纤维蛋白作为心血管组织工程应用中的细胞载体。

Fibrin as a cell carrier in cardiovascular tissue engineering applications.

作者信息

Mol Anita, van Lieshout Marjolein I, Dam-de Veen Christa G, Neuenschwander Stefan, Hoerstrup Simon P, Baaijens Frank P T, Bouten Carlijn V C

机构信息

Department of Biomedical Engineering, Eindhoven University of Technology, PO Box 513, 5600 MB Eindhoven, The Netherlands.

出版信息

Biomaterials. 2005 Jun;26(16):3113-21. doi: 10.1016/j.biomaterials.2004.08.007.

DOI:10.1016/j.biomaterials.2004.08.007

PMID:15603806

Abstract

In cardiovascular tissue engineering approaches, efficient seeding methods are essential. To achieve this and to save time, cells can be encapsulated in gels. Combining the advantages of a gel as a cell carrier with the advantages of a fiber-based scaffold, providing structural integrity to the developing tissue, might offer several advantages. In this study, seeding by using fibrin as a cell carrier is compared to the conventional static seeding method with regard to tissue development. Seeding with fibrin resulted in less loss of soluble collagen into the medium and a more mature extracellular matrix in a shorter period of time. The use of fibrin degradation inhibitors was shown to inhibit extracellular matrix formation, although it did not hamper cell proliferation. The use of fibrin as a cell carrier to seed cells into a fiber-based scaffold may represent a promising, timesaving approach in cardiovascular tissue engineering applications.

摘要

在心血管组织工程方法中，高效的接种方法至关重要。为实现这一点并节省时间，可将细胞封装在凝胶中。将凝胶作为细胞载体的优点与基于纤维的支架的优点相结合，为发育中的组织提供结构完整性，可能会带来诸多优势。在本研究中，就组织发育而言，将使用纤维蛋白作为细胞载体的接种方法与传统的静态接种方法进行了比较。用纤维蛋白接种导致可溶性胶原蛋白向培养基中的损失减少，并且在更短的时间内形成更成熟的细胞外基质。结果表明，使用纤维蛋白降解抑制剂可抑制细胞外基质的形成，尽管它并不妨碍细胞增殖。使用纤维蛋白作为细胞载体将细胞接种到基于纤维的支架中，可能是心血管组织工程应用中一种有前景的、节省时间的方法。

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纤维蛋白作为心血管组织工程应用中的细胞载体。

Fibrin as a cell carrier in cardiovascular tissue engineering applications.

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