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1. Single-cell phenotyping of extracellular electron transfer via microdroplet encapsulation

   https://doi.org/10.1128/aem.02465-24  

   Partipilo, Gina; Bowman, Emily K; Palmer, Emma J; Gao, Yang; Ridley, Rodney S; Alper, Hal S; Keitz, Benjamin K (January 2025, Applied and Environmental Microbiology)

   Nikel, Pablo Ivan (Ed.)

   ABSTRACT Electroactive organisms contribute to metal cycling, pollutant removal, and other redox-driven environmental processes via extracellular electron transfer (EET). Unfortunately, developing genotype-phenotype relationships for electroactive organisms is challenging because EET is necessarily removed from the cell of origin. Microdroplet emulsions, which encapsulate individual cells in aqueous droplets, have been used to study a variety of extracellular phenotypes but have not been applied to investigate EET. Here, we describe the development of a microdroplet emulsion system to sort and enrich EET-capable organisms from complex populations. We validated our system using the model electrogenShewanella oneidensisand described the tooling of a benchtop microfluidic system for oxygen-limited conditions. We demonstrated the enrichment of strains exhibiting electroactive phenotypes from mixed wild-type and EET-deficient populations. As a proof-of-concept application, we collected samples from iron sedimentation in Town Lake (Austin, TX) and subjected them to microdroplet enrichment. We measured an increase in electroactive organisms in the sorted population that was distinct compared to a population growing in bulk culture with Fe(III) as the sole electron acceptor. Finally, two bacterial species not previously shown to be EET-capable,Cronobacter sakazakiiandVagococcus fessus, were further cultured and characterized for electroactivity. Our results demonstrate the utility of microdroplet emulsions for isolating and identifying EET-capable bacteria.IMPORTANCEThis work outlines a new high-throughput method for identifying electroactive bacteria from mixed populations. Electroactive bacteria play key roles in iron trafficking, soil remediation, and pollutant degradation. Many existing methods for identifying electroactive bacteria are coupled to microbial growth and fitness—as a result, the contributions from weak or poor-growing electrogens are often muted. However, extracellular electron transfer (EET) has historically been difficult to study in high-throughput in a mixed population since extracellular reduction is challenging to trace back to the parent cell and there are no suitable fluorescent readouts for EET. Our method circumvents these challenges by utilizing an aqueous microdroplet emulsion wherein a single cell is statistically isolated in a pico- to nano-liter-sized droplet. Then, via fluorescence obtained from copper reduction, the mixed population can be fluorescently sorted and gated by performance. Utilizing our technique, we characterize two previously unrecognized weak electrogensVagococcus fessusandCronobacter sakazakii. 

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2. 3-D PRINTED REDOX-ACTIVE ORGANIC ELECTRODES TO BRIDGE ACROSS BIOLOGY AND ELECTRONICS

   Elhadad, Anwar; Choi, Seokheun (June 2022, Technical digest SolidState Sensor Actuator and Microsystems Workshop)

   An intimate and direct interface between inorganic electronics and living organisms will revolutionize the next generation of bioelectronics by bridging the signal and material gap between these two different fields. In this work, a redox-active microbial electrode is constructed as the novel interface by simultaneously 3-D printing and electropolymerizing 3,4-ethylenedioxythiophene (EDOT) in a liquid containing electrochemically active bacteria. A custom-made 3-D printer with a concurrent electrochemical control allows a scalable, template-free deposition of electrochemically active organic electrodes in a single printing. Electropolymerized poly(3,4-ethylenedioxythiophene) (PEDOT) acts as redox-active bridges by exploiting extracellularly transferred electrons generated from the bacterial respiration, constructing a seamless contact between the biological processes and the external abiotic systems. 

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3. Catechol‐Based Molecular Memory Film for Redox Linked Bioelectronics

   https://doi.org/10.1002/aelm.202000452  

   Wu, Si; Kim, Eunkyoung; Chen, Chen‐yu; Li, Jinyang; VanArsdale, Eric; Grieco, Christopher; Kohler, Bern; Bentley, William_E; Shi, Xiaowen; Payne, Gregory_F (July 2020, Advanced Electronic Materials)

   Abstract Redox is emerging as an alternative modality for bio‐device communication. In contrast to the more familiar ionic electrical modality: (i) redox involves the flow of electrons through oxidation–reduction reactions; (ii) the aqueous medium is an “insulator” to this electron flow since free electrons do not normally exist in water; and (iii) redox states are intrinsically digital (oxidized and reduced). By exploiting these unique features, a catechol‐based molecular memory film is reported. This memory is fabricated by electrochemically grafting catechol to a chitosan–agarose polysaccharide network to generate a redox‐active but non‐conducting matrix. The redox state of the grafted catechol moieties serves as the 2‐state memory. It is shown that these redox states: can be repeatedly switched by diffusible mediators (electron shuttles); can be easily read electrically or optically; are stable for at least 2 h in the absence of energy; are sensitive to biologically relevant oxidizing and reducing contexts; and can be switched enzymatically. This catechol‐based molecular memory film is a simple circuit element for redox linked bioelectronics. 

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4. Observation of super-Nernstian proton-coupled electron transfer and elucidation of nature of charge carriers in a multiredox conjugated polymer

   https://doi.org/10.1039/d4sc00785a  

   Tran, Duyen K; West, Sarah M; Speck, Elizabeth_M K; Jenekhe, Samson A (May 2024, Chemical Science)

   Observation of super-Nernstian proton-coupled electron transfer behavior with two protons per electron transferred in an electrochemically n-doped redox conjugated polymer. 

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5. Copper-based redox shuttles supported by preorganized tetradentate ligands for dye-sensitized solar cells

   https://doi.org/10.1039/c9dt04030g  

   Rodrigues, Roberta R.; Lee, Joseph M.; Taylor, Natalie S.; Cheema, Hammad; Chen, Lizhu; Fortenberry, Ryan C.; Delcamp, Jared H.; Jurss, Jonah W. (January 2020, Dalton Transactions)

   Three copper redox shuttles ([Cu( 1 )] 2+/1+ , [Cu( 2 )] 2+/1+ , and [Cu( 3 )] 2+/1+ ) featuring tetradentate ligands were synthesized and evaluated computationally, electrochemically, and in dye-sensitized solar cell (DSC) devices using a benchmark organic dye, Y123 . Neutral polyaromatic ligands with limited flexibility were targeted as a strategy to improve solar-to-electrical energy conversion by reducing voltage losses associated with redox shuttle electron transfer events. Inner-sphere electron transfer reorganization energies ( λ ) were computed quantum chemically and compared to the commonly used [Co(bpy) 3 ] 3+/2+ redox shuttle which has a reported λ value of 0.61 eV. The geometrically constrained biphenyl-based Cu redox shuttles investigated here have lower reorganization energies (0.34–0.53 eV) and thus can potentially operate with lower driving forces for dye regeneration (Δ G reg ) in DSC devices when compared to [Co(bpy) 3 ] 3+/2+ -based devices. The rigid tetradentate ligand design promotes more efficient electron transfer reactions leading to an improved J SC (14.1 mA cm −2 ), higher stability due to the chelate effect, and a decrease in V lossOC for one of the copper redox shuttle-based devices. 

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