材料科学
微流控
纳米技术
毛细管作用
制作
电极
激光器
光电子学
光学
化学
复合材料
医学
替代医学
物理化学
病理
物理
作者
Léonard Bezinge,Jake M. Lesinski,Akkapol Suea‐Ngam,Daniel A. Richards,Andrew J. de Mello,Chih‐Jen Shih
标识
DOI:10.1002/adma.202302893
摘要
Microfluidic paper-based analytical devices (µPADs) are indispensable tools for disease diagnostics. The integration of electronic components into µPADs enables new device functionalities and facilitates the development of complex quantitative assays. Unfortunately, current electrode fabrication methods often hinder capillary flow, considerably restricting µPAD design architectures. Here, laser-induced graphenization is presented as an approach to fabricate porous electrodes embedded into cellulose paper. The resulting electrodes not only have high conductivity and electrochemical activity, but also retain wetting properties for capillary transport. Paper-based electrofluidics, including a lateral flow device for injection analysis of alkaline phosphatase in serum and a vertical flow device for quantitative detection of HPV16 with a CRISPR-based assay are demonstrated. It is expected that this platform will streamline the development of diagnostic devices that combine the operational simplicity of colorimetric lateral flow tests with the added benefits and possibilities offered by electronic signaling.
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