血管化策略中的生物打印

Bioprinting in Vascularization Strategies.

作者信息

Jafarkhani Mahboubeh, Salehi Zeinab, Aidun Amir, Shokrgozar Mohammad Ali

机构信息

School of Chemical Engineering, College of Engineering, University of Tehran, Iran.

Tissues and Biomaterials Research Group (TBRG), Universal Scientific Education and Research Network (USERN), Tehran, Iran.

出版信息

Iran Biomed J. 2019 Jan;23(1):9-20. doi: 10.29252/.23.1.9.

DOI:10.29252/.23.1.9

PMID:30458600

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6305822/

Abstract

Three-dimensional (3D) printing technology has revolutionized tissue engineering field because of its excellent potential of accurately positioning cell-laden constructs. One of the main challenges in the formation of functional engineered tissues is the lack of an efficient and extensive network of microvessels to support cell viability. By printing vascular cells and appropriate biomaterials, the 3D printing could closely mimic in vivo conditions to generate blood vessels. In vascular tissue engineering, many various approaches of 3D printing have been developed, including selective laser sintering and extrusion methods, etc. The 3D printing is going to be the integral part of tissue engineering approaches; in comparison with other scaffolding techniques, 3D printing has two major merits: automation and high cell density. Undoubtedly, the application of 3D printing in vascular tissue engineering will be extended if its resolution, printing speed, and available materials can be improved.

摘要

三维（3D）打印技术因其在精确放置载细胞构建体方面的卓越潜力，给组织工程领域带来了变革。形成功能性工程组织的主要挑战之一是缺乏高效且广泛的微血管网络来维持细胞活力。通过打印血管细胞和合适的生物材料，3D打印能够紧密模拟体内条件以生成血管。在血管组织工程中，已经开发出许多不同的3D打印方法，包括选择性激光烧结和挤压法等。3D打印将成为组织工程方法的重要组成部分；与其他支架技术相比，3D打印有两个主要优点：自动化和高细胞密度。毫无疑问，如果能提高其分辨率、打印速度和可用材料，3D打印在血管组织工程中的应用将会得到扩展。

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血管化策略中的生物打印

Bioprinting in Vascularization Strategies.

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