Download This PaperMicrobial Electrochemical Transistors Amplify Extracellular Electron Signals for Rapid Bom Detection
22 Pages Posted: 23 Apr 2025
Abstract
Acquiring weak electron signals from electroactive bacteria is critical for applications in biosensing, wastewater treatment, and life science. However, current microbial electrochemical techniques are inefficient to capture these signals at microscale. While organic electrochemical transistors can amplify signals exponentially, they lack an effective cathodic reaction to sustain electroactive bacterial dominant communities. Hence, a microbial electrochemical transistor is developed, integrating microbial electrolytic cell with organic electrochemical transistor by employing platinum source and drain electrodes. This design enables seamless incorporation of microbial electronic circuits into the ion gated circuits. Results demonstrate effective signal amplification of extracellular electrons generated by microbial gates within the device. The extracellular electron signals are successfully acquired across varying concentrations of organic matters, achieving a substantially signal amplification of 3×104. The nonlinear relationship between biodegradable organic matter concentrations and device output signals is established. In continuous mode, a detection limit as low as 1 mgL-1 and a rapid response time less than 60 seconds are achieved. This novel device facilitates efficient bacterial signal acquisitions on the microscale, bridges microbial electrochemistry with semiconductor physics, opening new avenues for bioelectronic systems in advancing extracellular electron transfer research and promises in electroactive bacteria identification at even single-cell level.
Keywords: organic electrochemical transistor, extracellular electron transfer, electroactive bacteria, microbial electrolytic cell, microbial fuel cell
Suggested Citation: Suggested Citation