Electron transfer mechanisms between microorganisms and electrodes in bioelectrochemical systems

Microbes have been shown to naturally form veritable electric grids in which different species acting as electron donors and others acting as electron acceptors cooperate. The uptake of electrons from cells adjacent to them is a mechanism used by microorganisms to gain energy for cell growth and maintenance. The external discharge of electrons in lieu of a terminal electron acceptor, and the reduction of external substrates to uphold certain metabolic processes, also plays a significant role in a variety of microbial environments. These vital microbial respiration events, viz. extracellular electron transfer to and from microorganisms, have attracted widespread attention in recent decades and have led to the development of fascinating research concerning microbial electrochemical sensors and bioelectrochemical systems for environmental and bioproduction applications involving different fuels and chemicals. In such systems, microorganisms use mainly either (1) indirect routes involving use of small redox-active organic molecules referred to as redox mediators, secreted by cells or added exogenously, (2) primary metabolites or other intermediates, or (3) direct modes involving physical contact in which naturally occurring outer-membrane c-type cytochromes shuttle electrons for the reduction or oxidation of electrodes. Electron transfer mechanisms play a role in maximizing the performance of microbe?Celectrode interaction-based systems and help very much in providing an understanding of how such systems operate. This review summarizes the mechanisms of electron transfer between bacteria and electrodes, at both the anode and the cathode, in bioelectrochemical systems. The use over the years of various electrochemical approaches and techniques, cyclic voltammetry in particular, for obtaining a better understanding of the microbial electrocatalysis and the electron transfer mechanisms involved is also described and exemplified.     

Electrochemically active biofilms: facts and fiction. A review

This review examines the electrochemical techniques used to study extracellular electron transfer in the electrochemically active biofilms that are used in microbial fuel cells and other bioelectrochemical systems. Electrochemically active biofilms are defined as biofilms that exchange electrons with conductive surfaces: electrodes. Following the electrochemical conventions, and recognizing that electrodes can be considered reactants in these bioelectrochemical processes, biofilms that deliver electrons to the biofilm electrode are called anodic, ie electrode-reducing, biofilms, while biofilms that accept electrons from the biofilm electrode are called cathodic, ie electrode-oxidizing, biofilms. How to grow these electrochemically active biofilms in bioelectrochemical systems is discussed and also the critical choices made in the experimental setup that affect the experimental results. The reactor configurations used in bioelectrochemical systems research are also described and the authors demonstrate how to use selected voltammetric techniques to study extracellular electron transfer in bioelectrochemical systems. Finally, some critical concerns with the proposed electron transfer mechanisms in bioelectrochemical systems are addressed together with the prospects of bioelectrochemical systems as energy-converting and energy-harvesting devices.     

Electrochemically active biofilms: facts and fiction. A review

This review examines the electrochemical techniques used to study extracellular electron transfer in the electrochemically active biofilms that are used in microbial fuel cells and other bioelectrochemical systems. Electrochemically active biofilms are defined as biofilms that exchange electrons with conductive surfaces: electrodes. Following the electrochemical conventions, and recognizing that electrodes can be considered reactants in these bioelectrochemical processes, biofilms that deliver electrons to the biofilm electrode are called anodic, ie electrode-reducing, biofilms, while biofilms that accept electrons from the biofilm electrode are called cathodic, ie electrode-oxidizing, biofilms. How to grow these electrochemically active biofilms in bioelectrochemical systems is discussed and also the critical choices made in the experimental setup that affect the experimental results. The reactor configurations used in bioelectrochemical systems research are also described and the authors demonstrate how to use selected voltammetric techniques to study extracellular electron transfer in bioelectrochemical systems. Finally, some critical concerns with the proposed electron transfer mechanisms in bioelectrochemical systems are addressed together with the prospects of bioelectrochemical systems as energy-converting and energy-harvesting devices.     

Ferrocene-avidin conjugates for bioelectrochemical applications.

Coupling of ferrocene moieties to avidin via a flexible spacer molecule yields a conjugate which combines the unique biotin-binding properties of avidin with the reversible redox characteristics of ferrocenes. Synthesis of the conjugate has been optimised and the conjugates were characterised bio- and electrochemically. Covalent immobilisation of the conjugate on gold electrodes in a dense monolayer results in electrodes with a high binding capacity for biotinylated molecules as well as good electron transfer properties. The application potential of such electrodes for bioelectrochemical systems is demonstrated by electrochemical reduction of hydrogen peroxide under mild conditions catalysed by a bound biotin-microperoxidase MP11 conjugate.     

Preliminary investigation of a bioelectrochemical sensor for the detection of phenol vapours

This work investigates the feasibility of constructing a bioelectrochemical sensor that can operate directly in gases. A series of experiments are described, resulting in a sensor that is responsive to phenol vapours. The sensor was based on ionically conducting films that incorporate a biological redox catalyst at the surface of an array of interdigitated microband electrodes. Exposure to phenol vapour drives the bioelectrochemical reaction, providing a basis for a current signal under constant potential conditions. Ionic materials included Nafion and films based on tetrabutylammonium toluene-4-sulphonate (TBATS). The quasi-reversible electrode reaction of potassium hexacyanoferrate (II) within TBATS was investigated as a function of drying time. E^o′ and K⁰ were determined at a TBATS modified microdisc electrode under steady-state conditions. Drying time (water loss) from the TBATS film had the effect of increasing the film ionic strength. It was shown that as the film ionic strength increased, E⁰′ for potassium hexacyanoferrate (II) shifts toward positive potentials (because of ion pairing) and there was a corresponding increase in the heterogeneous rate constant K⁰. The latter effect was attributed to increasing ion-ion (cation-ferrocyanide ion) interactions as the film dried and the enhancing effect this had on the prevention of surface poisoning reactions at the electrode. These factors are discussed in relation to sensor design.     

Simultaneous topographic and amperometric membrane mapping using an AFM probe integrated biosensor

The investigation of the plasma membrane with intercorrelated multiparameter techniques is a prerequisite for understanding its function. Presented here, is a simultaneous electrochemical and topographic study of the cell membrane using a miniaturized amperometric enzymatic biosensor. The fabrication of this biosensor is also reported. The biosensor combines a scanning force microscopy (AFM) gold-coated cantilever and an enzymatic transducer layer of peroxidases (PODs). When these enzymes are brought in contact with the substrate, the specific redox reaction produces an electric current. The intensity of this current is detected simultaneously with the surface imaging. For sensor characterization, hydroquinone-2-carboxylic acid (HQ) is selected as an intrinsic source of H(2)O(2). HQ has been electrochemically regenerated by the reduction of antraquinone-2-carboxylic acid (AQ). The biosensor reaches the steady state value of the current intensity in 1 ± 0.2s.     

Electrochemical reduction of cytochromes P450 using electrodes containing immobilized substrates

A new approach for the electrochemical reduction of cytochromes P450 (P450, CYPs) with electrodes chemically modified with CYP appropriate substrates (“reverse” electrodes) has been proposed. The method is based on the analysis of cyclic voltammograms, square wave voltammograms, amperograms and determination of such electrochemical characteristics as catalytic current and redox potential. The differences of maximal current and potentials in square wave voltammograms and catalytic current in amperometric measurements are more sensitive and reliable. The planar mode of screen-printed electrodes permits to use 20–60 μl of electrolyte volume. We have investigated P450 2B4-benzphetamine or P450scc-cholesterol enzyme-substrate pairs. Electrochemical parameters of electrodes with nonspecific P450 substrate were differed from the electrodes with appropriate substrates.     

A new format of electrodes for the electrochemical reduction of cytochromes P450

New approach to the electrochemical reduction of cytochromes P450 (P450s, CYPs) at electrodes chemically modified with appropriate substrates for P450s ("reverse" electrodes) was proposed. The method is based on the analysis of cyclic voltammograms, square-wave voltammograms and amperograms with subsequent determination of electrochemical characteristics such as catalytic current and redox potential. The sensitivity of proposed method is 0.2-1 nmol P450/electrode. The changes of maximal current and of redox potentials in square-wave voltammograms as well as the changes of catalytic current in amperometric experiments proved to be informative and reliable. Planar regime of screen-printed electrodes (strip-type sensors) enabled to utilise 20-60 microl of electrolyte volume. The enzyme-substrate pairs P450 2B4/benzphetamine and P450scc/cholesterol were investigated. Electrochemical parameters of electrodes with unspecific P450 substrates differed considerably from electrodes with appropriate substrates.     

Electrochemical measuring system for the registration of transmucosal gastrointestinal potential differences

An electrochemical measuring system for the recording of transmucosal gastrointestinal potential differences based on silver electrodes with double-junctions and continuous-flow saline bridges is described. Under bioelectrochemical control, a probe can passed from the esophagus via the stomach into the duodenum can be accurately assigned to each of these three segments of the intestine. Measurements are demonstrated and applications discussed.     

2'-anthraquinone-conjugated oligonucleotide as an electrochemical probe for DNA mismatch

We previously prepared the oligonucleotides (ODNs) conjugated to an anthraquinone (AQ) group via one carbon linker at the 2'-sugar position. When these modified ODNs bind to cDNA sequences, the AQ moiety can be intercalated into the predetermined base-pair pocket of a duplex DNA. In this paper, 2'-AQ-modified ODNs are shown to be an excellent electrochemical probe to clarify the effect of a mismatch base on the charge transfer (CT) though DNA. Two types of DNA-modified electrodes were constructed by assembly of disulfide-terminated 2'-AQ-ODN duplexes onto gold electrodes. One type of electrodes (system I) contains fully matched base pairs or a single-base mismatch in duplex DNA between the redox center and the electrode. The other (system II) consists of the mismatch but at the outside of the redox center. The modified electrodes were analyzed by cyclic voltammetry to estimate the CT rate through duplex DNA. In system I, the CT rate was found to be approximately 50 s (-1) for the fully matched AQ-ODN duplexes, while the CT rates of the mismatched DNA were considerably slower than that of the fully matched DNA. In system II, the AQ-ODN duplexes showed almost similar CT rates ( approximately 50 s (-1)) for the fully matched DNA and for the mismatched DNAs. The detection of a single-base mismatch was then performed by chronocoulometry (CC). All the DNA duplexes containing a mismatch base in system I gave the reduced electrochemical responses when compared to the fully matched DNA. In particular, the mismatched DNAs including G--A mismatch can be differentiated from fully matched DNA without using any electrochemical catalyst. We further tested the usefulness of single-stranded (ss) AQ-ODN immobilized on a gold electrode in the electrochemical detection of a single-base mismatch through hybridization assay. The ss-AQ-ODN electrodes were immersed in target-containing buffer at room temperature, and the CC measurements were carried out to see the changes in the integrated charge. Within 60 min, the mismatched DNA was clearly distinguishable by the CC differences from the fully matched target. Thus, the electrochemical hybridization assay provides an easy and convenient detection for DNA mutation that does not require any extra reagents, catalyst, target labeling, and washing steps.     

A novel minimally invasive method for monitoring oxygen in microbial fuel cells

Oxygen availability is a potential rate-limiting step in the bioelectrochemical process catalyzed by microbes in microbial fuel cells (MFC). Determination of oxygen availability using a minimally invasive oxygen sensor is advantageous in terms of ease of usage, maintenance and cost-effectiveness as compared to using conventional probe-type oxygen sensors. The utility of this method is substantiated by using this sensor to demonstrate the relationship between oxygen availability and current density. 10 % drop in oxygen concentration resulted in a concomitant drop in current density by about 36 %, further establishing the criticality of monitoring oxygen levels in the MFC. The detachable sensor membrane of the minimally invasive sensor confers multiple advantages. The novel method would enable real-time monitoring of oxygen in MFCs, simplify process optimization and validation and more importantly, provide an impetus for development of more efficient MFC designs.     

Bioelectrochemical fuel cells

In the past 20 years, inorganic fuel cells have been transformed from novelty devices to practical energy transfer-energy storage units. However, the advantage of the high operating efficiency afforded by these fuel cells is partially offset by (a) the limited viability and high cost of the catalysts, (b) the highly corrosive electrolytes, and (c) the elevated operating temperatures. The possibility exists to reduce some of these problems through the development of bioelectrochemical fuel cells. Such biological/electrochemical systems incorporate either microorganisms or enzymes as an active component within the specified electrode compartments. Recent studies with microorganisms as part of the anode compartment have been aimed at defining the mechanism of the observed electrochemical reactions. Recent investigations on the use of cell-free enzyme preparations in the electrode compartments have dealt primarily with developing methodology and defining mechanisms for enhancing the rate of electron transfer from the enzyme-cofactor active site to the solid electrode surface. Applications of this developing technology have been envisioned for analytical chemistry, medical devices, energy transfer, electrochemical synthesis, and detoxification. In this review, the theory and problems of bioelectrochemical fuel cells are described and related to research, both recent and proposed, for the practical development of this area.     

Immobilization of glucose oxidase on thin-film gold electrodes produced by magnetron sputtering and their application in an electrochemical biosensor

An electrochemical biosensor is described consisting of a thin-layer gold film electrode prepared by cathodic sputtering using a poly(vinyl chloride) sheet as substrate, with voltammetric behaviour comparable to that of conventional polycrystalline gold electrodes, coated with the hydrolysed copolymer hydroxyethyl methacrylate-co-methyl methacrylate onto which glucose oxidase was immobilized. The mechanical properties of the plastic foil substrate permit easy construction of circular-shaped electrodes which were employed as working electrodes for batch injection analysis. The electrochemical biosensor fabrication is inexpensive and can be used as disposable enzyme sensor for the detection of hydrogen peroxide. The biosensor was tested for the determination of glucose in serum and a good correlation was obtained with the measurement using the electrochemical and the spectrophotometric methods.     

Glucose enzyme electrode using cytochrome b(562) as an electron mediator

We demonstrate the construction of glucose sensors employing pyrroloquinoline quinone (PQQ) glucose dehydrogenase (PQQGDH) from Acinetobacter calcoaceticus and glucose oxidase (GOD) from Aspergillus nigar coupled with Escherichia coli soluble cytochrome b(562) (cyt b(562)) as electron acceptor. PQQGDH and GOD do not show direct electrochemical recycling of the prosthetic group at the electrode surface leading to a corresponding current signal. We constructed PQQGDH and GOD electrodes co-immobilized with 100-fold molar excess of cyt b(562) and investigated the electrochemical properties without synthetic electron mediators. PQQGDH/cyt b(562) and GOD/cyt b(562) electrodes both responded well to glucose whereas no current increase was observed from the electrode immobilizing enzyme alone. The detection limits for the PQQGDH/cyt b(562) and GOD/cyt b(562) electrodes were 0.1 and 0.8 mM, respectively, and their linearity extended to over 2 and 9 mM, respectively. These results demonstrate that a sensor system can be constructed without a synthetic electron mediator by using a natural electron acceptor. Furthermore, we have demonstrated the potential application of cyt b(562) in direct electron transfer type sensor systems with oxidoreductases whose quaternary structure do not contain any electron transfer subunit.     

Electrochemical evaluation of glucose oxidase immobilized by different methods

Glucose oxidase electrodes were constructed on a platinum screen using polyacrylamide gel, glutaraldehyde crosslinking, and glutaraldehyde crosslinking with +0.04 volts dc on the platinum screen as the methods of enzyme immobilization. The electrodes were evaluated in an electrochemical cell for the oxidation of glucose at the enzyme electrode and the reduction of oxygen at a platinum auxiliary electrode, using constant current voltametry or under external load operation. The method of immobilization affected the extrapolated opencircuit potential as well as the half-cell potential and the steady current under external load operation. The charged glutaraldehyde electrode gave the best current performance; however, the small output (microamps) indicated that major problems in electron transfer from an enzyme catalyst to an external circuit must be resolved before such electrodes can be used in practical application.     

A biocompatible titanium nitride nanorods derived nanostructured electrode for biosensing and bioelectrochemical energy conversion

In this study, a facile method is proposed to fabricate biocompatible TiN nanorod arrays through solvent-thermal synthesis and subsequent nitridation in ammonia atmosphere. The TiN nanorod arrays are potential excellent nanostructured electrodes owing to their good electronic conductivity and large surface area. These nanostructured electrodes not only deliver superior electrocatalytic activity (the limit of detection, LOD is 0.5 μM) and highly selective sensing towards H(2)O(2), but also exhibit excellent biocompatibility with horseradish peroxidase (HRP) in a highly sensitive enzymatic biosensor for H(2)O(2) (the LOD can reach to 0.05 μM). Furthermore, a novel biocatalytic cathode based Li air fuel cell (bio-Li-air fuel cell) is explored based on the combination of TiN nanorod arrays and laccase (LAC) for electrochemical energy conversion. These results demonstrate that TiN nanorod arrays can be served as excellent nanostructured electrodes for multifunctional bioelectrochemical applications.     

Rapid diagnosis of multidrug resistance in cancer by electrochemical sensor based on carbon nanotubes-drug supramolecular nanocomposites

The multidrug resistance (MDR) in cancer is a major chemotherapy obstacle, rendering many currently available chemotherapeutic drugs ineffective. The aim of this study was to explore the new strategy to early diagnose the MDR by electrochemical sensor based on carbon nanotubes-drug supramolecular interaction. The carbon nanotubes modified glassy carbon electrodes (CNTs/GCE) were directly immersed into the cells suspension of the sensitive leukemia cells K562 and/or its MDR cells K562/A02 to detect the response of the electrochemical probe of daunorubicin (DNR) residues after incubated with cells for 1h. The fresh evidence from the electrochemical studies based on CNTs/GCE demonstrated that the homogeneous, label-free strategy could directly measure the function of cell membrane transporters in MDR cancer cells, identify the cell phenotype (sensitive or MDR). When the different ratios of the sensitive leukemia cells K562 and its MDR ones K562/A02 were applied as a model of MDR levels to simulate the MDR occurrence in cancer, the cathodic peak current showed good linear response to the fraction of MDR with a correlation coefficient of 0.995. Therefore, the MDR fraction can be easily predicted based on the calibration curve of the cathodic peak current versus the fraction of MDR. These results indicated that the sensing strategy could provide a powerful tool for assessment of MDR in cancer. The new electrochemical sensor based on carbon nanotubes-drug supramolecular nanocomposites could represent promising approach in the rapid diagnosis of MDR in cancer.     

Disposable electrodes modified with multi-wall carbon nanotubes for biosensor applications

This paper deals with the development of a disposable electrochemical sensor for the detection of hydrogen peroxide, using screen-printed carbon-based electrodes (SPCEs) modified with multi-wall carbon nanotubes (MWCNs) dispersed in a polyethylenimine (PEI) mixture. The modified sensors showed an excellent electrocatalytic activity towards the analyte, respect to the high overvoltage characterising unmodified screen-printed sensors. The composition of the PEI/MWCNT dispersion was optimised in order to improve the sensitivity and reproducibility. The optimised sensor showed good reproducibility (10% RSD calculated on three experiments repeated on the same electrode), whereas a reproducibility of 15% as RSD was calculated on electrodes from different preparations. Preliminary experiments carried out using glucose oxidase (GOD) as biorecognition element gave rise to promising results indicating that these new devices may represent interesting components for biosensor construction.     

Microelectrode arrays and application to biosensing devices

An electrochemical microanalytical system consisting of a microelectrode array, a micromachined flow-through assembly, and a multichannel potentiostat were constructed for highly sensitive biosensing. Thin-film platinum microelectrode arrays consisting of four interdigitated microelectrodes (IDAs), which are spaced in the sub-micrometer range, were fabricated using silicon technology. On top of this chip, a micromachined flow-through cell was mounted. Using a home made miniaturized multipotentiostat, amperometric measurements of the individual electrodes at different and changing potentials, respective to a single reference electrode, were performed simultaneously. The signal generation, signal processing and the analytical system were controlled by a computer (PC type) and special software. An improved sensor sensitivity was achieved by multielectrode detection and averaging of the IDA responses.

By applying both the oxidation and reduction potentials of reversible redox molecules to pairs of the interdigitated electrodes, an increased current generation can be observed. Thus the steady state current of mediators such as benzoquinone can be amplified by a factor of 30 compared with conventional electrodes. This measuring principle was applied to determine of the activity of hydrolases by detecting the enzyme generated p-aminophenol in the nanomolar range. By combining both, the averaging and the recycling procedures, the detection limit of amperometric biosensing devices may be lowered by about one and a half orders of magnitude.