![]() Yaoyao Zhao, Zhenwei Wei, Hansen Zhao, Jia Jia, Zhenzhen Chen, Sichun Zhang, Zheng Ouyang, Xiaoxiao Ma, and Xinrong Zhang.Electrogeneration of Gold Nanoparticles on Porous-Carbon Paper-Based Electrodes and Application to Inorganic Arsenic Analysis in White Wines by Chronoamperometric Stripping. Carmen Blanco-López, Agustín Costa-García, and M. Detection of Silver Nanoparticles by Electrochemically Activated Galvanic Exchange. Donor/Acceptor-Induced Ratiometric Photoelectrochemical Paper Analytical Device with a Hollow Double-Hydrophilic-Walls Channel for microRNA Quantification. Hongmei Yang, Mengsu Hu, Zhenglin Li, Peini Zhao, Li Xie, Xianrang Song, Jinghua Yu.Orientation-Controlled Bioconjugation of Antibodies to Silver Nanoparticles. Pollok, Charlie Rabin, Leilani Smith, Richard M. Electrochemical Detection of NT-proBNP Using a Metalloimmunoassay on a Paper Electrode Platform. Walgama, Leilani Smith, Ian Richards, Richard M. ![]() Absolute Chiral Recognition with Hybrid Wireless Electrochemical Actuators. Serena Arnaboldi, Bhavana Gupta, Tiziana Benincori, Giorgia Bonetti, Roberto Cirilli, Alexander Kuhn.Sandwich-Type Electrochemical Paper-Based Immunosensor for Claudin 7 and CD81 Dual Determination on Extracellular Vesicles from Breast Cancer Patients. Lorente, Gonzalo Tortella, Olga Rubilar, Karim Sapag, Mauro Bertotti, Martín A. Regiart, Alba Rodríguez-Martínez, Diego de Miguel-Pérez, María J. Silver Nanocubes as Electrochemical Labels for Bioassays. Pollok, Leilani Smith, Ian Richards, Richard M. Microfluidic Paper-Based Analytical Devices: From Design to Applications. Link, Catherine McMahon, Ilhoon Jang, Charles S. This article is cited by 75 publications. This material is available free of charge via the Internet at. Experimental section including instrumentation and protocols for biotinylation of AgNPs, preparation of the model analyte, modification of magnetic microbeads with fluorescein, ASVs obtained using the conventional electrochemical setup, thickening of carbon ink for stencil printing, adding electrical contacts to the stencil-printed electrodes, reagent loading on the oSlip, and drying conditions for measuring the capture efficiency of the model analyte at the WE results for two different conventional electrochemical configurations a scheme showing the detailed architecture of the oSlip additional evidence for the spontaneous oxidation of AgNPs by MnO 4 − effect of Cl − and PO 4 3− on the electrochemical signal micrographs showing the background fluorescence of the oSlip WE UV–vis spectra demonstrating formation of the model analyte optimization of the electrochemical signal using the conventional electrochemical setup evidence for the electrical insulation of the electrode with MnO 2 optimization of MnO 4 − resolvation in the oSlip.
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