对于应变对骨适应的贡献。我们使用有限元模型来设计体内实验，控制应变和流体流动的贡献。通过小鼠单轴压缩胫骨模型，我们证明了即使在低应变量级下，高流体流速也会导致显著的骨适应。相反，高应变量级与低流体速度配对不会引发骨反应。这些发现支持了先前的假设，即流体流动是驱动骨适应的主要机械刺激。此外，它们为骨适应性反应提供了新的见解，并为治疗与年龄相关的骨机械敏感性丧失提供了新的途径。

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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Bone

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