The determination of 2-hydroxynicotinic acid and its major metabolite in blood and urine by spectro-photofluorimetry and differential pulse polarography

A sensitive and specific spectrofluorimetric assay was developed for the determination of 2-hydroxynicotinic acid (1) and its major metabolite, the N-1-riboside (11) in blood and urine. Both compounds exhibit strong fluorescence in acidic media. Thin-layer chromatography is employed to separate the drug from its metabolite; the compounds are eluted from the silica gel into methanol—0.1 M hydrochloric acid (80+20). The sensitivity is 0.04–0.05 μg of I and 0.10–0.12 μg of II per ml of blood or urine. The two compounds can also be determined by differential pulse polarography, which is especially suitable for urine. The fluorimetric method was applied to the determination of blood levels and the urinary excretion of the drug in man after single oral 500-mg doses.     

Simultaneous determination of caffeic acid and its major pharmacologically active metabolites in rat plasma by LC‐MS/MS and its application in pharmacokinetic study

A simple, sensitive and selective high‐performance liquid chromatography electrospray ionization tandem mass spectrometry (LC‐MS/MS) method was developed for simultaneous determination and pharmacokinetic study of caffeic acid (CA) and its active metabolites. The separation with isocratic elution used a mobile phase composed of methanol and water (containing 0.1% formic acid) at a flow rate of 0.2 mL/min. The detection of target compounds was done in selected reaction monitoring (SRM) mode. The SRM detection was operated in the negative electrospray ionization mode using the transitions m/z 179 ([M ? H]^?) → 135 for CA, m/z 193 ([M ? H]^?) → 134.8 for ferulic acid and isoferulic acid and m/z 153 ([M ? H]^?) → 108 for protocatechuic acid. The method was linear for all analytes over the investigated range with all correlation coefficients 0.9931. The lower limits of quantification were 5.0 ng/mL for analytes. The intra‐ and inter‐day precisions (relative standard deviation) were <5.86 and <6.52%, and accuracy (relative error) was between ?5.95 and 0.35% (n = 6). The developed method was applied to study the pharmacokinetics of CA and its major active metabolites in rat plasma after oral and intravenous administration of CA. Copyright © 2014 John Wiley & Sons, Ltd.     

Determination of platinum in urine by differential pulse polarography

A method has been developed for determination of platinum in urine, after administration of cis-dichlorodiammineplatinum(II). The diethyldithiocarbamate complex of the platinum(II) is formed and extracted into chloroform, then mineralized with aqua regia. After removal of nitric acid the platinum is complexed with ethylenediamine. This chelate yields a catalytic current at a dropping mercury electrode, which is measurable by differential pulse polarography. The detection limit is ~10 ng ml . The calibration graph is linear over the range 20-800 ng ml .     

Determination of vitamin k1 in plasma by differential pulse polarography and its possible clinical application

Differential pulse polarography, following solvent extraction, is used to monitor the clearance of vitamin K₁ (2-methyl-3-phytyl-1,4-naphthoquinone) from human plasma after a 20-mg intravenous injection. The average recovery of vitamin K₁ added to plasma (200–3000 ng ml^-1) was 72.2%. The coefficient of variation was 3.0% at a concentration of 2.75 μg ml^-1 of plasma. Measurements of vitamin K₁ in plasma from patients given an intravenous injection of the vitamin, support the idea that a metabolic cycle involving vitamin K₁ underlies calcification of bone.     

Determination of mitomycin C in human blood plasma and urine by high-performance differential pulse polarography

High-performance differential pulse polarography is used for determining the antitumor antibiotic mitomycin C in human blood plasma and urine. The limit of determination (2-ml samples) is 25 ng ml^?1 when the substance is isolated by means of Amberlite XAD-2, and 200 ng mo_?1 when samples are not pretreated. The method was applied in a pharmacokinetic experiment; no metabolites of mitomycin C were observed in urine or plasma.     

The determination of a carbamate insecticide in soil samples by differential pulse polarography

Differential pulse polarography is shown to be a simple and potentially useful method for monitoring the degradation of a carbamate insecticide (Bendiocarb; 2,3-isopropyli-denedioxyphenyl-N-methylcarbamate) in soil samples. Only extraction from the soil sample with dichloromethane and evaporation of the extract is needed prior to polarography. Calibration plots were linear over the range 10–50 mg l^?1 at ?0.94 V vs. Ag/AgCl in an acetate buffer of pH 5.0. There is no apparent interference from hydrolysis products or soil components.     

The determination of phenobarbital and diphenylhydantoin in blood by differential pulse polarography

A sensitive differential pulse polarographic assay was developed for the determination of phenobarbital or diphenylhydantoin in blood. The assay involves the selective extraction of the compound into chloroform from whole blood buffered to pH 7.0. After suitable “clean-up” of the sample, each compound is nitrated in 10% potassium nitrate in sulfuric acid at 25° for 1 h. The nitro-derivatives are extracted into ethyl acetate, and the residues are dissolved in 1 M phosphate buffer (pH 7.0) or 0.1 M sodium hydroxide for phenobarbital and diphenylhydantoin, respectively; the solutions are deoxygenated, and analyzed by differential pulse polarography. The overall recovery of phenobarbital and diphenylhydantoin from blood was 72.3% ±6.5 (s_r) and 76.7 ±2.3 (s_r) respectively. The sensitivity limit is 1–2 μg ml^-1 of blood for both compounds. A modified assay for the determination of both compounds in blood with t.l.c. separation was also developed.     

Differential pulse polarography of some benzodiazepines and their determination in urine

A differential pulse polarographic method has been applied to the determination of diazepam, oxazepam, nitrazepam and flurazepam down to 2 x 10(-7)M (0.14 mug/ml). The method can also be used with biological materials such as urine, without prior extraction. Only a 2-ml volume of urine is necessary.     

The determination of trace levels of aluminium by differential pulse polarography

The direct determination of aluminium in aqueous solutions by differential pulse polarography is described. If the pH is carefully controlled to 4.00 ± 0.01, there is a linear relationship between the peak height of the polarographic wave and the aluminium concentration up to 2.5 × 10^-5 mol dm^-3. The coefficient of variation is about 4% at the 10^-5 mol dm^-3 level. With increasing aluminium concentrations, the relationship ceases to be linear, and above 9 × 10^-5 mol dm^-3, the peak splits, probably because of hydrolysis and polymerisation. Na⁺, NH₄⁺, Mg²⁺ and Ca²⁺ interfere at levels 100 times greater than that of the aluminium whereas Fe²⁺, Fe³⁺, Cu²⁺, Zn²⁺, Ni²⁺, NO₃^-, ClO₄^-, Cl^- and SO₄^2- do not interfere.     

Determination of oxytetracycline in urine and human serum by differential pulse polarography

Summary A differential pulse polarographic method for the determination of oxytetracycline in urine and human serum in acid media (HClO₄ of pH 2) is proposed. The effects of the amount of sample taken and the concentration of HClO₄ present were investigated. The detection limit was 5.5×10^–6 mol/l. The standard deviation of the determination of 5.5×10^–5 mol/l of oxytetracycline in 2 ml of urine was 1.7×10^–6 mol/l and that of the determination of 5.5×10^–5 mol/l of oxytetracycline in 2 ml of human serum was 1.9×10^–6 mol/l.

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Bestimmung von Oxytetracyclin in Urin und Humanserum durch Differential-Pulspolarography

     

Gas chromatographic method for determination of a piperazine derivative (Trelibet) and its metabolites in human plasma and urine

A sensitive gas chromatographic method was developed for the determination of Trelibet, 1-benzyl-4-(2'-pyridinecarbonyl)piperazine, and of its major metabolites in biological fluids. The compounds were extracted as bases into dichloromethane, and the extracts were analysed by a dimethylsilicone capillary column with a nitrogen-phosphorus flame-ionization detector. The lower limit of detection was 1 ng/ml for Trelibet and 5 ng/ml for the metabolites. Peak-area ratios of the compounds and internal standard were linearly correlated to their plasma concentrations between 1 and 1000 ng/ml. The method was used for quantification of Trelibet and two of its metabolites in depressed patients after oral administration of a single dose of 200 mg of Trelibet. Concentration data measured in plasma and urine showed that the method is sensitive enough to monitor concentrations both for pharmacokinetic studies and for plasma steady-state levels daily.     

The determination of chromium(VI) in natural waters by differential pulse polarography.

A method utilizing differential pulse polarography for the determination of chromium(VI) in natural water is described. Additions of 0.62 μg Cu(II) ml^-1 and 0.55 μg Fe(III) ml^-1 did not interfere with the determination of 0.050 μg Cr(VI) ml^-1. The natural water samples containing chromium(VI) were buffered to approximately pH 7 with 0.1 M ammonium acetate and 0.005 M ethylene diamine and analyzed. Natural water samples of chromium content from 0.035 μg ml^-1 to 2.0 μg ml^-1 may be analyzed directly without further preparation. The detection limit is 0.010 μg ml^-1.     

Direct and indirect methods for the determination of vitamin K3 using differential pulse polarography and application to pharmaceuticals

Two methods for the determination of vitamin K(3) have been developed. Vitamin K(3) in its oxidized form is determined by direct and indirect methods. Its standard solution was prepared by the indirect method using Ti(III) as reducing agent. For this purpose vitamin K(3) (menadion) in a clinical injection solution, which is in its hydroquinone form in the presence of sulfite, is oxidized with oxygen. In 0.2 M HAc and 0.02 M HCl electrolyte vitamin K(3) and Ti(IV) have reduction peaks at -0.58 V at -0.82 V respectively. The reaction between Ti(III) and vitamin takes place quantitatively in a medium of 0.2 M HAc and 0.002 M HCl. After the reduction, the reaction product Ti(IV) is followed from its polarographic peak at about -0.82 V. The most important result in this work is that, with this method vitamin K(3) can be standardized and after standardization this solution can be used for the direct determination in routine analysis with a very simple and fast method, using only the peak at -0.71 V in 0.2 M HAc medium. Both direct and indirect methods have been used for the determination of Vitamin K(3) in a clinical injection solution. The limit of quantification (LOQ) was 1.5x10(-6) M and in both methods the detection limit found was 7x10(-7) M.     

Contribution to the study of pulse polarography part III. Digital simulation of CE mechanisms in differential pulse polarography

The differential pulse polarographic behaviour of electrode reactions complicated by a first order homogeneous chemical reaction has been elucidated by a digital simulation procedure. The effect of systematic variations of the homogeneous and heterogeneous kinetic parameters on experimentally measurable parameters is described.     

Selection of optimum pH for the iodate determination using differential pulse polarography

The concentration of iodate in seawater samples was determined at various pH values using differential pulse polarography (DPP). The sensitivity for the iodate determination decreased rapidly below pH 7 and above pH 9. The decrease below pH 7 may be caused by conversion of iodate to iodide, followed by the successive formation of I₂ and I₃ ^–. The decrease above pH 9 is probably due to the combination of iodate and hydroxide. Theoretical calculations have demonstrated that the optimum pH for iodate determination is above pH 7.4 for Po₂ = 0.101 Pa.     

The applicability of the superposition principle in differential pulse polarography

It is shown theoretically that the superposition principle is applicable to pulse voltammetry if the electrochemical system can be separated into a potential-dependent nonlinear part and a linear part. For systems not complicated by adsorption or electrode kinetics, the applicability of the principle depends on diffusion coefficients, electrode and cell geometry. For plane semi-infinite diffusion, applicability is expected; this is generally not the case for spherical electrodes or bounded regions (film electrode or thinlayer cell). The implications of the theory on differential pulse polarography are discussed and an experimental study on the applicability for iron(III), cadmium(II) and lead(II) is presented.