Analytical applications of microbial fuel cells. Part II: Toxicity, microbial activity and quantification, single analyte detection and other uses
Microbial fuel cells were rediscovered twenty years ago and now are a very active research area. The reasons behind this new activity are the relatively recent discovery of electrogenic or electroactive bacteria and the vision of two important practical applications, as wastewater treatment coupled...
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2015
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Acceso en línea: | https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_09565663_v63_n_p591_Abrevaya http://hdl.handle.net/20.500.12110/paper_09565663_v63_n_p591_Abrevaya |
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paper:paper_09565663_v63_n_p591_Abrevaya |
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dspace |
institution |
Universidad de Buenos Aires |
institution_str |
I-28 |
repository_str |
R-134 |
collection |
Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA) |
topic |
Life sensor Metabolic sensor MFC Review Single analyte sensor Toxicity Biochemical oxygen demand Electric power systems Fuel cells Metabolism Molecular biology Reviews Space research Toxicity Wastewater treatment Aquatic organisms Biochemical oxygen demand Electric power systems Fuel cells Metabolism Molecular biology Reviews Space research Toxicity Wastewater treatment Analytes Analytical applications Analytical science MFC Microbial activities Microbial metabolism Operating principles Selectivity and sensitivity Space explorations Microbial fuel cells Microbial fuel cells analytic method bioassay biosensor chemical analysis chemical reaction kinetics economic evaluation electric power plant electrochemical detection environmental monitoring environmental protection equipment design microbial activity microbial fuel cell microbial metabolism microbial population dynamics microbiological examination microfluidics microorganism detection microtechnology molecular biology nonhuman review sensitivity and specificity single analyte sensor toxicity microbial biosensor transducer water quality bioenergy device failure analysis devices microbiology toxicity testing aquatic species bioassay biodegradation biosensor cation exchange Clostridium butyricum electrochemically active bacteria environmental factor Escherichia coli Geobacter sulfurreducens glucose sensor Lactobacillus fermentum life detection limit of detection limit of quantitation oxygen electrode Pseudomonas putida public health reproducibility Review Shewanella oneidensis Shewanella putrefaciens transgenic organism waste water water pollution biopolymer 2,6 dichlorophenolindophenol antibiotic agent biocide chloramine B methylene blue paraquat phenazine methosulfate silicon sulfadiazine sulfamethaxozole sulfonamide thionine triphenyltetrazolium unclassified drug Bioelectric Energy Sources Biological Assay Biopolymers Equipment Design Equipment Failure Analysis Toxicity Tests |
spellingShingle |
Life sensor Metabolic sensor MFC Review Single analyte sensor Toxicity Biochemical oxygen demand Electric power systems Fuel cells Metabolism Molecular biology Reviews Space research Toxicity Wastewater treatment Aquatic organisms Biochemical oxygen demand Electric power systems Fuel cells Metabolism Molecular biology Reviews Space research Toxicity Wastewater treatment Analytes Analytical applications Analytical science MFC Microbial activities Microbial metabolism Operating principles Selectivity and sensitivity Space explorations Microbial fuel cells Microbial fuel cells analytic method bioassay biosensor chemical analysis chemical reaction kinetics economic evaluation electric power plant electrochemical detection environmental monitoring environmental protection equipment design microbial activity microbial fuel cell microbial metabolism microbial population dynamics microbiological examination microfluidics microorganism detection microtechnology molecular biology nonhuman review sensitivity and specificity single analyte sensor toxicity microbial biosensor transducer water quality bioenergy device failure analysis devices microbiology toxicity testing aquatic species bioassay biodegradation biosensor cation exchange Clostridium butyricum electrochemically active bacteria environmental factor Escherichia coli Geobacter sulfurreducens glucose sensor Lactobacillus fermentum life detection limit of detection limit of quantitation oxygen electrode Pseudomonas putida public health reproducibility Review Shewanella oneidensis Shewanella putrefaciens transgenic organism waste water water pollution biopolymer 2,6 dichlorophenolindophenol antibiotic agent biocide chloramine B methylene blue paraquat phenazine methosulfate silicon sulfadiazine sulfamethaxozole sulfonamide thionine triphenyltetrazolium unclassified drug Bioelectric Energy Sources Biological Assay Biopolymers Equipment Design Equipment Failure Analysis Toxicity Tests Abrevaya, Ximena Celeste Sacco, Natalia Jimena Bonetto, Marìa Celina Cortón, Eduardo Analytical applications of microbial fuel cells. Part II: Toxicity, microbial activity and quantification, single analyte detection and other uses |
topic_facet |
Life sensor Metabolic sensor MFC Review Single analyte sensor Toxicity Biochemical oxygen demand Electric power systems Fuel cells Metabolism Molecular biology Reviews Space research Toxicity Wastewater treatment Aquatic organisms Biochemical oxygen demand Electric power systems Fuel cells Metabolism Molecular biology Reviews Space research Toxicity Wastewater treatment Analytes Analytical applications Analytical science MFC Microbial activities Microbial metabolism Operating principles Selectivity and sensitivity Space explorations Microbial fuel cells Microbial fuel cells analytic method bioassay biosensor chemical analysis chemical reaction kinetics economic evaluation electric power plant electrochemical detection environmental monitoring environmental protection equipment design microbial activity microbial fuel cell microbial metabolism microbial population dynamics microbiological examination microfluidics microorganism detection microtechnology molecular biology nonhuman review sensitivity and specificity single analyte sensor toxicity microbial biosensor transducer water quality bioenergy device failure analysis devices microbiology toxicity testing aquatic species bioassay biodegradation biosensor cation exchange Clostridium butyricum electrochemically active bacteria environmental factor Escherichia coli Geobacter sulfurreducens glucose sensor Lactobacillus fermentum life detection limit of detection limit of quantitation oxygen electrode Pseudomonas putida public health reproducibility Review Shewanella oneidensis Shewanella putrefaciens transgenic organism waste water water pollution biopolymer 2,6 dichlorophenolindophenol antibiotic agent biocide chloramine B methylene blue paraquat phenazine methosulfate silicon sulfadiazine sulfamethaxozole sulfonamide thionine triphenyltetrazolium unclassified drug Bioelectric Energy Sources Biological Assay Biopolymers Equipment Design Equipment Failure Analysis Toxicity Tests |
description |
Microbial fuel cells were rediscovered twenty years ago and now are a very active research area. The reasons behind this new activity are the relatively recent discovery of electrogenic or electroactive bacteria and the vision of two important practical applications, as wastewater treatment coupled with clean energy production and power supply systems for isolated low-power sensor devices. Although some analytical applications of MFCs were proposed earlier (as biochemical oxygen demand sensing) only lately a myriad of new uses of this technology are being presented by research groups around the world, which combine both biological-microbiological and electroanalytical expertises. This is the second part of a review of MFC applications in the area of analytical sciences. In Part I a general introduction to biological-based analytical methods including bioassays, biosensors, MFCs design, operating principles, as well as, perhaps the main and earlier presented application, the use as a BOD sensor was reviewed. In Part II, other proposed uses are presented and discussed. As other microbially based analytical systems, MFCs are satisfactory systems to measure and integrate complex parameters that are difficult or impossible to measure otherwise, such as water toxicity (where the toxic effect to aquatic organisms needed to be integrated). We explore here the methods proposed to measure toxicity, microbial metabolism, and, being of special interest to space exploration, life sensors. Also, some methods with higher specificity, proposed to detect a single analyte, are presented. Different possibilities to increase selectivity and sensitivity, by using molecular biology or other modern techniques are also discussed here. © 2014 Elsevier B.V. |
author |
Abrevaya, Ximena Celeste Sacco, Natalia Jimena Bonetto, Marìa Celina Cortón, Eduardo |
author_facet |
Abrevaya, Ximena Celeste Sacco, Natalia Jimena Bonetto, Marìa Celina Cortón, Eduardo |
author_sort |
Abrevaya, Ximena Celeste |
title |
Analytical applications of microbial fuel cells. Part II: Toxicity, microbial activity and quantification, single analyte detection and other uses |
title_short |
Analytical applications of microbial fuel cells. Part II: Toxicity, microbial activity and quantification, single analyte detection and other uses |
title_full |
Analytical applications of microbial fuel cells. Part II: Toxicity, microbial activity and quantification, single analyte detection and other uses |
title_fullStr |
Analytical applications of microbial fuel cells. Part II: Toxicity, microbial activity and quantification, single analyte detection and other uses |
title_full_unstemmed |
Analytical applications of microbial fuel cells. Part II: Toxicity, microbial activity and quantification, single analyte detection and other uses |
title_sort |
analytical applications of microbial fuel cells. part ii: toxicity, microbial activity and quantification, single analyte detection and other uses |
publishDate |
2015 |
url |
https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_09565663_v63_n_p591_Abrevaya http://hdl.handle.net/20.500.12110/paper_09565663_v63_n_p591_Abrevaya |
work_keys_str_mv |
AT abrevayaximenaceleste analyticalapplicationsofmicrobialfuelcellspartiitoxicitymicrobialactivityandquantificationsingleanalytedetectionandotheruses AT sacconataliajimena analyticalapplicationsofmicrobialfuelcellspartiitoxicitymicrobialactivityandquantificationsingleanalytedetectionandotheruses AT bonettomariacelina analyticalapplicationsofmicrobialfuelcellspartiitoxicitymicrobialactivityandquantificationsingleanalytedetectionandotheruses AT cortoneduardo analyticalapplicationsofmicrobialfuelcellspartiitoxicitymicrobialactivityandquantificationsingleanalytedetectionandotheruses |
_version_ |
1768545291101798400 |
spelling |
paper:paper_09565663_v63_n_p591_Abrevaya2023-06-08T15:56:15Z Analytical applications of microbial fuel cells. Part II: Toxicity, microbial activity and quantification, single analyte detection and other uses Abrevaya, Ximena Celeste Sacco, Natalia Jimena Bonetto, Marìa Celina Cortón, Eduardo Life sensor Metabolic sensor MFC Review Single analyte sensor Toxicity Biochemical oxygen demand Electric power systems Fuel cells Metabolism Molecular biology Reviews Space research Toxicity Wastewater treatment Aquatic organisms Biochemical oxygen demand Electric power systems Fuel cells Metabolism Molecular biology Reviews Space research Toxicity Wastewater treatment Analytes Analytical applications Analytical science MFC Microbial activities Microbial metabolism Operating principles Selectivity and sensitivity Space explorations Microbial fuel cells Microbial fuel cells analytic method bioassay biosensor chemical analysis chemical reaction kinetics economic evaluation electric power plant electrochemical detection environmental monitoring environmental protection equipment design microbial activity microbial fuel cell microbial metabolism microbial population dynamics microbiological examination microfluidics microorganism detection microtechnology molecular biology nonhuman review sensitivity and specificity single analyte sensor toxicity microbial biosensor transducer water quality bioenergy device failure analysis devices microbiology toxicity testing aquatic species bioassay biodegradation biosensor cation exchange Clostridium butyricum electrochemically active bacteria environmental factor Escherichia coli Geobacter sulfurreducens glucose sensor Lactobacillus fermentum life detection limit of detection limit of quantitation oxygen electrode Pseudomonas putida public health reproducibility Review Shewanella oneidensis Shewanella putrefaciens transgenic organism waste water water pollution biopolymer 2,6 dichlorophenolindophenol antibiotic agent biocide chloramine B methylene blue paraquat phenazine methosulfate silicon sulfadiazine sulfamethaxozole sulfonamide thionine triphenyltetrazolium unclassified drug Bioelectric Energy Sources Biological Assay Biopolymers Equipment Design Equipment Failure Analysis Toxicity Tests Microbial fuel cells were rediscovered twenty years ago and now are a very active research area. The reasons behind this new activity are the relatively recent discovery of electrogenic or electroactive bacteria and the vision of two important practical applications, as wastewater treatment coupled with clean energy production and power supply systems for isolated low-power sensor devices. Although some analytical applications of MFCs were proposed earlier (as biochemical oxygen demand sensing) only lately a myriad of new uses of this technology are being presented by research groups around the world, which combine both biological-microbiological and electroanalytical expertises. This is the second part of a review of MFC applications in the area of analytical sciences. In Part I a general introduction to biological-based analytical methods including bioassays, biosensors, MFCs design, operating principles, as well as, perhaps the main and earlier presented application, the use as a BOD sensor was reviewed. In Part II, other proposed uses are presented and discussed. As other microbially based analytical systems, MFCs are satisfactory systems to measure and integrate complex parameters that are difficult or impossible to measure otherwise, such as water toxicity (where the toxic effect to aquatic organisms needed to be integrated). We explore here the methods proposed to measure toxicity, microbial metabolism, and, being of special interest to space exploration, life sensors. Also, some methods with higher specificity, proposed to detect a single analyte, are presented. Different possibilities to increase selectivity and sensitivity, by using molecular biology or other modern techniques are also discussed here. © 2014 Elsevier B.V. Fil:Abrevaya, X.C. Universidad de Buenos Aires. Facultad de Ciencias Exactas y Naturales; Argentina. Fil:Sacco, N.J. Universidad de Buenos Aires. Facultad de Ciencias Exactas y Naturales; Argentina. Fil:Bonetto, M.C. Universidad de Buenos Aires. Facultad de Ciencias Exactas y Naturales; Argentina. Fil:Cortón, E. Universidad de Buenos Aires. Facultad de Ciencias Exactas y Naturales; Argentina. 2015 https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_09565663_v63_n_p591_Abrevaya http://hdl.handle.net/20.500.12110/paper_09565663_v63_n_p591_Abrevaya |