生物反应器辅助静态压缩三维聚合物支架对软骨细胞表型的调节及其对功能性软骨组织工程的潜在影响

P. Nair, N. Remya
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引用次数: 2

摘要

功能性软骨组织工程旨在利用外部生物力学刺激增强软骨细胞植入的三维支架的再生过程。静态压缩刺激对生物反应器中多孔支架中培养的软骨细胞表型的调节作用正在研究中。将软骨细胞植入多孔聚(乙烯)醇-聚卡己内酯支架中,在生物反应器中每天承受10%的静态无侧限压缩应变1h,持续7天。培养期结束后,采用活死法、生化组织学和实时PCR分析评估种子细胞的软骨表型。生物反应器似乎是一个很有前途的工具,以提供所需的生物力学刺激细胞种子结构。然而,以静态压缩的形式应用生物力学刺激似乎并不有益,因为它通过恢复成纤维细胞形态并分泌1型胶原蛋白外基质分子来调节软骨形成表型
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Modulation of Chondrocyte Phenotype by Bioreactor Assisted Static Compression in a 3D Polymeric Scaffold with Potential Implications to Functional Cartilage Tissue Engineering
Functional cartilage tissue engineering aims at augmenting the regeneration process of chondrocyte seeded three dimensional scaffolds by application of external biomechanical stimuli. The effect of static compressive stimuli in modulating the phenotype of chondrocytes cultured in porous scaffolds using a bioreactor is being investigated in the present study. Chondrocytes were seeded in porous Poly (vinyl) alcohol-Poly capro lactone scaffold and was subjected to static unconfined compressive strain of 10% for 1h everyday for a period of 7days using a bioreactor. After culture period, chondrogenic phenotype of seeded cells was assessed by live dead assay, biochemical histological and real time PCR analysis. Bioreactor seems to be a promising tool in delivering the desired biomechanical stimuli to the cell seeded constructs. However, application of biomechanical stimuli in the form of static compression doesn’t seem beneficial as it modulates chondrogenic phenotype by reverting to a fibroblastic morphology with the secretion of collagen type 1 extra cellular matrix molecules
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