Application of microtechnologies for the vascularization of engineered tissues.

Q4 Neuroscience
Robert Gauvin, Maxime Guillemette, Mehmet Dokmeci, Ali Khademhosseini
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引用次数: 17

Abstract

Recent advances in medicine and healthcare allow people to live longer, increasing the need for the number of organ transplants. However, the number of organ donors has not been able to meet the demand, resulting in an organ shortage. The field of tissue engineering has emerged to produce organs to overcome this limitation. While tissue engineering of connective tissues such as skin and blood vessels have currently reached clinical studies, more complex organs are still far away from commercial availability due to pending challenges with in vitro engineering of 3D tissues. One of the major limitations of engineering large tissue structures is cell death resulting from the inability of nutrients to diffuse across large distances inside a scaffold. This task, carried out by the vasculature inside the body, has largely been described as one of the foremost important challenges in engineering 3D tissues since it remains one of the key steps for both in vitro production of tissue engineered construct and the in vivo integration of a transplanted tissue. This short review highlights the important challenges for vascularization and control of the microcirculatory system within engineered tissues, with particular emphasis on the use of microfabrication approaches.

Abstract Image

Abstract Image

微技术在工程组织血管化中的应用。
医学和医疗保健的最新进展使人们的寿命更长,这增加了对器官移植的需求。然而,器官捐献者的数量一直无法满足需求,导致器官短缺。组织工程领域已经出现,以生产器官来克服这一限制。虽然皮肤和血管等结缔组织的组织工程目前已经进入临床研究阶段,但由于3D组织体外工程面临的挑战,更复杂的器官距离商业化还很遥远。大型组织结构工程的主要限制之一是由于营养物质无法在支架内长距离扩散而导致细胞死亡。这项由体内脉管系统完成的任务,在很大程度上被描述为工程3D组织中最重要的挑战之一,因为它仍然是组织工程构建体体外生产和移植组织体内整合的关键步骤之一。这篇简短的综述强调了工程组织中血管化和微循环系统控制的重要挑战,特别强调了微加工方法的使用。
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
Vascular Cell
Vascular Cell Neuroscience-Neurology
CiteScore
0.70
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0.00%
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