Fabrication of multilayer structured tubular tissue using water transfer printing

2013 IEEE International Conference on Mechatronics and Automation Pub Date : 2013-10-03 DOI:10.1109/ICMA.2013.6617927

Yuka Yamagishi, T. Masuda, H. Owaki, F. Arai, M. Matsusaki, M. Akashi

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Abstract

We proposed a 3D assembly technique using water transfer printing to fabricate a multilayer structured tubular tissue. This study was aimed to determine whether the tissue-engineered tubular structure maintains the normally mechanical property as the development and function by the artificial circulatory system. In this work, we demonstrated that fabricated tissues could rapidly assemble into aligned tubular tissue in the appropriate geometrical conditions using engineering approaches. This technique does not require a solid biodegradable scaffold. Therefore, this approach presents the simple and rapid method to create through the exploitation of the intrinsic potential of cells to assemble fabricated tissues into functional 3D tissues in a suitable tubular tissue environment. The described technique is applicable to many different cell types and can be used to engineer tissue constructs of user-defined size and shape with micro-scale control of the cellular organization, which could form the basis for constructing 3D engineered tissues with a hollow tubular tissue in vitro.

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水转移印花制备多层结构管状组织

我们提出了一种3D组装技术，利用水转移打印来制造多层结构的管状组织。本研究旨在确定组织工程管状结构在人工循环系统的发育和功能中是否能保持正常的力学性能。在这项工作中，我们证明了制造的组织可以在适当的几何条件下使用工程方法快速组装成对齐的管状组织。这项技术不需要固体的可生物降解支架。因此，这种方法提供了一种简单而快速的方法，通过利用细胞的内在潜力，在合适的管状组织环境中将制造的组织组装成功能的3D组织。所描述的技术适用于许多不同的细胞类型，并可用于通过对细胞组织的微尺度控制来设计用户定义的大小和形状的组织结构，这可以形成在体外构建具有中空管状组织的3D工程组织的基础。

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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来源期刊

2013 IEEE International Conference on Mechatronics and Automation

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