Your search keyword '"electrogen"' showing total 11 results

1. A 96-well high-throughput, rapid-screening platform of extracellular electron transfer in microbial fuel cells

Author

Tahernia, Mehdi, Mohammadifar, Maedeh, Gao, Yang, Panmanee, Warunya, Hassett, Daniel J., and Choi, Seokheun

Published

2020

2. Cultivating electroactive microbesfrom field to bench

Author

Yee, Mon Oo, Deutzmann, Joerg, Spormann, Alfred, and Rotaru, Amelia-Elena

Subjects

Anaerobiosis, Bacteria, Bacteriological Techniques, Bioelectric Energy Sources, Electrochemical Techniques, Electrodes, electroactive microorganisms, electrotroph, electrogen, microbial fuel cells, microbial electrosynthesis, bioelectrochemical systems, Nanoscience & Nanotechnology

Abstract

Electromicrobiology is an emerging field investigating and exploiting the interaction of microorganisms with insoluble electron donors or acceptors. Some of the most recently categorized electroactive microorganisms became of interest to sustainable bioengineering practices. However, laboratories worldwide typically maintain electroactive microorganisms on soluble substrates, which often leads to a decrease or loss of the ability to effectively exchange electrons with solid electrode surfaces. In order to develop future sustainable technologies, we cannot rely solely on existing lab-isolates. Therefore, we must develop isolation strategies for environmental strains with electroactive properties superior to strains in culture collections. In this article, we provide an overview of the studies that isolated or enriched electroactive microorganisms from the environment using an anode as the sole electron acceptor (electricity-generating microorganisms) or a cathode as the sole electron donor (electricity-consuming microorganisms). Next, we recommend a selective strategy for the isolation of electroactive microorganisms. Furthermore, we provide a practical guide for setting up electrochemical reactors and highlight crucial electrochemical techniques to determine electroactivity and the mode of electron transfer in novel organisms.

Published

2020

3. Cultivating electroactive microbes-from field to bench.

Author

Yee, Mon Oo, Deutzmann, Joerg, Spormann, Alfred, and Rotaru, Amelia-Elena

Subjects

Bacteria, Bacteriological Techniques, Electrodes, Bioelectric Energy Sources, Anaerobiosis, Electrochemical Techniques, electroactive microorganisms, electrotroph, electrogen, microbial fuel cells, microbial electrosynthesis, bioelectrochemical systems, Nanoscience & Nanotechnology

Abstract

Electromicrobiology is an emerging field investigating and exploiting the interaction of microorganisms with insoluble electron donors or acceptors. Some of the most recently categorized electroactive microorganisms became of interest to sustainable bioengineering practices. However, laboratories worldwide typically maintain electroactive microorganisms on soluble substrates, which often leads to a decrease or loss of the ability to effectively exchange electrons with solid electrode surfaces. In order to develop future sustainable technologies, we cannot rely solely on existing lab-isolates. Therefore, we must develop isolation strategies for environmental strains with electroactive properties superior to strains in culture collections. In this article, we provide an overview of the studies that isolated or enriched electroactive microorganisms from the environment using an anode as the sole electron acceptor (electricity-generating microorganisms) or a cathode as the sole electron donor (electricity-consuming microorganisms). Next, we recommend a selective strategy for the isolation of electroactive microorganisms. Furthermore, we provide a practical guide for setting up electrochemical reactors and highlight crucial electrochemical techniques to determine electroactivity and the mode of electron transfer in novel organisms.

Published

2020

4. Using Oxidative Electrodes to Enrich Novel Members in the Desulfobulbaceae Family from Intertidal Sediments

Author

Cheng Li, Clare E. Reimers, and Yvan Alleau

Subjects

Desulfobulbaceae, bioelectrochemical reactor, electrogen, electrogenic sulfur oxidation, cable bacteria, Biology (General), QH301-705.5

Abstract

Members in the family of Desulfobulbaceae may be influential in various anaerobic microbial communities, including those in anoxic aquatic sediments and water columns, and within wastewater treatment facilities and bioelectrochemical systems (BESs) such as microbial fuel cells (MFCs). However, the diversity and roles of the Desulfobulbaceae in these communities have received little attention, and large portions of this family remain uncultured. Here we expand on findings from an earlier study (Li, Reimers, and Alleau, 2020) to more fully characterize Desulfobulbaceae that became prevalent in biofilms on oxidative electrodes of bioelectrochemical reactors. After incubations, DNA extraction, microbial community analyses, and microscopic examination, we found that a group of uncultured Desulfobulbaceae were greatly enriched on electrode surfaces. These Desulfobulbaceae appeared to form filaments with morphological features ascribed to cable bacteria, but the majority were taxonomically distinct from recognized cable bacteria genera. Thus, the present study provides new information about a group of Desulfobulbaceae that can exhibit filamentous morphologies and respire on the oxidative electrodes. While the phylogeny of cable bacteria is still being defined and updated, further enriching these members can contribute to the overall understanding of cable bacteria and may also lead to identification of successful isolation strategies.

Published

2021

5. Using Oxidative Electrodes to Enrich Novel Members in the Desulfobulbaceae Family from Intertidal Sediments

Author

Yvan Alleau, Clare E. Reimers, and Cheng Li

Subjects

Microbiology (medical), Microbial fuel cell, biology, QH301-705.5, Ecology, Chemistry, Biofilm, biology.organism_classification, Microbiology, Anoxic waters, electrogen, Article, bioelectrochemical reactor, electrogenic sulfur oxidation, Bioelectrochemical reactor, Microbial population biology, cable bacteria, Phylogenetics, Virology, Desulfobulbaceae, Biology (General), Bacteria

Abstract

Members in the family of Desulfobulbaceae may be influential in various anaerobic microbial communities, including those in anoxic aquatic sediments and water columns, and within wastewater treatment facilities and bioelectrochemical systems (BESs) such as microbial fuel cells (MFCs). However, the diversity and roles of the Desulfobulbaceae in these communities have received little attention, and large portions of this family remain uncultured. Here we expand on findings from an earlier study (Li, Reimers, and Alleau, 2020) to more fully characterize Desulfobulbaceae that became prevalent in biofilms on oxidative electrodes of bioelectrochemical reactors. After incubations, DNA extraction, microbial community analyses, and microscopic examination, we found that a group of uncultured Desulfobulbaceae were greatly enriched on electrode surfaces. These Desulfobulbaceae appeared to form filaments with morphological features ascribed to cable bacteria, but the majority were taxonomically distinct from recognized cable bacteria genera. Thus, the present study provides new information about a group of Desulfobulbaceae that can exhibit filamentous morphologies and respire on the oxidative electrodes. While the phylogeny of cable bacteria is still being defined and updated, further enriching these members can contribute to the overall understanding of cable bacteria and may also lead to identification of successful isolation strategies.

Published

2021

6. Link between capacity for current production and syntrophic growth in Geobacter species.

Author

Rotaru, Amelia-Elena, Woodard, Trevor L., Nevin, Kelly P., Lovley, Derek R., Hassett, Daniel, and Clarke, Tom

Subjects

SYNTROPHISM, GEOBACTER, BACTERIAL growth

Abstract

Electrodes are unnatural electron acceptors, and it is yet unknown how some Geobacter species evolved to use electrodes as terminal electron acceptors. Analysis of different Geobacter species revealed that they varied in their capacity for current production. Geobacter metallireducens and G. hydrogenophilus generated high current densities (ca. 0.2 mA/cm²), comparable to G. sulfurreducens. G. bremensis, G. chapellei, G. humireducens, and G. uraniireducens, produced much lower currents (ca. 0.05 mA/cm²) and G. bemidjiensis was previously found to not produce current. There was no correspondence between the effectiveness of current generation and Fe(III) oxide reduction rates. Some high-current-density strains (G. metallireducens and G. hydrogenophilus) reduced Fe(III)-oxides as fast as some low-current-density strains (G. bremensis, G. humireducens, and G. uraniireducens) whereas other low-currentdensity strains (G. bemidjiensis and G. chapellei) reduced Fe(III) oxide as slowly as G. sulfurreducens, a high-current-density strain. However, there was a correspondence between the ability to produce higher currents and the ability to grow syntrophically. G. hydrogenophilus was found to grow in co-culture with Methanosarcina barkeri, which is capable of direct interspecies electron transfer (DIET), but not with Methanospirillum hungatei capable only of H2 or formate transfer. Conductive granular activated carbon (GAC) stimulated metabolism of the G. hydrogenophilus - M. barkeri co-culture, consistent with electron exchange via DIET. These findings, coupled with the previous finding that G. metallireducens and G. sulfurreducens are also capable of DIET, suggest that evolution to optimize DIET has fortuitously conferred the capability for high-density current production to some Geobacter species. [ABSTRACT FROM AUTHOR]

Published

2015

7. Accelerated start-up and improved performance of wastewater microbial fuel cells in four circuit modes: Role of anodic potential

Author

Zhenxing Ren, Guixia Ji, Hongbo Liu, Ming Yang, Suyun Xu, Mengting Ye, Eric Lichtfouse, University of Shanghai for Science and Technology, Centre européen de recherche et d'enseignement des géosciences de l'environnement (CEREGE), Institut de Recherche pour le Développement (IRD)-Aix Marseille Université (AMU)-Collège de France (CdF (institution))-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS)-Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE), Xi'an Jiaotong University (Xjtu), and Chongqing New World Environment Detection Technology Co. LTD

Subjects

Membrane fouling, microbial fuel cells, [SDV.BIO]Life Sciences [q-bio]/Biotechnology, [SDE.IE]Environmental Sciences/Environmental Engineering, Renewable Energy, Sustainability and the Environment, MFC, [SPI.NRJ]Engineering Sciences [physics]/Electric power, Start-up, Energy Engineering and Power Technology, electrogen, Wastewater MFC, [SDU]Sciences of the Universe [physics], Microbial community, pH balance, electricity, Electrical and Electronic Engineering, Physical and Theoretical Chemistry, Anodic potential, [CHIM.OTHE]Chemical Sciences/Other, wastewater

Abstract

International audience; Wastewater microbial fuel cells (MFCs) can transform the chemical energy into electricity; however, little is known on the effect of circuit modes on start-up and performance of wastewater MFCs. Here we have investigated the effect of four circuit modes on start-up, performance and membrane fouling of MFCs systematically. Besides shortening the start-up period and improving the performance of MFCs, applying anodic negative potential also balances pH of the system and thus enhances COD removal. The open-circuit constant potential mode (OC-MFC) presents the shortest start-up period of 5 days, with the highest voltage output of 810 mV and the slightest membrane fouling, which provides an effectively strategy to accelerate the start-up of wastewater MFCs. The circuit mode applied to start up wastewater MFC not only affects the degree of membrane fouling, but also causes significant differences in anode microbial communities. The total abundance of exoelectrogens in the closed-circuit intermittent potential (CI-MFC) mode was the highest up to 54.70%, but the performance of CI-MFC inferiors to OC-MFC, indicating that performance of the wastewater MFC is not solely determined by the dominant bacteria. Overall, the OC-MFC provides a new strategy to accelerate the start-up period and enhance performance of wastewater MFC simultaneously.

Published

2022

8. Enhanced power generation using controlled inoculum from palm oil mill effluent fed microbial fuel cell.

Author

Baranitharan, E., Khan, Maksudur R., Yousuf, Abu, Teo, Wee Fei Aaron, Tan, Geok Yuan Annie, and Cheng, Chin Kui

Subjects

*ELECTRIC power production, *PALM oil, *MICROBIAL fuel cells, *ANODES, *POLYMERASE chain reaction, *POLYACRYLONITRILES

Abstract

Enhancing the anode performance is a critical step for improving the power output of MFCs. This study deals with the dual chamber MFCs to increase the power generation using the controlled inoculum in Palm oil mill effluent (POME). Controlled inoculum (CI) was made using the predominant microorganisms such as Pseudomonas aeruginosa , Azospira oryzae , Acetobacter peroxydans and Solimonas variicoloris isolated from palm oil anaerobic sludge (AS) as well as from biofilm of MFC anode operated with AS and identified using BIOLOG gene III analysis, PCR, DGGE and sequencing. Biofilm formation on electrode was investigated by Fourier Transform Infrared spectroscopy (FTIR) and Thermogravimetric analayis (TGA). The MFC operated with Polyacrylonitrile carbon felt (PACF) anode and CI reached the maximum power density of 107.35 mW/m 2 , which was two times higher as compared to MFC operated with usual anaerobic sludge as inoculum. The maximum coulombic efficiency (CE) of 74% was achieved from the MFC with CI, which was 50% higher than the CE with anaerobic sludge. But, it showed lower COD removal efficiency of about 32%, which might be due to the absence of required fermentative microorganisms in CI to utilize POME. The electrochemical activities have been investigated by electrochemical impedance spectroscopy (EIS). EIS and the simulated results showed the significant reduction of charge transfer resistance ( R ct ) by ∼40% during the operation of the cell with CI. EIS results provided evidence that there was a substantial improvement in electron transfer between the microorganisms and the anode with CI. These results demonstrate that the power output of MFCs can be increased significantly using CI. [ABSTRACT FROM AUTHOR]

Published

2015

9. Role of the photosynthetic electron transfer chain in electrogenic activity of cyanobacteria.

Author

Pisciotta, John M., YongJin Zou, and Baskakov, Ilia V.

Subjects

*BACTERIA, *CYANOBACTERIA, *PHOTOSYNTHETIC bacteria, *ELECTRONS, *SOLAR energy

Abstract

Certain anaerobic bacteria, termed electrogens, produce an electric current when electrons from oxidized organic molecules are deposited to extracellular metal oxide acceptors. In these heterotrophic 'metal breathers', the respiratory electron transport chain (R-ETC) works in concert with membrane-bound cytochrome oxidases to transfer electrons to the extracellular acceptors. The diversity of bacteria able to generate an electric current appears more widespread than previously thought, and aerobic phototrophs, including cyanobacteria, possess electrogenic activity. However, unlike heterotrophs, cyanobacteria electrogenic activity is light dependent, which suggests that a novel pathway could exist. To elucidate the electrogenic mechanism of cyanobacteria, the current studies used site-specific inhibitors to target components of the photosynthetic electron transport chain (P-ETC) and cytochrome oxidases. Here, we show that (1) P-ETC and, particularly, water photolysed by photosystem II (PSII) is the source of electrons discharged to the environment by illuminated cyanobacteria, and (2) water-derived electrons are transmitted from PSII to extracellular electron acceptors via plastoquinone and cytochrome bd quinol oxidase. Two cyanobacterial genera ( Lyngbya and Nostoc) displayed very similar electrogenic responses when treated with P-ETC site-specific inhibitors, suggesting a conserved electrogenic pathway. We propose that in cyanobacteria, electrogenic activity may represent a form of overflow metabolism to protect cells under high-intensity light. This study offers insight into electron transfer between phototrophic microorganisms and the environment and expands our knowledge into biologically based mechanisms for harnessing solar energy. [ABSTRACT FROM AUTHOR]

Published

2011

10. Using Oxidative Electrodes to Enrich Novel Members in the Desulfobulbaceae Family from Intertidal Sediments.

Author

Li, Cheng, Reimers, Clare E., and Alleau, Yvan

Subjects

SALT marshes, MICROBIAL fuel cells, ELECTRODES, MICROBIAL communities, SEDIMENTS, WASTEWATER treatment, BIOLOGICAL nutrient removal

Abstract

Members in the family of Desulfobulbaceae may be influential in various anaerobic microbial communities, including those in anoxic aquatic sediments and water columns, and within wastewater treatment facilities and bioelectrochemical systems (BESs) such as microbial fuel cells (MFCs). However, the diversity and roles of the Desulfobulbaceae in these communities have received little attention, and large portions of this family remain uncultured. Here we expand on findings from an earlier study (Li, Reimers, and Alleau, 2020) to more fully characterize Desulfobulbaceae that became prevalent in biofilms on oxidative electrodes of bioelectrochemical reactors. After incubations, DNA extraction, microbial community analyses, and microscopic examination, we found that a group of uncultured Desulfobulbaceae were greatly enriched on electrode surfaces. These Desulfobulbaceae appeared to form filaments with morphological features ascribed to cable bacteria, but the majority were taxonomically distinct from recognized cable bacteria genera. Thus, the present study provides new information about a group of Desulfobulbaceae that can exhibit filamentous morphologies and respire on the oxidative electrodes. While the phylogeny of cable bacteria is still being defined and updated, further enriching these members can contribute to the overall understanding of cable bacteria and may also lead to identification of successful isolation strategies. [ABSTRACT FROM AUTHOR]

Published

2021

11. Link between capacity for current production and syntrophic growth in Geobacter species

Author

Amelia-Elena eRotaru, Trevor eWoodard, Kelly P. Nevin, and Derek R Lovley

Subjects

Microbiology (medical), Stereochemistry, direct interspecies electron transfer (DIET), ved/biology.organism_classification_rank.species, lcsh:QR1-502, Microbiology, lcsh:Microbiology, Electron transfer, chemistry.chemical_compound, Syntrophy, Formate, direct interspecies electron transfer, Original Research, chemistry.chemical_classification, biology, ved/biology, Ecology, Methanosarcina, Geobacter metallireducens, Electron acceptor, biology.organism_classification, electrogen, chemistry, Electrogens, syntrophy, Methanosarcina barkeri, Geobacter

Abstract

Electrodes are unnatural electron acceptors, and it is yet unknown how some Geobacter species evolved to use electrodes as terminal electron acceptors. Analysis of different Geobacter species revealed that they varied in their capacity for current production. Geobacter metallireducens and G. hydrogenophilus generated high current densities (ca. 0.2 mA/cm(2)), comparable to G. sulfurreducens. G. bremensis, G. chapellei, G. humireducens, and G. uraniireducens, produced much lower currents (ca. 0.05 mA/cm(2)) and G. bemidjiensis was previously found to not produce current. There was no correspondence between the effectiveness of current generation and Fe(III) oxide reduction rates. Some high-current-density strains (G. metallireducens and G. hydrogenophilus) reduced Fe(III)-oxides as fast as some low-current-density strains (G. bremensis, G. humireducens, and G. uraniireducens) whereas other low-current-density strains (G. bemidjiensis and G. chapellei) reduced Fe(III) oxide as slowly as G. sulfurreducens, a high-current-density strain. However, there was a correspondence between the ability to produce higher currents and the ability to grow syntrophically. G. hydrogenophilus was found to grow in co-culture with Methanosarcina barkeri, which is capable of direct interspecies electron transfer (DIET), but not with Methanospirillum hungatei capable only of H2 or formate transfer. Conductive granular activated carbon (GAC) stimulated metabolism of the G. hydrogenophilus - M. barkeri co-culture, consistent with electron exchange via DIET. These findings, coupled with the previous finding that G. metallireducens and G. sulfurreducens are also capable of DIET, suggest that evolution to optimize DIET has fortuitously conferred the capability for high-density current production to some Geobacter species.

Published

2015