Enzyme electrode system for oxalate determination utilizing oxalate decarboxylase immobilized on a carbon dioxide sensor

A highly selective enzyme electrode system for oxalate is described in which the enzyme oxalate decarboxylase is immobilized on a carbon dioxide gas-sensing electrode. The response of the system is linear with the logarithm of the oxalate concentration between 2 × 10^-4 and I × 10^-2 M with a slope of 57–60 mV/decade. The oxalate detection limit is 4 × 10^-5 M. Electrodes used with chemically immobilized enzyme are not affected by phosphate and sulfate at levels normally found in urine and are very stable showing no decrease in response after one month of operation. The enzyme electrode system functions well in urine, requiring minimal sample pretreatment. The recovery of oxalate added to five aliquots of a human control urine sample averaged 97.7% with an average relative standard deviation of 4.5%.     

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.     

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.     

Serine-selective membrane probe based on immobilized anaerobic bacteria and a potentiometric ammonia gas sensor

A new class of bioselective membrane probes using anaerobic bacteria is introduced with the successful construction of a L-serine-selective probe consisting of Clostridium acidiurici cells coupled to a potentiometric ammonia gas sensor. The intact cells containing the enzyme serine dehydratase are physically immobilized at the electrode surface in conjunction with iron(II) stearate, which is shown to enhance response characteristics. The potential vs. log concentration plot is linear from 1.6 × 10^-2 to 1.8 × 10^-4M serine with an average slope of 54 mV/decade and response times of 3–5 min. Optimal behavior of the probe is retained even in non-deaerated media for at least three days, and significant interference is posed only by L-glutamine. Quantitative conversion of serine is demonstrated over the linear concentration range, suggesting possible analytical or clinical applications for these probes utilizing anaerobic bacteria     

Chemically modified graphite electrode with immobilized enzyme as a potentiometric sensor for some l-amino acids

A chemically modified electrode with immobilized enzyme was constructed by covalent attachment of l-amino acid oxidase (E.C. 1.4.3.2) to a graphite rod via chemical modification of the electrode surface. Logarithmic response with concentration of selected l-amino acids was observed in the 10^-2–10^-5 M range. The electrodes displayed slopes of 24–29 mV/decade over the tested concentration range for l-phenylalanine, l-methionine, and l-leucine. The electrode slope degraded by 33% after 78 days under the defined storage conditions. Interaction of hydrogen peroxide with surface groups generated during cyanuric chloride modification appears to be the major contributor to the potentiometric response. Cations change the electrode potential but have essentially no effect on the electrode slope. A plausible model describing the mechanism of response is presented.     

Potentiometric Determination of L-Asparagine with an Enzymatic Electrode

A new enzyme electrode for the determination of L-asparagine is constructed by chemical immobilization of L-aspartase [E.C. 4.3.1.1] on an ammonia-gas-sensing probe. L-Asparagine was determined over a concentration range of 1.6 × 10^?5 to 1.5 × 10^?3 M with a subnerstian response of -51 mV/decade. The electrode was stable for more than 30 days. The effect of pH, substrate and metal activator concentrations, amount of immobilized enzyme, and interferents on the electrode response are reported.     

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.     

Ruthenium(III) Schiff's Base Complex as Novel Chloride Selective Membrane Sensor

A novel chloride PVC‐based membrane sensor based on a ruthenium(III) Schiff's base complex, as an excellent neutral carrier, has been developed. The ruthenium complex, in combination with a ketonic plasticizer and a cationic additive led to ISEs with fundamental characteristics, such as slope sensitivity, short response times and selectivity coefficients, which were sufficient for practical applications. The sensor with composition of 30% PVC, 62% benzyl acetate, 5% ruthenium(III) Schiff's base complex and 3% hexadecyltrimethyl ammonium bromide displays near‐Nernstian behavior in a wide concentration range (1.0×10^?1–3.0×10^?6 M with slope of ?54.5±0.5) with a detection limit of 2.0×10^?6 M (71.0 ng per mL). The response of the electrode is independent on pH in the range of 4.0–10.0 and can it be used for at least ten weeks. The proposed electrode shows a very short response time (<20 s) in whole concentration range. The sensor displays high selectivity toward chloride ions over several organic and inorganic anions. It was successfully applied for the determination of chloride in serum samples. It was also used as an indicator electrode in the potentiometric titration of chloride ions with silver nitrate solution.     

Electrochemical RNase A Detection Using an Electrode with Immobilized Ferrocenyl Deoxyribooligonucleotide Containing Cytidine Residue

A ferrocenyl deoxyribooligonucleotide (FcODN(rC)) with contiguous cytosine bases and a single ribonucleotide, cytidine, was immobilized on a gold electrode, and this electrode was used to detect RNase A. RNase A activity in a solution was assessed using cyclic voltammetry, and it was found that the current response of the sensor electrode decreased with increasing enzyme concentration. An extremely low detection limit of 1.0×10^?11 g mL^?1 RNase A was observed, with 15–90 % changes in the current signal. RNase activity can be an indicator of a number of diseases; therefore, this probe has great potential for applications in medical diagnostics.     

A bio-selective membrane electrode prepared with living bacterial cells.

A novel potentiometric sensor has been devised by coupling intact microorganisms (Streptococcus faecium) with an ammonia gas-sensing membrane electrode. The resulting electrode provides a linear response to arginine over the concentration range 5.0 × lO^-5–1. 0 × 10^-3 M in phosphate buffer pH 7.4, with selectivity over other amino acids. The slope of the calibration graph is -40 to -45 mV/decade during the period 2–20 days after preparation. This membrane electrode with living bacterial cells may serve as a model for the development of other new sensing systems.     

A specific enzyme electrode for urea

A truly specific, simple enzyme electrode is described for the assay of urea in blood serum. The sensor used is the newly developed air-gap electrode of R??i?ka and Hansen, and has advantages of speed of response and specificity over earlier enzyme electrodes for urea. Potassium, sodium and ammonium ions and other organic and inorganic species present in blood do not interfere. Linear curves are obtained from 2 · 10^-2M to 1 · 10^-4M urea with slopes close to Nernstian (about 0.90 pH/decade). Urea in blood was assayed with an accuracy of 2.2% and a precision of 2.0% with immobilized urease; only 3–5 min is required per assay. The electrode was used for a month and almost 500 assays with excellent results. Since the sensor never touches the sample solution, problems caused by blood components which block membrane pores are avoided.     

Chromium(III) Ion Selective Electrode Based on Oxalic Acid Bis(Cyclohexylidene Hydrazide)

A poly(vinyl chloride) membrane sensor based on oxalic acid bis (cyclohexylidene hydrazide) as membrane carrier was prepared and investigated as a Cr(III)‐selective electrode. The electrode reveals a Nernstian behavior (slope 19.8±0.4 mV decade^?1) over a wide Cr(III) ion concentration range 1.0×10^?7–1.0×10^?2 mol dm^?3 with a very low limit of detection (i.e., down to 6.3×10^?8 mol dm^?3). The potentiometric response of the sensor is independent of the pH of the test solution in the pH range 1.7–6.5. The electrode possesses advantage of very fast response, relatively long lifetime and especially good selectivity to wide variety of other cations. The sensor was used as an indicator electrode, in the potentiometric titration of chromium ion and in the determination of Cr(III) in waste water and alloy samples.     

Potentiometric determination of glucose by enzymatic oxidation in a flow system

A potentiometric determination is described for glucose based on oxidation by 1,4-benzoquinone with immobilized glucose oxidase as catalyst in an enzyme reactor. The electrode is preceded by an analytical dialysis unit to remove proteins. The ratio of quinone to hydroquinone was measured with a flow-through gold electrode. Another gold electrode preceded the enzyme reactor to correct for serum components (e.g. ascorbic acid) which can also reduce quinone. The operating range is 0.04–10 × 10^-3 M β-D-glucose. The dialysis proceeds with a linear dependence on glucose concentration, and the dialysis ratio can be adjusted by changing the buffer flow rate.     

Preparation and comparison of Proteus vulgaris and Proteus mirabilis bacterial electrodes for the determination of DL-phenylalanine

Bacterial electrodes for DL-phenylalanine were prepared by immobilizing the bacteria Proteus vulgaris and Proteus mirabilis on an ammonia gas-sensor. The response of the Proteus vulgaris bacterial electrode, when 10 mg of the bacteria was used, had a linear range between 3.0 × 10⁻⁴ and 1.0 × 10⁻² M DL-phenylalanine with a response slope of 43 mV/decade in pH 7.0, 0.1 M phosphate buffer solution at 30°C, while the response of the Proteus mirabilis bacterial electrode, when 3 mg of the bacteria was used, had a linear range between 3.0 × 10⁻⁴ and 3.0 × 10⁻² M DL-phenylalanine with a response slope of 49 mV/decade in pH 7.2, 0.1 M phosphate buffer solution at 30°C. The most important interferents were urea and l-asparagine, and inorganic salts reacted as an inhibitor. The Proteus vulgaris bacterial electrode could be used directly for the determination of DL-phenylalanine in nearly the same linear range during 3 days. On the other hand, the Proteus mirabilis bacterial electrode could be used continuously during 7 days in the above linear range.     

A Nitric Oxide Biosensor Based on Myoglobin Adsorbed on Multi‐Walled Carbon Nanotubes

Myoglobin (Myb) of horse heart is incorporated on multi‐walled carbon nanotubes (MWNTs) and immobilized at a glassy carbon (GC) electrode surface. Its electrochemical behavior and enzyme activity are characterized by employing electrochemical methods. The results indicate that MWNTs can obviously promote the direct electron transfer between Myb and electrode, and that the Myb on MWNTs behaves as an enzyme‐like activity towards the electrochemical reduction of nitric oxide (NO). Accordingly, an unmediated NO biosensor is constructed. Experimental results reveal that the peak current related to NO is linearly proportional to its concentration in the range of 2.0×10^?7–4.0×10^?5 mol/L. The detection limit is estimated to be 8.0×10^?8 mol/L. Considering a relative standard deviation of 2.1% in seven independent determinations of 1.0×10^?5 mol/L NO, this biosensor shows a good reproducibility. The biosensor based on Myb/MWNTs modified electrode can be used for the rapid determination of trace NO in aqueous solution with a good stability, nice selectivity and easy construction.     

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.     

The Electropolymerization of 2,6‐Diaminopyridine and Its Application as Mercury Ion Selective Electrode

A composite graphite (CG) electrode modified with poly(2,6‐diaminopyridine) (PDAP) was used as solid state‐ion selective electrode for determination of mercury. The electrooxidation of monomer 2, 6 diaminopyridine (DAP) onto CG was accomplished from the 30 mM DAP in 5% H₂SO₄ and 0.5 M ZnSO₄. The electrode displayed Nernstian response with slope of 28.4±1 mV decade⁻¹ in concentration range of 1×10⁻⁶ to 1×10⁻¹ M and in solution of pH 3–5. The limit of detection for electrode was 3×10⁻⁸ M with response time of 25 s. The electrode was also suitable as an indicator electrode in the potentiometric titration of Hg²⁺ with iodide.     

Determination of lead (II) ion by highly selective and sensitive lead (II) membrane electrode based on 2-(((E)-2-((E)-1-(2-hydroxyphenyl) methyliden)hydrazono)metyl)phenol

A PVC (poly vinyl chloride) membrane electrode for lead ion based on 2-(((E)-2-((E)-1-(2-hydroxyphenyl)methyliden)hydrazono)metyl)phenol (HMHMP) as a membrane carrier was prepared. This electrode exhibited linear response with Nernstian slope of 29.2?±?0.2?mV per decade within the concentration range of 2.0?×?10^?7–1.0?×?10^?1?M lead ion. The limit of detection, as determined from the intersection of the extrapolated linear segments of the calibration plot, was 8.0?×?10^?8 M. The electrode exhibited high selectivity for Pb (II). The response time of the electrode was about 5–10?s for different concentrations. The electrode is suitable for use in aqueous solutions in a pH range of 5.0–7.5. It was used as an indicator electrode in a titration of Pb (II) with chromate at constant pH. This electrode was used for the determination of lead in ore samples, and the results were in agreement with those obtained with an atomic absorption spectroscopy (AAS) method. Also lead selective electrode was used for monitoring of lead in spiked samples of the Zayanderud River and waste water by the potentiometry technique.     

Novel Gadolinium PVC‐Based Membrane Sensor Based on Omeprazole as an Antibiotic

A novel gadolinium ion‐selective electrode based on the antibiotic omeprazole as membrane carrier was prepared. The electrode has a linear dynamic range between 1.0×10^?1 and 1.0×10^?5 M, with a Nernstian slope of 19.3 ± 0.3 mV decade^?1 and a detection limit of 5.0×10^?6 M. The potentiometric response is independent of the pH of the solution in the pH range 4.0–10.0. The electrode possesses the advantages of short conditioning time, fast response time and especially, very good selectivity over a large number of other cations. The electrode can be used for at least 2 months without any considerable divergence in potentials. It was used as an indicator electrode in potentiometric titration of Gd(III) ions with EDTA.     

A new PVC matrix membrane sensor for determination of praseodymium(III) ion based on bis(salicylaldehyde)thiocarbohydrazone as an ion carrier

The sufficient amounts of bis(salicylaldehyde) thiocarbohydrazone (STCH) as a lipophilic selective element (3%, w/w), sodium nitrobenzene (NB) as a plasticizer (64%, w/w), tetraphenyl borate (NaTPB) as an anionic additive (3%, w/w), and poly vinyl chloride (PVC) as a polymeric matrix (30%, w/w) was employed to form a PVC membrane of a new Pr³⁺ ions selective sensor to apply as an indicator electrode in analytical applications. The best electrode response was observed in the slope (19.5 ± 0.7 mV per decade) over a wide concentrations from lower (1.0 × 10^?6 mol L^–1) to higher (1.0 × 10^?2 mol L^–1) of Pr³⁺ ion solution with a detection limit of 8.5 × 10^–7 mol L^–1. This electrode showed the fast response time about 10 second for praseodymium ion concentration range of 1.0 × 10^–6 to 1.0 × 10^–2 mol L^–1, in the pH range of 2.3–7.9. The matched potential method was applied to study the selectivity of electrode toward Pr³⁺ ions in comparison with many common cations. The results showed the negligible disturbance of all other cations on the proposed praseodymium(III) electrode. The making sensor has been employed successfully as an indicator electrode in the potentiometric titration of praseodymium(III) solution with EDTA at pH 6.0. Moreover the applicability of the sensor was studied in determination of Pr³⁺ ion in mixtures of different ions.