用于生物医学研究和医疗保健应用的下一代微流体。

IF 2.3 Q3 ENGINEERING, BIOMEDICAL
Biomedical Engineering and Computational Biology Pub Date : 2023-11-27 eCollection Date: 2023-01-01 DOI:10.1177/11795972231214387
Muhammedin Deliorman, Dima Samer Ali, Mohammad A Qasaimeh
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引用次数: 0

摘要

微流体系统提供了多种生物医学工具和方法,以提高人类的便利和健康。这些系统的进步使下一代微流体能够集成自动化,操作和智能读出系统,以及设计和三维(3D)打印,以快速和极大的灵活性精确生产微通道和其他微结构。这些3D打印的微流体平台不仅可以控制各种生物医学应用的复杂流体行为,还可以作为构建3D组织结构的微导管,是先进药物开发、毒性评估和准确疾病建模的一个组成部分。此外,其他新兴技术的整合,如先进的显微镜和机器人技术,能够在精确控制的微环境中进行时空操纵和细胞生理学的高通量筛选。值得注意的是,这些集成系统的便携性和高精度自动化能力促进了快速实验和数据采集,有助于加深我们对复杂生物系统及其行为的理解。虽然某些挑战,包括材料兼容性,缩放和标准化仍然存在,但与人工智能,物联网,智能材料和小型化的集成在重塑传统微流体方法方面具有巨大的希望。当与先进技术相结合时,这种变革潜力有可能彻底改变生物医学研究和医疗保健应用,最终造福人类健康。这篇综述强调了该领域的进展,并强调了下一代微流控系统在推进生物医学研究、即时诊断和医疗保健系统方面的关键作用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Next-Generation Microfluidics for Biomedical Research and Healthcare Applications.

Microfluidic systems offer versatile biomedical tools and methods to enhance human convenience and health. Advances in these systems enables next-generation microfluidics that integrates automation, manipulation, and smart readout systems, as well as design and three-dimensional (3D) printing for precise production of microchannels and other microstructures rapidly and with great flexibility. These 3D-printed microfluidic platforms not only control the complex fluid behavior for various biomedical applications, but also serve as microconduits for building 3D tissue constructs-an integral component of advanced drug development, toxicity assessment, and accurate disease modeling. Furthermore, the integration of other emerging technologies, such as advanced microscopy and robotics, enables the spatiotemporal manipulation and high-throughput screening of cell physiology within precisely controlled microenvironments. Notably, the portability and high precision automation capabilities in these integrated systems facilitate rapid experimentation and data acquisition to help deepen our understanding of complex biological systems and their behaviors. While certain challenges, including material compatibility, scaling, and standardization still exist, the integration with artificial intelligence, the Internet of Things, smart materials, and miniaturization holds tremendous promise in reshaping traditional microfluidic approaches. This transformative potential, when integrated with advanced technologies, has the potential to revolutionize biomedical research and healthcare applications, ultimately benefiting human health. This review highlights the advances in the field and emphasizes the critical role of the next generation microfluidic systems in advancing biomedical research, point-of-care diagnostics, and healthcare systems.

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