Jing Li , Haiqing Bai , Zihao Wang , Beibei Xu , Kristen N. Peters Olson , Chengyao Liu , Yinlei Su , Jiawei Hao , Jinying Shen , Xuetong Xi , Jie Zhen , Rong Yu , Yacong Sun , Xin Xie , Wen-xia Tian , Fei Yu , Xiaoheng Liu , Lihe Zhang , Demin Zhou , Longlong Si
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引用次数: 0
Abstract
Disease models that can accurately recapitulate human pathophysiology during infection and clinical response to antiviral therapeutics are still lacking, which represents a major barrier in drug development. The emergence of human Organs-on-a-Chip that integrated microfluidics with three-dimensional (3D) cell culture, may become the potential solution for this urgent need. Human Organs-on-a-Chip aims to recapitulate human pathophysiology by incorporating tissue-relevant cell types and their microenvironment, such as dynamic fluid flow, mechanical cues, tissue–tissue interfaces, and immune cells to increase the predictive validity of in vitro experimental models. Human Organs-on-a-Chip has a broad range of potential applications in basic biomedical research, preclinical drug development, and personalized medicine. This review focuses on its use in the fields of virology and infectious diseases. We reviewed various types of human Organs-on-a-Chip-based viral infection models and their application in studying viral life cycle, pathogenesis, virus-host interaction, and drug responses to virus- and host-targeted therapies. We conclude by proposing challenges and future research avenues for leveraging this promising technology to prepare for future pandemics.
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