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The electron mediators could enter the bacteria cells, extract the electrons from the metabolic reactions of the electricigens and supply these electrons to the anode of an MFC [ 8 ].

At first, the presence of electron mediators was considered to be essential for MFC operation [ 9 ]. They can be produced by the electricigens or externally added to the anodic chamber.

Many species have been identified to synthesize self-mediators such as phenazine [ 10 , 11 ], pyocyanin [ 12 ], and so on.

The potential difference between the mediators and the redox proteins would significantly affect the efficiency of electron transfer [ 13 ].

A number of chemical compounds like anthracenedione, thionine [ 14 ], neutral red [ 15 ], humic acid [ 16 ], riboflavin [ 17 ] and methylene blue [ 18 ] have been investigated to improve the efficiency of electron transfer.

However, the addition of exogenous mediators is not preferable as they always lead to relatively low current densities as well as being expensive and toxic to the microorganisms, thus causing decline of the performance during long time periods, which makes the technique difficult to commercialize.

Moreover, the regular addition of exogenous mediators is technologically unfeasible and environmentally questionable. Hence, if the microorganism can be efficiently used as a catalyst without adding exogenous mediators, it is feasible from a technical point of view that there is no need to gradually add electron mediators as well as being environmentally safe.

Self-mediators produced by electricigens and exogenous mediators used for indirect electron transfer in MFCs. As the biocatalyst of MFCs, electricigens are indispensable.

Up to now, hundreds of electricigens have been isolated and used in MFCs. Most of these electricigens belong to Proteobacteria and Firmicutes. Recent studies showed that the electricigens in MFCs had a diverse tendency.

Microorganisms that have the characteristics to generate electricity are still waiting to be discovered. In order to further understand the diversity and similarity of electricigens, it is necessary to systematically summarize the existing electricity-producing microorganisms.

Many archaea can survive in extreme environments such as high temperature and salinity which exert tremendous stress to the microorganisms.

They have the potential to serve as electricigens in MFCs under special conditions. Two species of halophilic archaea, Haloferax volcanii and Natrialba magadii , were tested as electricigens in the anode of an MFC.

Without any exogenous mediators, the maximum power density and current density reached When neutral red was added as the electron mediator, the maximum power density was further improved for both of the archaea and this power output was much higher than Escherichia coli under the same conditions [ 19 ].

Acidobacteria are physiologically diverse acidophilic bacteria. They can be found in a variety of environments and are able to utilize a wide range of substrates.

Several members of this phylum showed electrochemical activity. The iron-reducing bacteria Geothrix fermentans was able to produce electron mediators which promoted reduction reaction in the electrode.

After optimization of the operation conditions, the current generation rate in the G. Two members of the genus Arcobacter , belonging to acidobacteria, were isolated from an acetate-fed MFC.

Cyanobacteria are photosynthetic microorganisms and environmentally friendly sources for bioenergy production. During the past few years, many studies have focused on the applications of cyanobacteria in MFCs.

The bioelectrochemical systems based on cyanobacteria are called photosynthetic MFCs PMFCs , which work with light as the power source and generate electricity through the light-driven oxidation of water Fig.

Different species of cyanobacteria have been evaluated as the electricigens in PMFCs. The power output of this PMFC was stable with a maximum power density of PMFC using Spirulina platensis as the biocatalyst could be operated at high open circuit voltage without externally added feedstocks.

The maximum power density obtained by this PMFC reached 6. Synechococcus elongatus was used as the electricigen to study the response caused by electricity generation.

The photosynthetic parameters were determined to clarify the increases of current density. However, electricity generation efficiency of the PMFC was still very low [ 25 ].

The schematic diagram of a dual chamber PMFC with photosynthetic microorganisms acting as the electricigens in the anodic chamber. PEM, proton exchange membrane.

Firmicutes have thick cell walls and are tolerant to harsh conditions. They could be always isolated from mixed cultures in the anode of MFCs.

However, electrons need to pass through the cell wall to the anode and thus firmicutes show relatively lower electrochemical activity.

Clostridium butyricum is a successful isolate of firmicutes which has be applied in MFCs. This strict anaerobe can grow at a wide pH and temperature range.

The highest current of 0. Mutagenesis of C. The firmicute Thermincola sp. It generated an average current of 0. In a methanol-fed MFC, a new strain of firmicutes was isolated and identified to be Methylomusa anaerophila by 16S rRNA gene phylogenetic analysis [ 30 ].

Proteobacteria represent the largest class of electricigens which are the dominant strains in the microbial communities of MFCs. Many of them have the ability to directly transfer electrons to the electrode.

Therefore, they could also be applied in PMFCs. Rhodospirillum rubrum was the first strain used to construct PMFC [ 31 ]. The dual chamber PMFC of this bacterium could produce a maximum power density of 1.

Among them, R. The current generation ability of R. The performance of R. Rhodopseudomonas can be used for biohydrogen production and they also have the potential to generate electricity.

When R. Knockout of the nitrogenase of R. The power density of the mutant was increased from Electricity production at relatively low pH was achieved using the acidophilic bacterium, Acidiphilium cryptum.

The power output reached Electron mediators were not required in an R. MFC using pure culture of R. The maximum power density reached When Potter et al.

Genetic tools were employed to engineer E. Under anaerobic conditions, the tricarboxyl acid TCA cycle of E.

Knockout of the arcA gene, which encodes an inhibitor of the TCA cycle, greatly improved the performance and power output of the MFC [ 43 ].

The endogenous glycerol dehydrogenase was overexpressed in E. This engineered strain could synthesize electron mediators which promoted electron transfer between E.

Disruption of the lactic acid pathway of E. These electrons were released and then transferred to the anode. A much higher power output was observed when compared to the parental strain [ 45 ].

Shewanella is widely used in MFCs because of its well-characterized electron transfer mechanisms Fig. It is a facultative anaerobe capable of reducing metal ions such as iron and manganese.

When Kim et al. A recent study employed uniform nanoflaky nickel oxide array coating strategy to improve adhesion of bacterial cells to the electrode.

The performance of the S. The potential of other Shewanella strains as electricigens was also evaluated and S. Two sub-strains of this species, S.

A mutant library of S. A gene responsible for the biosynthesis of cell surface polysaccharide in S. The ydeH gene from E.

The MFCs constructed with this strain produced a peak power density of Pseudomonas aeruginosa is the earliest reported strain capable of synthesizing electron mediators.

Moreover, P. Biosynthesis of the electron mediators in P. A maximum current density of 0. The expression PilA structure gene coding for protein fibers to form nanowires from G.

The pilT gene encoding an ATPase could increase the number of pili when it was knocked out. The pilT mutant of P. The maximum power density was increased by 2.

Proposed electron transfer mechanism of Shewanella. It could attach to the electrode and remain viable for a long period. When this bacterium was first investigated for its electricity generation ability, G.

Then the anode of the MFC was balanced by potentiostat to overcome potential electrochemical limitations and a current density as high as 2.

Nevin et al. The maximum current density and power density reached 4. The differences in the power production between mixed communities and pure cultures were attributed to MFC design [ 61 ].

In another study, a variant of G. This mutant strain was much more effective than the wild-type strain. It generated a power output of 3.

Power output in an MFC with a pure culture of G. These MFCs could be used for wastewater treatment while generating electricity.

Geopsychrobacter electrodiphilus was an important electricigen isolated from marine sediment MFCs. This bacterium could grow at relatively low temperature and utilize various organic substrates.

A peak current density of 6. Various bacteria have been employed as the electricigens. However, there are relatively few studies on eukaryotes as catalysts for MFCs.

Yeasts are good candidates as electricigens due to their clear genetic background, fast growth rate and being generally recognized as safe [ 67 ].

An engineered strain of S. The MFC showed higher power output and current density than unmodified yeast [ 69 ]. In a recent study, S.

Using graphite as the anode, higher current and power densities were achieved in a single chamber MFC in the absence of exogenous mediators [ 70 ].

Yeast extract was successfully applied in an S. The addition of yeast extract can enhance the adhesion of yeast cells to the electrode.

Another yeast strain, Candida melibiosica , was also applied as the biocatalyst for MFCs. Immobilized cells of the yeast Hansenula anomala was also tested for its ability to act as the electricigen in a mediator-free MFC and efficient current generation was observed in this system.

The presence of redox proteins in cell membranes was thought to contribute to direct electron transfer in the MFC [ 73 ].

The non-conventional yeast Arxula adeninivorans was another choice as an MFC catalyst. It could transfer electrons to the anode through the secretion of reducing molecules.

The maximum power density in the A. Algae biomass always serves as the substrates for electricigens in MFCs [ 75 ]. Moreover, algae can be used as both electron donors in the anode and acceptors in the cathode.

In most cases, algae are placed at the cathode of MFCs because they can utilize CO 2 to generate O 2 and facilitate the cathodic reaction.

Up to now, only Chlamydomonas reinhardtii and Chlorella sp. The model microalga, C. The higher the light intensity, the better the performance of the PMFC [ 76 ].

By controlling the culture conditions, this alga could generate electricity without externally added substrates. A newly isolated Chlorella sp.

UMACC was used to form biofilms on the anode. The maximum power and current density in the PMFC reached 0. The algae were further immobilized in alginate gel within an MFC and the peak power output was enhanced to 0.

Generally, diverse of microorganisms have the potential to be used as the electricigens in MFCs. These species could be divided into three distinct groups, the archaebacteria, the eubacteria and the eukaryotes.

The eubacteria could be further classified into several subgroups according to their families and genera. There seems to be no direct correlation between the taxonomic status and their electricity-producing capability.

Their electrochemical activities should be the result of convergent evolution. Phylogenetic analysis was conducted using the MEGA7 software [ ].

Sequence alignment was performed by ClustralW. The phylogenetic tree was constructed using the Neighbor-Joining method.

JR, GU The activity of at least one electricigen is the requirement for MFCs to generate electricity. However, a diversity of electricigens can also contribute to current production and, in most cases, may be more efficient.

The idea of using mixed communities has thus been proposed in the last decade. Pure cultures are useful to clarify the electron transfer mechanism at the microbiological level and further reduce the specific microbial strains in mixed cultures.

However, pure cultured electricigens require relatively strict operating conditions and only selective substrates can be utilized while miscellaneous consortiums are more suitable for the use of complex substrates.

MFCs with the best performance are always achieved by using mixed communities, such as wastewater or activated sludge, as the anodic biocatalyst.

Some species of the microorganisms in wastewater are electrochemical active. Therefore, wastewater could be directly employed as the inoculum for MFCs.

Distillery wastewater contains organic substrates that can be easily degraded. It is a good source for electricity generation in MFCs.

Sugar beet processing wastewater was also used for electricity generation in a dual chamber MFC. Raw sugar beet processing wastewater was diluted to different concentrations and fed to the anode in batch-mode.

A maximum power density of Brewery wastewater was used as the substrates in an MFC with special chitosan copolymer proton exchange membrane.

The maximum current and power densities of this MFC were In a recent study, industrial wastewater from different sources including chocolate industry, gum industry and slaughterhouse industry were tested as the anodic catalyst.

Activated sludge is a biological floc containing microbial communities as well as their dependent biodegradable organic compounds.

It is also a good candidate as electricigens for MFCs [ 85 ]. Dentel et al. Activated sludge from biogas plants was used in MFCs to study the stability of the system and measure the power generated [ 87 ].

MFCs inoculated with three different types of activated sludges could simultaneously generate electricity and remove chemical oxygen demand. Heat and acid pretreatment of these sludges further improved their electricity production capacity [ 88 ].

Anaerobic sludge obtained from a wastewater treatment plant was used as mixed inoculums for a single-chamber MFC. Enriched activated sludge was obtained by inoculation of fly ash leachate to different media.

A maximum power density of 5. The microbial populations in MFCs inoculated with wastewater or activated sludge vary greatly. To exploit the diversity of electricigens in the mixed communities, the 16S rRNA gene sequencing technique was employed to analyze the microbial community structure.

Phylogenetic analysis showed that electricigens in these MFCs always consisted of the strains discussed above. For instance, Tkach et al.

The microbial communities are dynamically changed during the MFC operation processes and their dynamics can be also analyzed using similar strategies.

The correlation between the power density and the changes of microbial species were determined by denaturing gradient gel electrophoresis of partial 16S rRNA genes [ 92 ].

The mixed communities in wastewater and activated sludge are very complex, making it difficult to elucidate how current is generated in such systems.

Also, it is difficult to steer these mixed cultures to a stable performance. The performance of this MFC was improved when compared with the pure culture of G.

Therefore, it is an excellent strain to construct co-culture systems. Defined co-cultures of P. The fermentation parameters were studied to achieve higher electricity production and dissolved oxygen was identified as the key factor.

The defined co-culture system of P. Further optimization of the process parameters by response surface methodology led to a maximum power density of Klebsiella pneumonia was another strain that could secrete electron mediators.

The MFC constructed by co-culture of Klebsiella pneumonia and Lipomyces starkeyi produced a peak power density of Co-cultured microorganisms could expand the carbon source range in MFCs.

Lignocellulosic biomass is the most abundant carbohydrate in nature [ 98 ]. Since no microorganisms can simultaneously degrade biomass and transfer electrons to the electrode, the utilization of cellulosic biomass as substrates for MFCs requires a co-cultured system.

Ren et al. The co-culture conditions were systematically optimized to balance glucose catabolism and electron transfer. At present, the combination of two species did not give high gains of efficiencies as wastewater or activated sludge species.

However, defined co-culture MFCs provided a strategy to study the interaction between different microorganisms in miscellaneous consortia.

Metabonomics analysis showed that the consumption of both succinate and oxygen by E. The MFC technology has been greatly advanced in the past few years.

However, there are not yet any practical applications of MFCs due to the limitations of their power outputs. Electricigens are the fundamental issues in the MFC systems.

The application of electricigens will be the focus of future research for MFCs. To improve the performance of an MFC, it is necessary to select and breed high-quality electricigens.

Recently developed metabolic engineering and synthetic biology tools have been put forward to such an extent to modify current electricigens or create novel electricigens with excellent electrochemical activities [ ].

Using genetic modification, the largely unexplored potential to improve power output and electron transfer to the electrode is almost limitless.

The power densities are determined not only by the electricigens but also by the architecture, electrode spacing and electrolyte conductivity of MFCs [ ].

The improvements in these aspects would also contribute to enhancing the power generation efficiency of an MFC.

Moreover, MFC should be integrated with other processes to make this technique economically feasible. First, MFC can be used for wastewater treatment.

Application of MFC for wastewater treatment could be an attractive alternative to reduce the cost of existing systems.

The power generated by MFCs would reduce the electricity required by the wastewater treatment bioreactors [ ]. Second, MFC can be used to simultaneously produce valuable products i.

The protons generated in the anode could migrate to the cathode to form H 2. Third, electricigens can sense both the presence and toxicity of chemicals.

MFC-based biosensors are appropriate for real-time monitoring of environmental parameters [ ]. At last, MFC for bioremediation is another promising application.

MFCs have been proposed for the clean-up of various types of contamination, ranging from aromatic or substituted organic compounds to heavy metals [ ].

During the bioremediation process, electricity is also generated and thus the cost is reduced. The combination of the MFC technology with other applications can make the dream of a possible large-scale launch of MFC come true.

Microbial fuel-cells. Appl Biochem Biotechnol. Logan BE. Exoelectrogenic bacteria that power microbial fuel cells.

Nat Rev Microbiol. In Microbial Fuel Cells. New York: Wiley; Google Scholar. Extracellular electron transfer via microbial nanowires.

Techniques for the study and development of microbial fuel cells: an electrochemical perspective. Chem Soc Rev. Microbial nanowires for bioenergy applications.

Curr Opin Biotechnol. Electrically conductive bacterial nanowires produced by Shewanella oneidensis strain MR-1 and other microorganisms.

Renewable and Sustainable Energy Reviews , 69 , Denitrification in an integrated bioelectro-photocatalytic system. Recycling electroplating sludge to produce sustainable electrocatalysts for the efficient conversion of carbon dioxide in a microbial electrolysis cell.

Bharathiraja, T. Sudharsanaa, A. Bharghavi, J. Jayamuthunagai, R. Biohydrogen and Biogas — An overview on feedstocks and enhancement process.

Fuel , , H2 production by the thermoelectric microconverter coupled with microbial electrolysis cell.

International Journal of Hydrogen Energy , 41 48 , Recent advances and emerging challenges in microbial electrolysis cells MECs for microbial production of hydrogen and value-added chemicals.

Renewable and Sustainable Energy Reviews , 61 , The performance of the microbial fuel cell-coupled constructed wetland system and the influence of the anode bacterial community.

Environmental Technology , 37 13 , Process and kinetics of azo dye decolourization in bioelectrochemical systems: effect of several key factors.

Chandrasekhar, Mohd Sahaid Kalil. A comprehensive review of microbial electrolysis cells MEC reactor designs and configurations for sustainable hydrogen gas production.

Alexandria Engineering Journal , 55 1 , Biocatalysts in microbial electrolysis cells: A review. International Journal of Hydrogen Energy , 41 3 , Harvest and utilization of chemical energy in wastes by microbial fuel cells.

Chemical Society Reviews , 45 10 , Application of a weak magnetic field to improve microbial fuel cell performance.

Ecotoxicology , 24 10 , Water , 7 12 , Journal of Korean Society of Environmental Engineers , 37 9 , Speers, Gemma Reguera. Self-sustained reduction of multiple metals in a microbial fuel cell—microbial electrolysis cell hybrid system.

Alternate switching between microbial fuel cell and microbial electrolysis cell operation as a new method to control H2O2 level in Bioelectro-Fenton system.

Design of a single chambered microbial electrolytic cell reactor for production of biohydrogen from rice straw hydrolysate.

Biotechnology Letters , 37 6 , Separation and Purification Technology , , Comparison of Co II reduction on three different cathodes of microbial electrolysis cells driven by Cu II -reduced microbial fuel cells under various cathode volume conditions.

Buonomenna, J. Membrane processes and renewable energies. Renewable and Sustainable Energy Reviews , 43 , Assessment of five different cathode materials for Co II reduction with simultaneous hydrogen evolution in microbial electrolysis cells.

International Journal of Hydrogen Energy , 40 1 , A solar assisted microbial electrolysis cell for hydrogen production driven by a microbial fuel cell.

RSC Advances , 5 , Cobalt recovery with simultaneous methane and acetate production in biocathode microbial electrolysis cells.

Removal of organic matters and nitrogenous pollutants simultaneously from two different wastewaters using biocathode microbial fuel cell. Venkata Mohan, G.

Velvizhi, K. Vamshi Krishna, M. Lenin Babu. Microbial catalyzed electrochemical systems: A bio-factory with multi-facet applications.

Complete cobalt recovery from lithium cobalt oxide in self-driven microbial fuel cell — Microbial electrolysis cell systems. The source of inoculum plays a defining role in the development of MEC microbial consortia fed with acetic and propionic acid mixtures.

Journal of Biotechnology , , Microbial electrolysis cells turning to be versatile technology: Recent advances and future challenges. Water Research , 56 , Applied Biochemistry and Biotechnology , 5 , Metagenomic-based analysis of biofilm communities for electrohydrogenesis: From wastewater to hydrogen.

International Journal of Hydrogen Energy , 39 9 , Recovery of flakey cobalt from aqueous Co II with simultaneous hydrogen production in microbial electrolysis cells.

International Journal of Hydrogen Energy , 39 2 , A , 2 34 , Erable, A. Electroactive biofilms. Chinese Journal of Chemical Engineering , 21 12 , Electrosorption driven by microbial fuel cells to remove phenol without external power supply.

A comprehensive review of microbial electrochemical systems as a platform technology. Biotechnology Advances , 31 8 , Effective sulfur and energy recovery from hydrogen sulfide through incorporating an air-cathode fuel cell into chelated-iron process.

Journal of Hazardous Materials , , Production of bioelectricity, bio-hydrogen, high value chemicals and bioinspired nanomaterials by electrochemically active biofilms.

Biotechnology Advances , 31 6 , Copper catalysis for enhancement of cobalt leaching and acid utilization efficiency in microbial fuel cells.

Electrosorption driven by microbial fuel cells without electric grid energy consumption for simultaneous phenol removal and wastewater treatment.

Electrochemistry Communications , 34 , Hatzell, Younggy Kim, Bruce E. Powering microbial electrolysis cells by capacitor circuits charged using microbial fuel cell.

Alkali production from bipolar membrane electrodialysis powered by microbial fuel cell and application for biogas upgrading. Applied Energy , , Cobalt leaching from lithium cobalt oxide in microbial electrolysis cells.

Venkata Mohan, S. Srikanth, G. Velvizhi, M. A fuel-cell-assisted iron redox process for simultaneous sulfur recovery and electricity production from synthetic sulfide wastewater.

Zeng, Han-Qing Yu. A microbial fuel cell—membrane bioreactor integrated system for cost-effective wastewater treatment. Applied Energy , 98 , Anodic Fenton process assisted by a microbial fuel cell for enhanced degradation of organic pollutants.

Water Research , 46 14 , Pisciotta, Zehra Zaybak, Douglas F. Applied and Environmental Microbiology , 78 15 , Self-stacked submersible microbial fuel cell SSMFC for improved remote power generation from lake sediments.

Biosensors and Bioelectronics , 35 1 , Innovative self-powered submersible microbial electrolysis cell SMEC for biohydrogen production from anaerobic reactors.

Water Research , 46 8 , Fouling of proton exchange membrane PEM deteriorates the performance of microbial fuel cell. Water Research , 46 6 , Enhanced hydrogen production from waste activated sludge by cascade utilization of organic matter in microbial electrolysis cells.

Water Research , 46 4 , Hassett, Tingyue Gu. From wastewater to bioenergy and biochemicals via two-stage bioconversion processes: A future paradigm.

Biotechnology Advances , 29 6 , Kim, B. Hydrogen production from inexhaustible supplies of fresh and salt water using microbial reverse-electrodialysis electrolysis cells.

Proceedings of the National Academy of Sciences , 39 , Guwy, R. Dinsdale, J. Kim, J. Massanet-Nicolau, G.

Fermentative biohydrogen production systems integration. Bioresource Technology , 18 , Integrated hydrogen production process from cellulose by combining dark fermentation, microbial fuel cells, and a microbial electrolysis cell.

Bioresource Technology , 5 , Bal Krishna, Ahmad Jabari Kohpaei. Expediting COD removal in microbial electrolysis cells by increasing biomass concentration.

Bioresource Technology , 4 , An innovative miniature microbial fuel cell fabricated using photolithography.

Biosensors and Bioelectronics , 26 6 , Biohydrogen Production from Anaerobic Fermentation. Biohydrogen Production with High-Rate Bioreactors. Nanoparticle decorated anodes for enhanced current generation in microbial electrochemical cells.

Biosensors and Bioelectronics , 26 5 , Hydrogen production from propionate in a biocatalyzed system with in-situ utilization of the electricity generated from a microbial fuel cell.

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