Hydrogels as extracellular matrices for skeletal tissue engineering: state-of-the-art and novel application in organ printing.

Natalja E Fedorovich, Jacqueline Alblas, Joost R de Wijn, Wim E Hennink, Ab J Verbout, Wouter J A Dhert
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引用次数: 443

Abstract

Organ printing, a novel approach in tissue engineering, applies layered computer-driven deposition of cells and gels to create complex 3-dimensional cell-laden structures. It shows great promise in regenerative medicine, because it may help to solve the problem of limited donor grafts for tissue and organ repair. The technique enables anatomical cell arrangement using incorporation of cells and growth factors at predefined locations in the printed hydrogel scaffolds. This way, 3-dimensional biological structures, such as blood vessels, are already constructed. Organ printing is developing fast, and there are exciting new possibilities in this area. Hydrogels are highly hydrated polymer networks used as scaffolding materials in organ printing. These hydrogel matrices are natural or synthetic polymers that provide a supportive environment for cells to attach to and proliferate and differentiate in. Successful cell embedding requires hydrogels that are complemented with biomimetic and extracellular matrix components, to provide biological cues to elicit specific cellular responses and direct new tissue formation. This review surveys the use of hydrogels in organ printing and provides an evaluation of the recent advances in the development of hydrogels that are promising for use in skeletal regenerative medicine. Special emphasis is put on survival, proliferation and differentiation of skeletal connective tissue cells inside various hydrogel matrices.

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水凝胶作为骨骼组织工程的细胞外基质:在器官打印中的最新应用。
器官打印是组织工程领域的一种新方法,它应用计算机驱动的细胞和凝胶分层沉积技术来创建复杂的三维细胞负载结构。它在再生医学中显示出巨大的希望,因为它可能有助于解决组织和器官修复的供体移植物有限的问题。该技术通过在打印的水凝胶支架的预定位置结合细胞和生长因子,使解剖细胞排列成为可能。通过这种方式,三维生物结构,如血管,已经被构建。器官打印正在快速发展,在这一领域有令人兴奋的新可能性。水凝胶是一种高度水合的聚合物网络,在器官打印中用作支架材料。这些水凝胶基质是天然或合成的聚合物,为细胞的附着、增殖和分化提供了有利的环境。成功的细胞包埋需要水凝胶与仿生和细胞外基质成分相辅相成,以提供生物线索来引发特定的细胞反应并指导新组织的形成。本文综述了水凝胶在器官打印中的应用,并对水凝胶在骨骼再生医学中应用前景的最新进展进行了评价。重点研究了骨结缔组织细胞在不同水凝胶基质中的存活、增殖和分化。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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Tissue engineering
Tissue engineering CELL & TISSUE ENGINEERING-BIOTECHNOLOGY & APPLIED MICROBIOLOGY
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