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.     

Chemiluminometric -lysine determination with immobilized lysine oxidase by flow-injection analysis

An enzymatic flow-injection procedure for the determination of -lysine was developed. A lysine oxidase reactor is combined with a fibre-optic hydrogen peroxide detector. Hydrogen peroxide detection is based on the peroxidase-catalysed luminol reaction. The chemiluminescent light is detected by a photomultiplier. -Lysine can be determined in the range 10–1000 μM. A sampling rate of up to 90 h⁻ can be achieved. The whole sensing assay works for more than 1 month. The double logarithmic graph of the peak signal height vs. the lysine concentration is linear, the slope being larger than unity (r² = 0.991, n = 4).     

Determination of l-malate in wine by flow-injection with co-immobilized malate dehydrogenase/oxaloacetate decarboxylase

A method for determination of l-malate in wine is described. Malate dehydrogenase and oxaloacetate decarboxylase were immobilized on poly (vinyl alcohol) beads and incorporated in a flow-injection system with fluorescence detection. Sample solution (50 mul) was injected into the carrier stream [4mM NAD(+) in glycine buffer (pH 10.0)]. The fluorescence based on the NADH formed could be directly related to the amount of malate. The calibration graph was linear over the range 0.4-300muM. The detection limit was 0.2muM. Sampling throughout was 25 samples/hr.     

Simultaneous determination of carbon dioxide and sulphur dioxide in wine by gas-diffusion/flow-injection analysis

A method is proposed for the simultaneous determiantion of carbon dioxide and sulphur dioxide in complex matrices. The method involves preseparation of the analysis with a flow-through gas-diffusion unit. The analytes are sensed by two detectors in series, a potentiometric detector responsive to both analytes and a photometric detector for SO₂ (p-rosaniline—formadehyde method). The usefulness of the method was tested by applying it to samples of fruity wines and the results were compared with those obtained with the standard EEC recommended method. The reproducibility was generally 7% or better, with a sampling frequency of about 25 h^-1.     

A flow-injection system for the amperometric determination of xylose and xylulose with co-immobilized enzymes and a modified electrode

A flow-injection system is described for the detection of xylose and xylulose. The detection is based on three successive reactions taking place in an enzyme reactor containing xylose isomerase, mutarotase and glucose dehydrogenase co-immobilized on controlled-pore glass. The final product, NADH, is electrocatalytically oxidized at 0 mV vs. SCE at a chemically modified electrode. Straight calibration graphs for the two pentoses were obtained between 50 μM and 2 mM. The maximal sample throughput was 30 h^?1.     

Development of a tubular periodate electrode for flow-injection determination of glycerol

Periodate electrodes without inner reference solution based on tetraoctylammonium periodate plus solvent mediator (dibutyl phthalate or 2-nitrophenyl octylether) were constructed. Linear dynamic range, practical detection limit, slope, stability, selectivity coefficients, pH dependence, response time and lifetime were evaluated. A tubular version was further developed and coupled to a flow-injection system for glycerol determination in samples relevant to the industrial production of soaps, detergents and similar. The method involves glycerol oxidation by periodate with potentiometric evaluation of its consumption. The influence of oxidizing agent concentration (10(-5)-10(-2)M NalO(4)), ionic strength (0.0-1.0M Na(2)SO(4)) and mean resident time were investigated and the feasibility of using a single-fine manifold was discussed. The proposed system handles about 40 samples/hr, is very stable and suitable to industrial control. Results within the 1000 and 5000 mg/l range glycerol are precise (r.s.d. <0.005) and in fair agreement with conventional procedures. Baseline drift or noise is not observed and a thermostat water bath is not required. A noteworthy feature is the almost linear relationship between glycerol concentration and recorded peak height which is a consequence of combined effects of reaction kinetics and electrode Nernstian response.     

Automated method for the determination of boron in water by flow-injection analysis with in-line preconcentration and spectrophotometric detection

A sensitive, automated method for the determination of boron in water samples is described, involving flow injection with on-line ion-exchange preconcentration and spectrophotometric detection of the azomethine-H—boron complex. The method is applicable to various water samples and is free from interferences, even in coloured samples. Detection limits of 5 μg l^?1 at 20 samples h^?1 and 1 μg l^?1 at 10 samples h^?1 with relative standard deviations of < 10% at 1–10 μg l^?1 and < 5%at 10–200 μg l^?1 levels of boron were achieved. The recoveries for spiked natural water samples ranged from 96 to 101%. The method compares favourably with inductively coupled plasma atomic emission spectrometry.     

Spectrophotometric determination of iron with ferrozine by flow-injection analysis

Two methods for the determination of iron by normal FIA and reversed FIA were developed using sodium 3-(2-pyridyl)-5,6-diphenyl-1,2,4-triazine-4',4'-disulphonate (ferrozine). The reagent formed a chelate with Fe(II) in hexamethylentetramine buffered medium at pH 5.5. In one previous reaction coil Fe(III) was reduced to Fe(II) by ascorbic acid and in the other reaction coil the complexation reaction was developed. The linear range of the determination was 0.5-6 and 0.1-5 mug ml(-1) of iron for normal FIA and reversed FIA respectively. The proposed method was sensitive (detection limit 0.012 and 0.010 mug ml(-1)), rapid and reproducible (RSD 0.3 and 0.28%). The method was satisfactorily applied to the determination of iron in waste water, toadstool tissue, potato leaves, human hair and bauxites at a sampling rate of 90 and 50 samples h(-1) for normal FIA and reversed FIA respectively.     

Spectrophotometric determination of catecholamines with metaperiodate by flow-injection analysis

A flow-injection Spectrophotometric method for the determination of adrenaline and isoprenaline, based on the reaction with metaperiodate, is described. The calibration graphs are linear up to 2 × 10⁻⁴ M. Flow injection allows the measurement of 120 samples per hour. The method was successfully applied to the determination of both catecholamines in pharmaceuticals.     

Fluorimetric determination of aflatoxins by flow-injection analysis

Summary A fast and inexpensive fluorimetric method for the determination of total aflatoxins (B₁, B₂, G₁, and G₂) in food of use in screening numerous samples suspectedly containing these substances is proposed. The sensitivity of the method (determination range between 0.5 and 200.0 ng ml^–1) allows these analytes to be detected at concentrations well below legal limits; hence, separation-detection techniques such as HPLC need only be used with samples in which these compounds are found to occur. The method has been applied to maize, peanut and tapioca samples, obtaining average recoveries of 100.9 with deviations of ±5% with respect to 100% recovery.

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Fluorometrische Bestimmung von Aflatoxinen durch Fließinjektionsanalyse

     

Fluorometric determination of diphenhydramine by flow-injection analysis

A sensitive, rapid and simple flow injection procedure for the determination of diphenhydramine has been designed based on a fluorometric approach. An aqueous solution of diphenhydramine is injected into a carrierreagent stream containing Ce(IV) in dilute sulphuric acid and the fluorescence intensity of the Ce(III) produced is monitored. Chemical, FIA and instrumental variables were optimized. Analytical features of the method are: linear range 0.2–2 ppm, precision 0.7%, sample throughput 80/h. The influence of some foreign substances which can be found in typical pharmaceutical samples containing diphenhydramine was also investigated. The diphenhydramine content of a pharmaceutical preparation was determined.     

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.     

Spectrophotometric determination of silicate with Rhodamine B by flow-injection analysis

A spectrophotometric flow-injection method for the determination of silicate based on the formation of an ion pair between molybdosilicic acid and Rhodamine B is proposed. It allows silicate to be determined over the concentration range 0.17–2.0 mg 1^?1 at a sampling rate of 40 h^?1, is reasonably precise and is highly tolerant to ions that commonly occur in waters. It has been applied with satisfactory results to the determination of silicate in various types of water.     

On-line determination of sulphite in brine by flow-injection analysis

A spectrophotometric flow-injection procedure for the determination of sulphite in aqueous media over the range 0.5–20 mg 1^?1 is described. The reagent used was the organic disulphide 5,5′-dithiobis(2-nitrobenzoic acid). Results are presented for a laboratory-based method for sulphite in water and a potential on-line method for sulphite in high ionic strength potassium chloride brine. The general attractions of flow-injection-based monitors for the on-line analysis of liquid process streams are also discussed.     

流动注射结合化学发光法测定没食子酸

基于没食子酸与铬 (Ⅵ )的氧化还原反应 ,产生的铬 (Ⅲ )催化鲁米诺 H2 O2 化学发光体系的研究 ,结合流动注射技术 ,优化反应条件 ,建立了一种高灵敏度的快速测定没食子酸的新方法。方法的线性范围为 2 .0× 1 0 - 9～ 5 .0× 1 0 - 6g/mL ,检出限为 1 .2× 1 0 - 9g/mL ,对 1 .0× 1 0 - 7g/mL的没食子酸进行了 1 1次平行测定 ,相对标准偏差为 2 .1 %。方法成功地用于健民咽喉片中没食子酸的测定。     

Kinetic determination of lactate dehydrogenase in blood serum by multi-detection with a cyclic flow-injection system

The use of a cyclic flow-injection system for the determination of lactate dehydrogenase (LDH) is proposed. This configuration allows the repeated passage of the reacting plug through the detector resulting in multiple peak recordings. From the data obtained, which correspond to a typical kinetic curve, the required sensitivity can be selected by using procedures based on fixed-time measurements (peak maxima or minima) or reaction-rate measurements (signal increment between two successive maxima or minima). The methods were applied successfully to the determination of LDH in blood sera; the average recovery was 100.9%.     

Spectrophotometric determination of silicon in silicates by flow-injection analysis

A flow-injection spectrophotometric method has been developed for the accurate, continuous determination of silicon in silicate rocks. A rock sample solution is prepared by fusion with a 1:1 mixture of lithium carbonate and boric acid and subsequent dissolution of the cake in 1 M hydrochloric acid. The preparation technique is the same as that used for the determination of total iron, aluminium, calcium, titanium, and phosphorus in silicate rocks by flow-injection spectrophotometry. Because of the marked polymerization of silicic acid in acid solution, silicic acid is depolymerized in alkaline medium after a simple cation-exchange column filtration of the rock sample solution and then determined by a static or an FIA spectrophotometric method. The FIA system consists of two channels which carry the carrier solution and molybdate reagent, and allows the colour reaction to proceed under controlled conditions. The FIA system permits high throughput of 70 samples per hour. The procedure has been applied to a variety of standard silicate rocks of the U.S. Geological Survey and the Geological Survey of Japan, and gave satisfactory agreement with the recommended values.     

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.     

Chemiluminescence determination of vitamin B12 by a flow-injection method

Chemiluminescence analysis with flow injection was used for the determination of vitamin B₁₂ by means of the luminol-hydrogen peroxide system. The linear range is three orders of magnitude and the detection limit is 1 ng for 50-μ1 samples injected. The results were compared with those obtained by a spectrophotometric method.     

Spectrophotometric flow-injection determination of cellobiose dehydrogenase activity in fermentation samples with 2,6-dichlorophenolindophenol

Cellobiose dehydrogenase activity (0.25–1 U Ml^?1) is monitored by oxidation of cellobiose to cellobionolactone, thus reducing 2,6-dichlorophenolindophenol to a colourless compound. To prevent any β-glucosidase from reacting, gluconolactone is added as inhibitor. The sample throughput is 120 h^?1.