一种热可逆、光交联胶原生物墨水,可用于再生医学支架的自由形态制造。

TECHNOLOGY Pub Date : 2017-12-01 Epub Date: 2017-10-17 DOI:10.1142/S2339547817500091
Kathryn E Drzewiecki, Juilee N Malavade, Ijaz Ahmed, Christopher J Lowe, David I Shreiber
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引用次数: 0

摘要

作为一种生物材料,胶原蛋白已被广泛应用于组织工程和再生医学中。胶原蛋白原生于人体,具有很高的生物相容性,能自然促进细胞粘附和再生。然而,胶原纤维和胶原水凝胶固有的微弱机械特性阻碍了胶原作为生物墨水的进一步发展。在此,我们展示了改性 I 型胶原蛋白--甲基丙烯酰胺胶原(CMA)作为纤维形成生物墨水在自由形态支架制造中的应用。与胶原蛋白一样,CMA 也能在生理条件下自组装成纤维状水凝胶。相比之下,CMA 具有光交联性和热可逆性,光交联消除了热可逆性。通过 CMA 水凝胶的自组装、使用光罩对相关结构进行光交联以及冷却整个水凝胶(这将导致未光交联区域的冷熔化),可实现 CMA 的自由形态制造。打印水凝胶的分辨率约为 350 微米,可在制造过程中加入或不加入细胞并保持活力,也可进一步加工成冻干海绵,同时保持图案的保真度。一项皮下植入研究证实,CMA 的生物相容性优于胶原蛋白。CMA 的自由形态制造可打印出具有良好图案保真度的宏观定制支架,并可相对容易地在组织工程中继续研究和开发基于胶原蛋白的支架。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

A thermoreversible, photocrosslinkable collagen bio-ink for free-form fabrication of scaffolds for regenerative medicine.

A thermoreversible, photocrosslinkable collagen bio-ink for free-form fabrication of scaffolds for regenerative medicine.

A thermoreversible, photocrosslinkable collagen bio-ink for free-form fabrication of scaffolds for regenerative medicine.

A thermoreversible, photocrosslinkable collagen bio-ink for free-form fabrication of scaffolds for regenerative medicine.

As a biomaterial, collagen has been used throughout tissue engineering and regenerative medicine. Collagen is native to the body, is highly biocompatible, and naturally promotes cell adhesion and regeneration. However, collagen fibers and the inherent weak mechanical properties of collagen hydrogels interfere with further development of collagen as a bio-ink. Herein, we demonstrate the use of a modified type-I collagen, collagen methacrylamide (CMA), as a fibril-forming bio-ink for free-form fabrication of scaffolds. Like collagen, CMA can self-assemble into a fibrillar hydrogel at physiological conditions. In contrast, CMA is photocrosslinkable and thermoreversible, and photocrosslinking eliminates thermoreversibility. Free-form fabrication of CMA was performed through self-assembly of the CMA hydrogel, photocrosslinking the structure of interest using a photomask, and cooling the entire hydrogel, which results in cold-melting of unphotocrosslinked regions. Printed hydrogels had a resolution on the order of ~350 μm, and can be fabricated with or without cells and maintain viability or be further processed into freeze-dried sponges, all while retaining pattern fidelity. A subcutaneous implant study confirmed the biocompatibility of CMA in comparison to collagen. Free-form fabrication of CMA allows for printing of macroscale, customized scaffolds with good pattern fidelity and can be implemented with relative ease for continued research and development of collagen-based scaffolds in tissue engineering.

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来源期刊
TECHNOLOGY
TECHNOLOGY ENGINEERING, MULTIDISCIPLINARY-
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