Microfluidics for brain endothelial cell-astrocyte interactions

Jayita Sanapathi , Pravinkumar Vipparthi , Sushmita Mishra , Alejandro Sosnik , Murali Kumarasamy
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Abstract

With the approval of the Food and Drug (FDA) Modernization Act 2.0, the pharmaceutical industry is poised to expand its research components with a plethora of alternative models, including organ-on-microfluidic chips in pharma and biotechnology, resulting in a personalized approach. Microfluidics opens new possibilities for the study of cell biology, especially for a better understanding of cell-cell interactions and the pathophysiology of neurodegenerative diseases in vitro, and the use of these models to assess the efficacy of novel therapies is promising. These thumb-sized organ-on-a-chip systems have the potential to reduce animal testing and replace simple 2D culture systems that do not succeed to resemble the complex physiology of tissues and organs. Restoring critical aspects of endothelial-brain immune cell communication in a biomimetic system using microfluidics may accelerate the process of central nervous system (CNS) drug discovery and improve our understanding of the mechanisms of multiple neurodegenerative diseases. In addition, these organ-on-chip technologies can be used to optimize drug targets and assess drug efficacy and toxicity in real-time, which can significantly help minimize animal testing requirements, as authorized by the recent FDA Act. This Review initially summarizes the fundamental advantages of microfluidic systems in creating a compartmentalized cell culture for the complex three-dimensional architectures of neural tissue cells such as neurons, glial cells, and endothelial cells, and their ability to recapitulate the spatiotemporal biophysicochemical gradients and mechanical microenvironments. Then, brain endothelial cell-astroglia-on-a-chip models with a focus on neurodegenerative diseases such as Alzheimer's disease, Parkinson's disease, Huntington's disease and amyotrophic lateral sclerosis are introduced. Finally, the current limitations of these microfluidic devices and strategies to overcome them are discussed.

Abstract Image

Abstract Image

用于脑内皮细胞与胃红细胞相互作用的微流体技术
随着《食品和药品现代化法案 2.0》的批准,制药业准备利用大量替代模型(包括制药和生物技术中的器官微流控芯片)扩大其研究内容,从而实现个性化方法。微流控技术为细胞生物学研究提供了新的可能性,特别是有助于更好地了解体外细胞-细胞相互作用和神经退行性疾病的病理生理学,利用这些模型评估新型疗法的疗效前景广阔。这些拇指大小的片上器官系统有可能减少动物试验,取代简单的二维培养系统,因为后者无法成功模拟组织和器官的复杂生理结构。利用微流体技术在生物仿真系统中恢复内皮-脑免疫细胞通讯的关键环节,可能会加快中枢神经系统(CNS)药物发现的进程,并增进我们对多种神经退行性疾病机理的了解。此外,这些片上器官技术还可用于优化药物靶点、实时评估药物疗效和毒性,从而大大有助于最大限度地减少动物实验要求,这也是最近美国食品与药物管理局法案所授权的。本综述首先总结了微流控系统在为神经元、神经胶质细胞和内皮细胞等神经组织细胞的复杂三维结构创建分区细胞培养方面的基本优势,以及它们再现时空生物物理化学梯度和机械微环境的能力。然后,介绍了脑内皮细胞-脑胶质细胞-芯片模型,重点是神经退行性疾病,如阿尔茨海默病、帕金森病、亨廷顿病和肌萎缩侧索硬化症。最后,还讨论了这些微流控设备目前存在的局限性以及克服这些局限性的策略。
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
Organs-on-a-chip
Organs-on-a-chip Analytical Chemistry, Biochemistry, Genetics and Molecular Biology (General), Cell Biology, Pharmacology, Toxicology and Pharmaceutics (General)
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125 days
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