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Syntrophy drives the microbial electrochemical oxidation of toluene in a continuous-flow “bioelectric well”

Matteo Tucci, A. Milani, Marco Resitano, Carolina Cruz Viggi, Ottavia Giampaoli, Alfredo Miccheli, Simona Crognale, Bruna Matturro, Simona Rossetti, Falk Harnisch, Federico Aulenta

2022Journal of environmental chemical engineering14 citationsDOIOpen Access PDF

Abstract

Microbial electrochemical technologies (MET) are promising for the remediation of groundwater pollutants such as petroleum hydrocarbons (PH). Indeed, MET can provide virtually inexhaustible electron donors or acceptors directly in the subsurface environment. However, the degradation mechanisms linking contaminants removal to electric current flow are still largely unknown, hindering the development of robust design criteria. Here, we analysed the degradation of toluene, a model PH, in a bioelectrochemical reactor known as “bioelectric well” operated in continuous-flow mode at various influent toluene concentrations. With increasing concentration of toluene, the removal rate increased while the current tended to a plateau, hence the columbic efficiency decreased. Operation at open circuit confirmed that the bioelectrochemical degradation of toluene proceeded via a syntrophic pathway involving cooperation between different microbial populations. First of all, hydrocarbon degraders quickly converted toluene into metabolic intermediates probably by breaking the aromatic ring upon fumarate addition. Subsequently, fermentative bacteria converted these intermediates into volatile fatty acids (VFA) and likely also H2, which were then used as substrates by electroactive microorganisms forming the anodic biofilm. As toluene degradation is faster than subsequent conversion steps, the increase in intermediate concentration could not result in a current increase. This work provides valuable insights on the syntrophic degradation of BTEX, which are essential for the application of microbial electrochemical system to groundwater remediation of petroleum hydrocarbons.

Topics & Concepts

TolueneChemistryDegradation (telecommunications)Environmental chemistryEnvironmental remediationBiodegradationMicrobial biodegradationElectrochemistryPollutantGroundwater remediationBTEXChemical engineeringMicroorganismContaminationEthylbenzeneOrganic chemistryBacteriaElectrodeEcologyTelecommunicationsComputer scienceEngineeringGeneticsPhysical chemistryBiologyMicrobial Fuel Cells and BioremediationMicrobial Community Ecology and PhysiologyWastewater Treatment and Nitrogen Removal
Syntrophy drives the microbial electrochemical oxidation of toluene in a continuous-flow “bioelectric well” | Litcius