组织工程应用的脱细胞细胞外基质

Hady Elmashhady, B. Kraemer, Krishna H Patel, S. Sell, K. Garg
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引用次数: 24

摘要

摘要脱细胞去除细胞抗原,同时保留细胞外基质(ECM)的超微结构和组成。脱细胞ECM(DECM)支架已广泛应用于各种组织工程应用中,并取得了不同程度的成功。DECM支架的机械、结构和生物活性在很大程度上取决于脱细胞方法,并决定其临床疗效。本文强调了DECM支架临床应用的优势和挑战。机械强度差是一些DECM支架在修复承载组织和临界尺寸缺陷方面的一个显著缺点,其中再生组织需要长期的机械支持。将DECM支架与合成的生物相容性聚合物相结合可以提供一种有用的策略来避免较差的机械稳定性问题。本文综述了将各种组织的DECM支架与合成聚合物相结合,使用静电纺丝制造混合支架的研究。这些混合支架提供了机械骨架,同时保留了DECM的生物活性,从而为组织工程和再生医学应用提供了显著优势。
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Decellularized extracellular matrices for tissue engineering applications
Abstract Decellularization removes cellular antigens while preserving the ultrastructure and composition of extracellular matrix (ECM). Decellularized ECM (DECM) scaffolds have been widely used in various tissue engineering applications with varying levels of success. The mechanical, architectural and bioactive properties of a DECM scaffold depend largely on the method of decellularization and dictate its clinical efficacy. This article highlights the advantages and challenges associated with the clinical use of DECM scaffolds. Poor mechanical strength is a significant disadvantage of some DECM scaffolds in the repair of load-bearing tissues as well as critical-size defects, where long-term mechanical support is required for the regenerating tissue. Combining DECM scaffolds with synthetic biocompatible polymers could provide a useful strategy to circumvent the issues of poor mechanical stability. This article reviews studies that have combined DECM scaffolds from various tissues with synthetic polymers to create hybrid scaffolds using electrospinning. These hybrid scaffolds provide a mechanical backbone while retaining the bioactive properties of DECM, thus offering a significant advantage for tissue engineering and regenerative medicine applications.
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