F. J. del Campo

TL;DR: In this paper, the authors presented the development of microfluidic fuel cells as paper-based power sources in a standard lateral flow test format, where the fuel cells benefit from the laminar flow occurring in a porous material by capillarity to separately react with two parallel streams, anolyte and catholyte.

TL;DR: It is proposed that the utilisation of phages as capture biocomponent for bacteria capture and EIS detection allows in-chip signal confirmation.

TL;DR: In this paper, the electroanalytical detection of sulfite has been explored at an in situ formed copper ultramicroelectrode arrays with a sensitivity and detection limit of 0.35 nA mu M-1 and 6 mu M respectively in pH 2.5 using linear sweep voltammetrv.

TL;DR: The present paper reports for the first time the integration of a microfluidic system, electronics modules, amperometric sensor and display, all powered by a single micro direct methanol fuel cell, pushing forward the development of truly autonomous point-of-care devices relying on electrochemical detection.

TL;DR: Li et al. as discussed by the authors proposed a controlled and reproducible way to fabricate bacteria-modified electrodes, which consists of an immobilisation step using a cellulose matrix, followed by an electrode polarization in the presence of ferricyanide and glucose.