Hydrogen‐Atom Abstraction Reactions by Manganese(V)– and Manganese(IV)–Oxo Porphyrin Complexes in Aqueous Solution

High‐valent manganese(IV or V)–oxo porphyrins are considered as reactive intermediates in the oxidation of organic substrates by manganese porphyrin catalysts. We have generated Mn^V– and Mn^IV–oxo porphyrins in basic aqueous solution and investigated their reactivities in C? H bond activation of hydrocarbons. We now report that Mn^V– and Mn^IV–oxo porphyrins are capable of activating C? H bonds of alkylaromatics, with the reactivity order of Mn^V–oxo>Mn^IV–oxo; the reactivity of a Mn^V–oxo complex is 150 times greater than that of a Mn^IV–oxo complex in the oxidation of xanthene. The C? H bond activation of alkylaromatics by the Mn^V– and Mn^IV–oxo porphyrins is proposed to occur through a hydrogen‐atom abstraction, based on the observations of a good linear correlation between the reaction rates and the C? H bond dissociation energy (BDE) of substrates and high kinetic isotope effect (KIE) values in the oxidation of xanthene and dihydroanthracene (DHA). We have demonstrated that the disproportionation of Mn^IV–oxo porphyrins to Mn^V–oxo and Mn^III porphyrins is not a feasible pathway in basic aqueous solution and that Mn^IV–oxo porphyrins are able to abstract hydrogen atoms from alkylaromatics. The C? H bond activation of alkylaromatics by Mn^V– and Mn^IV–oxo species proceeds through a one‐electron process, in which a Mn^IV–‐oxo porphyrin is formed as a product in the C? H bond activation by a Mn^V–oxo porphyrin, followed by a further reaction of the Mn^IV–oxo porphyrin with substrates that results in the formation of a Mn^III porphyrin complex. This result is in contrast to the oxidation of sulfides by the Mn^V–oxo porphyrin, in which the oxidation of thioanisole by the Mn^V–oxo complex produces the starting Mn^III porphyrin and thioanisole oxide. This result indicates that the oxidation of sulfides by the Mn^V–oxo species occurs by means of a two‐electron oxidation process. In contrast, a Mn^IV–oxo porphyrin complex is not capable of oxidizing sulfides due to a low oxidizing power in basic aqueous solution.     

Electrical double layer in surface-inactive electrolyte solution and adsorption of halide ions from 0.1 M solutions on liquid Cd–Ga and In–Ga alloys in gamma-butyrolactone

The double-layer characteristics of liquid renewable Cd–Ga (0.3 at % Cd) and In–Ga (14.2 at % In) electrodes in the gamma-butyrolactone (GBL) solutions of various electrolytes are studied by measuring the differential capacitance and using the method of open-circuit jet electrode. For the (Cd–Ga)/GBL and (In–Ga)/GBL interfaces, the zero-charge potentials, which are not distorted by the specific adsorption of ions, and the chemisorption potential drops of solvent are determined. It is shown that, in spite of the fact that the work function decreases as we pass from (In–Ga) to (Cd–Ga), the chemisorption potential drops of solvent on both electrodes are close. This behavior is explained by a closer approach of GBL dipoles to the surface of (Cd-Ga) electrode providing more effective overlapping of donor–acceptor levels of metal and solvent. It is shown that, in GBL, the adsorption parameters of halide ions and their surface activity series depend on the metal nature. On the (Cd–Ga) and (In–Ga) electrodes, the reversed surface activity series of halide ions is observed: on the Hg electrode in various solvents, the surface activity increases in the series Cl^– < Br^– < I^–, whereas on the (Cd–Ga) and (In–Ga) electrodes in GBL, it varies in the reverse series I^– < Br^– < Cl^–.     

Simultaneous determination of three chloroacetic acids,three herbicides,and 12 anions in water by ion chromatography

An ion chromatography method was developed for the simultaneous detection of three soluble herbicides (glyphosate, bentazone and picloram), three chlorine disinfection byproducts (monochloroacetic acid, dichloroacetic acid and trichloroacetic acid) and 12 anions in water (Cl^–, Br^–, SO₄^2–, CO₃^2–, ClO₃^–, ClO₄^–, BrO₃^–, PO₄^3–, NO₂^–, NO₃^–, CH₃COO^– and COO^–). High linearity (r² > 0.996) was observed for all target analytes for each respective concentration range. The limit of detection and limit of quantitation were between 0.21–0.85 and 0.06–25.46 μg/L, respectively. However, the interference effect of Cl^–, NO₃^–, SO₄^2– and CO₃^2– on some target analytes must be considered during the analysis. Sample pre‐treatment by a hydrogen column (H‐column) required to reduce the negative effect of CO₃^2–. Additionally, sample pre‐treatment by a sliver–hydrogen column (Ag–H‐column) is required when Cl^– > 100 mg/L and SO₄^2– < 50 mg/L, and pre‐treatment by both a barium column (Ba‐column) and an H‐column is required when Cl^– > 100 mg/L and SO₄^2– > 50 mg/L. When Cl^– > 100 mg/L, SO₄^2– > 50 mg/L and CO₃^2– > 20 mg/L, the sample pre‐treatment by either an Ag–H–Ba‐column or an Ag–H‐column and Ba‐column is required to minimize interference.     

Flow injection chemiluminescence determination of isoniazid with electrogenerated hypochlorite

A flow-injection chemiluminescence method for the determination of isoniazid based on the sensitizing effect of isoniazid on the chemiluminescence generating luminol-hypochlorite reaction is described. The hypochlorite was electrogenerated on-line by constant current electrolysis, thus, eliminating instability of hypochlorite solution prepared from commercially available sodium hypochlorite. The calibration graph is linear in the range 1 × 10^–8 to 1 × 10^–6 g mL^–1, and the detection limit is 6 × 10^–9 g mL^–1. The relative standard deviation for determination of 5 × 10^–8 g mL^–1 is 2.8%. The proposed method has been successfully applied to the determination of isoniazid in pharmaceutical preparations.     

Synthesis of insulin fragments with disulfide bridges between intact chains A20-B19

The synthesis of six insulin fragments is described, in which various sequences of the two chains are linked by the disulfide bridge between A²⁰ and B¹⁹. The fragments in question are: A^20–21–B^19–21, A^20–21–B^18–21, A^20–21–B^17–21, A^19–21–B^19–21, A^16–21–B^18–21 and A^20–21–B^12–21. In order to build up the simpler fragments the disulfide bridge was established by oxidation with iodine of two S-trityl cysteine peptides in which the carboxyl and amino groups were protected by the t-butyl and t-butyloxycarbonyl residue. From the mixture obtained the unsymmetrical cystine peptide was separated in all cases from the two symmetrical ones by counter-current distribution. In the synthesis of the more complex fragments advantageous use was made of smaller unsymmetrical fragments prepared as above but having one amino group protected by the N-trityl residue. After selective elimination of this group it was possible to lengthen the peptide chain at this position. The free peptides were obtained by removal of the protecting groups with strong acids, in particular concentrated hydrochloric acid. While in this deprotecting step the disulfide bond was stable, conditions are discussed under which disproportionation was observed. None of the six synthetic insulin fragments showed activity in stimulating rat adipose tissue to convert ¹⁴C-labelled glucose to CO₂ in vitro.     

The relationship between self-organization and membrane effects of aqueous dispersion systems of the thyroliberin oligopeptide

The relationship between rearrangement of the dispersed phase inducing considerable changes in the pH and nonmonotonic concentration dependences of membrane effects in aqueous systems of the endogenous regulatory peptide, thyroliberin (thyrotropin-releasing hormone), in 10^–3–10^–16 mol/L concentration range was demonstrated for the first time. The membrane structure modification in the 10^–13–10^–16 mol/L range was found to be due to accumulation of nanoassociates, while the oppositely directed pronounced structural changes in the 10^–6–10^–12 mol/L range may be associated with the coexistence and rearrangement of dispersed phases of various nature (domains and associates) whose action on membrane lipid components is regulated in this concentration range by the correlated changes in the dispersed phase parameters and pH.     

Electron spectra of WO molecule. New electron state <Superscript>3</Superscript>Π

The electron spectrum of the tungsten monooxide molecule is observed in the 550–800 nm region using intracavity laser absorption spectroscopy. The WO molecules are produced in a pulsed electric discharge through the mixture of tungsten hexacarbonyl vapors. The spectrum is recorded using a diffraction spectrometer (resolving power of 240000). The bands in the 16400–15500 cm^–1 region are assigned to the ³Π₀–X³Σ⁺ component of the ³Π₀–X³Σ⁺–³XΣ⁺ electron transition. The rotational analysis of the 0-0 and 1-0 bands is carried out and the rotational constants for the ground X″³Σ and the exited ³Π₀ states are computed: В′ = 0.385738 cm^–1, B″ = 0.415538 cm^–1.     

Rapid synthesis of carbon materials by microwave-assisted hydrothermal method at low temperature and its adsorption properties for uranium (VI)

The cathelicidin-derived peptide (CDP1) is a human antimicrobial peptide that preferentially targets bacterial membranes in response to infection. CDP1 was functionalised with NODAGA and DOTA for complexation with gallium-68 to evaluate its potential as an infection imaging tracer. The synthesis of [⁶⁸Ga]Ga–NODAGA–CDP1 and [⁶⁸Ga]Ga–DOTA–CDP1 were optimised for pH, molarity, incubation time and temperature, and product purification. The integrity and protein binding were investigated employing [⁶⁸Ga]GaCl₃ and [⁶⁸Ga]Ga–DOTA–TATE as internal references. [⁶⁸Ga]Ga–NODAGA–CDP1 displayed good labelling properties with higher product yield compared to [⁶⁸Ga]Ga–DOTA–CDP1. In contrast, [⁶⁸Ga]Ga–DOTA–CDP1 showed better stability and is the preferred candidate for an in vivo investigation.

     

Sensitive spectrofluorimetric determination of zinc at ultra-trace levels

An ultra-trace method based on the reaction of zinc with salicylthiocarbohydrazone (SATCH) and Triton X-100 as a non-ionic surfactant was developed for the fluorimetric determination of zinc at the picogram level. The reaction is carried out in the pH range 4.4–4.7 in an aqueous ethanolic medium [52% (v/v) ethanol]. The influence of the reaction variables is discussed. The detection limit is 10 pg ml^?1 and the range of application is 0.01–500 μg l^?1, with an optimum range of 0.04–400 μg l^?1. The relative standard deviations are 0.68% (0.01–0.1 μg l^?1 of zinc), 0.41% (0.1–1.0 μg l^?1 of zinc), 0.64% (1–10 μg l^?1 of zinc), 0.82% (10–100 μg l^?1 of zinc) and 0.15% (100–500 μg l^?1 of zinc). The method is highly sensitive and selective in the presence of Cd^II and Hg^II. The effect of interferences from other metal ions and anions was studied; the masking action is discussed. The advantages of the proposed method include its high sensitivity, simplicity and selectivity.     

A nitrate-selective microelectrode based on a lipophilic derivative of iodocobalt(III)salen

The synthesis of iodo{2,2′-[1,2-octadecanediylbis(nitrilomethylidyne)]diphenolato}cobalt is described. Liquid membrane microelectrodes based on this carrier exhibit Nernstian behaviour with a selectivity sequence according to the Hofmeister series: I^– > NO₃ ^– > NO₂ ^– > Cl^– > HCO₃ ^– > AcO^–. The selectivity coefficient of nitrate over nitrite and chloride amounts to –1.6 and –2.7, respectively. The detection limit for nitrate in water amounts to 10^–5.2 mol/L. A nitrate profile measured in a nitrifying biofilm is presented as a practical application.     

Model oxygen-evolving center composed of polymer membrane and dimer ruthenium complex

The in situ spectrocyclic voltammetric investigations of the dimeric ruthenium complex used for water oxidation, [(bpy)₂(H₂O)Ru–O–Ru(H₂O)(bpy)₂]⁴⁺ (H₂O–Ru^III–Ru^III–OH₂), were carried out in a homogeneous aqueous solution and in a Nafion membrane under different pH conditions. The in situ absorption spectra recorded for the dimer show that the dimer H₂O–Ru^III–Ru^III–OH₂ complex underwent reactions initially to give the detectable H₂O–Ru^III–Ru^IV–OH and H₂O–Ru^III–Ru^IV–OH₂ complexes, and at higher positive potentials, this oxidized dimer underwent further oxidation to produce a presumably higher oxidation state Ru^V–Ru^V complex. Since this Ru^V–Ru^V complex is reduced rapidly by water molecules to H₂O–Ru^III–Ru^IV–OH₂, it could not be detected by absorption spectrum. Independent of the pH conditions and homogeneous solution/Nafion membrane systems, the dimer Ru^III–Ru^IV was detected at higher potentials, suggesting that the dimer complex acts as a three-electron oxidation catalyst. However, in the Nafion membrane system it was suggested that the dimer complex may act as a four-electron oxidation catalyst. While the dimer complex was stable under oxidation conditions, the reduction of the dimer Ru^III–Ru^III to Ru^II–Ru^II led to decomposition, yielding the monomeric cis-[Ru(bpy)₂(H₂O)₂]²⁺.     

Selective photometric redox determination of periodate and iodate ions in bottled drinking water

method has been developed for the selective photometric redox determination of periodate and iodate ions in bottled drinking water based on redox reactions of analytes with Methylene Blue with different duration of processes, products of which form the analytical signal. The limits of detection for periodate and iodate ions are 0.5 and 0.2 µg/L, respectively. The allowable weight ratios for concomitant ions for (at the analyte concentration 2 µg/L) are as follows: I^–, Br^–, IO₃^–, BrO₃^–, ClO^–, CIO^–, CIO₂^–, CIO₃^– and CIO₄^–(1: 100); and for IO₃^– (1 µg/L) are: BrO₃^–₂^–, NO (1: 60), CIO^–, CIO₂^–, (1: 100), and I^–, Br^–, IO₄^–, CIO₃^–, and CIO₄^– (1: 200). The HCIO₃^–, Cl^–, and SO₄^2- anions and Ca²⁺, Mg²⁺, Na⁺, K²⁺, and NH₄⁺ cations are macrocomponents of drinking water and at total concentrations up to 10 g/L do not affect the results of analysis. In the concentration range 1–10 µg/L of IO₄^– andIO₃^–, the total error of determination is 5–7%.     

Properties of the Magnesium(II) and Calcium(II) Complexes of 5‐ and 6‐Uracilmethylphosphonate (5 Umpa2– and 6 Umpa2–) in Aqueous Solution

The stability constants of the 1 : 1 complexes formed between Mg²⁺ or Ca²⁺ and 5 Umpa^2– or 6 Umpa^2– were determined by potentiometric pH titrations in aqueous solution (25 °C; I = 0.1 M, NaNO₃). Based on previously established log K^M_M(R‐PO3) versus pK^H_H(R‐PO3) straight‐line plots (M²⁺ = Mg²⁺ or Ca²⁺; R‐PO₃^2– = simple phosphate monoester or phosphonate ligands where R is a non‐interacting residue), it is shown that the Mg(5 Umpa), Ca(5 Umpa), Mg(6 Umpa) and Ca(6 Umpa) complexes have the stability expected on the basis of the basicity of the phosphonate group in 5 Umpa^2– and 6 Umpa^2–. This means, these ligands may be considered as simple analogues of nucleotides, e. g. of uridine 5′‐monophosphate. In the higher pH range deprotonation of the uracil residue in the M(5 Umpa) and M(6 Umpa) complexes occurs and this leads to the negatively charged M(5 Umpa–H)^– and M(6 Umpa–H)^– species. Based on the comparison of various acidity constants it is shown that the M(5 Umpa) complexes are especially acidic; or to say it differently, the M(5 Umpa–H)^– species are especially stable. This increased stability is attributed to the formation of a seven‐membered chelate involving next to the phosphonate group also the carbonyl oxygen atom at C4 (after deprotonation of the (N3)H site). The formation degree of this chelated isomer reaches about 45% for the Mg(5 Umpa–H)^– and Ca(5 Umpa–H)^– species. No indication for chelate formation was observed for the M(6 Umpa–H)^– complexes.     

Oil-in-water emulsions as suitable working media for the direct polarographic determination of aziprotryne and desmetryne from its organic extracts in water samples

The electroanalytical behavior of the reduction of the herbicides aziprotryne (2-azido-4-isopropylamino-6-methylthio-1,3,5-triazine) and desmetryne (4-isopropylamino-6-methylamino-2-methylthio-1,3,5-triazine) in oil-in-water emulsions is reported. This medium allows the differential pulse polarographic determination of these s-triazines directly from their sample extracts in an appropriate organic solvent. Sodium pentanesulfonate was chosen as the most suitable surfactant to be used as emulsifying agent, whereas ethyl acetate was selected as the organic solvent to form the emulsions. The peak current was maximum in a 0.3 mol L^–1 HClO₄ medium of the continuous aqueous phase for aziprotryne, and at pH 3.0 for desmetryne, and the potential became more negative as the pH increased for both herbicides. The limiting current is diffusion controlled and the electrode process is irreversible. Four electrons are involved in the overall electrochemical reduction process as determined by controlled potential coulometry, whereas the αn_a values suggested that two electrons are involved in the rate-determining step. Using differential pulse polarography, aziprotryne and desmetryne can be determined in the emulsified medium over the concentration ranges 1.0 · 10^–7–1.0 · 10^–4 mol L^–1, with limits of detection of 4.5 · 10^–8 mol L^–1 and 6.6 · 10^–8 mol L^–1, respectively. The method was applied to the determination of aziprotryne and desmetryne in spiked irrigation water. At concentration levels of 6.0 · 10^–7 mol L^–1 aziprotryne and 4.0 · 10^–7 mol L^–1 desmetryne, recoveries of 94 ± 3% and 94 ± 4%, respectively, were obtained after preconcentration on Sep-Pack C₁₈ cartridges. Finally, partial least-squares regression (PLSR) has been used for treatment of the polarographic data obtained from mixtures of aziprotryne, desmetryne and simazine in oil-in-water emulsions. The size of the calibration set was of 29 samples by ninety two current measurements at different potentials. Prediction of the herbicides concentration within the range 1.0 · 10^–6 –1.0 · 10^–5 mol L^–1 was possible.     

A rapid automated method for wine analysis based upon sequential injection (SI)-FTIR spectrometry

A new process control methodology for the simultaneous determination of sugars, alcohols and organic acids in wine based on multivariate evaluation of mid-IR transmission spectra of wine samples is presented. In addition to ethanol several lower level wine components (glucose, fructose, glycerol, citric-, tartaric-, malic-, lactic- and acetic acid) were determined. To establish a multivariate calibration model a set of 72 calibration solutions was prepared and measured, using a novel, fully automated sequential injection (SI) system with Fourier transform infrared (FTIR) detection. The resulting spectra were evaluated using a partial least square (PLS) model. The developed PLS model was then applied to the analysis of real wine samples containing 79–91 g L^–1 ethanol, 5.9–8.1 g L^–1 glycerol, 0.4–6.9 g L^–1 glucose, 1.5–7.5 g L^–1 fructose, 0.3–1.6 g L^–1 citric acid, 1.0–1.7 g L^–1 tartaric acid, 0.02–3.2 g L^–1 malic acid, 0.4–2.8 g L^–1 lactic acid and 0.15–0.60 g L^–1 acetic acid, yielding results which were in good agreement with those obtained by an external reference method (HPLC-IR). The short analysis time (less than 3 min) together with high reproducibility makes the newly developed method applicable to process control and screening purposes (average of the standard deviations calculated from four repetitive measurements of six different real samples: ethanol: 0.55 g L^–1, glycerol: 0.037 g L^–1, glucose: 0.056 g L^–1, fructose: 0.036 g L^–1, citric acid: 0.020 g L^–1, tartaric acid: 0.010 g L^–1, malic acid: 0.052 g L^–1, lactic acid: 0.012 g L^–1 and acetic acid: 0.026 g L^–1).     

Trip-Multiplett-Übergänge und Resonanz-Raman-Spektren von Halogeno-2,3-naphthalocyaninato(2–)mangan(III) und Vergleich mit Halogenophthalocyaninato(2–)mangan(III)

Trip-Multiplet Transitions and Resonance Raman Spectra of Halo-2,3-naphthalocyaninato(2–)manganese(III) and Comparison with Halophthalocyaninato(2–)manganese(III) Dehydrated manganese chloride and bromide reacts with 2,3-dicyanonaphthalene in ethylene glycol yielding green, scarcely soluble halo-2,3-naphthalocyaninato(2–)manganese(III), [Mn(X)nc^2–] (X = Cl, Br). The magnetic moment (μ_eff £ 5.3 μ_B at 300 K) confirms the electronic high-spin d⁴ ground-state of penta-coordinated Mn^III. The electronic absorption spectra show (in cm^–1) the typical B (∼ 11200), Q (20000–28000), N (34600) and L region (39600). Additional bands at 5300/7200 cm^–1 and 16200/17600 cm^–1 are attributed to spin-allowed trip-quintet transitions (TQ1, TQ2). The Mn–X stretching vibration is at 283 cm^–1 (X = Cl) and 223 cm^–1 (X = Br), respectively; its intensity is selectively enhanced by coincidence of the excitation frequency of the resonance Raman spectra with TQ2. The spectroscopic properties are compared to those of the structurally related Mn^III phthalocyaninates.     

Silver(I) salts with penicillin anions

Silver(I) salts with benzylpenicillin (Bzp^–), ampicillin (Amp^–), and oxacillin (Oxa^–) anions with compositions of AgBzp, AgAmp, and AgOxa are isolated from an aqueous solution in the solid state and characterized by IR spectroscopy and thermal analysis (TG/DSC). IR spectroscopy data lead to the conclusion that Ag(I) coordinates the Oxa^– ion through carbonyl oxygen atoms of the ß-lactam and amide groups. No coordination is observed for the Bzp^– and Amp^– anions.     

Synthese und Eigenschaften von (Acido)(nitrosyl)phthalocyaninato(2–)ruthenium

Synthesis and Properties of (Acido)(nitrosyl)phthalocyaninato(2–)ruthenium (Acido)(nitrosyl)phthalocyaninato(2–)ruthenium, [Ru(X)(NO)pc^2–] (X = F, Cl, Br, I, CN, NCO, NCS, NCSe, N₃, NO₂) is obtained by acidification of a solution of bis(tetra(n-butyl)ammonium) bis(nitro)phthalocyaninato(2–)ruthenate(II) in tetrahydrofurane with the corresponding conc. mineral acid or aqueous ammonium salt solution. The nitrite-nitrosyl conversion is reversal in basic media. The cyclic and differential pulse voltammograms show mainly three quasi-reversible one-electron processes at 1.05, –0.65 and –1.25 V, ascribed to the first ring oxidation and the stepwise reduction to the complexes of type {RuNO}⁷ and {RuNO}⁸, respectively. The B < Q < N regions in the electronic absorption spectra are still typical for the pc^2– ligand, but are each split into two strong absorptions (14500/16500(B); 28000/30500(Q); 34500/37000 cm^–1(N)), whose relative intensities strongly depend on the nature of the axial ligand X. In the IR spectra is active the N–O stretching vibration between 1827 (X = I) and 1856 cm^–1 (F), the C–N stretching vibration at 2178 (X = NCO), 2072 (NCS), 2066 (NCSe), 2093 cm^–1 (CN), the N–N stretching vibration of the azide ligand at 2045 cm^–1, the fundamentals of the nitrito(O) ligand at 1501, 932, and 804 cm^–1, and the Ru–X stretching vibration at 483 (F), 332 (Cl), 225 (Br), 183 (I), 395 (N₃), 364 (ONO), 403 (CN), 263 (NCS), and 231 cm^–1 (NCSe). In the resonance Raman spectra, excited in coincidence with the B region, the Ru–NO stretching vibration and the very intense Ru–N–O deformation vibration are selectively enhanced between 580 and 618 cm^–1, and between 556 and 585 cm^–1, respectively.     

Flow injection-solid phase spectrofluorimetric determination of pyridoxine in presence of group B-vitamins

A flow-through optosensor has been prepared for the sensitive and selective determination of pyridoxine (vitamin B₆) in aqueous solutions. The sensor was developed in conjunction with a monochannel flow-injection analysis system with fluorimetric detection using Sephadex SP-C25 resin as an active sorbent substrate. This method of determination is carried out without any derivatization. The wavelengths of excitation and emission were 295 and 385 nm, respectively. When a HCl (10^–3 mol L^–1) / NaCl (3 × 10^–2 mol L^–1) solution is used as carrier solution, the sensor responds linearly in the measuring range of 5–200, 10–400 and 50–1800 ng mL^–1 with detection limits of 0.33, 0.67, and 5.70 ng mL^–1 for 2000, 1000 and 200 μL of sample volume, respectively. The relative standard deviation for ten independent determinations is less than 0.75% for 0.2 and 1.0 mL of sample volumes used, and 1.31% for 2.0 mL of sample volume used. The method was satisfactorily applied to the determination of vitamin B₆ in pharmaceutical preparations.     

Complexation of divalent metal ions with diols in the presence of anion auxiliary ligands: zinc‐induced oxidation of ethylene glycol to glycolaldehyde by consecutive hydride ion and proton shifts

Ternary complexes of the type AH???M²⁺???L^– (AH = diol, including diethylene and triethylene glycol, M = Ca, Mn, Fe, Co, Ni, Cu and Zn and auxiliary anion ligand L^– = CH₃COO^–, HCOO^– and Cl^–) have been generated in the gas phase by MALDI and ESI, and their dissociation characteristics have been obtained. Use of the auxiliary ligands enables the complexation of AH with the divalent metal ion without AH becoming deprotonated, although A^–???M²⁺ is often also generated in the ion source or after MS/MS. For M = Ca, dissociation occurs to AH + M²⁺???L^– and/or to A^–???M²⁺ + LH, the latter being produced from the H‐shifted isomer A^–???M²⁺???LH. For a given ligand L^–, the intensity ratio of these processes can be interpreted (barring reverse energy barriers) in terms of the quantity PA(A^–) – Ca_aff(A^–), where PA is the proton affinity and Ca_aff is the calcium ion affinity. Deuterium labeling shows that the complex ion HOCH₂CH₂OH???Zn²⁺???^–OOCCH₃, in addition to losing acetic acid (60 Da), also eliminates glycolaldehyde (HOCH₂CH=O, also 60 Da); it is proposed that these reactions commence with a hydride ion shift to produce the ion–dipole complex HOCH₂CHOH⁺??? HZnOOCCH₃, which then undergoes proton transfer and dissociation to HOCH₂CH=O + HZn⁺???O = C(OH)CH₃. In this reaction, ethylene glycol is oxidized by consecutive hydride ion and proton shifts. A minor process leads to loss of the isomeric species HOCH=CHOH. Copyright © 2012 John Wiley & Sons, Ltd.