Contribution a l'électrochimie des thiols et disulfures : Partie I. Cystéine et cystine

A study of the electrochemical characteristics of cysteine and cystine was carried out by d.c., a.c. and differential pulse polarography. Up to three waves were observed depending on the concentration and pH. The waves of the two amino acids could be separated in a borate buffer of pH 9.2. Differential pulse polarography made it possible to determine as little 0.12 mg of cysteine and 0.24 mg of cystine per litre.     

Specific determination of cysteine and penicillamine through cyclization to 2-thioxothiazolidine-4-carboxylic acids

A very simple and highly specific method for the determination of cysteine and penicillamine is presented. Treatment with 1,1'-thiocarbonyldiimidazole in slightly basic solutions converts cysteine rapidly and quantitatively to a very stable derivative, 2-thioxothiazolidine-4-carboxylic acid, which is not formed by thiols or amines. The cyclic derivative has a characteristic UV spectrum with a maximum at 272 nm and it can be quantified by one of two ways. (1) When only inorganic ions and common additives are present, a spectrophotometer or a plate reader capable of handling multiple samples is sufficient to estimate cysteine in the concentration range of 2-150 muM. Penicillamine is determined similarly by cyclization to 5,5-dimethyl-2-thioxothiazolidine-4-carboxylic acid. The method is also applicable to derivatives of cysteine modified only at the carboxyl group. (2) To determine cysteine in complex mixtures, a liquid chromatograph connected to a UV detector is used. The elution is rapid with well-separated peaks for the thiazolidine derivatives. The detection limit is 2 pmole of cysteine or penicillamine per injection and the detector response is linear up to 1 nmole. The usefulness of the method is demonstrated by determining cysteine and penicillamine in capsules and by measuring cysteine in a dietary supplement.     

Voltammetric study of some macromolecule - metal complexes

The usefulness of a voltammetric model for studying macromolecule - metal complex systems is verified. Complexes formed by a metal ion (Zn(II), Cd(II), Pb(II) or Cu(II)) and a macromolecule (polymethacrylic (PMA), polyacrylic (PAA), alginic (AA) or polygalacturonic (PGA) acids) are investigated. Several voltammetric techniques have been used: sampled direct current polarography (DCP), normal pulse polarography (NPP), differential pulse polarography (DPP), reverse pulse polarography (RPP), cyclic voltammetry (CV) and differential pulse anodic stripping voltammetry (DPASV). Results confirm the validity of the model, in determining not only formation constants but also diffusion coefficients of the complexes. The behaviour of some systems agrees with that predicted by the model. Nonetheless, other systems only partially fulfil the predictions for different reasons, which are discussed.     

Modified reverse pulse polarographic behaviour of magnesium ion in aqueous solution

Modified reverse pulse polarography (MRPP) is proposed for measuring the quantity of a reduction product formed at the initial potential in reverse pulse polarography. A double potential-step method is employed for this purpose. MRPP has been applied to the study of the electrochemical behaviour of magnesium in aqueous solution. For magnesium the height of the MRPP anodic wave was proportional to concentration at low pH, but not in unbuffered neutral solution. This difference is attributed to formation of hydroxo-magnesium complexes because of depletion of hydrogen ions near the electrode in a neutral solution.     

Electrochemical flow-through detector for the determination of cystine and related compounds

An electrochemical double cell for the detection of cystine in aqueous liquid streams is described. A column electrode of amalgamated silver powder is used to reduce cystine quantitatively to cysteine, which is detected amperometrically at a mercury electrode. The double cell is applied to the detection of cystine, cysteine and penicillamine in high-pressure liquid chromatography and to the selective determination of cystine and cysteine by flow-injection analysis.     

Polarographic and liquid chromatographic methods for the determination of sulfur residues on grapes and wheat

Sampled d.c. and differential pulse polarography are used, in batch mode, to determine sulfur in methanol/0.1 M ammonium acetate (pH 5.0). A two-electron reaction (reduction of sulfur to sulfide) is shown to be involved. Differential pulse polarography is sensitive for the determination of sulfur in relatively clean solutions; the detection limit is 7.2 μg l^?1. The interference of heavy metals (Pb and Cd) is avoided by addition of EDTA. For complex matrices, such as extracts of wheat and grapes, matrix effects are serious. For such samples, reversed-phase liquid chromatography with amperometric detection (dropping mercury electrode) gives excellent results. A relatively simple procedure is described for the determination of sulfur residues in wheat and grapes at levels ? 0.5 mg kg ^?1; linear response is obtained up to ca. 7 mg kg^?1.     

Adsorbing colloid flotation separation and polarographic determination of Mo(VI) in water

A method is described for the flotation and determination of Mo(VI) in water at ng/ml levels. Mo(VI) is preconcentrated and separated by adsorbing colloid flotation employing aluminium(III) hydroxide as collector and sodium lauryl sulphate as surfactant at pH 5.3 ± 0.1. The molybdenum content in the froth is estimated by using the catalytic wave of Mo(VI) in the presence of nitrate by charging current compensated d.c. polarography (CCCDCP) or differential pulse polarography (DPP). The effect of variables such as pH, ionic strength, concentration of collector and surfactant, time of stirring and gas flow-rate on the recovery of Mo by flotation is reported. The effects of various cations and anions on the flotation and determination of Mo are studied. This method is employed for the determination of molybdenum in natural fresh water samples.     

正交回归多元标准加入法同时测定干扰组分

提供了同时测定混合物中彼此严重干扰的多种组分的新方法。该方法采用多元标准加入法的正交回归设计,因此,由微机上的正交回归分析,得到一组准确的回归方程,该方法用于光度法中,同时测定了工业污水中的铜,镍,镉,锌,并用于差分脉冲极谱法中,同时测定了河水中的铅,铊,镉,测定结果的误差均不大于4％,这个结果说明该方法具有良好的准确性和可靠性。     

Application of differential pulse polarography for trace determination of polycytidylic acid in absence and presence of some metal ions

Summary A differential pulse polarographic method has been applied to the determination of trace concentrations of polycytidylic acid (Poly-C) in absence and presence of metal ions. The applicability of differential pulse polarography for the trace determination of the investigated biological compound was examined with regard to the dependence of differential pulse current on various parameters such as pH, pulse amplitude, scan rate and drop time. The selectivity of this technique for the determination of binary and a ternary mixtures of poly-C and some metal ions has been also reported. Limits of detection and quantitation have been calculated for the differential pulse polarographic determination of the poly-C and various metal ions. The validity of this method is supported by the constancy of the i_p/C values and a statistical analysis is included on calibration curve parameters and observed concentration.     

An investigation into the determination of stability constants of metal complexes by convolution-deconvolution cyclic voltammetry

A technique is described for calculating stability constants of metal-ligand complexes from convolution-deconvolution voltammetry. Semi-integration of the cyclic voltammetric currents with respect to time allows calculation of E(1 2 ) values in a manner comparable to the use in polarography of the Heyrovsky-Ilkovic equation. The technique described also allows determination of the ratio of the diffusion coefficients of the free and complexed metal ions and provides a second check of the stoichiometry. A reliable route to the metal-complex stability constants by the equations of Lingane and DeFord and Hume is therefore obtained. Advantages of this technique compared with the use of polarography, differential pulse polarography and pH titrations are discussed, with the complexes formed by cadmium with glycine, alanine, valine and aspartic acid as examples.     

Polarographic determination of α-amylase activity

The enzyme α-amylase splits blue starch in fragments bearing electroactive groups which exhibit two waves in the pulse polarograms. This behaviour is the basis of the polagraphic determination of bacterial and human serum α-amylase activity. The differential pulse mode is more sensitive by a factor of 25 as compared with normal pulse polarography. With serum α-amylase, protein adsorption disturbs the determination of low activities.     

Sensitive method for the measurement of citrate lyase activity by differential pulse polarography

Summary A method is described for the determination of citrate lyase (E.C. 4.1.3.6) activity using differential pulse polarography. It is based on the measurement of the reduction wave of the reaction product pyruvate in the presence of an excess of citrate as the substrate. The method is very sensitive and rapid. Additionally, kinetic parameters and the Michaelis constant (K_m) can be obtained.     

Removal of interference in the differential pulse polarographic determination of progestogens in some combined low-dosage oral contraceptives

Previously published differential pulse methods for the determination of certain progestogens (laevonorgestrel and norethisterone) are not applicable to combined low-dosage oral contraceptives because interference from excipients in the tablets completely eliminates the polarographic response. An ultrafiltration device allows rapid prior extraction of the interfering substances before the polarographic determination in 50% ($\text{v}\text{v}$) methanol—phosphate buffer (pH 6.0). Recoveries of 100 ± 1% were obtained by the recommended method, and data for a range of formulations are in excellent agreement with expected values. Electrode characteristics of the progestogens and interfering substances are reported, based on studies employing cyclic voltammetry at a hanging mercury drop electrode, a.c. polarography and normal pulse polarography. Competitive adsorption processes seem to occur when the progestogen and excipients are simultaneously present.     

Reactant adsorption in analytical pulse polarography: An outline in terms of the concentration profile

The consequences of adsorption of the electroactive species in analytical pulse polarography are discussed. For both normal pulse polarography (NPP) and differential pulse polarography (DPP) explanations are given in terms of the concentration profiles as they are developed upon adsorption before pulse application. An approximate interpretation of the depressed NPP limiting current is sometimes possible by taking its dependence on pulse duration into account. In a number of cases NPP offers the possibility of avoiding adsorption effects by choosing a suitable initial potential. In DPP reactant adsorption generally causes peak enlargement, but the theoretical approach is complex and practical means for checking or eliminating adsorption effects in DPP are limited. Analytical calibration curves start with a linear portion corresponding with the linear adsorption regime; at higher concentrations the DPP curve bends downwards, whereas the NPP curve bends slightly upwards, before reaching the linear region of diffusion control. Several analytical pitfalls connected with the adsorption phenomena are indicated.     

Electrochemical methods for the determination of heparin

A review of studies on the determination of heparin in various samples (pharmaceuticals, biological fluids) by electrochemical methods of analysis in 1976–2014 is presented. Heparin is most often determined in pharmaceuticals by polarography using cationic dyes, and in biological samples, by differential pulse methods on non-stationary mercury electrodes. Works on the creation of heparin-selective electrodes coated with a polyvinylchloride membrane with quarternary ammonium salts are most promising; they can, probably, be used for the creation of portable devices for the determination of heparin.     

Polarographic determination of butorphanol tartrate

A new indirect polarographic method is proposed for the determination of butorphanol tartrate in the injectable solution form (Stadol). Direct-current polarography and differential pulse polarography (DPP) were applied for the study of authentic butorphanol and its injectable solution form in alkaline medium after nitration with 1 M potassium nitrite in presence of 1 M hydrochloric acid. The standard addition method was employed for the evaluation of the results and the mean percentage found for the injectable solution form was 99.2 +/- 1.0.     

Determination of pseudouridine at submicromolar concentrations by cathodic stripping voltammetry at a mercury electrode

Pseudouridine (5-ribosyluracil), uridine (N,1-ribosyluracil), deoxyuridine (N,1-deoxyribosyluracil) and uracil are investigated by means of d.c. polarography and by differential and normal pulse polarography. Pseudouridine, which is known to be a cancer marker, yields anodic polarographic currents in the pH range 7–11, whereas uridine and deoxyuridine are inactive under the same conditions. The polarographic response of pseudouridine obtained is due to the formation of a sparingly soluble mercury compound. Pseudouridine can be determined by differential pulse polarography in the concentration range 2–6 × 10^?6 M and by differential-pulse cathodic stripping voltammetry at concentrations two orders of magnitude lower. Small excesses of uridine, deoxyuridine or proteins do not interfere with the determination.     

Pulse polarograpmc study of the electrochemical reduction of lucigenin in aqueous medium

The electrochemical reduction of lucigenin (bis-N-methylacridinium nitrate) in aqueous solution was studied by normal pulse polarography, normal pulse polarography with differential detection of the current, and differential pulse polarography with cathodic and anodic pulses at several pulse amplitudes. The effects of pH and lucigenin concentration were studied. In confirmation of an earlier d.c. polarographic study, lucigenin is shown to be reduced in two separate one-electron steps. An adsorption peak accompanies the first step, while the second, below pH 3.5, is catalytic owing to chemical regeneration of the intermediate reduction product at the electrode surface.     

Polarographic determination of thiabendazole

Summary Polarographic Determination of Thiabendazole Thiabendazole is used as a fungistat on citrus fruit to protect it from decay.In order to work out a polarographic determination the electrochemical behaviour of thiabendazole was investigated by sampledd c polarography and differential pulse polarography. Thiabendazole shows one wave or peak in the polarogram, when a short drop time (0.4 s) is used. Detection is most sensitive at pH 8. The current measured is proportional to the concentration. The detection limit is 0.5 ppm.By evaluating further experimental data it was possible to conclude, that mercury is first oxidised. Thereby two electrons are exchanged. Then mercury(II) ions formed in this way react with two molecules thiabendazole. Two protons are involved in this chemical process.Applying drop times greater than 0.4 s and concentrations higher than 1.5·10^–4 M a polarogram with two peaks is formed. This is due to the adsorption of the reaction product.For quantitative determination several citrus fruits were peeled and the peels were extracted with ethylacetate. After removing interfering substances by shaking with sodium hydroxide solution, thiabendazole was extracted by diluted hydrochloric acid and quantitatively determined by differential pulse polarography. The recovery of thiabendazole is 70.0% with a relative standard deviation of 2.9%. For all samples investigated the thiabendazole concentrations were below the permitted value.Cordially dedicated to Univ.-Prof. Dr. Dr. h. c. K. Kratzl on the occasion of his 70th birthday.     

Cathodic Stripping Voltammetry of Sulphur-Containing Amino Acids and Peptides in the Presence of Nickel Ion. Catalytic and Inhibiting Effects

Abstract

The paper reviews recent studies on the effect of addition of Ni(II) in the cathodic stripping voltammetry of the following compounds: cysteine, penicillamine, cystine, glutathione (either reduced or oxidised) and N-acetylcysteine. With the exception of N-acetylcysteine, the above compounds give a cathodic stripping peak at -0.6 V (vs. Ag/AgCl, 3 M KCl electrode) which is due to the catalytic reduction of nickel ion. Even in the case of the disulphides the actual catalyst is the thiol produced by the cleavage of the -S-S- bond during the accumulation step. The catalytic peak enables the detection of the analyte with a better selectivity than is obtained with the stripping peak due to the reduction of mercury thiolates. In addition, Ni(II) suppresses the mercury thiolate peak of ligands such as cysteine or penicillamine, but does not modify the behaviour of thiols with low complexing properties (such as N-acetylcysteine). Consequently, compounds such as cysteine and its N-acyl derivatives can be determined simultaneously by means of the catalytic peak and the mercury thiolate peak (at -0.4 V) respectively.