基于 Clay Sculpture 的 3D 打印微笼模块，采用生物黏附组装，用于特定形状组织的血管化和再生。

Clay Sculpture-Inspired 3D Printed Microcage Module Using Bioadhesion Assembly for Specific-Shaped Tissue Vascularization and Regeneration.

机构信息

Department of Plastic Surgery, Union Hospital, Tongji Medical College, Huazhong University of Science and Technology, Wuhan, 430022, China.

出版信息

Adv Sci (Weinh). 2024 Jun;11(21):e2308381. doi: 10.1002/advs.202308381. Epub 2024 Mar 6.

DOI:10.1002/advs.202308381

PMID:38447173

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11151015/

Abstract

3D bioprinting techniques have enabled the fabrication of irregular large-sized tissue engineering scaffolds. However, complicated customized designs increase the medical burden. Meanwhile, the integrated printing process hinders the cellular uniform distribution and local angiogenesis. A novel approach is introduced to the construction of sizable tissue engineering grafts by employing hydrogel 3D printing for modular bioadhesion assembly, and a poly (ethylene glycol) diacrylate (PEGDA)-gelatin-dopamine (PGD) hydrogel, photosensitive and adhesive, enabling fine microcage module fabrication via DLP 3D printing is developed. The PGD hydrogel printed micocages are flexible, allowing various shapes and cell/tissue fillings for repairing diverse irregular tissue defects. In vivo experiments demonstrate robust vascularization and superior graft survival in nude mice. This assembly strategy based on scalable 3D printed hydrogel microcage module could simplify the construction of tissue with large volume and complex components, offering promise for diverse large tissue defect repairs.

摘要

3D 生物打印技术能够制造不规则的大型组织工程支架。然而，复杂的定制设计增加了医疗负担。同时，集成的打印过程阻碍了细胞的均匀分布和局部血管生成。通过采用水凝胶 3D 打印进行模块化生物黏附组装，引入了一种新方法来构建大尺寸的组织工程移植物，开发了一种光敏感和黏附的聚乙二醇二丙烯酸酯（PEGDA）-明胶-多巴胺（PGD）水凝胶，可通过 DLP 3D 打印精细制造微笼模块。PGD 水凝胶打印的微笼具有柔韧性，允许各种形状和细胞/组织填充，用于修复各种不规则的组织缺陷。体内实验证明在裸鼠中具有强大的血管生成和优异的移植物存活率。这种基于可扩展 3D 打印水凝胶微笼模块的组装策略可以简化具有大体积和复杂成分的组织的构建，为各种大型组织缺陷修复提供了前景。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/963f/11151015/7a04ba669ac7/ADVS-11-2308381-g007.jpg

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基于 Clay Sculpture 的 3D 打印微笼模块，采用生物黏附组装，用于特定形状组织的血管化和再生。

Clay Sculpture-Inspired 3D Printed Microcage Module Using Bioadhesion Assembly for Specific-Shaped Tissue Vascularization and Regeneration.

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