Detection of Oxidase Generated Hydrogenperoxide by a Solid State Peroxyoxalate Chemiluminescence Detector

Abstract

The compatability of a solid state peroxyoxalate chemiluminescence detector for hydrogen peroxide with an immobilized oxidase reactor is investigated. As a model system glucose oxidase immobilized by electrostatic forces on an ion-exchanger or chemically bonded to glass beads were chosen. The former support is less suitable for immobilization of oxydases due to strong retention of hydrogenperoxide on the ion exchanger.

The relatively little flow dependence of these systems renders them suitable for low-cost manual sample injection monitors as well as in a flow injection analyses (FIA) mode with low-cost pumping systems. The system was operated with 80% acetonitrile water solutions. A detection limit of 8 × 10^?7M of glucose was achieved in directly injected samples.

Enzymes more sensitive to organic solvents can be operated with pure water and adjustment for optimal chemiluminescence condition is achieved with a make-up flow prior to detection. A detection limit of 5 × 10^?8M glucose is achieved under these conditions. The feasability of this approach to other oxidase based monitors and to detection in liquid chromatography is discussed.     

Enzyme-Induced Chemiluminescence-Determination of Blood Glucose Using Luminol

Abstract

Hydrogen peroxide, produced by the interaction of glucose with immobilized glucose oxidase, reacts with the ferricyanide-luminol system to produce chemiluminescence linearly proportional to glucose concentration. The coupled reaction is used as a sensitive precise micro method for the determination of true blood glucose. The linear range of detection is 10^?7 - 10^?4 M glucose. The method correlates quantitatively with two glucose reference techniques.     

Quantification of Glucose Using Extended Colorimetry

Abstract

The use of extended colorimetry to increase the range over which colorimetric measurments can be made without loss of sensitivity is described. Its potential for use with dehydrogenase and oxidase enzymes is demonstrated. Construction of a device for the quantification of glucose based on this technique is described. The results of assays on undiluted solutions containing glucose in the range 1 - 20mM were assesed using reflectance spectrophotometry.     

Composite poly(dimethylsiloxane)/glass microfluidic system with an immobilized enzymatic particle-bed reactor and sequential sample injection for chemiluminescence determinations

A three-layer poly(dimethylsiloxane) (PDMS)/glass microfluidic system for performing on-chip solid-phase enzymatic reaction and chemiluminescence (CL) reaction was used for the determination of glucose as a model analyte. A novel method for the immobilization of controlled-pore-glass based reactive particles on PDMS microreactor beds was developed, producing an on-chip solid-phase reactor that featured large reactive surface and low flow impedance. Efficient mixing of reagent/sample/carrier streams was achieved by incorporating chaotic mixer structures in the microfluidic channels. A conventional sequential injection (SI) system was adapted for direct coupling with the microfluidic system, and combined with hydrostatic delivery of reagents to achieve efficient and reproducible sample introduction at 10 μl levels. A detection limit of 10 μM glucose (3σ), and a precision of 3.1% RSD (n=7, 0.2 mM glucose) were obtained using the SI-microfluidic-CL system integrated with a glucose oxidase (GOD) reactor. Carryover was <5% at a throughput of 20 samples/h.     

Flow Injection Analysis of Glucose in Human Serum by Chemiluminescence

Abstract

Combining the rigidly controlable conditions of Flow Injection Analysis with detection by chemiluminescence, a method for determination of glucose in serum via enzymatic degradation by glucose in serum via enzymatic degradation by glucose oxidase is described. With a Standard deviation of less than 2% the sampling frequency is 75 samples per hour. Results obtained by the proposed procedure are compared with those acquired by a routine AutoAnalyzer method used at a local hospital. It is shown that any influence on the yield of chemiluminescence due to difference in viscosity of the injected samples effectively can be eliminated.     

Chemiluminescence microfluidic system sensor on a chip for determination of glucose in human serum with immobilized reagents

A chemiluminescence (CL) biosensor on a chip coupled to microfluidic system is described in this paper. The CL biosensor measured 25×45×5 mm in dimension, was readily produced in analytical laboratory. Glucose oxidase (GOD) was immobilized onto controlled-pore glass (CPG) via glutaraldehyde activation and packed into a reservoir. The analytical reagents, including luminol and ferricyanide, were electrostatically co-immobilized on an anion-exchange resin. The most characteristic of the biosensor was to introduce the air as the carrier flow in stead of the common solution carrier for the first. The glucose was sensed by the CL reaction between hydrogen peroxide produced from the enzymatic reaction and CL reagents, which were released from the anion-exchange resin. The proposed method has been successfully applied to the determination of glucose in human serum. The linear range of the glucose concentration was 1.1-110 mM and the detection limit was 0.1 mM (3σ).     

Glutathione-capped CdTe quantum dots for the sensitive detection of glucose

A simple and sensitive assay system for glucose based on the glutathione (GSH)-capped CdTe quantum dots (QDs) was developed. GSH-capped CdTe QDs exhibit higher sensitivity to H₂O₂ produced from the glucose oxidase catalyzed oxidation of glucose, and are also more biocompatible than other thiols-capped QDs. Based on the quenching of H₂O₂ on GSH-capped QDs, glucose can be detected. The detection conditions containing reaction time, the concentration of glucose oxidase and the sizes of QDs were optimized and the detection limits for glucose was determined to be 0.1 μM; two detection ranges of glucose from 1.0 μM to 0.5 mM and from 1.0 mM to 20 mM, respectively were obtained. The detection limit was almost a 1000 times lower than other QDs-based optical glucose sensing systems. The developed glucose detection system was simple and facile with no need of complicated enzyme immobilization and modification of QDs.     

Bienzyne Electrodes for ATP,NAD+, Starch and Disaccharides Based on a Glucose Sensor

Abstract

A glucose measuring device based on the oxidation of glucose by glucose oxidase and an amperometric kinetic detection was developed. The characteristics obtained with this instrument are comparable with the present glucose instruments but the stability of the enzyme membrane is better and the measuring frequency is higher. In order to expand the applicability of this device to other substrates there was developed a family of bioenzyme electrodes. Enzymes producing glucose as enzymes consuming glucose in addition to glucose oxidase were used.

For determination of peroxidase substrates besides a peroxidase-catalase electrode a three-enzyme system consisting of glucose oxidase, peroxidase and catalase was used.     

Electrochemical Redundant Microsensor Arrays for Glucose Monitoring with Patterned Polymer Films

Redundant microsensor arrays for glucose sensing were fabricated using photopolymerization of poly(ethylene glycol) diacrylate (PEG‐DA) with 2‐hydroxy‐2‐methyl phenyl‐propanone as photoinitiator to encapsulate the enzyme glucose oxidase. Silicon micro fabrication technologies were used to fabricate microelectrode sensor arrays on flexible polyimide sheets. These microarray sensors were individually addressable as observed using square‐wave voltammetry. Redox polymer, poly[4‐vinylpyridine Os(bipyridine)₂Cl]‐co‐ethylamine, was first immobilized on the electrode surface and then glucose oxidase was entrapped in PEG‐DA hydrogels. The redox polymer was found to exchange electrons with glucose oxidase in biocompatible PEG‐DA hydrogels. The entrapped glucose oxidase was found to respond linearly to glucose in solution (0–20 mM) as determined using square‐wave voltammetry.     

Glucose Oxidase Electrode Based on Graphite and Methylthio Tetrathiafulvalene as Mediator

Abstract

A glucose sensor based on glucose oxidase and a new mediator - 4,5-dimethyl-4′-methylthio-Δ 2,2′-bi-1,3-dithiole (MTTTF) is described. The background for sensor action is the effective MTTTF cation interaction (apparent bimolecular constant (2.0+/-0.5)?10⁶ M^?1 s^?1 at 25°C and pH 7.0) with reduced glucose oxidase and the high electrochemical rate of mediator transformation.

A glucose sensor was prepared by adsorbing mediator (MTTTF) and glucose oxidase on graphite rods. The sensor responds to glucose at electrode potentials higher than 50 mV vs SCE, but the maximal activity is obtained at a potential of 250 mV. In air saturated solution the electrode shows a non-linear calibration curve with a half-saturation concentration 10.4 mM and Hill coefficient 2.08 at 250 mV. Sensor response changes little at pH 6.5–8.0. The energy of activation of the sensor response calculated from the Arrhenius equation was 64.5 kJ/mol, and the temperature coefficient at 25°C was 9.2%.     

Hollow‐fiber liquid‐phase microextraction for the direct determination of flumequine in urban wastewaters by flow‐injection analysis with terbium‐sensitized chemiluminescence

A flow‐injection analysis chemiluminescence method based on the enhancement effect of the flumequine‐Tb(III) complex on the weak native emission of the Ce(IV)‐Na₂SO₃ system has been developed for the determination of flumequine. The method includes a cleanup and preconcentration stage (750‐fold) of the sample by hollow‐fiber liquid‐phase microextraction using an Accurel^® Q 3/2 polypropylene hollow fiber impregnated with 1‐octanol as the supported liquid membrane. The obtained 50 μL acceptor phase was injected in a 1 mM Tb(III) + 4 mM Ce(IV) in 5% v/v H₂SO₄ stream and mixed with a 2 mM Na₂SO₃ stream before its introduction into the flow cell. The chemiluminescence signal was linear in the 0.3–15 ng/mL range, with detection and quantitation limits of 0.1 and 0.3 ng/mL, respectively. The method allows the selective extraction and determination of flumequine in wastewater samples, using simpler and lower‐cost instrumentation and with shorter extraction and analysis times than traditional high‐performance liquid chromatography analysis.     

Amperometric Glucose Biosensing of Gold Nanoparticles and Carbon Nanotube Multilayer Membranes

A novel multilayer gold nanoparticles/multiwalled carbon nanotubes/glucose oxidase membrane was prepared by electrostatic assembly using positively charged poly(dimethyldiallylammonium chloride) to connect them layer by layer. The modification process and membrane structures were characterized by atomic force microscopy, scanning electron microscopy and electrochemical methods. This membrane showed excellent electrocatalytic character for glucose biosensing at a relatively low potential (?0.2 V). The K_m value of the immobilized glucose oxidase was 10.6 mM. This resulting sensor could detect glucose up to 9.0 mM with a detection limit of 128 μM and showed excellent analytical performance.     

Flow-injection determination of sugars with immobilized enzyme reactions and chemiluminescence detection

Glucose is determined by reaction with gluocose oxidase to produce hydrogen peroxide which is quantified via a chemiluminescence reaction with luminol. Sucrose, maltose, lactose and fructose are determined by enzymatic conversion to glucose (using invertase, amyloglucosidase, lactase. and glucose isomerase, respectively) and subsequent determination of the glucose, All enzymes are immobilized on controlled-pore glass and contained in flow-through reactors. For glucose, sucrose, and maltose the linear log-log working range 0.2 μM-1 mM, with a detection limit of 0.1 μM; for lactose and fructose the linear working range is 3 μM-1 mM with a detection limit of 1 μM. Assay time is 2 min.     

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.     

An Enzyme Biosensor for Rapid Assay of Glucosinolates

Abstract

A novel electrochemical method for analysis of glucosinolates is described. Glucose, released by the action of myrosinase on the analyte, is detected amperometrically by a glucose electrode having glucose oxidase immobilised on a platinised carbon base. The dependence of current responses on analyte concentration was linear up to 5mM for sinigrin and progoitrin, and the applicability of the method for determination of total glucosinolate in rape seed was demonstrated. An alternative approach was also examined which employed a bi-enzyme electrode made by co-immobilising the two enzymes on the same electrode.     

Immobilization of Cytochrome P-450 and its Application in Ehzikb Electrodes

Abstract

For application in enzyme electrodes liver microsomal cytochrome P-450 was immobilized in a membraneous form. The immobilization yielded 60% of activity and did not impair the functional stability of the enzyme. By coimmobilization of glucose oxidase with P-450 the cofactor NADPH could be replaced by H₂O₂ formed from the enzymatic glucose oxidation. Fixed to a graphite electrode the obtained preparations were employed for quantitative substrate analysis. The P-450 substrate aniline was measured by anodic oxidation of its hydroqlation product at +250mV. A linear dependence of: the current on aniline concentration up to 0.5mM was obtained.     

An Amperometric Glucose Sensor Based on Isoporous Crystalline Protein Membranes as Immobilization Matrix

Abstract

S-layer ultrafiltration membranes (SUMs) with an active filtration layer composed of coherent two-dimensional, isoporous protein crystals (S-layers) have been used as matrix for immobilizing monolayers of enzymes. Since S-layers are formed by periodic repetition of identical protein subunits, functional groups are present on the crystalline array in an identical position and orientation. As a consequence monolayers of enzymes can bind in a geometrically well defined way. For the covalent immobilization of enzymes carboxyl groups from the S-layer protein were activated with carbodiimide and allowed to react with amino groups of the enzyme. SUMs were employed as a new type of immobilization matrix for the developement of an amperometric glucose sensor using glucose oxidase (GOD) as the biologically active component. Glucose oxidase covalently bound to the surface of the S-layer protein retained approximately 40% of its activity. The enzyme loaded SUMs were covered with a layer of gold or platinum to function as working electrodes. These sensors yielded high signals (150nA/mm²/mmol glucose), fast response times (10–30s) and a linearity range up to 12 mM glucose. The stability under working conditions was more than 48 hours. There was no loss in activity after a storage period of 6 month.     

Glucose nanosensors based on redox polymer/glucose oxidase modified carbon fiber nanoelectrodes

This paper describes glucose nanosensors based on the co-electrodeposition of a poly(vinylimidazole) complex of [Os(bpy)₂Cl]^+/2+ and glucose oxidase (GOD) on a low-noise carbon fiber nanoelectrodes (CFNE). The SEM image shows that the osmium redox polymer/enzyme composite film is uniform. The film modified CFNE exhibits the classical features of a kinetically fast redox couple bound to the electrode surface. A strong and stable electrocatalytic current is observed in the presence of glucose. Under the optimal experimental conditions, the nanosensor offers a highly sensitive and rapid response to glucose at an operating potential of 0.22 V. A wide linear dynamic rang of 0.01-15 mM range was achieved with a detection limit of 0.004 mM. Compared with the conventional gold electrode, the nanosensor possessed higher sensitivity and longer stability. Successful attempts were made in real time monitoring rabbit blood glucose levels.     

Amperometric Glucose Sensor Fabricated by Combining Glucose Oxidase Micelle Membrane and Aminated Glassy Carbon Electrode

Abstract

An amperometric glucose biosensor based on the detection of the reduction of oxygen has been developed by combining an aminated glassy carbon electrode with a polystyrene (PS) membrane containing glucose oxidase (GOD) micelles. The structure of GOD micelles contained in PS membrane was observed by scanning electron microscope. The micelle has a roughly spherical shape, and the enzyme colony is contained inside the micelle. This glucose sensor exhibited good sensitivity with short response time (within 2 min). A good linear relationship was observed in the concentration range of 0.2 mM to 2.6 mM when the applied potential was ? 0.45 V vs. Ag/AgCl.     

Enzymatic immunoassay of α-fetoprotein,insulin and 17-α-hydroxyprogesterone base on chemiluminescence in a flow-injection system

Highly-sensitive enzymatic immunoassay procedures based on a chemiluminescent reaction are described. Glucose oxidase was used as the labelling enzyme conjugated with anti-α-fetoprotein IgG, insulin or 17-α-hydroxyprogesterone. Free and bound fractions present after the immune reaction were separated by an immobilized antibody or a second antibody. The enzyme activity was measured by the chemiluminescence produced by luminol and hydrogen peroxide, catalyzed by potassium hexacyanoferrate(III) after incubation with glucose. The chemiluminescence was measured in a flow-injection system, with a home-made luminescence detector equipped with a spiral flow cell. The detection limits for each substance were 10^?15–10^?17 mol. Recoveries of added α-fetoprotein from diluted serum were quantitative.