期刊
MACROMOLECULAR BIOSCIENCE
卷 22, 期 10, 页码 -出版社
WILEY-V C H VERLAG GMBH
DOI: 10.1002/mabi.202200189
关键词
gelatin; hydrogel; self-folding; silk fibroin; tissue engineering
资金
- Natural Science Foundation Project of CQ [cstc2021jcyj-msxmX0707, cstc2021jcyj-msxmX0360]
- Science and Technology Research Program of Chongqing Municipal Education Commission [KJQN202101534]
- Chongqing Graduate Education and Teaching Reform Research Project [yjg202036]
- Graduate Science and Technology Innovation Project in Chongqing University of Science and Technology [YKJCX2020518]
In this study, a novel self-folding hydrogel using photocrosslinkable silk fibroin and gelatin composite hydrogel is developed. The impact of different proportions of beta-sheets in composite hydrogels on their swelling, mechanics, and internal microstructures is investigated. The self-folding hydrogel is proven to be cytocompatible and capable of building a 3D coculture system, making it a promising candidate for applications in blood vessel tissue engineering and regenerative medicine.
Self-folding is a rapidly evolving method for converting flat objects into three-dimensional (3D) structures. However, because there are few materials with suitable properties, the application of self-folding in tissue engineering has been hindered greatly. Herein, a novel self-folding hydrogel using conformational transition mechanism is developed by employing photocrosslinkable silk fibroin and gelatin composite hydrogel. It is hypothesized that differences in the amount of beta-sheet (beta-sheet) formation between the upper and lower layers will supply additional folding stress and drive the self-folding behavior of a bilayer patch, which can improve the mechanical properties and long-term stability of the self-folded structure. In this study, the impact of various proportions of beta-sheets in composite hydrogels on their swelling, mechanics, and internal microstructures are investigated. Subsequently, the folding process parameters are optimized, and diffusion through the folded tubular structure is studied with a perfusion test. Finally, it is proven that the self-folding hydrogel system is cytocompatible and can be utilized to build a 3D coculture system of endothelial cells-smooth muscle cells. These findings suggest that the self-folding hydrogel can be a promising candidate for applications in blood vessel tissue engineering and regenerative medicine.
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