用于组织工程的三维支架:孔径和结构均匀性的重要性。
Three-dimensional scaffolds for tissue engineering: the importance of uniformity in pore size and structure.
机构信息
Department of Biomedical Engineering, Washington University, St. Louis, Missouri 63130, United States.
出版信息
Langmuir. 2010 Dec 21;26(24):19001-6. doi: 10.1021/la104206h. Epub 2010 Nov 23.
Abstract
To validate the importance of uniformity in pore size and structure of a scaffold for tissue engineering, we fabricated two types of scaffolds with uniform (inverse opal scaffolds) and nonuniform pore sizes and structures, and then evaluated their properties in terms of diffusion of macromolecules, spatial distribution of fibroblasts, and differentiation of preosteoblasts. Our results confirmed the superior performance of the inverse opal scaffolds due to the uniform pore size, homogeneous environment, and high interconnectivity: a higher diffusion rate, a uniform distribution of cells, and a higher degree of differentiation. In addition, we found that both the differentiation of cells and secretion of extracellular matrix were dependent on the properties of the individual pore to which the cells were attached, rather than the bulk properties of a scaffold. Our results clearly indicate that inverse opal scaffolds could provide a better microenvironment for cells in comparison to a scaffold with nonuniform size and structure.
摘要
为了验证支架孔径和结构均匀性对于组织工程的重要性,我们制备了两种具有均匀(反蛋白石支架)和非均匀孔径和结构的支架,并从大分子扩散、成纤维细胞的空间分布和前成骨细胞分化等方面评估了它们的性能。我们的结果证实了反蛋白石支架由于孔径均匀、环境均匀和高连通性而具有更好的性能:更高的扩散率、细胞均匀分布和更高的分化程度。此外,我们还发现细胞的分化和细胞外基质的分泌不仅依赖于细胞附着的单个孔的特性,还依赖于支架的整体特性。我们的结果清楚地表明,与具有非均匀尺寸和结构的支架相比,反蛋白石支架可为细胞提供更好的微环境。
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