血脑屏障微流控芯片及其应用

Mengmeng Li , Mingyang Zhu , Ruolan Huang, Kun Wang, Zhilong Zeng, Lu Xiao, Yi Lin, Dan Liu
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引用次数: 0

摘要

血脑屏障(blood - brain barrier, BBB)是将血液与脑实质分离的天然动态屏障,主要由脑微血管内皮细胞(brain microvascular endothelial cells, BMECs)、周细胞、星形胶质细胞和多种神经元组成。血脑屏障调节各种物质在脑和血液之间的高度选择性运输,并维持中枢神经系统(CNS)的稳定性。由于这种严格的控制,血脑屏障对药物和其他外源性化合物进入中枢神经系统构成了巨大的挑战,这已经成为许多中枢神经系统疾病药物开发的瓶颈。因此,需要高效、精确的血脑屏障体外模型来评估靶向中枢神经系统药物的疗效和毒性,为药物设计提供依据,提高药物进入临床评估的成功率。体外血脑屏障模型从早期的二维(2D)静态模型迅速发展到目前的三维(3D)动态微流控芯片。尽管常用的静态体外血脑屏障模型构建简单,TEER值检测方便,但静态模型并不能提供理想的(即准确的)血脑屏障环境,因为它们缺乏正确的生理尺寸/尺度和血流动力学剪切应力,而这两者在促进和维持EC向特定血脑屏障表型的分化中起着重要作用。与传统的静态模型相比,三维微流体模型通过模拟具有更自然信号转导的微环境,使细胞的反应方式更接近于体内行为。因此,动态三维血脑屏障模型可以更准确地再现人体血脑屏障的结构和功能。本文综述了体外微流控血脑屏障芯片及其研究应用的最新进展,并讨论了该技术的发展前景和面临的挑战。
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Blood–brain barrier microfluidic chips and their applications

As a natural dynamic barrier separating blood from brain parenchyma, the blood–brain barrier (BBB) is mainly composed of brain microvascular endothelial cells (BMECs), pericytes, astrocytes, and a variety of neurons. The BBB regulates the highly selective transport of various substances between the brain and blood and maintains the stability of the central nervous system (CNS). Owing to this tight control, the BBB represents a formidable challenge for the delivery of drugs and other exogenous compounds into the CNS, which has bottlenecked the development of many drugs for CNS diseases. Therefore, efficient and precise in vitro models of the BBB are needed to assess the efficacy and toxicity of drugs targeting the CNS to inform drug design and to improve the success rate of agents that enter clinical evaluation. In vitro BBB models have rapidly advanced from the early two-dimensional (2D) static models to the current three-dimensional (3D) dynamic microfluidic chips. Although the commonly used, static, in vitro BBB models are simple to construct and TEER values are convenient to detect, the static models do not provide an ideal (i.e., accurate) BBB environment, since they lack the correct physiological size/scale and hemodynamic shear stress, both of which play substantial roles in promoting and maintaining EC differentiation into a specific BBB phenotype. Compared with traditional static models, 3D microfluidic models thus enable cells to react in a manner more closely resembling in vivo behavior by simulating a microenvironment with more natural signal transduction. As a result, the dynamic 3D BBB model can more accurately recapitulate the structure and function of the human BBB. Here we summarize the recent progress in in vitro microfluidic BBB chips and their research applications as well as discuss the prospects and challenges for where the technology is headed.

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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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审稿时长
125 days
期刊最新文献
Simple design for membrane-free microphysiological systems to model the blood-tissue barriers Microfluidics for brain endothelial cell-astrocyte interactions Advancements in organs-on-chips technology for viral disease and anti-viral research Generation of cynomolgus monkey airway, liver ductal, and kidney organoids with pharmacokinetic functions Blood–brain barrier microfluidic chips and their applications
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