Polarographic determination of penicilloic acid in penicillin preparations with a flow-injection system

A flow-injection method for the determination of the penicilloic acid content of benzylpenicillin, phenoxymethylpenicillin, ampicillin, cloxacillin and carbenicillin is described. The penicilloate is detected polarographically at a dropping mercury flow-through detector mounted on a conventional polarographic capillary. A constant potential of + 0.04 V vs. SCE is applied and the current is measured in the sampled direct current mode. A pH 9.2 borate buffer containing 0.05% Triton X-100 is used. Triton displaces the reduction wave of oxygen about 400 mV towards negative potentials so that deaeration is not necessary. The penicilloate gives linear calibration graphs for 2 × 10^-6–1 × 10^-4 M solutions. The relative standard deviation for 10 injections of a 5 × 10^-5 M solution is 0.2%. Results for the determination of penicilloate in the presence of large amounts of penicillin (the latter in 10–1000-fold excess) are compared with results obtained by two titrimetric procedures.     

A flow-injection system using immobilized peroxidase and chromogenic reagents for possible determination of hydrogen peroxide

Summary A flow injection system with a reactor containing peroxidase immobilized on porous glass was used for the determination of hydrogen peroxide. A number of chromogenic reagents were studied in combination with different immobilization methods, in particular with regard to adsorption of the coloured product on the enzyme support. A f. i. a. manifold had a throughout of 210 samples h^–1 and a detection limit of 0.1 M H₂O₂ and could be used for at least 17000 determinations with the same enzyme reactor. Systems with higher sensitivity or higher sample throughput are also described.     

Application of flow-injection potentiometric system for determination of total concentration of aliphatic carboxylic acids

In this work, flow-injection system with potentiometric detection was tested for determination of total carboxylic acid concentration. Detection part of the examined system consists of ion-selective electrodes (ISEs) with polymer membranes of different compositions. First electrode is based on Zr(IV)-tetraphenylporphyrin as ionophore selective towards carboxylic acid anions, the membrane of second one contains only liphophilic anion exchanger - tridodecylmethylammonium chloride. Final response of the system is a result of combination of EMF signals from both electrodes. Combination of two detectors enables significant decrease of differences between potentiometric signals induced by mixtures of studied anions of various concentrations as compared to results obtained only with metalloporphyrin-based ISE. The use of anion-exchanger based detector allows for elimination of the influence of aliphatic carboxylic acids lipophilicity.Proposed potentiometric flow-injection system was employed for determination of short-chain aliphatic carboxylic acids (so-called VFA - volatile fatty acids) in samples originating from an anaerobic digester. Results obtained for these relatively complicated samples are in good agreement with results obtained with the use of reference colorimetric method.Linear response towards carboxylic acids was observed in the concentration range of 10⁻⁴ to 10⁻² mol dm⁻³, with the slopes in the range of −110 to −150 mV dec⁻¹ (for acetate⁻ and butyrate⁻, respectively). System enables for determination of about 6 samples per hour. Life time of ISEs average about 2 months.     

Enzymatic methods for the determination of ethanol based on linear and cyclif flow-injection systems

Linear and cyclic systems are described for the determination of ethanol (ca. 0.17–30×10^?3 M). In the linear system, the solution passes either through a minicolumn of yeast alcohol dehydrogenase (YADH) immobilized on controlled-pore glass or through minicolumns of the immobilized YADH and of yeast aldehyde dehydrogenase immobilized on cyanogen bromide-activated Sepharose-4B. The NADH formed is monitored either spectrophotometrically or spectrofluorimetrically. In the cyclic system, the solution passes through the same enzyme columns, and the NADH produced is monitored similarly before reconversion to NAD⁺ in a minicolumn of glutamate dehydrogenase immobilized on cyanogen bromie-activated Sepharose-4B in the presence of α-ketoglutarate and ammonium ions also present in the flow system. the sample throughout for both systems is ca. 40 h^?1 and 50 h^?1 for spectrophotometric and spectrofluorimetric detection, respectively. An on-line double-injection technique is described as an alternative to the cyclic system for limiting the consumption of NAD⁺.     

Quantitative validation of a flow-injection determination of penicillin in pharmaceutical formulations by means of a validation program based on an expert system

The quantitative validation of the results of a flow-injection determination of penicillin in pharmaceutical formulations is described. The validation procedure is done by using VALID, which is a generally applicable validation program based on an expert system program. The automated penicillin assay is based on the enzymatic hydrolysis of the penicillin to the corresponding penicilloic acid, which reacts with iodine generated on-line; the iodine consumption is detected amperometrically. The method is evaluated for applicability in pharmaceutical quality control. The complete validation procedure is described. During the program run, the system evaluates the calibration procedure, the drift of the analytical systemm and the effect of the sample matrix. The reliability of the flow-injection method is estimated by evaluating the maximum total error (MTE), which includes both random error and systematic error. The latter was assessed by comparing of the results of the flow-injection method with the results obtained by titration with mercury(II) as the reference method. The user requirement for the assay was an MTE of 10%. The validation procedure showed that the analytical method complied with the requirements for the major part of the concentration range (0.066–0.25 mM).     

New conventional coated-wire ion-selective electrodes for flow-injection potentiometric determination of chlordiazepoxide.

New chlordiazepoxide hydrochloride (Ch-Cl) ion-selective electrodes (conventional type) based on ion associates, chlordiazepoxidium-phosphomolybdate (I) and chlordiazepoxidium-phosphotungstate (II), were prepared. The electrodes exhibited mean slopes of calibration graphs of 59.4 mV and 60.8 mV per decade of (Ch-Cl) concentration at 25 degrees C for electrodes (I) and (II), respectively. Both electrodes could be used within the concentration range 3.16 x 10(-6)-1 x 10(-2) M (Ch-Cl) within the pH range 2.0-4.5. The standard electrode potentials were determined at different temperatures and used to calculate the isothermal coefficients of the electrodes, which were 0.00139 and 0.00093 V degrees C(-1) for electrodes (I) and (II), respectively. The electrodes showed a very good selectivity for Ch-Cl with respect to the number of inorganic cations, amino acids and sugars. The electrodes were applied to the potentiometric determination of the chlordiazepoxide ion and its pharmaceutical preparation under batch and flow injection conditions. Also, chlordiazepoxide was determined by conductimetric titrations. Graphite, copper and silver coated wires were prepared and characterized as sensors for the drug under investigation.     

Flow-through chemiluminescence sensor using immobilized oxidases for the selective determination of L-glutamate in a flow-injection system.

A selective and sensitive chemiluminometric flow sensor for the determination of L-glutamate in serum, based on immobilized oxidases such as glutamate oxidase (GOD), uricase (UC) and peroxidase (POD), is described herein. The principle for the selective chemiluminometric detection for L-glutamate is based on coupled reactions of four sequentially aligned immobilized oxidases, UC/POD/GOD/POD in a flow cell. The immobilized UC was employed to decompose urate, which is one of the major interfering components in serum for a luminol-H2O2 chemiluminescence reaction. The H2O2 produced from the UC reaction readily reacted with reducing components, such as ascorbate and glutathione, and then the excess H2O2 was decomposed by the immobilized POD. L-Glutamate in the sample plug was enzymatically converted to H2O2 with immobilized GOD. Subsequently, the peroxide reacts with luminol on the immobilized POD to produce chemiluminescence, proportional to glutamate concentration. The enzymes were immobilized on tresylated poly(vinyl alcohol beads). The immobilized enzymes were packed into TPFE tube (1.0 mm i.d. x 60 cm), in turn, and used as a flow cell. The sampling rate was 30 h-1. The calibration graph for L-glutamate is linear for 20 nM-5 microM; the detection limit (signal-to-noise = 3) is 10 nM.     

Indirect potentiometric flow-injection determination of silver in photographic fixing solutions

The thiosulfate present in fixing solutions was destroyed on-line by acidification and the undissolved gaseous products were separated from the flow stream by use of polytetrafluoroethylene microporous tubing. The silver was precipitated with an excess of sulfide, and the excess was measured with a silver/silver sulfide electrode. Silver was determined in several ranges from 1 mg 1^?1 to 10 g l^?1.     

Oxidative removal of interferences in flow-injection potentiometric determination of chloride

Direct potentiometric determination of chloride in a flow-injection system can be performed in the presence of excess bromide, iodide, sulphide and cyanide, when potassium bromate in nitric acid is used as the carrier solution. The hydrodynamics and temperature of such a system have been examined and various oxidants and indicating electrodes investigated. The analysis can be performed at a maximum rate of 120 samples per hour.     

Preparation of a potentiometric immobilized urease electrode and urea determination in serum

Polyvinylalcohol was activated with 2-fluoro-1-methylpyridiniumtoluene-4-sulphonate and urease (EC.3.5.1.5) was covalently linked to the activated matrix. PVA-urease was then immobilized on the surface of a pH glass electrode with gelatine gel and it was cross-linked using glutaraldehyde. This potentiometric membrane electrode provides a linearity to urea in the 8.910⁻⁵ to 1.110⁻³ M concentration range, but by changing the buffer concentration can be studied in the range of 10⁻⁴ to 10⁻² M urea concentration. Reproducibility experiments (n:20) were carried out with the urease enzyme electrode and with photometric methods for pooled serum sample. Average values for the two methods were 5.96 and 5.86 mM, variation coefficients were 2.5 and 3.5% respectively.     

Rapid determination of microorganisms using a flow-injection system

An automated method for the rapid determination of microorganisms using a flow-injection system is presented. Electrochemical measurement of a mediator reduced by microbial metabolism allowed the determination of fungi and bacteria in a few minutes. The lowest detection limit was 5 × 10⁶ colony-forming units (cfu) ml^?1 for Escherichia coli. Correlation between the flow-injection method and standard microbiological methods was excellent (r = 0.997, n = 4 for Beauveria bassiana; r = 0.997, n = 7 for E. coli). The flow-injection system was applied to the on-line control of an E. coli cultivation.     

A new potentiometric ibuprofenate ion sensor immobilized in a graphite matrix for determination of ibuprofen in tablets

The characteristics, performance, and application of an electrode, namely, Pt|Hg|Hg₂(IBP)₂|Graphite, where IBP stands for ibuprofenate ion, are described. This electrode responds to IBP with sensitivity of (58.6 ± 0.9) mV decade^− 1 over the range 5.0 × 10^− 5–1.0 × 10^− 1 mol L^− 1 at pH 6.0–9.0 and a detection limit of 3.8 × 10^− 5 mol L^− 1. The electrode is easily constructed at a relatively low cost with fast response time (within 15–30 s) and can be used for a period of 5 months without any considerable divergence in potentials. The proposed sensor displayed good selectivity for ibuprofen in the presence of several substances, especially concerning carboxylate and inorganic anions. It was used for the direct assay of ibuprofen in commercial tablets by means of the standard additions method. The analytical results obtained by using this electrode are in good agreement with those given by the United States Pharmacopeia procedure.     

A flow-injection system for assay of the activity of an immobilized enzyme chemically-modified electrode

Chymotrypsin, covalently immobilized to the surface of an IrO₂-coated titanium electrode, responds potentiometrically to various substrates. A flow-injection system is described for assay of the activity of the immobilized enzyme with N-benzoyl-l-tyrosine ethyl ester as substrate and an ultraviolet detector. Least-squares fits of peak height vs. time typically yield correlation coefficients of 0.999 and standard errors of estimate of 0.0043 absorbance for a total absorbance change of about 0.130. Slopes of such plots vary linearly with enzyme activity.     

A potentiometric microbial sensor based on immobilized escherichia coli for glutamic acid

The sensor consists of immobilized E. coli (which contains glutamate decarboxylase) and a carbon dioxide gas-sensor. Continuous introduction of sample solution into a flow system incorporating the sensor gives a potential which increases until a steady state is reached after 5 min. Measurements can also be made with only a 1- or 3-min introduction period with little loss of sensitivity. Calibration plots of mV measurements vs. logarithmic glutamic acid concentration are linear in the range 100–800 mg l^-1. The sensor is highly selective, stable and reproducible. It has been applied to the determination of glutamic acid in fermentation broths.     

Enzymatic flow-injection determination of urea in blood serum using potentiometric gas sensor with internal nonactin based ISE

Ion-selective electrode with cellulose triacetate membrane containing nonactin is employed for the potentiometric detection of ammonia produced in biocatalytic reaction in flow-injection system with enzyme reactor. The elimination of interferences occurring in the presence of alkali metal ions was achieved by covering a nonactin membrane with outer hydrophobic gas permeable membrane. The obtained flow-injection response to ammonia indicates a possibility of ammonia determination down to 10 microM ammonia. In the flow-injection system for urea determination 200 microl of 10-fold diluted blood serum sample was injected into carrier stream of distilled water merged with TRIS buffer, passed through the urease flow-through reactor and then after merging with NaOH stream delivered to the detector. It was found in several series of natural blood serum samples, that the correction for endogenous ammonia in such a determination is not indispensable.     

Extraction-spectrophotometric determination of anionic surfactants with a flow-injection system

Anionic surfactants are preconcentrated from 5-ml samples by extraction as the ion-pair with ethyl violet into toluene. The absorbance of aliquots of the toluene phase is measured at 610 nm in a flow-injection system. A phase converter is located prior to the injection valve to convert a water stream to, pumped with ordinary pump tubing, to a toluene stream. The working range was 0.01–1.0 mg l^?1 and the reproductibility (r.s.d, n = 10) was 2% for 0.4 mg l^?1 sodium dodecyl sulphate. The non-aqueous flow-injection system serves to miniaturize the extraction from separatory funnel (200 ml) to test tube (10 ml) scale without loss of precision or validity.     

Determination of l-alanine in a flow-injection system with an immobilized enzyme reactor

A flow-injection system for the determination of l-alanine is described. Alanine dehydrogenase is immobilized on poly(vinyl alcohol) beads and used in a packed-bed enzyme reactor. The system responds linearly to injected samples (50 μl) in the concentration range 0.5–500 μM. The maximum throughput was 40 samples per hour. The immobilized enzyme reactor was stable for at least 6 weeks. Its usefulness for assay of l-alanine in serum and beverages is described.     

Urea potentiometric biosensor based on urease immobilized on chitosan membranes

Potentiometric biosensors based on urease (E.C. 3.5.1.5.) immobilized on chitosan membranes coupled to all-solid-state nonactin ammonium ion selective electrodes are described. The enzyme was immobilized on the chitosan membranes by four procedures: (A) adsorption; (B) adsorption followed by reticulation with dilute aqueous glutaraldehyde solution; (C) activation with glutaraldehyde followed by contact with the enzyme solution; and (D) activation with glutaraldehyde, contact with the enzyme solution and reduction of the Schiff base with sodium borohydride. The response characteristics of the biosensors obtained with these enzymatic membranes were determined and compared. The biosensor with best response characteristics, obtained by procedure (B), showed the following characteristics of response to urea: (i) linearity in the 10(-4) to 10(-2) M range; (ii) slope of up to 56 mV per decade; (iii) response time between 30 s and 2 min; and (iv) lifetime of 2 months. This biosensor was tested in the determination of urea in blood serum samples.     

Simultaneous determination of l(+)- and d(−)-lactic acid by use of immobilized enzymes in a flow-injection system

The system comprises l(+)- and d(?)-lactate dehydrogenase reactors in parallel and a diaphorase electrode. Separate peaks are obtained for l(+)- and d(?)-lactic acid. The peak current is linearly related to the concentration of both isomers in the range 1 × 10^?5?2 × 10^?3 M.     

Simultaneous determination of sulfite and phosphate in wine by means of immobilized enzyme reactions and amperometric detection in a flow-injection system

A flow-injection system is proposed for the simultaneous determination of sulfite and phosphate in wine. A sulfite oxidase immobilized reactor and purine nucleoside phosphorylase-xanthine oxidase co-immobilized reactor are incorporated at fixed positions (parallel configuration) in the flow line, which is based on the splitting of the flow after sample injection and subsequent confluence. A poly(1,2-diaminobenzene)-coated platinum electrode is used as an amperometric detector to detect selectively hydrogen peroxide generated enzymatically in the enzyme reactors, without any interference from oxidizable species and proteins present in wine. Because each channel has a different residence time, two peaks are obtained. The first peak corresponds to sulfite and the second peak to phosphate. The peak current is linearly related to the concentrations of sulfite between 1 × 10⁻⁵ and 2 × 10⁻³M and phosphate between 2 × 10⁻⁵ and 5 × 10⁻³M. The simultaneous determination of sulfite and phosphate in wine can be performed at a rate of 30 samples/hr with satisfactory precision (less than 1.2% RSD) and no pretreatment except for the sample dilution.