Characterization and design of 3D scaffolds for biofluidic criteria

2009 IEEE International Conference on Computational Intelligence for Measurement Systems and Applications Pub Date : 2009-05-11 DOI:10.1109/CIMSA.2009.5069957

Qing Li, Jiani Yu, M. Schellekens, Shiwei Zhou, Wei Li, S. Armfield, R. Appleyard

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Abstract

The success of tissue regeneration to a certain extent lies on the mechanical and biological environments that the scaffold provides. The former has been addressed in terms of stiffness and strength in a range of tissue engineering scenarios. The latter is often related to fluid flow capacity of facilitating nutrient delivery, waste removal, and more importantly promoting tissue remodeling. This paper aims at developing a computational fluid dynamics (CFD) analysis for scaffold characterization and design in terms of fluidic wall shear stress. A certain level of wall shear stress (WSS) is considered essential to stimulate the cell differentiation and tissue growth, thereby making load-bearing neotissue more functional. This paper will firstly examine the transporting performance of scaffold topology that was designed based upon the stiffness criterion. Then a WSS based topological design is developed by using bidirectional evolutionary structural optimization (BESO) method, where a more uniform and favorable WSS distribution can be obtained.

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生物流体标准三维支架的表征和设计

组织再生的成功在一定程度上取决于支架所提供的机械环境和生物环境。前者已经在一系列组织工程场景的刚度和强度方面得到了解决。后者通常与促进营养物质输送，废物清除，更重要的是促进组织重塑的流体流动能力有关。本文旨在建立一种基于流体壁剪切应力的计算流体动力学(CFD)分析方法，用于支架的表征和设计。一定水平的壁剪切应力(WSS)被认为是刺激细胞分化和组织生长所必需的，从而使承载的新组织更有功能。本文首先对基于刚度准则设计的支架拓扑结构的运输性能进行了研究。然后，采用双向进化结构优化(BESO)方法，提出了一种基于WSS的拓扑设计方法，使WSS分布更加均匀和有利。

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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2009 IEEE International Conference on Computational Intelligence for Measurement Systems and Applications

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