Amperometric biosensor for the detection of hydrogen peroxide using catalase modified electrodes in polyacrylamide

A simple biosensor for the detection of hydrogen peroxide in organic solvents has been developed and coupled to a flow injection analysis (FIA) system. Catalase was entrapped in polyacrylamide gel and placed on the surface of platinum (working electrode) fixed in a Teflon holder with Ag-wire (auxiliary electrode), followed by addition of filter paper soaked in KCl. The entrapped catalase gel was held on the electrode using membranes. The effects of cellulose and polytetrafluroethylene (PTFE) membranes on the electrode response towards hydrogen peroxide have been studied. The modified electrode has been used to study the detection of hydrogen peroxide in solvents like water, dimethyl sulfoxide (DMSO), and 1,4-dioxane using amperometric techniques like cyclic voltammetry (CV) and FIA. The CV of modified catalase electrode showed a broad oxidation peak at -150 mV and a clear reduction peak at -212 mV in the presence of hydrogen peroxide. Comparison of CV with hydrogen peroxide in various solvents has been carried out. The electrode showed an irreversible kinetics with DMSO as the solvent. A flow cell has been designed in order to carry on FIA studies to obtain calibration plots for hydrogen peroxide with the modified electrode. The calibration plots in several solvents such as water, dimethyl sulfoxide, 1,4-dioxane have been obtained. The throughput of the enzyme electrode was 10 injections per hour. Due to the presence of membrane the response time of the electrode is concentration dependent.     

The role of polypyrrole as charge transfer mediator and immobilization matrix for d-fructose dehydrogenase in a fructose sensor

A fructose dehydrogenase (FDH) modified electrode is produced by the electroadsorption of a layer of FDH on a platinum electrode followed by the electropolymerization of a polypyrrole (PPy) film around and over the enzyme. This immobilizes and stabilizes the enzyme as well as providing an electron transfer pathway to the electrode. The amperometric response to fructose and the enzymatic activity are measured as a function of PPy film thickness. The electrode is shown to have a maximum response at a PPy thickness of approximately the thickness of the enzyme layer. A measure of the electrode efficiency is also obtained, this is the amperometric response to fructose as a percentage of that expected on the basis of the enzyme activity. The functioning of the electrode is also dependent on the counter-ion used for PPy polymerization. This is shown to be mainly related to the nucleation and growth of the PPy film in the interfacial region.     

Oxygen-stabilized enzyme electrode for d-glucose analysis in fermentation broths

A new principle for the construction of oxygen-dependent enzyme electrodes is presented. The enzyme electrode is based on a galvanic oxygen electrode which is furnished with an electrolysis anode covered by immobilized enzyme and placed close to the oxygen-sensing surface. An ordinary oxygen electrode is used as a reference electrode. The enzymatic consumption of oxygen in the enzyme electrode generates a potential difference between the electrodes which is utilized to control electrolytic generation of oxygen from water in such a way that zero differential potential is maintained. Thus, the enzyme electrode operates under ambient oxygen tension and does not suffer from oxygen limitation. The electrolytic current in this system gives a measure of the concentration of substrate surrounding the enzyme electrode. The electrode has been applied for continuous d-glucose analysis in situ during batch cultures of Candida utilis.     

The development of a catechol enzyme electrode and its possible use for the diagnosis and monitoring of neural crest tumours.

A catechol enzyme electrode is described, in which a Clark-type oxygen electrode is coupled to immobilised polyphenol oxidase in albumin cross linked with glutaraldehyde on a dialysis membrane. Electrode calibration, response time, pH response profile, stability, detection limit and selectivity are evaluated and the feasibility of using the electrode for the measurement of catecholamines in the urine of patients with neural crest tumours is assessed.     

A rapid competitive binding nonseparation electrochemical enzyme immunoassay (NEEIA) test strip for microcystin-LR (MCLR) determination

A competitive binding nonseparation electrochemical enzyme immunoassay (NEEIA) is described for the determination of microcystin-LR (MCLR) using a double-sided microporous gold electrode in cartridge-type cells. A gold film sputtered on one side of porous nylon membrane constitutes a working electrode, while another gold film formed on the opposite side serves as a pseudo reference electrode. After immobilizing MCLR antibody on working electrode by physical adsorption, the double-sided electrode was placed simply in a diffusion U-type or within a dry strip-type cell with a conjugate pad pre-loaded with a glucose oxidase labeled MCLR (GOx-MCLR) on working electrode side. Assays were performed in two steps: an MCLR-containing sample mixed with a known amount of GOx-MCLR conjugate either in buffer solution or in pre-loaded dry pad was incubated for an appropriate period (about 10 min) to induce competitive reaction with an immobilized anti-MCLR antibody on working electrode, and a fixed concentration of glucose solution (substrate) was then added to the backside of the working electrode. Due to the competitive nature of the assay, enzymatically generated product, hydrogen peroxide (H2O2), was detected at the working gold electrode (at +800 mV versus Au) by oxidation, and the magnitude of amperometric current was inversely proportional to the concentration of MCLR in the sample. The response time after substrate addition was about 30s. Mean recovery of MCLR added to tap water was 93.5%, with a coefficient of variation (CV) of 6.6%. The proposed competitive NEEIA system is in general comparable to existing heterogeneous enzyme immunoassays with a similar detection limit (100 pg/mL MCLR), and suitable for developing a disposable type biosensor for on-site monitoring of environment.     

Model-based optimization of a conductive matrix enzyme electrode

A mathematical model has been developed to describe the mechanism for internal mass transfer and enzyme reaction kinetics of an amperometric conductive matrix enzyme electrode. The model is simplified and solved analytically to arrive at a representation for the response slope in the linear range as well as for the response time. This is the first time that the response time of an enzyme electrode is described by a mathematical model. Simulations give information on how the design parameters influence the performance of the electrode for a glucose oxidase catalyzed sensing reaction process. Based on this information, several designs were constructed and tested showing suitable agreement with theoretical predictions. Finally, an optimized electrode was designed and validated.     

A technique for the long-term application of surface electrodes

A technique is reported for the long-term application of surface electrodes for ambulatory electromyographic (EMG) recording. Prior to electrode application the surrounding skin is lightly painted with tincture of benzoin. This treatment improves adherence to the skin of disposable electrodes and electrode attachment collars, reduces skin trauma associated with electrode removal, and minimizes sensitivity to electrode adhesives.     

Carbonate ion-selective electrode with reduced interference from salicylate

A carbonate ion-selective electrode for determination of total carbon dioxide species such as carbon dioxide, bicarbonate and carbonate with reduced interference from salicylate is described. Derivatives of trifluoroacetophenone were used as neutral carriers for carbonate. A polymer-free liquid carbonate-selective membrane with a cellophane outer membrane was found to give a carbonate-selective electrode with a negligible response to salicylate. The electrical contact was obtained by insertion of a silver/silver chloride electrode directly into the liquid membrane. The electrode does not require any aqueous filling solution and is therefore maintenance-free. The response to carbon dioxide species was found to be highly reproducible with a response time of 1-2 min at total carbon dioxide concentrations in the range from 5 to 50 mM. The lifetime of the electrode was at least 3 months. The electrode is regarded as very promising for clinical analysis of carbon dioxide species in body fluids such as plasma and serum.     

A new membrane electrode for the detection of antibody.

A new membrane electrode sensitive to specific antibody is described which incorporates dinitrophenyl antigen in polyvinyl chloride matrix membrane on to the surface of a solid-state graphite-loaded epoxy-resin electrode. The sensitivity of the electrode is based on the ionophoric property of the dinitrophenyl antigen. Response curves for the potassium ion and its specific antibody are reported.     

Urate oxidase electrode based on dissolved oxygen probe for urine uric acid determination

A biosensor for the specific determination of uric acid in urine was developed using urate oxidase (EC 1.7.3.3) in combination with a dissolved oxygen probe. Urate oxidase was immobilized with gelatin by means of glutaraldehyde and fixed on a pretreated teflon membrane to serve as enzyme electrode. The electrode response was maximum when 50 mM glycine buffer was used at pH 9.2 and 35 degrees C. The enzyme electrode response depends linearly on uric acid concentration between 5-40 microM with a response time of 5 min. The enzyme electrode is stable for more than 2 weeks and during this period over 35 assays were performed.     

Chronocoulometric techniques in the study of computerized enzyme electrode systems

The electrochemical transient of a two-substrate enzyme electrode was studied theoretically and experimentally. Operation of such electrodes in the chronocoulometric mode leads to increased electrode sensitivity and makes possible the retrieval of useful information on transport and kinetics parameters. Digital simulation was used to solve the kinetics and transport equations and to produce the theoretical chronocoulometric response. A glucose electrode based on glucose oxidase crosslinked to different matrices was tested with air oxygen and p-benzoquinone as the cosubstrate. A computerized electrochemical system was employed for electrode potential control and data acquistion and analysis.     

A technique for the long-term application of surface electrodes

A technique is reported for the long-term application of surface electrodes for ambulatory electromyographic (EMG) recording. Prior to electrode application the surrounding skin is lightly painted with tincture of benzoin. This treatment improves adherence to the skin of disposable electrodes and electrode attachment collars, reduces skin trauma associated with electrode removal, and minimizes sensitivity to electrode adhesives.This research was supported in part by NIH grant No. NS25114.     

Electrochemical detection of DNA hybridization using a change in flexibility

A novel electrochemical method of detecting DNA hybridization is presented based on the change in flexibility between the single and double stranded DNA. A recognition surface based on gold nanoparticles (GNPs) is firstly modified via mixing self-assembled monolayer of thiolated probe DNA and 1,6-hexanedithiol. The hybridization and electrochemical detection are performed on the surface of probe-modified GNPs and electrode, respectively. Here in our method the charge transfer resistance (R(ct)) signal is enhanced by blocking the surface of electrode with DNA covered GNPs. The GNPs will be able to adsorb on the gold electrode when covered with flexible single stranded DNA (ssDNA). On the contrary, it will be repelled from the electrode, when covered with stiff double stranded DNA (dsDNA). Therefore, different R(ct) signals are observed before and after hybridization. The hybridization events are monitored by electrochemical impedance spectroscopy (EIS) measurement based on the R(ct) signals without any external labels. This method provides an alternative route for expanding the range of detection methods available for DNA hybridization.     

A new assay method for hydrogenase based on an enzymic electrode reaction. The enzymic electric cell method.

A new assay method for hydrogenase [EC 1.12.2.1] based on the enzymic electrode reaction of H2-H+ equilibrium has been established. The method is based on the experimental fact that the short-circuit current of the electric cell composed of an electrode with hydrogenase and methylviologen as the mediator of H2-H+ equilibrium and a saturated calomel electrode as the counter electrode, is practically proportional to the amount of hydrogenase in the cell. The new method is referred to as the "enzymic electric cell method." This technique has applications not only to routine activity assay but also to the direct determination of the time course of enzyme denaturation, which has not previously been possible.     

Study of electric discharges between moving electrodes in air

A barrier electric discharge excited between a fixed electrode and a rotating electrode covered with a dielectric layer in atmospheric-pressure air is studied experimentally. A distinctive feature of this type of discharge is that it operates at a constant voltage between the electrodes. An advantage of the proposed method for plasma generation in the boundary layer of the rotating electrode (e.g., for studying the influence of plasma on air flows) is the variety of forms of the discharge and conditions for its initiation, simplicity of the design of the discharge system, and ease of its practical implementation     

On applicability of laccase as label in the mediated and mediatorless electroimmunoassay: effect of distance on the direct electron transfer between laccase and electrode

Applicability of laccase as enzyme-label has been investigated. It was shown that the property of laccase to catalyze the oxygen electroreduction at an electrode allows to develop a mediatorless and pseudoreagentless electro-enzyme-immunoassay (EEIA). In this case the electrode acts as an electron-donor substrate. When the bioelectrocatalytic reaction takes place, some electric charge is collected on the electrode. A method of determination of the electrode charge as well as the concentration of oxidized form of the mediator at the electrode surface has been elaborated. For this aim a technique of the measurement of current-surge was employed. Human immunoglobulin G and insulin were taken as model in this investigation. A back titration schemes without any mediator and in the presence of o-carboxybenzoylferrocene as a mediator was applied. The antibody carbon-black and the antigen glassy-carbon electrodes were used. The limits of detection were found to be 0.3 and 1.6 nM, respectively. The advantage of the mediatorless assay is that the charge leakage is imperceptible by open circuit for a long time and the accumulation of the charge occurs linearly with time. The charge accumulation for a long time allows to diminish the limit of detection. However, there is a limitation of the method. The direct electron transfer slows down with increasing the distance between the enzyme molecule and the electrode surface. This effect reduces the sensitivity of the method. The decrease of the electron transfer rate with distance has been estimated. Monolayer of hemoglobin dividing the laccase molecule from the electrode surface decreases the rate by four times. The electron transfer rate for the antibody electrode with associated antigen-laccase conjugate is less than that for the analogous electrode, covered with monolayer of covalently attached laccase, by 210 times. The current-surge peak was expected to decrease with distance by an equation of the form I = I0 exp[-r/r0]. The parameter r0 is equal to 2.2 +/- 0.8 nm. The possibility of the sensitivity increase in the mediatorless mode by 'wiring' through the multilayer film of immunoproteins immobilized on the electrode is discussed.     

Reversible capture of genomic DNA by a Nafion-coated electrode

A method in which an electrode itself is used as the sample preparation microchip is described. The gold electrode was coated with an ion-permeable polymer, Nafion, to prevent the permanent adsorption and destruction of DNA. The modified electrode was able to capture as much DNA as the bare gold electrode and to release the captured DNA effectively, whereas the bare gold electrode could not release bound DNA. The elution efficiency was greater than 70% for the Nafion-coated electrode, whereas it was less than 10% for the bare electrode. The DNA obtained was undamaged and could be amplified by polymerase chain reaction.     

Calibration of a Clark-Type oxygen electrode by tyrosinase-catalyzed oxidation of 4-tert-butylcatechol.

A procedure for calibrating a Clark-type oxygen electrode is described. This method is based on the oxidation of 4-tert-butylcatechol (TBC) by O2 catalyzed by tyrosinase, to yield 4-tert-butyl-o-benzoquinone (TBCQ). This reaction consumes known amounts of oxygen in accordance with the stoichiometry: 2TBC + O2----2TBCQ + 2H2O and can be used to determine the relation between the oxygen concentration and the oxygen electrode response. TBCQ is very stable in the reaction medium for more than 30 min and shows no significant breakdown, which makes the calibration possible. A kinetic study of the oxidation of 3,4-dihydroxyphenylalanine by tyrosinase using the oxygen electrode is shown to confirm the validity of the calibration method.     

Mediatorless voltammetric oxidation of NADH and sensing of ethanol

A simple, selective and sensitive method for the detection of NADH and ethanol is presented. Self-assembled monolayers (SAMs) of mercaptopyrimidine (MPM) and their derivatives, thiocytosine (TC) and 4,6-diamino-2-mercaptopyrimidine (DMP) on gold (Au) electrode are used for the voltammetric detection of NADH and ethanol in neutral aqueous solution. A decrease of 200-300 mV in the overpotential associated with an observable increase in the peak current was obtained for the oxidation of NADH on MPM and TC monolayer-modified electrodes without any redox mediator. The facilitated electron transfer for the oxidation of NADH at the TC monolayer is ascribed to the existence of stable cationic p-quinonoid form of TC. The electrode modified with DMP monolayer could not exhibit stable response for NADH owing to the fouling of electrode surface. The MPM and TC monolayer-modified electrodes show high selectivity and excellent sensitivity (MPM: 0.633+/-0.005 microA cm(-2) microM(-1); TC: 0.658+/-0.008 microA cm(-2) microM(-1)) towards NADH with detection limit (3sigma) of 2.5 and 0.5 microM, respectively. Presence of large excess of ascorbate (AA) does not interfere the detection of NADH and the monolayer-modified electrode shows individual voltammetric peaks for AA and NADH. Voltammetric sensing of ethanol using alcohol dehydrogenase on MPM and TC monolayer-modified electrode is successfully demonstrated and these electrode can detect as low as 0.5 mM ethanol in neutral pH. The sensitivity of the MPM and TC monolayer-modified electrodes toward ethanol was found to be 3.24+/-0.03 and 3.435+/-0.04 microA cm(-2) mM(-1), respectively.     

Spectroscopic measurements and numerical simulations of the electrode plasma of an electrode microwave discharge in hydrogen

The structure of an electrode microwave discharge in hydrogen at pressures of 1–8 torr and incident powers of 20–100 W is studied using optical spectroscopy. A two-dimensional computer code is developed for self-consistently simulating a self-sustained steady-sate electrode microwave discharge ignited at the end of the inner conductor of a coaxial line. The model is based on simultaneously solving time-dependent Maxwell’s equations, the balance equations for charged particles, and a homogeneous Boltzmann equation. The numerical results referring to the electrode region of the discharge are in fair agreement with the experimental data. This confirms the early suggestion (inferred from experimental data) of the combined “self-sustained-non-self-sustained” character of the electrode discharge. It is shown that the self-sustained discharge domain is located in the electrode region of the discharge.