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由血管生成和成骨微组织组成的多模块血管化骨构建体。

Multimodular vascularized bone construct comprised of vasculogenic and osteogenic microtissues.

机构信息

Department of Biomedical Engineering, University of Michigan, Ann Arbor, Michigan, USA.

出版信息

Biotechnol Bioeng. 2022 Nov;119(11):3284-3296. doi: 10.1002/bit.28201. Epub 2022 Aug 12.

DOI:10.1002/bit.28201
PMID:35922969
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9547967/
Abstract

Bioengineered bone designed to heal large defects requires concomitant development of osseous and vascular tissue to ensure engraftment and survival. Adult human mesenchymal stromal cells (MSC) are promising in this application because they have demonstrated both osteogenic and vasculogenic potential. This study employed a modular approach in which cells were encapsulated in biomaterial carriers (microtissues) designed to support tissue-specific function. Osteogenic microtissues consisting of MSC embedded in a collagen-chitosan matrix; vasculogenic (VAS) microtissues consisted of endothelial cells and MSC in a fibrin matrix. Microtissues were precultured under differentiation conditions to induce appropriate MSC lineage commitment, and were then combined in a surrounding fibrin hydrogel to create a multimodular construct. Results demonstrated the ability of microtissues to support lineage commitment, and that preculture primes the microtissues for the desired function. Combination of osteogenic and vasculogenic microtissues into multimodular constructs demonstrated that osteogenic priming resulted in sustained osteogenic activity even when cultured in vasculogenic medium, and that vasculogenic priming induced a pericyte-like phenotype that resulted in development of a primitive vessel network in the constructs. The modular approach allows microtissues to be separately precultured to harness the dual differentiation potential of MSC to support both bone and blood vessel formation in a unified construct.

摘要

为了确保植入和存活,旨在修复大缺陷的生物工程骨需要同时发展骨组织和血管组织。成体人间充质基质细胞(MSC)在这一应用中很有前途,因为它们已经表现出成骨和血管生成的潜力。本研究采用了一种模块化方法,即将细胞包裹在生物材料载体(微组织)中,这些载体旨在支持组织特异性功能。由嵌入胶原-壳聚糖基质中的 MSC 组成的成骨微组织;由内皮细胞和 MSC 组成的血管生成(VAS)微组织位于纤维蛋白基质中。微组织在分化条件下进行预培养,以诱导适当的 MSC 谱系承诺,然后在周围的纤维蛋白水凝胶中结合,以创建多模块结构。结果表明微组织能够支持谱系承诺,并且预培养使微组织为所需功能做好准备。将成骨微组织和血管生成微组织组合成多模块结构表明,成骨前体在血管生成培养基中培养时仍能持续产生成骨活性,而血管生成前体诱导出一种类似于周细胞的表型,从而在构建体中发展出原始的血管网络。模块化方法允许将微组织分别进行预培养,以利用 MSC 的双重分化潜力,在一个统一的构建体中同时支持骨和血管的形成。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/6649/9804175/45ad568348be/BIT-119-3284-g001.jpg
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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/6649/9804175/f1a0c3e96f79/BIT-119-3284-g008.jpg
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