基于双向流固耦合的骨修复支架设计与研究

Design and research of bone repair scaffold based on two-way fluid-structure interaction.

作者信息

Fu Mengguang, Wang Fei, Lin Guimei

机构信息

School of Mechanical and Automotive Engineering, Qilu University of Technology (Shandong Academy of Sciences), Jinan 250353, China.

出版信息

Comput Methods Programs Biomed. 2021 Jun;204:106055. doi: 10.1016/j.cmpb.2021.106055. Epub 2021 Mar 18.

DOI:10.1016/j.cmpb.2021.106055

PMID:33784546

Abstract

BACKGROUND AND OBJECTIVE

Porous bone repair scaffolds are an important method of repairing bone defects. Fluid flow in the scaffold plays a vital role in tissue differentiation and permeability and fluid shear stress (FSS) are two important factors. The differentiation of bone tissue depends on the osteogenic differentiation of cells, FSS affects cell proliferation and differentiation, and permeability affects the transportation of nutrients and metabolic waste. Therefore, it is necessary to better understand and analyze the FSS on the cell surface and the permeability of the scaffold to obtain better osteogenic performance.

METHODS

In this study, computational fluid dynamics (CFD) was used to analyze fluid flow in the scaffold. Three structures and nine scaffold unit cell models were designed and the cell models were loaded onto the scaffold surface. Considering cell deformability, the two-way fluid-structure interaction (FSI) method was used to evaluate the FSS on the cell surface.

RESULTS

The simulation results showed that as the pore size of the scaffold increases, its permeability increases and the FSS decreases. The FSS received on the cell surface was much larger than scaffold surface. Moreover the FSS on the cell surface was distributed in steps.

CONCLUSIONS

The results showed the permeability of all models matches that of human bone tissue. Based on the cell surface FSS as the criterion, it was found that the spherical-560 scaffold exhibited the best osteogenic performance. This provided a strategy to design a better bone repair scaffold from biological aspects.

摘要

背景与目的

多孔骨修复支架是修复骨缺损的重要方法。支架内的流体流动在组织分化中起着至关重要的作用，渗透率和流体剪切应力（FSS）是两个重要因素。骨组织的分化取决于细胞的成骨分化，FSS影响细胞增殖和分化，渗透率影响营养物质的运输和代谢废物的排出。因此，有必要更好地理解和分析细胞表面的FSS以及支架的渗透率，以获得更好的成骨性能。

方法

在本研究中，采用计算流体动力学（CFD）分析支架内的流体流动。设计了三种结构和九个支架单胞模型，并将细胞模型加载到支架表面。考虑细胞的可变形性，采用双向流固耦合（FSI）方法评估细胞表面的FSS。

结果

模拟结果表明，随着支架孔径的增加，其渗透率增加，FSS降低。细胞表面受到的FSS远大于支架表面。此外，细胞表面的FSS呈阶梯状分布。

结论

结果表明所有模型的渗透率均与人骨组织的渗透率相匹配。以细胞表面FSS为标准，发现球形-560支架具有最佳的成骨性能。这为从生物学角度设计更好的骨修复支架提供了一种策略。

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基于双向流固耦合的骨修复支架设计与研究

Design and research of bone repair scaffold based on two-way fluid-structure interaction.

作者信息

机构信息

出版信息

BACKGROUND AND OBJECTIVE

METHODS

RESULTS

CONCLUSIONS

背景与目的

方法

结果

结论

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