对加载骨单位的骨小管内的流体流动和流体剪切应力进行数学建模。

Mathematically modeling fluid flow and fluid shear stress in the canaliculi of a loaded osteon.

作者信息

Wu Xiaogang, Wang Ningning, Wang Zhaowei, Yu Weilun, Wang Yanqin, Guo Yuan, Chen Weiyi

机构信息

Shanxi Key Lab. of Material Strength & Structural Impact and College of Mechanics, Taiyuan University of Technology, Taiyuan, 030024, People's Republic of China.

出版信息

Biomed Eng Online. 2016 Dec 28;15(Suppl 2):149. doi: 10.1186/s12938-016-0267-x.

DOI:10.1186/s12938-016-0267-x

PMID:28155688

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5260136/

Abstract

BACKGROUND

Mechanical load-induced intraosseous pressure gradients may result in some fluid stimuli effects, such as fluid flow and fluid shear stress (FSS), which may enable bone cells to detect external mechanical signals. Interstitial bone fluid flow is known to occur in lacunar-canalicular porosity (PLC).

METHODS

In order to characterize lacunar-canalicular fluid flow behavior, a hierarchical osteon system is developed. The osteon is modeled as a poroelastic annular cylinder with two types of impermeable boundary cases considered on its outer wall: one is elastic restrained (Case I), whereas the other is displacement confined (Case II). Analytical solutions such as canalicular fluid velocity, pressure, fluid flow rate (FFR), and shear stress are obtained.

RESULTS

Results show that the amplitudes of FFR and FSS are proportional to strain amplitude and frequency. However, the key loading factor governing canalicular fluid flow behavior is the strain rate. The larger canalicular radius is, the larger amplitudes of FFR and FSS generalized, especially, the FSS amplitude is proportional to canalicular radius. In addition, both FFR and FSS amplitudes produced in case II are larger than those of case I.

CONCLUSION

Strain rate can be acted as a representative loading parameter governing the canalicular fluid flow behavior under a physiological state. This model can facilitate better understanding the load induced the fluid permeation in the PLC. The approach can also be used to analyze the structure of the proteoglycan matrix in the fluid space surrounding the osteocytic process in the canaliculus.

摘要

背景

机械负荷引起的骨内压力梯度可能会产生一些流体刺激效应，如流体流动和流体剪切应力（FSS），这可能使骨细胞能够检测外部机械信号。已知间隙骨液流动发生在骨陷窝-骨小管孔隙率（PLC）中。

方法

为了表征骨陷窝-骨小管内的流体流动行为，构建了一个分层骨单位系统。将骨单位建模为一个多孔弹性环形圆柱体，并考虑其外壁上的两种不可渗透边界情况：一种是弹性约束（情况I），另一种是位移受限（情况II）。获得了诸如骨小管内流体速度、压力、流体流速（FFR）和剪切应力等解析解。

结果

结果表明，FFR和FSS的幅值与应变幅值和频率成正比。然而，控制骨小管内流体流动行为的关键加载因素是应变率。骨小管半径越大，FFR和FSS的幅值越大，特别是FSS幅值与骨小管半径成正比。此外，情况II中产生的FFR和FSS幅值均大于情况I。

结论

应变率可作为生理状态下控制骨小管内流体流动行为的代表性加载参数。该模型有助于更好地理解PLC中负荷诱导的流体渗透。该方法还可用于分析骨小管内骨细胞突起周围流体空间中蛋白聚糖基质的结构。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/3872/5260136/56f1d09ba200/12938_2016_267_Fig1_HTML.jpg

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对加载骨单位的骨小管内的流体流动和流体剪切应力进行数学建模。

Mathematically modeling fluid flow and fluid shear stress in the canaliculi of a loaded osteon.

作者信息

机构信息

出版信息

BACKGROUND

METHODS

RESULTS

CONCLUSION

背景

方法

结果

结论

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