A chemiluminometric method for NADPH and NADH using a two-enzyme bioreactor and its application to the determination of magnesium in serum

Chemiluminometric methods are described for the automated flow injection analysis of NADPH and NADH using an immobilized enzyme column reactor and serum magnesium. This application is for the clinical analysis of NADPH and NADH. The reactor for NADPH and NADH contains immobilized L-glutamate dehydrogenase and L-glutamate oxidase, and that for serum magnesium immobilized hexokinase, glucose-6-phosphate dehydrogenase, L-glutamate dehydrogenase and L-glutamate oxidase. When the sample is introduced into the four-enzyme bioreactor, hydrogen peroxide is produced in proportion to the concentration of serum magnesium by the successive reactions. A co-immobilized hexokinase/glucose-6-phosphate dehydrogenase/glutamate dehydrogenase column reactor gave better efficiency compared with an enzyme column which was prepared by packing co-immobilized hexokinase/glucose-6-phosphate dehydrogenase and immobilized glutamate dehydrogenase to make two layers. Magnesium in serum was determined with 1 microL of the sample without carry-over and for an assay time of approximately 15 s. The present method is sensitive (detection limit 0.1 nmol) because Mg2+ is recycled in a column, and gives perfect linearity of the data up to 3.0 mmol/L with satisfactory precision, reproducibility, and accurate reaction recoveries.     

Enzyme electrodes with substrate and co-enzyme amplification

The enzyme couples horseradish peroxidase/glucose dehydrogenase, glucose oxidase/glucose dehydrogenase, and cytochrome b₂/lactate dehydrogenase are applied in enzyme electrodes. Based on amplification by the recyclization reactions catalyzed by these two-enzyme systems, NADH, NAD⁺, glucose, lactate and pyruvate, are determined with 8–40-fold increased sensitivity compared to the unamplified reactions. Detection limits are 1.0 × 10^?6 M NADH, 1.2 × 10^?6 M NAD⁺, 8 × 10^?7 M glucose, and 3 × 10^?7 M lactate or pyruvate.     

Selective enzyme amplification of NAD/NADH using coimmobilized glycerol dehydrogenase and diaphorase with amperometric detection

A flow system for substrate recycling of NAD⁺/NADH was set up with an enzyme reactor containing coimmobilized glycerol dehydrogenase (GDH) and diaphorase. The product from the diaphorase catalysis, hexacyanoferrate(II), aws detected amperometrically at a glassy carbon electrode. The amplification factor was 150 for a reactor volume of 100 μ l at a flow-rate of 0.5 ml/min. With a stopped flow of four minutes, the signal increased another 88 times, resulting in a signal amplification of 13 300 times. Equations are derived for the amplification factor and used for a discussion of the optimization of amplification systems. The K_m for GDH with glycerol as a substrate was found to be 5 × 10⁻³ M at pH 8.0. GDH from Cellulomonas sp. was purified on a gel filtration column and the purified enzyme showed a specificity toward NAD⁺, compared to NADP⁺, that was higher than 99.9%. Due to the NAD⁺ specificity of the purified GDH, the enzyme amplification system reported here could be used in detection systems for enzyme immunoassays when using alkaline phosphatase as a label and NADP⁺ as a substrate. The stability of immobilized GDH and diaphorase is several orders of magnitude better than that of alcohol dehydrogenase, which is the enzyme commonly used for NAD⁺-specific detection in these applications.     

Enzymatic Assay by Flow Injection Analysis with Detection by Chemiluminescence: Determination of Glucose,Creatinine, Free Cholesterol and Lactic Acid Using an Integrated Fia Microconduit

Abstract

A miniaturized flow injection system for the determination of D-glucose, L-lactic acid, creatinine and free cholesterol is described. All substrates are degraded enzymatically by means of oxidases which, along with ancillary coenzymes (creatinine assay), are immobilized on controlled porosity glass and incorporated into small PVC column reactors. The hydrogen peroxide generated by the individual oxidases is determined by chemiluminescence with an alkaline reagent containing luminol and hexacyanofer rate (III). The injection valve, flow channels, enzyme reactor and light detector are integrated into a FIA microconduit. The detection limits were 0.03 mg glucose/dl, 0.03 mg lactate/dl, 0.3 mM creatinine and 0.5 mg cholesterol/dl. The enzyme reactors all showed little change in activity over a 3 months period of operation and were found fully compatible with serum samples.     

Simultaneous microchip enzymatic measurements of blood lactate and glucose

A miniaturized capillary electrophoretic (CE) microchip device for the simultaneous measurements of lactate and glucose is described. The new microchip bioassay protocol integrates an electrophoretic separation of lactate and glucose, post-column enzymatic reactions of these metabolites with their respective oxidase enzymes, and an amperometric (anodic) detection of enzymatically-liberated hydrogen peroxide at a gold-coated thick-film carbon detector. Factors influencing the response have been examined and optimized, and the analytical performance has been characterized. Applicability of the microchip assay to clinical samples, such as serum and blood, is demonstrated. The microchip protocol obviates cross enzymatic reactions and interferences from major oxidizable constituents common to dual glucose-lactate enzyme electrodes. Such ability to rapidly separate and quantitate lactate and glucose on a small microchip platform should find important clinical and biotechnological applications.     

Determination of Urinary Glucose by a Flow Injection Analysis Amperometric Biosensor and Ion-Exchange Chromatography

A practical biosensor system has been developed for the determination of urinary glucose using a flow-injection analysis (FIA) amperometric detector and ion-exchange chromatography. Glucose oxidase was immobilized onto porous aminopropyl glass beads via glutaraldehyde activation to form an immobilized enzyme column. On the basis of its negative charge at pH 5.5, endogenous urate in urine samples was effectively retained by an upstream anion-exchange resin column. The biosensor system possessed a sensitivity of 160 ±2.4 RU μM^-1 (RU or relative unit is defined as 2.86 μV at the detection output) for glucose with a minimum detection level of 10 μM. When applied for the determination of urinary glucose, the result obtained compared very well with that of the widely accepted hexokinase assay. The immobilized glucose oxidase could be reused for more than 1000 repeated analyses without losing its original activity. The reuse of the acetate anion-exchange column before replacement would be about 25–30 analyses. Acetaminophen and ascorbic acid were also effectively adsorbed by the acetate anion exchanger. The introduction of this type of anion exchanger thus greatly improved the selectivity of the FIA biosensor system and fostered its applicability for the determination of glucose in urine samples.     

High performance liquid chromatography of glucose using a post-column reactor of immobilized enzyme followed by electrochemical detection (glucose-LCEC)

A sensitive and selective, reasonably fast method for the determination of glucose content has been developed. A glucose oxidase immobilized column was coupled to a small-size anion exchange column/borate buffer chromatograph. The hydrogen peroxide produced in the enzyme reaction was detected directly by an amperometric detector using a platinum working electrode. The detection limit was 0.03 ppm (1.5 x 10(-7) M, 3 pmol/injection). The linear dynamic range was three orders of magnitude at least. The system was stable and reproducible both in short- and long-term operation. The proposed method is suitable for analysis of complicated matrices of biological samples because of its good selectivity and sensitivity.     

Determination of myo-inositol in a flow-injection system with co-immobilized enzyme reactors and amperometric detection

A selective and sensitive flow-injection system for the determination of myo-inositol (hexahydroxycyclohexane) is described. Inositol dehydrogenase, IDH, lactate dehydrogenase, LDH, and lactate oxidase, LOD, are co-immobilized on porous glass and used in a packed-bed enzyme reactor. myo-Inositol reacts to produce an equivalent amount of hydrogen peroxide, which oxidizes hexacyanoferrate(II) to hexacyanoferrate(III) in a second reactor containing immobilized peroxidase. The hexacyanoferrate(III) is then detected amperometrically at 0 mV vs. SCE in a flow-through detector. The system responds linearly to injected samples of myo-inositol (25 μl) in the concentration range 1–300 μM. The maximum throughput was 90 samples per hour. The IDH/LDH/LOD reactor was stable for at least 5 weeks.     

Novel enzymatic assay for determination of alkyl polyglycosides with short chain fatty alcohols

An enzymatic assay has been developed for the quantitative detection of alkyl polyglycosides after enzymatic hydrolysis with different carbohydrolases. A three-step enzymatic method was used for the quantification of alkyl polyglycosides. In the first step the enzymatic hydrolysis of alkyl polyglycosides was performed with different carbohydrolases, or an acid hydrolysis was used. The second step was quantification of free glucose with an enzyme electrode, which was covered with an immobilized glucose oxidase membrane; glucose was used as standard. The last step was the enzymatic quantification of fatty alcohols, which are the second substrate after enzymatic hydrolysis of alkyl polyglycosides. Surprisingly, the enzyme alcohol dehydrogenase ADH (E.C. 1.1.1.1) from bakers' yeast could efficiently oxidize a wide variety of aliphatic alcohols and had the highest catalytic specificity with short and medium fatty alcohol substrates, including octanol and decanol.     

Strategies for the reversible immobilization of enzymes by use of biotin-bound anti-enzyme antibodies

Glucose oxidase (E.C. 1.1.3.4) is reversibly immobilized in a reactor coupled to a flow-injection analysis system using an immunological reaction. The antibody used is irreversibly immobilized on the reactor support by an avidin-biotin linkage. The bond between avidin and biotin is nearly irreversible under normal elution conditions for antibody-antigen reactions. The reactor is packed with a support on which avidin is covalently attached and a biotin-bound second antibody is passed over the reactor packing, which immobilizes this antibody. An immune complex of the enzyme, or first anti-enzyme antibody followed separately by enzyme, is introduced into the flow system, resulting in enzyme immobilization. The reactor produced can be used in the determination of 1 x 10(-11) -1 x 10(-6) mole of glucose with a sample size of 20 mul and a sample throughput of 20-30/hr. These results are comparable to or better than those obtained with glucose oxidase directly immobilized on the same support. The enzyme can be removed by elution with low-pH buffers, and the reactor regenerated by injection of the anti-enzyme antibody and the enzyme.     

Miniaturized on-line proteolysis-capillary liquid chromatography-mass spectrometry for peptide mapping of lactate dehydrogenase

In this study, methodology was developed for on-line and miniaturized enzymatic digestion with liquid chromatographic (LC) separation and mass spectrometric (MS) detection. A packed capillary LC-MS system was combined with on-line trypsin cleavage of a model protein, lactate dehydrogenase, to provide an efficient system for peptide mapping. The protein was injected onto an enzymatic capillary reactor and the resulting peptides were efficiently trapped on a capillary trapping column. Different trapping columns were evaluated to achieve a high binding capacity for the peptides generated in the enzyme reactor. The peptides were further eluted from the pre-column and separated on an analytical capillary column by a buffer more suitable for the following an electrospray ionisation (ESI) MS process. An important aspect of the on-line approach was the desalting of peptides performed in the trapping column to avoid detrimental signal suppression in the ESI process. The developed on-line system was finally compared to a classical digestion in solution, with reference to peptide sequence coverage and sensitivity. It was shown that the on-line system gave more than 100% higher peptide sequence coverage than traditional digestion methods.     

Quinoprotein glucose dehydrogenase modified thick-film electrodes for the amperometric detection of phenolic compounds in flow injection analysis

The use of thick-film electrodes as basic transducers for highly sensitive amperometric biosensors using PQQ (pyrroloquinoline quinone) dependent glucose dehydrogenase (GDH) with short response times is described. The enzyme is embedded in a polyurethane matrix on top of a platinum based thick film electrode and its ability to reduce oxidized phenolic compounds is exploited. The electrochemical amplification is based on the oxidation of the analyte on the surface of the electrode followed by its enzymatic reduction. Different parameters of the glucose dehydrogenase electrode system using dopamine as a model analyte were optimized, e.g., membrane thickness, pH value, buffer system, flow rate and storage conditions. Using optimized parameters the sensitivity and detection limits for various phenolic compounds were evaluated. The comparison of electrodes from the identical as well as from different batches shows the ability to produce a number of well reproducible sensors showing remarkably small differences with respect to parameters as sensitivity, response times and measuring range.     

Electrochemically-assisted deposition of oxidases on platinum nanoparticle/multi-walled carbon nanotube-modified electrodes

Platinum nanoparticles were electrodeposited by a multi-potential step technique onto a multi-walled carbon nanotube (MWCNT) film pre-casted on a glassy carbon (GC) or boron-doped diamond (BDD) electrode. The MWCNT network consisted of Pt nanoparticles with an average diameter of 120 nm after an optimization of 36 deposition cycles. The resulting electrochemical sensors were capable of detecting hydrogen peroxide as low as 25 nM. Five different enzymes: glucose, lactate, glutamate, amino acid and xanthine oxidases, respectively, were deposited by a constant current technique for 5-10 min to form a stable and active biolayer for the analysis of their corresponding analytes. The glucose oxidase-based biosensor was linear up to 10 mM glucose with a detection limit of 250 nM and a response time of 5 s. Similar response times and detection limits were observed with glutamate, lactate, and amino acid oxidase despite the fact that the linear ranges were noticeably narrower. The mechanism of deposition was attributed to the decrease of local pH, created by oxygen evolution and effected enzyme precipitation.     

Amperometric detection of acetylcholine and choline in a liquid chromatographic system with an immobilized enzyme reactor

Acetylcholinesterase and choline oxidase were co-immobilized by reaction with glutaraldehyde onto alkylamino-bonded silica, which was incorporated as the enzyme reactor in an h.p.l.c. system for the determination of acetylcholine and choline. The hydrogen peroxide produced enzymatically in the enzyme reactor, after the separation of acetylcholine and choline by the reverse-phase column, was monitored amperometrically. The detection limits were 1.2 pmol for choline and 1.8 pmol for acetylcholine.     

Minimally‐invasive Microneedle‐based Biosensor Array for Simultaneous Lactate and Glucose Monitoring in Artificial Interstitial Fluid

Here we report the first mediated pain free microneedle‐based biosensor array for the continuous and simultaneous monitoring of lactate and glucose in artificial interstitial fluid (ISF). The gold surface of the microneedles has been modified by electrodeposition of Au‐multiwalled carbon nanotubes (MWCNTs) and successively by electropolymerization of the redox mediator, methylene blue (MB). Functionalization of the Au‐MWCNTs/polyMB platform with the lactate oxidase (LOX) enzyme (working electrode 1) and with the FAD‐Glucose dehydrogenase (FADGDH) enzyme (working electrode 2) enabled the continuous monitoring of lactate and glucose in the artificial ISF. The lactate biosensor exhibited a high sensitivity (797.4±38.1 μA cm^?2 mM^?1), a good linear range (10–100 μM) with a detection limit of 3 μM. The performance of the glucose biosensor were also good with a sensitivity of 405.2±24.1 μA cm^?2 mM^?1, a linear range between 0.05 and 5 mM and a detection limit of 7 μM. The biosensor array was tested to detect the amount of lactate generated after 100 minutes of cycling exercise (12 mM) and of glucose after a normal meal for a healthy patient (10 mM). The results reveal that the new microneedles‐based biosensor array seems to be a promising tool for the development of real‐time wearable devices with a variety of sport medicine and clinical care applications.     

Highly sensitive detection of l-glutamate by on-line amperometric micro-flow analysis based on enzymatic substrate recycling

A highly selective and sensitive on-line monitoring system is proposed for amperometric assay of trace amounts of l-glutamate. The system includes a microdialysis probe, immobilized enzyme reactor, and poly(1,2-diaminobenzene)-coated platinum electrode. The enzyme reactor prepared by the co-immobilization of l-glutamate oxidase and glutamate dehydrogenase are here employed to enhance the sensitivity of l-glutamate as an on-line amplifier based on the substrate recycling. The l-glutamate in the dialysate from the probe are recycled enzymatically during passage through the reactor in the presence of sufficient amounts of NADH and oxygen to produce a large amount of hydrogen peroxide, which is detected if selectively at a downstream poly(1,2-diaminobenzene)-coated platinum electrode without interference from oxidizable species such as l-ascorbate in the sample and NADH added to the carrier buffer. The cycle is also initiated with 2-oxoglutarate, and so saccharopine dehydrogenase reactor is positioned in series before the amplifier reactor to remove 2-oxoglutarate in the dialysate. By the present method, l-glutamate is selectively assayed with a 160-fold increase in sensitivity compared with the unamplified responses. The detection limit is 0.5x10(-7) M of l-glutamate.     

Chemiluminometric flow-injection method for determination of free l-malate in wine with co-immobilized malate dehydrogenase/NADH oxidase

A flow-injection system with a co-immobilized malate dehydrogenase/reduced nicotineamide adenine dinucleotide (NADH) oxidase reactor and a chemiluminometer is described for the determination of free l-malate in wine. Malate dehydrogenase and NADH oxidase were co-immobilized on poly(vinyl alcohol) beads and packed into a stainless-steel column (5 cm x 4 mm i.d.). The hydrogen peroxide produced was detected chemiluminometrically via a luminol-hexacyanoferrate(III) reaction. The calibration graph was linear from 3 x 10(-7) M to 2.5 x 10(-4) M (the linear correlation coefficient was 0.9998); the detection limit (signal-to-noise ratio, 3) was 8 x 10(-8) M. The sample throughput was 30 h(-1) without carryover. The ractor was renewed every 2 weeks.     

Quinoprotein glucose dehydrogenase modified thick-film electrodes for the amperometric detection of phenolic compounds in flow injection analysis

The use of thick-film electrodes as basic transducers for highly sensitive amperometric biosensors using PQQ (pyrroloquinoline quinone) dependent glucose dehydrogenase (GDH) with short response times is described. The enzyme is embedded in a polyurethane matrix on top of a platinum based thick film electrode and its ability to reduce oxidized phenolic compounds is exploited. The electrochemical amplification is based on the oxidation of the analyte on the surface of the electrode followed by its enzymatic reduction. Different parameters of the glucose dehydrogenase electrode system using dopamine as a model analyte were optimized, e.g., membrane thickness, pH value, buffer system, flow rate and storage conditions. Using optimized parameters the sensitivity and detection limits for various phenolic compounds were evaluated. The comparison of electrodes from the identical as well as from different batches shows the ability to produce a number of well reproducible sensors showing remarkably small differences with respect to parameters as sensitivity, response times, and measuring range. Received: 15 August 2000 / Revised: 17 October 2000 / Accepted: 24 October 2000     

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.     

Amperometric screen-printed biosensor arrays with co-immobilised oxidoreductases and cholinesterases

Amperometric screen-printed biosensor arrays for detection of pesticides (organophosphates and carbamates) and phenols have been developed. Cholinesterases (AChE and BChE), tyrosinase (TYR), peroxidases (SBP, soybean and HRP, horseradish) and cellobiose dehydrogenase (CDH) were combined on the same array consisting of one Ag/AgCl reference electrode surrounded by eight radially distributed working electrodes of either carbon or platinum. Mainly cross-linking with glutaraldehyde was employed for enzyme immobilisation. The substrates for the enzymes were acetylthiocholine for cholinesterases (ChEs), cellobiose for CDH and hydrogen peroxide for peroxidases. Hydrogen peroxide was generated in the presence of glucose by co-immobilised glucose oxidase (GOx). All measurements were performed in an electrochemical steady state system specially constructed for eight channel screen-printed electrode arrays. The achieved relative standard deviation values calculated for different enzyme substrates (10 measurements) were typically below 7% and one assay was completed within less than 10 min. The detection limits for pesticides and phenols were in the nanomolar and micromolar ranges, respectively. The developed biosensor array was evaluated on wastewater samples. To simplify interpretation of results, the measured data were treated with multivariate analysis-principal component analysis (PCA).