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Translating Extracellular Electron Transfer Activities with Organic Electrochemical Transistors
In This Article
Summary
Here, we present a protocol for using organic electrochemical transistors (OECTs) to translate extracellular electron transfer (EET) activity in Shewanella oneidensis into electrical signals. The hybrid OECT system provides enhanced robustness, sensitivity, and potential for rapid, high-throughput testing, making it an effective tool for EET measurements.
Abstract
Extracellular electron transfer (EET) is a process through which certain microorganisms can transfer electrons across their cell membranes to external electron acceptors, linking cellular metabolism to their environment. While Geobacter and Shewanella have been the primary models for EET research, emerging studies reveal that EET-active species are also associated with fermentation and the human gut microbiome. Leveraging the ability of EET to bridge biological and electronic systems, we present a protocol for using organic electrochemical transistors (OECTs) to translate microbial EET activity into easily detectable electrical signals. This system enables the use of cellular responses to external stimuli for biosensing and biocomputing applications. Specifically, we demonstrated the de-doping of the p-type poly(3,4-ethylenedioxythiophene): poly(styrenesulfonate) (PEDOT: PSS) channel in the OECT is driven by cellular EET from Shewanella oneidensis. By transcriptionally controlling EET flux by genetic circuits, we establish the biosensing capability of this hybrid OECT system to detect chemical stimuli, such as inducer molecules. Furthermore, we introduce plasmid-based Boolean logic gates within the cells, allowing them to process environmental signals and drive current changes in the OECTs, further demonstrating the biocomputing potential of these devices. This method provides a novel interface between biological systems and electronics, enabling future high-throughput screening, biosensing, and biocomputing applications.
Introduction
Devices that can transduce and amplify biological and chemical activities into electrical signals are crucial across various fields, such as sensing1,2, neuromorphic computing3,4, and wearable electronics5. Among these, organic electrochemical transistors (OECTs) have emerged as exceptional interfaces between biological systems and electronic readouts due to their compatibility with aqueous environments and low operating voltages6,7. OECTs differ from conventional electr....
Protocol
NOTE: All chemicals were used as received without further purification. If not specified, analytical-grade chemicals were used.
1. OECT device fabrication
NOTE: The OECTs are fabricated on quartz microscope slides using standard microfabrication techniques adapted from prior work24. As shown in Figure 2A, eight OECT devices are arranged on a single standard slide. Pre-cut polydimethylsiloxane (PDMS.......
Representative Results
Fitted rate constant k
The fitted rate constant k of the OECT channel current IDS serves as a reliable metric for assessing the EET activity of the sample. While the constant gate bias voltages would affect the rate constants, we choose 0.2 V to ensure positive bias to encourage bacterial electron transfer while avoiding fast de-doping at higher gate voltages and providing and minimizing electrochemical stress on the bacteria cells23
Discussion
Electrochemical Cell (EC) Comparison
One major advantage of fitting the rate constant from the OECT channel current is that it minimizes device variation by focusing on the underlying dynamics of IDS changes rather than the raw output. Combined with the inherent signal amplification capability of OECTs, this approach enhances the robustness of hybrid OECT systems compared to traditional electrochemical cells (EC). For example, at the end of each 24-hour OECT experiment, transfer curves a.......
Disclosures
The authors declare no competing interests.
Acknowledgements
Base plasmids for the NAND circuit were generously provided by the Voigt Lab via Addgene (#49375, #49376, #49377). This research was financially supported by the Welch Foundation (Grant F-1929, B.K.K.), the National Institutes of Health under award number R35GM133640 (B.K.K.), an NSF CAREER award (1944334, B.K.K.), and the Air Force Office of Scientific Research under award number FA9550-20-1-0088 (B.K.K.). A.J.G. was supported through a National Science Foundation Graduate Research Fellowships (Program Award No. DGE-1610403). The authors acknowledge the use of shared research facilities supported in part by the Texas Materials Institute, the Center for Dynamics and C....
Materials
| Name | Company | Catalog Number | Comments |
| 3-oxohexanoyl-homoserine lactone | Sigma-Aldrich | ||
| anhydrotetracycline hydrochloride | VWR | ||
| casamino acids | VWR | ||
| Equipment | |||
| Ethylene glycol | Sigma-Aldrich | anhydrous 99.8%, | |
| HEPES buffer solution | VWR | 1 M in water, pH = 7.3 | |
| isopropyl ß-D-1-thiogalactopyranoside | Teknova | ||
| kanamycin sulfate | Growcells | ||
| Magnesium(II) sulfate heptahydrate | VWR | ||
| PEDOT:PSS aqueous suspension | Heraeus Epurio LLC | Clevios PH1000 | |
| Potassium phosphate dibasic | Sigma-Aldrich | ||
| Potassium phosphate monobasic | Sigma-Aldrich | ||
| Potentiostat | PalmSens BV | MultiPalmSens4 | |
| Quartz microscopic slides | AdValue | FQ-S-003 | |
| Quartz microscopic slides | |||
| Sodium chloride | VWR | ||
| Sodium DL-lactate | TCI | 60% in water | |
| Sodium fumarate | VWR | 98% | |
| Sulfuric acid | Sigma-Aldrich | 95.0%-98.0% | |
| Two-part silicone elastomer | Electron Microscopy Sciences | Sylgard184 | |
| Wolfe's Trace Mineral Mix | ATCC |
References
- Luo, Y. F., et al. Technology roadmap for flexible sensors. Acs Nano. 17 (6), 5211-5295 (2023).
- Din, M. O., Martin, A., Razinkov, I., Csicsery, N., Hasty, J. Interfacing gene circuits with microelectronics through engineered p....
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