Comparative study of potentiometric and amperometric tissue-based electrodes for oxalate

Acetone-precipitated pulp from banana skins is physicall entrapped at the tip of a carbon dioxide gas-sensor and on a hydrogen peroxide sensor probe to determine oxalate potentiometrically and amperometrically in aqueous solution and inurine. The enzyme present in the tissue is oxalate oxidase. The potentiometric response has a slope of 47–50 mV/decade for 1 × 10^?4 M–2 × 10^?3 M oxalate with a detection limit of 2 × 10^?5 M. The amperometric response is linear for 2 × 10^t-5–3 × 10^?4 M oxalate with a dectection limit of 2 × 10^?6 M. Average recoveries of oxalate added to aqueous samples were 96.2% and 98.0%, and average relative standrd deviations were 3.8% and 3.6% for the potentiometric and amperometric systems, respectively. Oxalate was determined in six control urine samples, with relative errors of about 2.5%, by both electrode systems after a simple clean-up.     

Flow-injection amperometric determination of oxalate with immobilized oxalate oxidase

Oxalate is immobilized on controlled-pore glass and is used on-line in a glass minicolumn (2.5×25 mm). The hydrogen peroxide formed is detected amperometrically. Oxalate (6×10^?6?9×10^?4 M) is determined in a flowing stream of pH 3.5 citrate (or succinate) buffer. As little as 20 ng (in 40 μl; 5.7×10^?6 M) of oxalate can be detected. Copper inhibition can be removed either by adding EDTA to the carrier stream or incorporating a chelating-resin minicolumn into the flow system prior to the enzyme column.     

A coated-metal enzyme electrode for urea determinations

A potentiometric enzyme electrode is reported in which an enzyme immobilized in polyvinyl chloride is used to coat an antimony metal electrode to detect changes in pH when the electrode is immersed in a solution of the enzyme substrat. As an example, urea is determined in solution by using immobilized urease on an antimony electrode, giving a linear concentration range of 5.0 × 10^-4–1.0 × 10^-2 M urea with a slope of 44 mV per decade change in urea concentration. The response slope is stable for about 1 week, with response times in the range 1–2 min, but with absolute potential changes occurring from day to day.     

Reagentless biosensor for phenolic compounds based on tyrosinase entrapped within gelatine film

A simple and new reagentless phenolic compound biosensor was constructed with tyrosinase immobilized in the gelatine matrix cross-linked with formaldehyde. The morphologies of gelatine and gelatine/tryosinase were characterized by SEM. The tyrosinase retains its bioactivity when being immobilized by the gelatine film. Phenolic compounds were determined by the direct reduction of biocatalytically liberated quinone at -0.1 V vs SCE. The process parameters for the fabrication of the enzyme electrode were studied. Optimization of the experimental parameters has been performed with regard to pH, operating potential, temperature and storage stability. This biosensor exhibits a fast amperometric response to phenolic compounds. The linear range for catechol, phenol, and p-Cresol determination was from 5×10⁻⁸ to 1.4×10⁻⁴ M, 5×10⁻⁸ to 7.1×10⁻⁵ M, and 1×10⁻⁷ to 3.6×10⁻⁵ M, with a detection limit of 2.1×10⁻⁸ M, 1.5×10⁻⁸ M, and 7.1×10⁻⁸ M, respectively. The enzyme electrode retained ca.77% of its activity after 7 days of storage at 4°C in a dry state. The proposed sensor presented good repeatability, evaluated in terms of relative standard deviation (R.S.D.=8.6%) for eight different biosensors and was applied for determination in water sample. The recovery for the sample was from 99.0% to 99.8%.     

Amperometric biosensor for oxalate determination in urine using sequential injection analysis

An amperometric flow biosensor for oxalate determination in urine samples after enzymatic reaction with oxalate oxidase immobilized on a modified magnetic solid is described. The solid was magnetically retained on the electrode surface of an electrode modified with Fe (III)-tris-(2-thiopyridone) borate placed into a sequential injection system preceding the amperometric detector. The variables involved in the system such as flow rate, aspired volumes (modified magnetic suspension and sample) and reaction coil length were evaluated using a Taguchi parameter design. Under optimal conditions, the calibration curve of oxalate was linear between 3.0-50.0 mg·L^-1, with a limit of detection of 1.0 mg·L^-1. The repeatability for a 30.0 mg·L^-1 oxalate solution was 0.7%. The method was validated by comparing the obtained results to those provided by the spectrophotometric method; no significant differences were observed.     

Mucin/carbopol matrix to immobilize oxalate oxidase in a urine oxalate amperometric biosensor

An enzymatic amperometric electrode with extended analytical range and improved stability for oxalate determination has been developed. Glutarlaldehyde/mucin/carbopol matrix was used for the crosslinking of the enzyme between polymeric membranes to form a classical laminate construction (sandwich) and compared with the glutaraldehyde/mucin/enzyme and glutaraldehyde/albumin/enzyme.The use of a sulphonated membrane as internal membrane allowed rejection of the most important electrooxidable urine interferents. The recovery assays were highly satisfactory. The wide linear response in the range 2-400 μM after 1/10 urine dilution (corresponding to 20-4000 μM) made it suitable for clinical range. High correlation with the standard spectrophotometric method was obtained (r² = 0.98, y = 0.89x, n = 25).     

Determination of pesticides in vegetable samples using an acetylcholinesterase biosensor based on nanoparticles ZrO2/chitosan composite film

An amperometric pesticides inhibition biosensor has been developed and used for determination of pesticides in vegetable samples. To eliminate the interference of ascorbic acid, multilayer films of polyelectrolyte (chitosan/polystyrensulfonate) were coated on the glass carbon electrode. Then, acetylcholinesterase was immobilized on the electrode based on surface-treated nanoporous ZrO₂/chitosan composite film as immobilization matrix. As a modified substrate, acetylthiocholine was hydrolysed by acetylcholinesterase and produced thiocholine which can be oxidized at +700?mV vs. SCE. Pesticides inhibit the activity of enzyme with an effect of decreasing of oxidation current. The experimental conditions were optimized. The electrode has a linear response to acetylthiocholine within 9.90?×?10^?6 to 2.03?×?10^?3?M. The electrode provided a linear response over a concentration range of 6.6?×?10^?6 to 4.4?×?10^?4?M for phoxim with a detection limit of 1.3?×?10^?6?M, over a range of 1.0?×?10^?8 to 5.9?×?10^?7?M for malathion, and over a range of 8.6?×?10^?6 to 5.2?×?10^?4?M for dimethoate. This biosensor has been used to determine pesticides in a real vegetable sample.     

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.     

Flow-injection analysis for l-glutamate using immobilized l-glutamate oxidase: comparison of an enzyme reactor and enzyme electrode

An enzyme electrode and enzyme based on immobilized l-glutamate oxidase are used for the determination of l-glutamate in a flow-injection system. The hydrogen peroxide produced is monitored amperometrically. The enzyme reactor system surpasses the enzyme electrode system with regard to sensitivity and analytical speed. For both systems, the peak current is linearly related to the l-glutamate concentration in the range 5 × 10^?6-1 × 10^?3 M. l-Glutamate in seasoning can be determined very selectively with < 0.7% r.s.d.     

Flow-Injection Spectrophotometric Determination of Oxalate,Citrate and Tartrate Based on Photochemical Reactions

Abstract

A flow-injection configuration for the spectrophotometric determination of oxalate, citrate and tartrate is proposed. The procedure is based on the photochemical decomposition of the complexes formed between iron(III) and these anions. The iron(II) produced in the photochemical reactions was detected by measuring the absorbance after complexation with ferrozine (λ_max=562 nm). Linear calibration graphs were obtained over the concentration ranges 5.0 × 10^?6 - 1.0 × 10^?4 M, 8 × 10^?6 - 1.8 × 10^?4 M and 1.0 × 10^?6 - 2 × 10^?5 M for oxalate, citrate and tartrate, respectively. The relative standard deviations at the 1x10^?5 M concentration level were within the range 1.29 - 1.47 %. The sampling frequency was about 40 samples h^?1. The usefulness of the method was tested in the determination of oxalate in urine and spinach, of citrate in pharmaceuticals and soft drinks and of tartrate in pharmaceuticals. For the determination of oxalate in urine samples a prior separation of the analyte by precipitation with calcium chloride is recommended.     

An enzyme reactor electrode for urea determinations.

An enzyme reactor electrode system for the determination of urea is described. A buffer is pumped through an enzyme reactor (0.4 ml) containing urease immobilized with glutaraldehyde to glass. The effluent is mixed with sodium hydroxide pumped through a second channel and fed through an ammonia gas electrode. Samples are introduced via a third flow channel and mixed with the buffer. The conversion of urea to ammonia is quantitative for sample concentrations of less than 0.03 M for a flow rate of 40 ml h^-1. The reactor electrode shows a Nernstian slope of 57 mV/decade for 5·10^-5–3·10^-2 M urea. The response is independent of variations in the flow rate, enzyme activity or temperature of the reactor.     

Mediated amperometric biosensor for hypoxanthine based on a hydroxymethylferrocene-modified carbon paste electrode

An amperometric enzyme electrode for the determination of hypoxanthine in fish meat is described. The hypoxanthine sensor was prepared from xanthine oxidase immobilized by covalent binding to cellulose triacetate and a carbon paste electrode containing hydroxymethylferrocene. The xanthine oxidase membrane was retained behind a dialysis membrane at a carbon paste electrode. The sensor showed a current response to hypoxanthine due to the bioelectrocatalytic oxidation of hypoxanthine, in which hydroxymethyiferrocene served as an electron-transfer mediator. The limit of detection is 6 × 10^?7 M, the relative standard deviation is 2.8% (n=28) and the response is linear up to 7 × 10^?4 M. The sensor responded rapidly to a low hypoxanthine concentration (7 × 10^?4 M), the steady-state current response being achieved in less than 1 min, and was stable for more than 30 days at 5 ° C. Results for tuna samples showed good agreement with the value determined by the conventional method.     

Simultaneous determination of oxalate, thiosulfate, and thiocyanate in urine by ion-exclusion chromatography with electrochemical detection

Summary A sensitive ion-exclusion chromatographic method has been developed for determination of oxalate, thiosulfate, and thiocyanate. The method is based on separation of these anions on a polymethacrylate-based, weakly acidic cation-exchange resin (TSKgel OApak-A) and detection by means of a glassy carbon (GC) electrode electrochemically modified with polyvinylpyridine (PVP), palladium, and iridium oxide (PVP/Pd/IrO₂). The electrochemical behavior of oxalate, thiosulfate, and thiocyanate at this chemically modified electrode (CME) have been investigated by cyclic voltammetry. The results indicated that electrocatalytic oxidation of these anions by the electrode was efficient and that the sensitivity, stability, and lifetime of the electrode were relatively high. Combined with ion-exclusion chromatography the PVP/Pd/IrO₂ electrode was used as the working electrode for amperometric detection of these anions. All linear ranges were over two orders of magnitude and detection limits, defined asS/N=3, were 9.0×10⁻⁷ mol L⁻¹ for oxalate, 6.7×10⁻⁷ mol L⁻¹ for thiosulfate, and 5.6×10⁻⁷ mol L⁻¹ for thiocyanate. Correlation coefficients were all>0.998. Coupled with microdialysis sampling the method has been successfully applied to the determination of oxalate, thiosulfate, and thiocyanate in urine.     

A Prospect for the Analysis of Species Acting as Enzyme Inhibitors as Illustrated by Heavy Metal Inhibition

Abstract

A flow system incorporating an amperometric glucose oxidase enzyme electrode has been used to study the inhibitory effects of 16 metal cations on glucose oxidase. Only copper(II), mercury(II) and silver(I) caused any significant inhibition. the enzyme electrode could be reactivated by EDTA, the reactivation being most effective for copper(II) and least so for silver(I). Other complexing agents were tried for reactivation but proved to be unsatisfactory.

The ability to reactivate the enzyme on the electrode following copper(II) inhibition, and the linear response of the system to the level of this inhibitor according to I/A = -9.49 × 10^?7 log([Cu]/M) + 4.84 × 10^?8; r = 0.994 between 2.5 × 10^?4M and 5 × 10^?3M [Cu]²⁺ indicates a prospect for the use of a flow system for determining enzyme inhibitors in samples.     

Flow-coulometric detector for uric acid in human urine

A novel flow-coulometric detector integrating an immobilized uricase reactor and an electrolytic cell was fabricated and used for the determination of uric acid in human urine. The procedure is based on the measurement of the total charge with and without passing the sample through an enzyme reactor which allows the complete conversion of the electro-active uric acid in electro-inactive products. The amount of uric acid is linearly related to the difference between the two total charges. The current efficiencies for 1 × 10^?4-1 × 10^?3 M uric acid were found to be nearly 100% (r.s.d. < 1%).     

New Potentiometric Membrane Sensors Responsive to Pb(Ii) Based on Some Recently Synthesized 9, 10- Anthraquinone Derivatives

ABSTRACT

New potentiometric membranesensorsresponsive to Pb(II) have been developed. The membrane sensors are based on three different 9, 10-anthraquinone derivatives. The electrode based on 1, 4-bis (prop-2¹-enyloxy)-9, 10-anthraquinone exhibits a good Nernstian response for Pb(II) ions over a wide concentration range (2.5×10^?6 - 1.0×10^?2 M) with a slope of 29.8 mV decade^?1. Detection limit is 1.5×10^?6 M. The response time of the sensor is 15s and the useful working pH range is 4.7-6.8. The membrane can be used for more than 4 months without any considerable divergence in potentials. The electrodes revealed comparatively good selectivities with respect to alkali, alkaline earth and some transition and heavy metal ions. It was used as an indicator electrode in potentiometric titration of lead ions (with sulfate and oxalate ions), and for the determination of lead in waste waters.     

Induced bacterial electrode for the potentiometric measurement of tyrosine

A bacterial tyrosine-selective potentiometric electrode is proposed in which the desired biocatalytic activity is biochemically induced during growth of the bacterial cells. As the result of this induction, a normally ineffective biocatalyst, Aeromonas phenologenes ATCC 29063 can be coupled with an ammonia gas-sensing electrode in order to produce a useful tyrosine-selective electrode. The sensor shows excellent response characteristics, having a slope of 50–58 mV/decade, a range of logarithmic response from 8.3 × 10^-5 M to 1.0 × 10^-3 M tyrosine, a lower limit of detection of 3.3 × 10^-5 M tyrosine, response times of 4–6 min, and a useful lifetime in excess of one week. Specific enzyme inhibitors are employed to enhance the selectivity of the electrode while maintaining high biocatalytic activity with respect to tyrosine.     

Ammonia abatement in an enzymatic flow system for the determination of creatinine in blood sera and urine

The abatement of ammonia in standard solutions, and in human blood and urine samples is achieved by adding suitable amounts of NADPH and α-ketoglutarate to the sample and passing it through a 2-m nylon tube with glutamate dehydrogenase immobilized on the inner wall. The procedure provides removal of 98% of the ammonia (1–5 × 10^?4 M) in the original sample in 50 s. The abatement of ammonia permits the use of an ammonia probe coupled with an immobilized degradative enzyme for the determination of creatinine. Creatinine was determined in clinical blood and urine samples by first removing the ammonia from the sample and then cleaving the creatinine to N-methylhydantoin and ammonia with immobilized creatininase. Only 200 μl of sample is needed and the entire process is conducted in a single flow stream.     

Electrochemical investigation and determination of ceftazidime in pharmaceutical dosage forms and human urine

A voltammetric study of the oxidation of Ceftazidime (CEFT) has been carried out at the glassy carbon electrode by cyclic, differential pulse (DPV) and square wave (SWV) voltammetry. The oxidation of CEFT was irreversible and exhibited diffusion controlled process depending on pH. The oxidation mechanism was proposed and discussed. According to the linear relationship between the peak current and concentration, DPV and SWV voltammetric methods for CEFT assay in pharmaceutical dosage forms and human urine were developed. For analytical purposes, a well resolved diffusion controlled voltammetric peak was obtained in 0.1 M H₂SO₄ at 1.00 and 1.02 V for differential pulse and square wave voltammetric techniques, respectively. The linear response was obtained within the range of 4 × 10^?6?8 × 10^?5 M with a detection limit of 6 × 10^?7 M for differential pulse and 4 × 10^?6–2 × 10^?4 M with a detection limit of 1 × 10^?6 M for square wave voltammetric technique. The determination of CEFT in 0.1 M H₂SO₄ was possible over the 2 × 10^?6–1 × 10^?4 M range in urine sample for both techniques. The standard addition method was used for the recovery studies.     

Development of an Amperometric Enzymatic Biosensor Based on Gold Modified Magnetic Nanoporous Microparticles

Gold modified nanoporous silica based magnetic microparticles have been prepared as support for the immobilization of the enzyme horseradish peroxidase (HRP). The enzyme modified gold microparticles were retained onto the surface of a solid carbon paste electrode with the help of a permanent magnet. The analytical performances of the resulting biosensor were characterized by studying hydroquinone (HQ) and hydrogen peroxide. The former was monitored by the direct electroreduction of the biocatalytically generated quinone. Several experimental parameters influencing the biosensor response were investigated. A linear response to HQ was obtained in the concentration range comprised between 5×10^?7 and 4.5×10^?6 M with a detection limit of 4×10^?7 M. The enzyme electrode provided a linear response to hydrogen peroxide over a concentration range comprised between 5×10^?7?1.3×10^?4 M with a detection limit of 4×10^?7 M. The inhibition of the biosensor response in the presence of thiols e.g. cysteine, captopril, glutathione and Nacystelyn (NAL) has been pointed out.