Electroanalysis of microbial anodes for bioelectrochemical systems: basics, progress and perspectives

Rimboud, Mickaël; Pocaznoi, Diana; Erable, Benjamin; Bergel, Alain

doi:10.1039/c4cp01698j

Cited by 82 publications

(62 citation statements)

References 157 publications

(323 reference statements)

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“…Conversely, such a system is detrimental to CE values, particularly when non-electrochemical reactions compete for the consumption of the substrate, as was the case here. An electroanalytical device properly designed to characterize a microbial anode under the most favourable conditions should result in low Coulombic efficiencies when complex microbial systems are implemented [50], as observed in the present work. The compost leachate may contain various electron acceptors (nitrates, sulphates, etc.)…”

Section: à2mentioning

confidence: 62%

“…The most likely explanation of the low CE values was the presence of acetoclastic methanogenic Archaea that consumed acetate to produce methane and carbon dioxide [62,63]. Because of the low ratio of the electrode surface area to solution volume, used here to work in suitable electroanalysis conditions [50], the effect of planktonic side-reactions was enhanced.…”

Section: à2mentioning

confidence: 97%

“…CEs increased considerably from the first to the third oxidation peak: from 1.42 ± 0.38% to 38.2 ± 5% at 40 C and from 3.1 ± 0.35% to 47.7 ± 5.2% at 25 C. The fact that CE values remained low had two synergetic causes: the small surface area of the electrodes (10 cm 2 ) in comparison with the relatively large solution volume (650 mL) on the one hand, and the richness of the medium on the other hand. As theorized by Rimboud et al [50], an electroanalysis system must implement a working electrode of small surface area in a large volume of solution in order to favour the highest possible current density. Conversely, such a system is detrimental to CE values, particularly when non-electrochemical reactions compete for the consumption of the substrate, as was the case here.…”

Section: à2mentioning

confidence: 99%

“…Characterizing the behaviour of each of the elements that constitute an electro-microbial reactor, by specific analytical experiments, is a pre-requisite to the launch of an engineering-based strategy for the development of the related technologies [49]. The study was therefore carried out in electroanalytical conditions [50] by using a three-electrode set-up to protect the anode from most interactions due to the other elements of the system, and particularly from variations in the kinetics of the auxiliary electrode. The potential applied to the anode was thus perfectly controlled.…”

Section: Introductionmentioning

confidence: 99%

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Increasing the temperature is a relevant strategy to form microbial anodes intended to work at room temperature

Oliot¹,

Erable²,

Solan³

et al. 2017

Electrochimica Acta

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OATAO is an open access repository that collects the work of Toulouse researchers and makes it freely available over the web where possible. Reducing the time required for the formation of microbial anodes from environmental inocula is a great challenge. The possibility of reaching this objective by increasing the temperature during the bioanode preparation was investigated here. Microbial anodes were formed at 25 C and 40 C under controlled potential with successive acetate additions. At 25 C, around 40 days were required to perform three acetate batches, which led to current density of 9.4 ± 2 A.m À2 , while at 40 C, 20 days were sufficient to complete three similar batches, leading to 22.9 ± 4.2 A.m À2 . The bioanodes formed at 40 C revealed three redox systems and those formed at 25 C only one. The temperature also impacted the biofilm structure, which was less compact at 40 C. When the bioanodes formed at 40 C were switched to 25 C, they produced current densities similar to those of bioanodes formed at 25 C; they recovered the single redox system that was developed by the bioanodes formed at 25 C and the difference in biofilm structures was mitigated. It is consequently fully appropriate to accelerate the formation of microbial anodes by increasing the temperatures to 40 C even if they are finally intended to operate at room temperature.

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Section: à2mentioning

confidence: 62%

Section: à2mentioning

confidence: 97%

Section: à2mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Increasing the temperature is a relevant strategy to form microbial anodes intended to work at room temperature

Oliot¹,

Erable²,

Solan³

et al. 2017

Electrochimica Acta

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“…82 Within this study, the focus lies rather on process discovery than process optimization for the highest possible rates. Therefore, the BESs were designed to enable multiple simultaneous fully controlled fermentations with a high level of comparability.…”

Section: Development Of a Standardised Reactor Platformmentioning

confidence: 99%

Understanding extracellular electron transport of industrial microorganisms and optimization for production application

Kracke¹

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Microbial electrosynthesis (MES) and electro-fermentation are novel approaches to increase microbial production by stimulating the metabolism of the cells electrically. The technique is still in its infancy and while already hyped as promising method to convert CO 2 or cheap carbon sources and electrical energy into valuable chemicals and fuels, little is known about its true potential. This project uses a combination of in silico and in vivo approaches to gather novel information about the benefits and limitations of microbial electrosynthesis as well as its fundamental mechanisms.Understanding microbial electron transport mechanisms is the key to optimization of any bioelectrochemical technology. Therefore, this work analyses the different electron transport chains that nature offers for organisms such as metal respiring bacteria and acetogens, but also standard biotechnological organisms currently used in bioproduction.Special focus lies on the essential connection of redox and energy metabolism, which is often ignored when studying bioelectrochemical systems. The possibility of extracellular electron exchange at different points in each organism is discussed regarding required redox potentials and effect on cellular redox and energy levels. Key compounds such as electron carriers (e.g. cytochromes, ferredoxins, quinones, flavins) are identified and analysed regarding their possible role in electrode-microbe-interactions.Based on these findings a stoichiometric network analysis is performed analysing the effect of electrical stimulation on the microbial metabolism theoretically. Escherichia coli is used as model organism for production with the aim to identify target processes for MES.For the first time, 20 different valuable products were screened for their potential to show increased yields during anaerobic electrically enhanced fermentation. Surprisingly it was found that an increase in product formation by electrical enhancement is not necessarily dependent on the degree of reduction of the product but rather the metabolic pathway it is derived from. Contrary to the usual assumption a reduced product would always require electron supply by a cathode this study shows that a complex metabolic analysis is needed to identify the overall redox state of each process. A variety of beneficial processes is presented with product yield increases of maximal +36% in reductive and +84% in oxidative fermentations and final theoretical product yields up to 100%. This includes compounds that are already produced at industrial scale such as succinic acid, ii lysine and diaminopentane as well as potential novel bio-commodities such as isoprene, para-hydroxybenzoic acid and para-aminobenzoic acid. Furthermore, it is shown that the way of electron transport has major impact on achievable biomass and product yields. The coupling of electron transport to energy conservation could be identified as crucial for most processes.The in vivo approach of this project introduces the development of a standardised reactor platfor...

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Advanced Nanomaterials for the Design and Construction of Anode for Microbial Fuel Cells

Bai

Zhou

Gu³

2016

Advanced Electrode Materials

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Electroanalysis of microbial anodes for bioelectrochemical systems: basics, progress and perspectives

Cited by 82 publications

References 157 publications

Increasing the temperature is a relevant strategy to form microbial anodes intended to work at room temperature

Increasing the temperature is a relevant strategy to form microbial anodes intended to work at room temperature

Understanding extracellular electron transport of industrial microorganisms and optimization for production application

Advanced Nanomaterials for the Design and Construction of Anode for Microbial Fuel Cells

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