开发用于生物医学应用的芯片器官。

Developing organs-on-chips for biomedical applications.

作者信息

Sun Lingyu, Chen Hanxu, Xu Dongyu, Liu Rui, Zhao Yuanjin

机构信息

Department of Rheumatology and Immunology Nanjing Drum Tower Hospital School of Biological Science and Medical Engineering Southeast University Nanjing China.

Mechanobiology Institute National University of Singapore Singapore Singapore.

出版信息

Smart Med. 2024 May 21;3(2):e20240009. doi: 10.1002/SMMD.20240009. eCollection 2024 Jun.

DOI:10.1002/SMMD.20240009

PMID:39188702

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11236011/

Abstract

In recent years, organs-on-chips have been arousing great interest for their bionic and stable construction of crucial human organs in vitro. Compared with traditional animal models and two-dimensional cell models, organs-on-chips could not only overcome the limitations of species difference and poor predict ability but also be capable of reappearing the complex cell-cell interaction, tissue interface, biofluid and other physiological conditions of humans. Therefore, organs-on-chips have been regarded as promising and powerful tools in diverse fields such as biology, chemistry, medicine and so on. In this perspective, we present a review of organs-on-chips for biomedical applications. After introducing the key elements and manufacturing craft of organs-on-chips, we intend to review their cut-edging applications in biomedical fields, incorporating biological analysis, drug development, robotics and so on. Finally, the emphasis is focused on the perspectives of organs-on-chips.

摘要

近年来，器官芯片因其能够在体外仿生且稳定地构建关键人体器官而备受关注。与传统动物模型和二维细胞模型相比，器官芯片不仅能够克服物种差异和预测能力差的局限性，还能够重现复杂的细胞间相互作用、组织界面、生物流体及其他人体生理状况。因此，器官芯片被视为生物学、化学、医学等多个领域中具有前景且强大的工具。在此视角下，我们对用于生物医学应用的器官芯片进行综述。在介绍了器官芯片的关键要素和制造工艺后，我们旨在综述其在生物医学领域的前沿应用，包括生物分析、药物研发、机器人技术等。最后，重点聚焦于器官芯片的前景展望。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/b444/11236011/d9b927c9d811/SMMD-3-e20240009-g010.jpg

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开发用于生物医学应用的芯片器官。

Developing organs-on-chips for biomedical applications.

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