Microbial reductive dechlorination of trichloroethene to ethene with electrodes serving as electron donors without the external addition of redox mediators

Aulenta, Federico; Canosa, Andrea; Reale, P.; Rossetti, Simona; Panero, S.; Majone, Mauro

doi:10.1002/bit.22234

Cited by 144 publications

(79 citation statements)

References 36 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…MET are anaerobic systems in which microorganisms catalyse oxidation or reduction reactions using solid‐state electrodes, suitably deployed in the contaminated matrix, as virtually inexhaustible electron acceptors or donors, respectively (Aulenta et al ., 2009; Zhang et al ., 2010, 2013; Lovley et al ., 2011; Rodrigo Quejigo et al ., 2016; Lai et al ., 2017). Laboratory‐scale studies have shown that MET can be employed to stimulate the anaerobic oxidation of a variety of reduced contaminants in soil and groundwater, including lower chlorinated compounds and PHs (Daghio et al ., 2017).…”

Section: Introductionmentioning

confidence: 99%

The bioelectric well: a novel approach for in situ treatment of hydrocarbon‐contaminated groundwater

Palma

Daghio

Franzetti

et al. 2017

Microbial Biotechnology

Self Cite

View full text Add to dashboard Cite

SummaryGroundwater contamination by petroleum hydrocarbons (PHs) is a widespread problem which poses serious environmental and health concerns. Recently, microbial electrochemical technologies (MET) have attracted considerable attention for remediation applications, having the potential to overcome some of the limiting factors of conventional in situ bioremediation systems. So far, field‐scale application of MET has been largely hindered by the limited availability of scalable system configurations. Here, we describe the ‘bioelectric well’ a bioelectrochemical reactor configuration, which can be installed directly within groundwater wells and can be applied for in situ treatment of organic contaminants, such as PHs. A laboratory‐scale prototype of the bioelectric well has been set up and operated in continuous‐flow regime with phenol as the model contaminant. The best performance was obtained when the system was inoculated with refinery sludge and the anode potentiostatically controlled at +0.2 V versus SHE. Under this condition, the influent phenol (25 mg l−1) was nearly completely (99.5 ± 0.4%) removed, with an average degradation rate of 59 ± 3 mg l−1 d and a coulombic efficiency of 104 ± 4%. Microbial community analysis revealed a remarkable enrichment of Geobacter species on the surface of the graphite anode, clearly pointing to a direct involvement of this electro‐active bacterium in the current‐generating and phenol‐oxidizing process.

show abstract

Section: Introductionmentioning

confidence: 99%

The bioelectric well: a novel approach for in situ treatment of hydrocarbon‐contaminated groundwater

Palma

Daghio

Franzetti

et al. 2017

Microbial Biotechnology

Self Cite

View full text Add to dashboard Cite

show abstract

“…Bioelectrochemical systems with microbial biocathodes may offer lower-cost cathode catalysts and get more opportunities for commercial applications [3,4]. Recently, microbial biocathodes have been explored to be used in other fields, including the biological recovery of heavy metal [5,6], reduction of nitrate [7e9] and chlorinated [10,11]. The use of CO 2 by means of fixation and transformation for producing chemicals, which can simultaneously reduce CO 2 emissions and generate added value [12].…”

mentioning

confidence: 99%

Bioelectrochemical systems for simultaneously production of methane and acetate from carbon dioxide at relatively high rate

Jiang

Zhang

et al. 2013

International Journal of Hydrogen Energy

203

105

View full text Add to dashboard Cite

“…Few studies have focused on microbes accepting electrons from electrodes or minerals. Strychaz et al (12) and Aulenta et al (13) revealed that a graphite electrode could be the sole electron donor for Geobacter lovleyi to dechlorinate the tetrachlorethene. However, although a series of papers on microbes utilizing electrons from electrodes have been published, many of them mainly focused on the microbes' dechlorination (14) and carbon dioxide transformation under anaerobic conditions (15,16).…”

mentioning

confidence: 99%

Enhanced Alcaligenes faecalis Denitrification Rate with Electrodes as the Electron Donor

Wang

Zeng

et al. 2015

Appl Environ Microbiol

View full text Add to dashboard Cite

bThe utilization by Alcaligenes faecalis of electrodes as the electron donor for denitrification was investigated in this study. The denitrification rate of A. faecalis with a poised potential was greatly enhanced compared with that of the controls without poised potentials. For nitrate reduction, although A. faecalis could not reduce nitrate, at three poised potentials of ؉0.06, ؊0.06, and ؊0.15 V (versus normal hydrogen electrode [NHE]), the nitrate was partially reduced with ؊0.15-and ؊0.06-V potentials at rates of 17.3 and 28.5 mg/liter/day, respectively. The percentages of reduction for ؊0.15 and ؊0.06 V were 52.4 and 30.4%, respectively. Meanwhile, for nitrite reduction, the poised potentials greatly enhanced the nitrite reduction. The nitrite reduction rates for three poised potentials (؊0.06, ؊0.15, and ؊0.30 V) were 1.98, 4.37, and 3.91 mg/liter/h, respectively. When the potentials were cut off, the nitrite reduction rate was maintained for 1.5 h (from 2.3 to 2.25 mg/liter/h) and then greatly decreased, and the reduction rate (0.38 mg/liter/h) was about 1/6 compared with the rate (2.3 mg/liter/h) when potential was on. Then the potentials resumed, but the reduction rate did not resume and was only 2 times higher than the rate when the potential was off.A lcaligenes faecalis is a Gram-negative heterotrophic bacterium that is common in soil (1). A. faecalis was reported to aerobically produce nitrite (NO 2 Ϫ ), nitrate, nitric oxide (NO), and nitrous oxide in both peptone-meat extract and defined media with ammonium and citrate as the sole nitrogen and carbon sources (2). Nevertheless, A. faecalis also had denitrification ability as the bacterium had a copper-containing nitrite reductase that catalyzes the reduction of nitrite (NO 2 Ϫ ) to nitric oxide (NO) (3). Recent research by Lu et al. revealed that A. faecalis might be able to use extracellular electrons from semiconducting mineral photocatalysis for metabolism (4). In their study, with photoelectrons A. faecalis gradually became the dominant species in the soil microbial community, indicating this bacterium might have a potential to utilize photoelectrons (4).The interaction between microbes and solid minerals is becoming a worldwide hot spot in the field of geomicrobiology, an interdisciplinary field involving geology and microbiology. Especially, the electron flows between microbes and minerals (or electrodes) are a major research interest in this field. Currently, the models of microbes donating electrons to minerals (or electrodes) are categorized into three types: direct contact, electron shuttle, and microbial extracellular appendages (5). Direct contact between cells and the electrode surface will no doubt facilitate the electron exchanges (6). Under some circumstances, the environmental chemicals or microbially secreted chemicals could act as an electron shuttle, transferring electrons via redox reactions (7,8). Besides secreting chemical compounds, some bacteria have evolved extracellular structures, the conductive flagella called "nanowir...

show abstract

Microbial reductive dechlorination of trichloroethene to ethene with electrodes serving as electron donors without the external addition of redox mediators

Cited by 144 publications

References 36 publications

The bioelectric well: a novel approach for in situ treatment of hydrocarbon‐contaminated groundwater

The bioelectric well: a novel approach for in situ treatment of hydrocarbon‐contaminated groundwater

Bioelectrochemical systems for simultaneously production of methane and acetate from carbon dioxide at relatively high rate

Enhanced Alcaligenes faecalis Denitrification Rate with Electrodes as the Electron Donor

Contact Info

Product

Resources

About