第五章。基于剪切变薄水凝胶的三维组织建模

Biomaterials Science Series Pub Date : 2019-01-02 DOI:10.1039/9781788012683-00094

Christopher D. Lindsay, S. Heilshorn

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引用次数: 0

摘要

水凝胶是水膨胀的交联聚合物网络，可以广泛调整以适应许多应用。几十年来，水凝胶一直被用作组织工程平台，但尚未被广泛用作3D生物打印的墨水。与更常见的液相(溶胶相)生物墨水相比，水凝胶(凝胶相)生物墨水具有许多优点，这些将在第1节中讨论。第2节将描述如何凝胶相墨水可以调整，包括重要的生物活性线索，为特定的组织工程应用。在第3节中，将介绍不同的交联策略和材料，以创建凝胶相生物墨水。最后，第4节将讨论如何使用凝胶相生物墨水来创建先进医学未来所需的复杂结构。

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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Chapter 5. Shear Thinning Hydrogel-based 3D Tissue Modelling

Hydrogels are water-swollen, crosslinked polymer networks that can be widely tuned to fit many applications. Hydrogels have been used as tissue engineering platforms for decades, but have not been widely adopted as inks for 3D bioprinting. Compared to the more common liquid solution phase (sol-phase) bioinks, hydrogel (gel-phase) bioinks have many advantages, which will be discussed in Section 1. Section 2 will describe how gel-phase inks can be tuned to include important bioactive cues for specific tissue engineering applications. In Section 3, different crosslinking strategies and materials will be presented for the creation of gel-phase bioinks. Finally, Section 4 will discuss how gel-phase bioinks can be used to create complex structures that are required for the future of advanced medicine.

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Biomaterials Science Series

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