A revised method for the spectrophotometric determination of glyoxylic acid

The spectrophotometric determination of glyoxylic acid at 520 nm based on formation of the 1,5-diphenyl formazan derivative is revised. The colour can be developed at room temperature if the acid or its sodium salt is pure. The molar absorptivity is improved to 32 250 l mol^?1 cm^?1. The differences from the earlier procedures are discussed.     

Use of 2,4-dinitrophenylhydrazone of glyoxylic acid for the determination of glyoxylic acid by the chromatographic-spectrophotometric method and by differential pulse polarography

Two different methods (one based on chromatography and spectrophotometry and the other on polarography) have been developed for the determination of glyoxylic acid in the form of a derivative with 2,4-dinitrophenylhydrazine (DNPHGA). The TLC method allows the separation of two DNPHGA isomers (trans and cis). Spectrophotometric measurements of the eluents of the separated compounds (=360 nm) allow the determination of GA within the range from 4 to 30 g. Using differential pulse polarography, the conditions of DNPHGA formation were examined. The reduction peak of this derivative (E_P=–0.430 V), observed by dpp, was used to develop a polarographic determination of GA within the concentration range from 110^-4 to 710^–4 mol/l.     

Use of 2,4-dinitrophenylhydrazone of glyoxylic acid for the determination of glyoxylic acid by the chromatographic-spectrophotometric method and by differential pulse polarography

Two different methods (one based on chromatography and spectrophotometry and the other on polarography) have been developed for the determination of glyoxylic acid in the form of a derivative with 2,4-dinitrophenylhydrazine (DNPH. GA). The TLC method allows the separation of two DNPH. GA isomers ("trans" and "cis"). Spectrophotometric measurements of the eluents of the separated compounds (lambda=360 nm) allow the determination of GA within the range from 4 to 30 microg. Using differential pulse polarography, the conditions of DNPH. GA formation were examined. The reduction peak of this derivative (E(P)=-0.430 V), observed by dpp, was used to develop a polarographic determination of GA within the concentration range from 1.10(-4) to 7.10(-4) mol/l.     

A new chemiluminescence method for the determination of nickel ion

A new chemiluminescence (CL) phenomenon described as the second-chemiluminescence (SCL) was observed and a strong CL signal was detected, when Ni(II) ion was injected into the mixture after the end of the reaction of potassium permanganate with alkaline luminol. The possible CL mechanism is proposed based on the kinetic curve of the CL reaction, CL spectra, UV-vis spectra and some other experiments. A flow-injection analysis for the determination of nickle(II) ion has been developed, based on the catalysis of nickel(II) ion on the CL reaction between potassium manganate produced on-line and luminol under alkaline condition. Under the optimum conditions, the SCL intensity is linear with the concentration of nickel(II) ion in the range of 8.0-200.0 microg l-1 and 0.2-2.0 mg l-1. The R.S.D. was 4.5% for 11 determinations of 250 microg l-1 nickel(II) ion and the detection limit (3sigma) for nickel(II) ion was 0.33 microg l-1. The method was applied to determine nickel(II) ion in synthetic samples with satisfactory results.     

A method for measuring semi- and non-volatile organic halogens by combustion ion chromatography

Recent studies have shown that various semi- and non-volatile organohalogen compounds are ubiquitous in the environment: these include halogenated dioxins including chlorinated dioxins, other persistent organic pollutants (POPs), brominated flame retardants (BFRs), and perfluorooctane sulfonate (PFOS). However, monitoring and assessment of these compounds by the analyses of individual compounds and their isomers is onerous because of their low environmental concentrations and large number of compounds. In this study, we have developed a new method that is capable of screening and monitoring an array of organohalogen compounds efficiently by combustion ion chromatography (CIC) - the new analyzer that serially connects combustion furnace and ion chromatograph. Analyzer performance was evaluated in terms of its applicability, reproducibility, and sensitivity as limit of detection (LOD). Recoveries of organochlorine, organobromine, and organoiodine compounds by the CIC were between 97 and 105%; those of organofluorine compounds were from 86 to 91%. In all cases, the relative standard deviation of five analyses was 4% or smaller. The analyzer would exhibit good sensitivity for various environmental matrices (e.g., 2.8-31ng-X/g-soil, 1.4-16ng-X/L-water, and 9.2-100ng-X/m3N-gas). The method is fast and can provide information regarding the occurrence of organohalogen compounds within 1 or 2 days after sampling. Applicability of the new method for the assessment of contamination in flue gas and fly ash was also demonstrated. Our results show that the method is efficient to investigate emission sources and areas contaminated by organohalogen compounds.     

A new method for the determination of oxygen in organic compounds

Oxygen in compounds of carbon, hydrogen, and oxygen can be determined by heating the sample with an excess of strontium oxide and graphite in. a nickel bomb or sealed Vycor glass tube. During the heating period, three hours at 650° C, the oxygen of the sample is converted to carbonate. The carbonate is then determined volumetrically. The accuracy of the method was found to be ± 0.3% (absolute percentage error) for several types of compounds. Most elements other than carbon, hydrogen, and oxygen interfere. Compounds like phenol, that are exceedingly resistant to complete pyrolysis, yield low resuilts. Carbon in organic compounds can be determined by heating the sample with barium nitrate, and subsequently determining carbonate in the mixture.     

A new method for the titrimetric determination of the ferricyanide ion

The direct titration of ferricyanide ions with the mercurous-thiocyanate system is studied, the influence of pH, thiocyanate concentration, time and temperature being considered. The standard deviation of the proposed method is 0.26 per cent.     

A method for determination of selenium in organic tissues using microwave digestion and liquid chromatography

An existing laboratory procedure for selenium analysis using open-vessel wet digestion and liquid chromatographic fluorescence determination was modified for use with microwave digestion. The proposed microwave digestion method eliminated the hazards associated with the use of HClO4 while maintaining excellent recoveries of selenium. A 2-step HNO3/H2O2 digestion procedure was developed. Digested samples were derivatized with 2,3-diaminonaphthalene, and the resultant piazselenol complex was measured fluorometrically using a liquid chromatograph. Measured values were in agreement with 9 different certified reference materials. The detection limit for this method was 0.54 ng Se/g tissue (3 sigma), and the calibration curve remained linear (r2 = 0.9968) up to 2 microg Se/g.     

Development and optimization of organic acid analysis in tobacco with ion chromatography and suppressed conductivity detection

With the aid of a central composite face-centered design, an ion chromatographic method was developed and optimized for analyzing organic acids in tobacco. A Dionex-100 ion chromatograph with an ion suppressor and a conductivity detector, and a Bio-Rad Aminex HPX-87H column were employed. Only 13 analyses were required to optimize two factors: column temperature and eluent strength. Two sets of optimal conditions for separating nine acids were found: 1.8 mM HFBA eluent and 42 °C column temperature, and 0.8 mM HFBA eluent and 50 °C column temperature. The flow-rate was 0.6 ml min⁻¹ and the analysis time was 18 min or less. A sample preparation procedure included extraction of 2 g ground tobacco with 100 ml of 5 mM sulfuric acid solution for 3 h, filtration of the extract, and dilution of the filtrate 10-fold with deionized water.     

A simple ion chromatography method for inorganic anion analysis in edible seaweeds

A new, simple, fast and sensitive ion chromatography (IC) method, for the simultaneous analysis of fluoride, chloride, nitrite, bromide, nitrate, phosphate and sulphate in edible seaweeds was developed and reported for the first time. The validation of the analytical method was studied in terms of linearity, sensitivity, precision and accuracy. All standard calibration curves showed very good correlation between anion peak area and concentration (r > 0.999). Limits of detection and quantitation ranged between 0.002-0.05 mg/L and 0.01-0.1 mg/L, respectively and indicated the high sensitivity of the method. Relative standard deviation values of repeatability and inter-day precision for standard anions with the same sample were less than 2%. Anion recoveries ranged from 97 to 113% for chloride and from 87 to 105% for sulphate, respectively and showed the fairly good accuracy of the method. The method was applied to the analysis of inorganic anions in brown and red edible seaweeds. Brown seaweeds were characterized by higher chloride content up to 33.7-36.9%, while red seaweeds were characterized by higher sulphate content (45-57%). Sulphate content in seaweeds is related to the presence of sulphated polysaccharides of biological importance. The method developed was well applicable to mineral anion analysis in edible seaweeds and shows suitability and reliability of use in other food samples of nutritional importance.     

Spectrophotometric determination of oxalic acid in presence of glyoxylic acid and chloride

Glyoxylic acid gives a yellow 1:1 complex, [FeCHOCOO]²⁺ with iron(III). The dissociation contant, measured by two spectrophotometric methods, is K = 9.7 ± 1 mol l^?1. Oxalic acid gives two complexes with iron(III) which absorb in the same range around 400 nm. With appropriate precautions and corrections, oxalic acid concentrations of about 10^?1–10^?2 M can be determined in the presence of glyoxylic acid and chloride.     

Developments in suppressor technology for inorganic ion analysis by ion chromatography using conductivity detection

A review is presented detailing the development and use of suppression devices for the conductimetric detection of inorganic ions by ion chromatography (IC). An overview of the general response equation for conductivity detection is also given. Topics of discussion include the role and function of suppressors, the development of early suppressors including packed column and membrane devices from 1975 to 1990 and the subsequent progression towards present day commercially available suppressors and recent innovations. Post-suppression devices for signal enhancement are also discussed.     

Simultaneous determination of carbohydrates and organic acids in beer and wine by ion chromatography

The simultaneous determination of mono-organic acids and carbohydrates by ion chromatography with both conductometric and pulsed amperometric detection is described. The carbohydrates, such as mannitol, arabinose, glucose, fructose, lactose, sucrose, raffinose, and maltose, as well as monoorganic acids including acetate, glycolate, formate, pyruvate, and fluoride are separated as anions by ion-exchange chromatography with 0.080 mol/L sodium hydroxide eluent at 1 mL/min within 12 min. Carbohydrates are determined by pulsed amperometric detection and mono-organic acids are determined by suppressed conductivity detection. The species in beverages are determined.     

An anion-exchange high-performance liquid chromatography method coupled to total organic carbon determination for the analysis of water-soluble organic aerosols

The chemical composition of water-soluble organic carbon (WSOC) in atmospheric aerosol particles is largely unexplored, due to the myriad of individual compounds, which has hampered attempts to attain a full characterization at the molecular level. An alternative approach, focusing on the analysis of a few main chemical classes, allowed the quantitative fractionation of WSOC into neutral compounds (NC), mono- and di-acids (MDA) and polyacids (PA) through an anion-exchange liquid chromatographic method. Previous attempts to quantify NC, MDA and PA relied on a low-pressure chromatographic technique using a volatile buffer, followed by total organic carbon (TOC) analysis of the fractions, or alternatively on a faster HPLC-UV method which provided a quantification of the fractions based on empirical relationships between UV signal and TOC concentration. Here, we report an upgraded anion-exchange HPLC technique, allowing direct TOC analysis of the eluted fractions, without any pre-treatment, thus permitting a great simplification of quantitative analysis and preventing sample losses. The new HPLC-TOC methodology, employing completely inorganic eluents shows the same efficiency of the former HPLC-UV method employing organic additives, with the exception of phenolic compounds, which are retained on the column by secondary interactions, and low-molecular weight tricarboxylic acids, which are recovered among MDA. The new anion-exchange liquid chromatographic method can recover a substantial amount (86-100%) of water-soluble organic carbon from atmospheric aerosol extracts, thus allowing a higher retention and fractionation capacity with respect to alternative techniques, like solid phase extraction.     

A new gas chromatography/mass spectrometry method for the simultaneous analysis of target and non-target organic contaminants in waters

In this study we developed a GC–MS method for the analysis of priority pollutants, personal care products (PCPs) and other emerging contaminants in waters using large volume injection with backflushing. Analyses are performed in the SIM/scan mode, so that in addition to the targeted organic contaminants, this method allows the simultaneous screening of non-target compounds. The scan data are analysed using Deconvolution Reporting Software (DRS) which screens the results for 934 organic contaminants. Deconvolution helps identify contaminants that are buried in the chromatogram by co-extracted materials and significantly reduces chromatographic resolution requirements, allowing shorter analysis times. All compounds have locked retention times and we can continually update and extend the mass spectral library including new compounds. Linearity and limits of detection in SIM and full-scan mode were studied. Method detection limits (MDLs) in effluent wastewater ranged in most of the cases from 1 to 36 ng/L in SIM mode and from 4 to 66 ng/L in full-scan mode; while in river water from 0.4 to 14 and 2–29 ng/L in SIM and full-scan mode, respectively. We obtained a linearity of the calibration curves over two orders of magnitude. The method has been applied to the screening of a large number of organic contaminants – not only to a subset of targets – in urban wastewaters from different wastewater treatment plants and also in river waters. Most of the target compounds were detected at concentration levels ranging from 11 to 8697 ng/L and from 7 to 1861 ng/L in effluent wastewater and river waters, respectively. Additionally, a group of 12 new compounds were automatically identified using the AMDIS and NIST libraries. Other compounds, such as the 4-amino musk xylene, a synthetic fragrance metabolite, which was not included in the databases, but has been manually searched in the full-scan chromatograms.     

A new method for handling liquid samples in organic elemental analysis

Summary A method for handling liquid samples in automatic CHN analysis is described. It involves the use of an aluminum pan in which the sample is hermatically sealed by means of a sealing press. Satisfactory results have been obtained with liquids boiling between 35° and 290°.

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Zusammenfassung Zur Einwaage flüssiger Proben für die automatische CHN-Analyse werden Aluminiumschälehen verwendet, die sich mit einer Presse hermetisch verschließen lassen. Zwischen 35 und 290° siedende Flüssigkeiten lassen sich so mit gutem Erfolg analysieren.

     

A new ultra-pressure liquid chromatography method for the determination of biogenic amines in cheese

A fast and reliable ultra-performance liquid chromatography (UPLC™) method for the determination of biogenic amines (ethanolamine, methylamine, agmatine, histamine, dimethylamine, ethylamine, octopamine, pyrrolidine, dopamine, isopropylamine, propylamine, tyramine, putrescine, butylamine, cadaverine, tryptamine, 2-phenylethylamine, 3-methylbutylamine, spermidine, spermine) in cheese was established. After pre-column derivatization with 6-aminoquinolyl-N-hydroxy-succinimidyl carbamate (AQC), 20 primary and secondary biogenic amines were separated on an Acquity™ UPLC™ column (BEH C₁₈, 1.7 μm; 2.1 mm × 50 mm) within 9 min. Limits of detection (mg/100 g cheese) ranged from 0.04 (ethanolamine) to 1.62 (spermine), and limits of quantification were between 0.16 (ethanolamine) and 6.09 (spermine). The UPLC™ method was applied to the analysis of 58 cheese samples as retailed in Austria. About 13.8% of samples had a histamine content above 10 mg/100 g, and 22.4% had a tyramine content above 10 mg/100 g. Moreover, 8.6% of samples had a putrescine or cadaverine content higher than 10 mg/100 g. The total concentration of biogenic amines in two cheese samples was about 194 mg/100 g. Thus, obligatory monitoring of biogenic amines should be considered to ensure quality of cheese in future.     

A new method for simultaneous determination of nitrogen,hydrogen and halogen in organic compounds

Summary A new method for the determination of nitrogen, hydrogen and halogen in organic compounds is described. It is based on flash combustion in a fast stream (100 ml/min) of an automatically generated gas mixture (CO₂+20% O₂). A sample placed in an aluminium capsule and mixed with about 20 mg of V₂O₅ is combusted in the presence of CO₃O₄ coated on porous silica. Rapid gravimetric methods for final determination of hydrogen and halogens and a volumetric method for nitrogen are used. The combustion process has been examined by a rapid photography technique, mass spectrometry and gas chromatography. From an extensive statistical analysis (about 300 analyses) of various compounds containing C, H, O, N, Br, Cl, I and S, the following precision is obtained:s _N=0.03–0.15%;s _H=0.09–0.14%;s=0.07–0.20% absolute. The automation of the final determination of nitrogen and hydrogen has been examined.

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Eine neue Methode zur gleichzeitigen Bestimmung von Stickstoff, Wasserstoff und Halogen in organischen Verbindungen

Zusammenfassung Eine neue Methode zur Bestimmung von Stickstoff, Wasserstoff und Halogen wird beschrieben. Sie beruht auf der Entflammungsmineralisation in einem schnell fließenden (100 cm³/min) automatisch erzeugten Gasgemisch (CO₂+20% O₂). Die Probe wird in einer Aluminiumkapsel mit etwa 20 mg V₂O₅ vermischt und in Gegenwart von CO₃O₄ auf porösem Siliziumdioxid verbrannt. Zur Endbestimmung von Wasserstoff und Halogenen wurden schnelle, gravimetrische Methoden angewandt (die Jodogravimetrie für Halogene), während der Stickstoff gasvolumetrisch erfaßt wird. Zur Überprüfung des Verbrennungsprozesses wurden die Photographie, die Massenspektrometrie und die Gaschromatographie eingesetzt. Statistische Auswertung der Analysenergebnisse (etwa 300 Analysen) für verschiedene C-, H-, O-, N-, Br-, Cl-, J- und S-haltige Verbindungen ergab die folgenden Standardabweichungen:s _N=0,03–0,15 %;s _H=0,09–0,14% unds _X= 0,07–0,20% absolut. Die Möglichkeiten einer Automatisierung der Bestimmungsverfahren von Stickstoff und Wasserstoff wurden geprüft.