Grape tissue-based electrochemical sensor for the determination of hydrogen peroxide

The use of grape tissue as a source of catalase for the determination of hydrogen peroxide is reported. A slice of grape tissue attached to the membrane of a Clark-type oxgen sensor was used to monitor the oxidation of hydrogen peroxide by catalase. At the steady state, the sensor responds linearly to hydrogen peroxide in the concentration range 1 × 10^?5–5 × 10^?4 M. The response time (T₉₀) was of the order of 1 min for this sensor. No interference was observed from ethanol, amino acids, glucose and lactic acid. The long-term stability of the grape tissue sensor was much better than previously reported immobilized enzyme and liver tissue-based hydrogen peroxide sensors.     

Determination of glutamate-pyruvate transaminase activity in blood serum with a pyruvate oxidase/poly(vinyl chloride) membrane sensor

Pyruvate oxidase (E.C. 1.2.3.3.) is immobilized by adsorption on a wet PVC membrane. Glutamate-pyruvate transaminase activity (5–1600 IU l^?1) in serum is determined by a pyruvate oxidase sensor consisting of the immobilized pyruvate oxidase coupled to a platinum electrode for measuring hydrogen peroxide, after an l-alanine—α-ketoglutarate reaction. The assay requires ?60 s, and has a precision of 2–3%. Endogenous pyruvate should not interfere if measurements are made > 30 s after starting the reaction.     

An enzyme immunosensor for the electrochemical determination of the tumor antigen α-fetoprotein

A specific sensor for a tumor antigen, α-fetoprotein (AFP) can be prepared from a membrane with immobilized antibody and an oxygen probe with a permeable teflon membrane. Anti-AFP antibody is covalently immobilized on a membrane prepared from cellulose triacetate, 1,8-diamino-4-aminomethyloctane and glutaraldehyde. The sensor is applied to enzyme immunoassay based on competitive antigen-antibody reaction with catalase-labelled antigen. After competitive binding of free and catalase-labelled AFP, the sensor is examined for catalase activity by amperometric measurement after addition of hydrogen peroxide. AFP can be determined in the range 10^-11–10^-8 g ml^-1.     

Amperometric acetylcholine and choline sensors with immobilized enzymes

Acetylcholine and choline sensors are prepared by immbilizing enzymes on nylon net attached to a hydrogen peroxide snsor. Choline oxidase is used for the choline sensor; acetylcholinesterase choline oxidase are used for acetylcholine. The platinum/silver electrode pair is polarized at +0.6 V. The assembly is protected with an acetate cellulose membrane to enhance selectivity. The ranges measured are 1–10 μmol l^?1 in 0.1–1 ml of sample. The response times are 1–2 min.     

Development of microbiosensors

Semiconductor fabrication technology was used for development of ion sensitive field effect transistor (ISFET) and micro-electrodes which have been utilized as transducers of enzyme-based microbiosensors. A urea sensor consisted of two ISFETs; one ISFET is urease-coated ISFET and the other ISFET is reference ISFET. A linear relationship was obtained between the initial rate of voltage change and the logarithm of urea concentration over the range 1.3 to 16.7 mM. ATP and hypoxanthine sensors were also developed utilizing ISFET as a transducer. Furthermore, microelectrodes such as hydrogen peroxide and oxygen sensors were prepared by the silicone fabrication technology. A glucose sensor consisted of a hydrogen peroxide electrode and immobilized glucose oxidase membrane. A linear relationship was observed between the current increase and the concentration of glucose (1–100 mg dl⁻¹). A microoxygen electrode was constructed from Au electrodes, polymer matrix containing alkaline electrolyte and a photocross-linkable polymer membrane. This electrode was used as a transducer in microglucose sensor. A microglutamic acid sensor is also described.     

The application of the ph-stat method to metal ion-catalyzed reactions

The pH-stat method, which is well known in organic chemistry and biochemistry, is used for the kinetic determination of metal ion catalysts. Indicator reactions that involve protons can be followed by controlled addition of standard base or acid. This is illustrated by the following examples: determination of copper(II) (0.03–0.3 μg ml^-1) with the indicator reaction ascorbic acid—peroxydisulphate; determination of molybdenum(VI) (0.2–2.5 μg ml^-1) with the indicator reaction thiosulphate—hydrogen peroxide; determination of zirconium(IV) (0.2–2 μg ml^-1) with the indicator reaction iodide—hydrogen peroxide; and determination of vanadium(V) (0.2–2 μg ml^-1) with the indicator reaction iodide—bromate. For one example, the copper—ascorbic acid—peroxydisulphate reaction, it is shown that the pH-stat method has distinct advantages over closed systems, giving considerably better sensitivity for the determination of copper (0.5–5 ng ml^-1 ).     

Sensor System for Simultaneous Measurement of Oxygen and Hydrogen Peroxide Concentration During Glucose Oxidase Activity

An amperometric sensor system, based on a repetitive double step potential method at a glassy carbon electrode, has been developed for the simultaneous measurement of hydrogen peroxide and oxygen concentrations. The current measured at a potential of –1 V (vs. Ag/AgCl/saturated Cl^–) corresponds to the sum of the reduction currents of hydrogen peroxide and dissolved oxygen. The current measured at –0.55 V (vs. Ag/AgCl/saturated Cl^–) is due to the reduction of dissolved oxygen to hydrogen peroxide. Alternatively, the concentration of dissolved oxygen can also be determined using a Clark electrode. The concentration of hydrogen peroxide and dissolved oxygen during enzymatic conversion of glucose can be followed on line and be used to control the process.     

Amperometric determination of glucose in undiluted food samples

Glucose oxidase is immobilized onto a cellulose acetate membrane by glutaraldehyde linkage, and the membrane is used to cover the platinum electrode of a hydrogen peroxide sensor. A silanized polycarbonate membrane then covers the enzyme layer, and extends the linear calibration range to higher concentrations. The sensor, when incorporated into a flow-injection system, allows the determination of glucose at levels up to 1 M in soft drinks at a rate of 60 samples h^?1 without sample dilution.     

Amperometric assay of glucose and lactic acid by flow injection analysis

A computer-controlled flow-injection system is described for the assay of D-glucose and L-lactic acid in undiluted plasma. Glucose or lactate is quantified by coupling an immobilized glucose oxidase or lactate oxidase membrane with an amperometric sensor; the hydrogen peroxide generated is directly related to the concentration of glucose or lactate. The linear range is 0–40 mM and 0–10 mM for glucose and lactic acid, respectively. The sample frequency is 60 h^?1 with a standard deviation of less than 1.5%. Correlation with the results for blood plasma obtained by routine clinical analyzers was good for both glucose and lactic acid.     

An Unmediated Hydrogen Peroxide Sensor Based on a Hemoglobin-sds Film Modified Electrode

ABSTRACT

An unmediated hydrogen peroxide sensor is designed in this paper by employing a hemoglobin-SDS film modified electrode. Hemoglobin exhibits direct (unmediated) electrochemistry at the modified electrode. The protein also shows elegant catalytic activity towards the electrochemical reduction of hydrogen peroxide. Consequently, a prototype hydrogen peroxide sensor is prepared. Under optimum conditions, this sensor provides a linear response over the hydrogen peroxide concentrations in the range of 1×10^-5～1×10^-4 mol/L. The detection limit was 2×10^-6 mol/L The relative standard deviation was 4.2% for 6 successive determinations of the hydrogen peroxide at 1×10^-5 mol/L. This configuration is shown to be sensitive, stable and easily fabricated. It might be useful in the biological and industrial fields.     

Enzyme Electrode Sensor for Hydrogen Peroxide

Abstract

An enzymatic sensor was constructed from an oxygen amperometric sensor on whose surface a dialysis membrane containing covalently bonded catalase was set. Immobilization of the enzyme on the dialysis membrane surface was achieved with 2,4-dichloro-6-methoxy-s-triazine, a derivative of cyanuric chloride, which unlike others of its monosubstituted derivatives ensures some advantages. The time of measurement is less than 12 sec, for the kinetic method of the initial slope and one minute for the steady-state method. The sensor responds linearly to hydrogen peroxide in the concentration range 10^?3 - 10^?5 moles/1. The utilization of this sensor in intermittent and continuous operation in a laboratory enzymatic minireactor is discussed.     

Improved determination of hydrogen peroxide by measurement of peroxyoxalate chemiluminescence

Chemiluminescence from the reaction of bis-(2,4,5-trichloro-6-carbopentoxyphenyl) oxalate with hydrogen peroxide in the presence of triethylamine in t-butanol—water has been investigated as a means of determining hydrogen peroxide. Increasing the percentage of t-butanol increases the signal-to-background ratio but reduces the absolute magnitude of the emission signal. The sensitivity is greatest in aqueous solutions at pH 8; the response is linear from the detection limit (2 × 10^-8 M) to 10^-3 M. The system is also shown to respond linearly to uric acid concentrations in the range 1–4 × 10^-6 M, when uricase is used to catalyze uric acid oxidation to yield hydrogen peroxide.     

A Novel Fluorescent Reagent for Analysis of Hydrogen Peroxide

IntroductionTheoxidationofmanyclinicalsubstancesinbodyfluidsproducesaquantityofhydrogenperoxide ,sothedetermina tionoftracehydrogenperoxideisofconsiderableimportanceinclinicalchemistry .1Further,themonitoringofhydrogenperoxideisalsonecessarytoenvironmentalsciencesinceitisakeyspeciesinthereactionsofthetroposphere,beingin volvedinimportantreactionssuchasthecatalyzedoruncat alyzedaqueousphaseoxidationofSO2 andtheultraviolet en hancedaqueousphaseoxidationoforganicspecies.2 Uptonow ,variousmethods…     

Determination of selenium and tellurium in electrolytic copper by anodic stripping voltammetry at a gold film electrode

A simple procedure for the determination of selenium and tellurium in electrolytic copper is described. These two elements are first separated from copper by passing an ammoniacal solution of the sample through Chelex-100 resin. Voltammetric interferences from nitrite liberated during the dissolution of the metal sample in nitric acid and from arsenic and antimony present in the metal are eliminated by addition of hydrogen peroxide. Excess of peroxide is quickly decomposed by the copper(II) ions present. As little as 0.01 μg Se g^-1 and 0.02 μg Te g^-1 can be determined; relative standard deviations (n = 5) are in the ranges 1.4–3.7% for selenium concentrations of 7.3–0.6 ppm in copper and 1.6—3.1% for tellurium concentrations of 4.6—0.5 ppm.     

Trace Level Determination of Hydrogen Peroxide at a Carbon Ceramic Electrode Modified with Copper Oxide Nanostructures

An electrochemical sensor was developed for determination of hydrogen peroxide based on nanocopper oxides modified carbon sol‐gel or carbon ceramic electrode (CCE). The modified electrode was prepared by electrodeposition of metallic copper on the CCE surface and derivatized in situ to copper oxides nanostructures and characterized by scanning electron microscopy (SEM) and X‐ray diffraction (XRD) techniques. The modified electrode responded linearly to the hydrogen peroxide (H₂O₂) concentration over the range 0.78–193.98 µmol L^?1 with a detection limit of 71 nmol L^?1 (S/N=3) and the sensitivity of 0.697 A mol^?1 L cm^?2. This electrode was used as selective amperometric sensor for determination of H₂O₂ contents in hair coloring creams.     

Determination of glutamate pyruvate transaminase and pyruvate with an amperometric pyruvate oxidase sensor

Pyruvate oxidase (E.C. 1.2.3.3.) is immobilized by adsorption on a porous acetylcellulose membrane, and combined with an oxygen electrode to provide a sensor for pyruvate (0.1–0.8 mM). The response time is 2 min. Glutamate pyruvate transaminase (0.5–180 × 10^-3 I.U. ml^-1) is determined by its effect on pyruvate production by the alanine—α-ketoglutarate reaction. The sensor is stable for more than 10 days and 100 assays.     

Localized surface plasmon resonance sensor for simultaneous kinetic determination of peroxyacetic acid and hydrogen peroxide

A new sensor for simultaneous determination of peroxyacetic acid and hydrogen peroxide using silver nanoparticles (Ag-NPs) as a chromogenic reagent is introduced. The silver nanoparticles have the catalytic ability for the decomposition of peroxyacetic acid and hydrogen peroxide; then the decomposition of them induces the degradation of silver nanoparticles. Hence, a remarkable change in the localized surface plasmon resonance absorbance strength could be observed. Spectra-kinetic approach and artificial neural network was applied for the simultaneous determination of peroxyacetic acid and hydrogen peroxide. Linear calibration graphs were obtained in the concentration range of (8.20 × 10⁻⁵ to 2.00 × 10⁻³ mol L⁻¹) for peroxyacetic acid and (2.00 × 10⁻⁵ to 4.80 × 10⁻³ mol L⁻¹) for hydrogen peroxide. The analytical performance of this sensor has been evaluated for the detection of simultaneous determination of peroxyacetic acid and hydrogen peroxide in real samples.     

Evaluation of a Multi-Walled Carbon Nanotube-Hemin Composite for the Voltammetric Determination of Hydrogen Peroxide in Dental Products

A simple, low cost sensor was developed for the voltammetric determination of hydrogen peroxide in mouthwash and dental whitening gel based on multi-walled carbon nanotubes incorporated with hemin. The sensor showed electrocatalytic activity toward the reduction of hydrogen peroxide in 0.05 mol L^?1 Tris-HCl buffer solution (pH 7.0) using cyclic voltammetry. The optimum composition of paste was 20:10:70% (m/m/m) (multi-walled carbon nanotubes:hemin:mineral oil). A linear plot of the square root of scan rate vs. cathodic peak current showed that reduction of hydrogen peroxide is diffusion controlled. Using linear sweep voltammetry, the analytical curve ranged from 0.2 up to 1.4 mmol L^?1 (r = 0.9996) with a sensitivity of 3.62 × 10^?2 mA mol^?1 L. The limits of detection and quantification were found to be 12.5 µmol L^?1 and 41.7 µmol L^?1, respectively. The developed method was applied for hydrogen peroxide determination in dental formulations. The results were compared with a volumetric method as a reference technique. No significant differences at the 95% level (paired student t test) were observed, thus demonstrating the accuracy of the sensor for the analysis of real samples.     

Double indication in catalytic—kinetic analysis; Determination of iron(III), cyanide and molybdenum(VI)

The reactions in catalytic—kinetic methods are followed simultaneously with two independent indication systems. The information delivered by the two indication methods can be used alone or in combination for the determination of the catalyst or the inhibitor. The following examples illustrate the method: the determination of iron(III) by its catalytic action on the decomposition of hydrogen peroxide (thermometric and biamperometric indication)in the range 10–100 ng Fe/6 ml; the determination of cyanide which inhibits the catalytic activity of copper on the decomposition of hydrogen peroxide thermometric and biamperometric indication) in the range 2–60 μg CN^-/7 ml; and the determination of molybdenum based on the Landolt-type system iodide—bromate— ascorbic acid (thermometric and photometric indication) in the range 0.8–40 μg Mo/8 ml.     

Determination of Hydrogen Peroxide Using a Novel Sensor Based on Fe3O4 Magnetic Nanoparticles

Fe₃O₄ magnetic nanoparticles were synthesized by chemical co-precipitation with sodium citrate as a surfactant and were used with chitosan to construct a novel hydrogen peroxide sensor. The electrochemical behavior of hydrogen peroxide at the sensor was investigated by cyclic voltammetry. The composite film electrocatalyzed the reduction of hydrogen peroxide, and the peak current increased linearly with concentration from 1.00 × 10^?5 to 1.00 × 10^?3 mol · L^?1 (R = 0.9974) with a detection limit of 1.53 × 10^?6 mol · L^?1. This novel nonenzyme sensor provided good sensitivity, stability, and precision with potential applications.