An enzyme electrode for the amperometric determination of glucose

An amperometric method utilizing a glucose electrode has been developed for the determination of blood glucose. The time of measurement is less than 12 s if a kinetic method is used and 1 min if a steady-state method is used. The long-term stability of the electrode is ca. 0.1% change from maximum response per day when stored at room temperature for over 10 months. The enzyme electrode determination of blood sugar compares favorably with commonly used methods with respect to accuracy, precision, and stability. The only reagent required for blood sugar determinations is a buffer solution. The electrode consists of a metallic sensing layer covered by a thin film of immobilized glucose oxidase held in place by means of cellophane. When poised at the correct potential, the current produced is proportional to the glucose concentration.     

Pulse Voltammetric Biosensing System for the Rapid Determination of Glucose With Micro-Enzyme Sensor

Abstract

An electrochemically prepared micro-enzyme electrode whose diameter is 50 jim is combined with an Pt auxiliary electrode and a reference electrode to assemble a three electrode device for the rapid determination of glucose. Since the device is very small, glucose sample whose volume is only 2 μ1 can be successfully determined. Pulse voltammetry is shown to be an effective approach for making the sensing device work without any attachments such as magnetic stirrer and pump. The transient sensor output, oxidizing current for the hydrogen peroxide generated by the immobilized glucose oxidase, shows a good linearity in the glucose concentration range from 1 mM to 20 mM.     

A Micro Planar Ampehometric Glucose Sensor Using an Isfet as a Reference Electrode

Abstract

A very small glucose sensor has been realized, which consists of a gold working electrode with a glucose oxidase immobilized membrane on it, and a gold counter electrode, all made on a sapphire substrate. By using the pH sensitive ISFET as a reference electrode, the potential for a solution, whose pH is constant, can be measured and irreversible metal electrodes, such as gold or platinum, can be used as working electrode and counter electrode. The sensor is very suitable for miniaturizing and mass production, because the Integrated Circuit (IC) fabrication process can be applied. The glucose oxidase immobilized membrane was also deposited by a lift off method, one of the IC processes. A glucose concentration, from 1 to 100 mg/dl, was measured with good linear current output.     

Myoglobin immobilized on Fe3O4@SiO2 magnetic nanoparticles: Direct electron transfer,enhanced thermostability and electroactivity

Myoglobin (Mb) has been successfully immobilized in alternation with oppositely charged poly(dimethyldiallylammonium chloride) via the sequential layering approach on the biocompatible Fe₃O₄@SiO₂ nanoparticles. The bound Mb could be easily separated by an external magnetic field and used as less costly, more stable, and reusable alternatives to the soluble ones. Direct electron transfer between the immobilized Mb and the electrode was observed. Moreover, the immobilized Mb provided remarkable thermostability up to 70 °C and high electroactivity with the apparent Michaelis–Menten constant (k_M) of 45 μM.     

Permeability Improvement of Electropolymerized Polypyrrole Films in Water Using Magnetic Hydrophilic Microbeads

The electrochemical polymerization of polypyrrole films onto magnetically immobilized hydrophilic microbeads was carried out. Poly(pyrrole‐pyrene)‐microbeads coatings display thus higher permeability in water towards the diffusion of ferrocyanide than a pure poly(pyrrole‐pyrene) film. In addition, the modulation of this permeability through an applied magnetic field that attracts the microbeads on the electrode surface or pushes back them was shown. Moreover, a glucose biosensor was prepared by adsorbing and electropolymerizing on a platinum electrode, an aqueous mixture containing glucose oxidase, amphiphilic pyrrole monomer and microbeads attracted by a magnet. The presence of microbeads inside the biocoating, markedly increases the biosensor performance.     

Flow injection analysis for glucose and urea with enzyme reactors and on-line dialysis

A flow injection system for glucose and urea determination is described. The glucose determination uses immobilized glucose oxidase in a reactor designed to give 100% substrate conversion. The hydrogen peroxide formed is converted to a coloured complex with 4-aminophenazone and N,N-dimethylaniline. The coupling is catalysed by a reactor containing immobilized peroxidase. The coloured complex is measured in a flow-through spectrophotometric cell. Urea is converted to ammonia in a reactor with immobilized urease and detected with an ammonia gas membrane electrode. Proteins and other interfering species from serum samples are removed in an on-line dialyzer. Calibration curves are linear for glucose in the range 1.6 × 10^-4–1.6 × 10^-2 M and for urea in the range 10^-4–10^-1 M. The samples are 25 μl for glucose determination and 100 μl for urea determination. Linear ranges can be changed by varying the sample sizes. The effects of the dialyser, enzyme reactors and detectors on dispersion are evaluated.     

Voltammetric behaviors of wheat-germ agglutinin on a chitin-modified carbon-paste electrode.

The voltammetric behavior of wheat-germ agglutinin (WGA) on a chitin-modified carbon-paste electrode (CPE) was investigated using glucose labeled with an electroactive compound. WGA usually consists of two subunits, each with two binding sites for sugars. WGA was immobilized on the electrode surface by selective binding to a N-acetylglucosamine residue of chitin. Because glucose also combines with WGA, the glucose was coupled with electroactive daunomycin to evaluate the binding. When a WGA-labeled glucose complex was formed, the electroactive moiety became electroinactive. The binding caused a decrease in the peak current of the labeled glucose. In a measurement of only daunomycin used as a label, the peak current in a solution with WGA was similar to that in a solution without WGA. Therefore, it is clear that the labeled glucose was held in the remaining binding site of WGA on the electrode surface. Thus, a CPE modified with chitin would be powerful as a reaction field between sugar and lectin.     

Application of a magnetic immobilizedβ-glucosidase in the enzymatic saccharification of steam-exploded lignocellulosic residues

Aβ-glucosidase preparation derived fromAspergillus niger was immobilized onto a magnetic support and used in the enzymatic saccharification of a lignocellulosic material. The enzyme was immobilized onto polyethyleneimine-glutaraldehyde activated magnetite (PAM) and also onto titanium (IV) oxide (TiO₂)-coated magnetite (TAM). Although > 80% of the protein applied was immobilized, only 15–27% of the enzyme activity was recovered after immobilization. Theβ-glucosidase immobilized onto TiCO₂-coated magnetite suffered from enzyme being removed from the matrix under hydrolysis-use conditions, whereas the PAM enzyme remained attached to the matrix. The physicochemical properties of the immobilizedβ-glucosidase preparations are described. Both immobilizedβ-glucosidase preparations were capable of completely hydrolyzing cellobiose. Recycling of the immobilized enzymes (IME) resulted in reduced rates of hydrolysis with each recycling of the enzyme, although cellobiose was still capable of being completely hydrolyzed. The reduced hydrolysis performance was attributable to physical losses of IME during recovery and, in the case of TAM, enzyme loss from the matrix. Supplementing cellulase digests of steam-explosion pretreatedEucalyptus regnons pulps with immobilizedβ-glucosidase resulted in enhanced hydrolysis. Cellulose-to-glucose yields of 80% of theoretical predictions resulted within 24 h. The magnetically immobilizedβ-glucosidase could easily be recovered from the lignocellulose solids suspension in a stirred batch reactor by applying a magnetic field. The recycled immobilized enzyme continued to convert cellobiose into glucose in 80% yields over a 24-h period. This is the first report of a magnetically immobilizedβ-glucosidase preparation used in the enzymatic saccharification of a lignocellulosic material.     

Magnetic immobilization and electrochemical detection of leukemia K562 cells

A new protocol was proposed for rapid magnetic isolation, immobilization and electrochemical detection of leukemia K562 cells via their decoration with cationic magnetic nanoparticles (CMNPs). The CMNPs (3-aminopropyltriethoxysilane-treated Fe₃O₄) were synthesized in liquid solution and characterized by transmission electron microscopy. After the incubation of pre-cultured leukemia K562 cells in the coexistence of CMNPs for a period of time, the CMNPs modified living cells could be rapidly isolated from the medium and immobilized firmly on the electrode surface via a magnetic field, as traced by quartz crystal microbalance. The cyclic voltammetric experiments of the cells immobilized at glassy carbon electrode exhibited an irreversible anodic current peak whose height is proportional to cell viability, and the 5-fluorouracil cytotoxicity results obtained from the proposed magnetic-electrochemical method were supported by conventional MTT assays. The proposed method is simple, rapid, inexpensive, and convenient in electrode renewal, which is recommended as a promising experimental platform for wider applications in biosensing and cellular researches.     

Direct electron transfer of glucose oxidase promoted by carbon nanotubes is without value in certain mediator-free applications

We have investigated the direct electron transfer (DET) promoted by carbon nanotubes (CNTs) on an electrode containing immobilized glucose oxidase (GOx) with the aim to develop a third-generation glucose biosensor and a mediator-free glucose biofuel cell anode. GOx was immobilized via chitosan (CS) on a glassy carbon electrode (GCE) modified with multi-walled carbon nanotubes (MWCNTs). Cyclic voltammetric revealed that the GOx on the surface of such an electrode is unable to simultaneously demonstrate DET with the electrode and to retain its catalytic activity towards glucose, although the MWCNTs alone can promote electron transfer between GOx and electrode. This is interpreted in terms of two types of GOx on the surface, the distribution and properties of which are quite different. The first type exhibits DET capability that results from the collaboration of MWCNTs and metal impurities, but is unable to catalyze the oxidation of glucose. The second type maintains its glucose-specific catalytic capability in the presence of a mediator, which can be enhanced by MWCNTs, but cannot undergo DET with the electrode. As a result, the MWCNTs are capable of promoting the electron transfer, but this is without value in some mediator-free applications such as in third-generation glucose biosensors and in mediator-free anodes for glucose biofuel cells.

Simultaneous determination of glucose and sucrose by a glucose-sensing enzyme electrode combined with an invertase-attached cell

Glucose and sucrose are simultaneously determined by using a glucose-sensing enzyme electrode combined with a cell that contains immobilized invertase. The electrode current changes linearly with time for several minutes from ca. 1 min after the addition of a glucose-sucrose mixture. The concentration of sucrose (60 μM-6 mM) is determined from the rate of current change in the linear region, and that of glucose (5 μM-1 mM) is determined by extrapolating the straight current-time line to t=0.45 min and by measuring the intercept on the vertical (current) axis at t=0.45 min. The relative standard deviations are 1.8% for glucose and 3.7% for sucrose (n=10). More than 20 food samples can be analysed in 1 h.     

Preparation of immobilized glucose oxidase membrane by the plasma polymerization technique

Glucose oxidase was immobilized on a Millipore (MP) filter by coating with plasma-polymerized propargyl alcohol. The resulting immobilized enzyme membrane was used as a glucose sensor. The properties as a glucose electrode system were evaluated by amperometric response with either the steady-state method or the reaction rate method. The response was proportional to concentrations of the glucose solution up to 2 mM and the sensitivity was dependent on the amount of GOD impregnated into the MP filter.     

Macroscopically Oriented Magnetic Core-regularized Nanomaterials for Glucose Biosensors Assisted by Self-sacrificial Label

Magnetic core-regular nanostructures composed of magnetite and regular Prussian blue was prepared by self-sacrificial macro-oriented method. Magnetic graphene oxide (MGO) was vertically oriented on the surface of home-made screen-printing electrode with the help of constant magnetic field (CMF).Then regular nanostructured Prussian blue (RPB) was realized by chemical reaction through an aerosol deposition. Finally, glucose oxidase (GOx) was immobilized by glutaraldehyde cross-linking to fabricate glucose biosensors. The linear range of CMF-RPB/MGO sensor towards glucose was 0.03∼1.35 mM, and the detection limit was 13.4 μM. The CMF-RPB/MGO sensor could apply to analyze glucose in human serum samples.     

Development of Lactose Biosensor Based on β‐Galactosidase and Glucose Oxidase Immobilized into Gelatin

In this article, we describe the preparation of a new lactose biosensor based on electrode coating with β‐galactosidase and glucose oxidase immobilized gelatin. For this purpose, β‐galactosidase and glucose oxidase enzymes were immobilized onto gelatin by crosslinking with glutaraldehyde. Properties of the immobilized β‐galactosidase and glucose oxidase enzymes electrode have been studied. The effects of glutaraldehyde concentration, temperature and pH variations and reusability were among the subjects analyzed. Lactose biosensors were subjected to continuous repeated use in order to observe reusability and shelf life; where standard lactose and milk samples were used as substrate solutions. Continuous reuse experiments showed that most of the lactose biosensors activities were retained even after the 10th use in a period of 30 days.     

Effect of enzyme concentration on the dynamic behavior of a membrane-bound enzyme system

The dynamic behavior of the reaction-diffusion system, composed of glucose oxidase (EC 1.1.3.4) immobilized at a uniform concentration in a membrane, used as a glucose electrode is represented by a diffusion equation with a nonlinear reaction-term in one-dimensional space. The mathematical model is analyzed by computer simulation, that is, numerical integration of the equation under various initial and boundary conditions, to examine the effect of enzyme concentration on the response characteristics (responsiveness and linearity in response) of the electrode. The analysis of the responses of the system to stepwise changes in the boundary value (glucose concentration in simple solution) infers that the enzyme concentration governs the patterns of the spatial distributions of the substrates (glucose and dissolved oxygen) in steady states and transient responses. It is also revealed that the response characteristics of the electrode are optimized with concentration of immobilized enzyme and that the system establishes the steady states at the same spatial distributions of the substrates, regardless of the boundary value. The diffusion of the substrates and the oxygen concentration also have significant effects on the response characteristics of the electrode.     

Direct electron transfer with glucose oxidase immobilized in an electropolymerized poly( N-methylpyrrole) film on a gold microelectrode

Direct electron transfer between active glucose oxidase (GOD) and a gold electrode was obtained when GOD was immobilized in poly(N-methylpyrrole) electrochemically prepared on the gold electrode. When electropolymerization was accomplished at 50 °C, after glucose addition, the cyclic voltammograms showed an increased oxidation peak at ca. ?0.45 V vs. Ag/AgCl. This potential corresponds to the oxidation potential for FADH₂. Although the GOD becomes much less selective, a glucose-dependent current response is obtained.     

Direct electrochemical sensing of glucose using glucose oxidase immobilized on functionalized carbon nanotubes via a novel metal chelate-based affinity method

We report on a novel amperometric glassy carbon biosensing electrode for glucose. It is based on the immobilization of a highly sensitive glucose oxidase (GOx) by affinity interaction on carbon nanotubes (CNTs) functionalized with iminodiacetic acid and metal chelates. The new technique for immobilization is exploiting the affinity of Co(II) ions to the histidine and cysteine moieties on the surface of GOx. The direct electrochemistry of immobilized GOx revealed that the functionalized CNTs greatly improve the direct electron transfer between GOx and the surface of the electrode to give a pair of well-defined and almost reversible redox peaks and undergoes fast heterogeneous electron transfer with a rate constant (k _s) of 0.59?s^?1. The GOx immobilized in this way fully retained its activity for the oxidation of glucose. The resulting biosensor is capable of detecting glucose at levels as low as 0.01?mM, and has excellent operational stability (with no decrease in the activity of enzyme over a 10?days period). The method of immobilizing GOx is easy and also provides a model technique for potential use with other redox enzymes and proteins.

Glucose oxidase/colloidal gold nanoparticles immobilized in Nafion film on glassy carbon electrode: Direct electron transfer and electrocatalysis

The direct electron transfer of glucose oxidase (GOD) was achieved based on the immobilization of GOD/colloidal gold nanoparticles on a glassy carbon electrode by a Nafion film. The immobilized GOD displayed a pair of well-defined and nearly reversible redox peaks with a formal potential (Eo ') of -0.434 V in 0.1 M pH 7.0 phosphate buffer solution and the response showed a surface-controlled electrode process. The dependence of Eo ' on solution pH indicated that the direct electron transfer reaction of GOD was a two-electron-transfer coupled with a two-proton-transfer reaction process. The experimental results also demonstrated that the immobilized GOD retained its electrocatalytic activity for the oxidation of glucose. So the resulting modified electrode can be used as a biosensor for detecting glucose.     

Preparation and application of a new glucose sensor based on iodide ion selective electrode

An electrode for glucose has been prepared by using an iodide selective electrode with the glucose oxidase enzyme. The iodide selective electrode used was prepared from 10% TDMAI and PVC according our previous study. The enzyme was immobilized on the iodide electrode by holding it at pH 7 phosphate buffer for 10 min at room temperature. The H₂O₂ formed from the reaction of glucose was determined from the decrease of iodide concentration that was present in the reaction cell. The iodide concentration was followed from the change of potential of iodide selective electrode. The potential change was linear in the 4×10⁻⁴ to 4×10⁻³ M glucose concentration (75-650 mg glucose/100ml blood) range. The slope of the linear portion was about 79 mV per decade change in glucose concentration. Glucose contents of some blood samples were determined with the new electrode and consistency was obtained with a colorimetric method. The effects of pH, iodide concentration, the amount of enzyme immobilized and the operating temperature were studied. No interference of ascorbic acid, uric acid, iron(III) and Cu(II) was observed. Since the iodide electrode used was not an AgI-Ag₂S electrode, there was no interference of common ions such as chloride present in biological fluids. The slope of the electrode did not change for about 65 days when used 3 times a day.     

Magneto-electrical cyclic voltammetry for visualization of current distribution in the electrolyte

Cyclic voltammetry is widely used in electrochemistry. To visualize the current distribution in the electrolyte, we developed a two-dimensional magnetic imaging system, combining the electric measurement component used in conventional cyclic voltammetry with a pair of MR (magnetic resistive) sensors to detect the x- and y-magnetic components. The resulting system allows simultaneous measurement of the electronic current of the working electrode and the magnetic field resulting from the transport of ions by migration in the bulk electrolyte. The current distribution in the electrolyte was reconstructed using the magnetic field strength data obtained at multiple points. Consequently, we could observe the change in current distribution when changing the length of the working electrode immersed in the electrolyte.