Sensitive flow-injection method with peroxyoxalate chemiluminescence detection combined with preparative high-performance liquid chromatography for determination of choline-containing phospholipids in human serum

A sensitive and rapid flow-injection analysis (FIA) of total choline-containing phospholipids (PLs) and a selective FIA method for the class assay of choline-containing PLs combined with preparative HPLC were described. The FIA method is based on peroxyoxaxalate chemiluminescence (PO-CL) detection of hydrogen peroxide enzymatically formed from choline-containing PL. The linear standard curves were obtained up to 1 nmol/20-μl injection (r>0.999) with the detection limits of 1.3–1.6 pmol at a signal-to-noise ratio of 2. The total amounts of choline-containing PLs in human serum were ranged from 1.63 to 3.19 mg/ml. The HPLC separation of choline-containing PLs was achieved with an aminopropyl-modified silica gel column using a mixture of acetonitrile-methanol-10 mM ammonium phosphate buffer pH 5.8 as eluent. The eluate corresponding to each choline-containing PL was collected, evaporated, dissolved in 0.1% Triton X-100 aqueous solution, and then injected into FIA system. The FIA method combined with preparative HPLC was applied to the assay of human serum.     

Chemiluminescence determination of hydroperoxides following radiolysis and photolysis of free amino acids

Hydroperoxides were determined in selected amino acids using three free radical generating systems by a sensitive (50 pmol limit of detection) and specific high performance liquid chromatography (HPLC)/chemiluminescence method. UVB and gamma radiation produced significant hydroperoxide formation, particularly in the aromatic amino acids tyrosine and tryptophan. Hydroperoxide yield was found to be dependent on both amino acid and irradiation source. Generation of hydrogen peroxide as a by-product of irradiation caused interference with chemiluminescence detection demonstrating the need for catalase addition. Hydroperoxides were not detectable following metal-catalysed H₂O₂ breakdown. We suggest that metal ions could interfere with the detection of hydroperoxides by causing preferential decomposition.     

Analysis of tamoxifen-DNA adducts by high-performance liquid chromatography using postcolumn online photochemical activation

Tamoxifen, a widely used nonsteroidal antiestrogen in the treatment of breast cancer, forms several metabolites. 4-Hydroxytamoxifen (4-OHTam), a metabolite found in the bloodstream, has much higher affinity for the estrogen receptor than tamoxifen itself. Oxidative activation of 4-OHTam induces DNA damage. DNA isolated from HL-60 cells exposed to 10 microM 4-OHTam in the presence of 1 microM hydrogen peroxide was digested enzymatically to release both normal and modified nucleosides. The modified nucleosides were enriched by butanol extraction. Using UV detection, HPLC analysis of the butanol extract from 200 microg DNA digest detected approximately 4 4-OHTam-dG adducts per 10(7) nucleotides (n = 3). Online postcolumn UV irradiation in HPLC and fluorescence detection improved the detection sensitivity by 3 x 10(2) times. Using 4-OHTam as an example, this report demonstrated for the first time the power of the technique to assay tamoxifen-DNA adducts directly in the DNA digest without relying on postlabeling.     

Observation of the complex formation between Cu(II) and protein by capillary electrophoretic system incorporating an UV/CL dual detector

We investigated the complex formation between Cu(II) and human serum albumin (HSA) through a biuret reaction by use of capillary electrophoretic system incorporating an ultra-violet absorption (UV) and chemiluminescence (CL) dual detector. Cu(II)-tartrate complex and Cu(II)-human serum albumin complex were detected by UV detection (282 nm) with on-capillary, followed by CL detection (luminol-hydrogen peroxide CL reaction) with end-capillary. We examined the effects of the reaction time and temperature on the UV and CL responses. On the basis of the obtained results we considered the Cu(II)-human serum albumin complex formation processes and its catalytic activity for the CL reaction. The system easily, rapidly, and simultaneously produced useful information concerning the complex formation of Cu(II) and human serum albumin due to the presence of the both detectors.     

Optimization of an HPLC peroxyoxalate chemiluminescence detection system for some dansyl amino acids

Bis(2,4,6-trichlorophenyl) oxalate (TCPO)-hydrogen-peroxide-generated chemiluminescence (CL) of four dansyl amino acids has been used as a model system for the optimization of a detection system in reversed-phase high-performance liquid chromatography. Dansylated alanine, glutamic acid, methionine, and norleucine were subjected to peroxyoxalate induced CL in a static system and in a flow system under various conditions with respect to TCPO (ethyl acetate) and hydrogen peroxide (acetone) concentrations, solvent composition and flow, using a two-pump or a one-pump post-column reagent system. From the CL-decay curve, the influence on the emission signal from the total flow rate in the detector was investigated. Special attention was focused on the mixing of the LC eluate and the reagent in order to combine an efficient collection of the emitted light using a 74μI flow cell (originally 10μI in the fluorescence detector) with minimal extra column band broadening. Therefore, a capillary fused-silica tubing of about 100μm i.d. was inserted against the end-frit of the column and brought through a mixing tee, in which the solutions of TCPO and hydrogen peroxide were added. The column end tubing ended in the flow cell and the LC eluate and the reagents were mixed when entering the flow-cell. Average detection limits (S/N=2) of 200fmol injected dansylated amino acid could be reached. A comparison is made between the use of TCPO and DNPO (bis (2, 4-dinitrophenyl) oxalate).     

Flow system for the automatic screening of the effect of phenolic compounds on the luminol–hydrogen peroxide–peroxidase chemiluminescence system

In this work, an automated flow‐based procedure for the screening of the effect of the different phenolic compounds on the chemiluminescence (CL) luminol–hydrogen peroxide–horseradish peroxidase (HRP) system is presented. This procedure involves the combination of multisyringe flow injection analysis (MFSIA) and sequential injection analysis (SIA) techniques and exploits the ability of the different subgroups of phenols, such as cholorophenols, nitrophenols, methylphenols and polyphenols, to enhance or inhibit the described CL system. The implementation of this reaction in the SIA–MSFIA system enabled favourable and precise conditions to evaluate the effect of phenolic compounds, as it involves an in‐line reaction between the phenolic derivative, hydrogen peroxide and peroxidase and subsequent oxidized HRP intermediates generation prior to the fast reaction with the chemiluminogenic reagent. Several studies were then performed with the aim of establishing the appropriate flow system configuration and reaction conditions. It was shown that phenol and chlorophenols produce an enhanced CL response and nitrophenols, methylphenols and polyphenols are inhibitors within the range of concentrations studied (1–100 mg/L). Based on these studies, the developed method was applied to the determination of total polyphenol and phenol content in wine/grape seeds and water samples, respectively, and the results obtained showed good agreement with those furnished by the corresponding Folin–Ciocalteu and 4‐aminoantipyrine reference methods. The developed approach is further pursued by designing an automated generic tool for performing studies of peroxidase‐catalysed CL reactions of luminol focused on the detection of compounds that will affect the rate of those reactions. Copyright © 2011 John Wiley & Sons, Ltd.     

Diversity of bacterial capabilities in utilizing alkylated benzenes and other aromatic compounds

E. LANG. 1996. Seventeen aerobic bacterial strains known to degrade one or more aromatic compounds were tested for their ability to utilize benzene, seven different methylated benzenes or other aromatic compounds as their sole source of carbon. The results are discussed with respect to the possibility of finding strains which degrade one or more of these compounds by the applied method of screening, and to their taxonomic status.     

Photographic detection of fluorescent-labelled oligodeoxynucleotide in the blotting format by peroxyoxalate chemiluminescence

The preparation of a fluorescent labelled oligonucleotide and its photographic detection by peroxyoxalate chemiluminescence (PO-CL) are described. Fluorescent labelling of an oligonucleotide (15-mer) was performed with naphthalene-2,3-dicarboxaldehyde to give an N-substituted 1-cyanobenz[f]isoindole (CBI) derivative (CBI-15-mer). For the photographic detection of CBI-15-mer, the bis(2,6-difluorophenyl) oxalate (DFPO)-dimethyl phthalate (DMP) system was selected to obtain a long-lived CL emission. After optimizing the conditions for the CL reaction, the system was applied to the photographic detection, and as little as 250 fmol per spot of CBI-15-mer on a membrane were detected as a visible spot with an instant photographic film. © 1998 John Wiley & Sons, Ltd.     

Ozone-3,6-dihydroxynaphtha-2,7-disulphonate chemiluminescence system is used for online ozone detection

The chemiluminescence (CL) reaction between ozone and 3,6-dihydroxynaphtha-2,7-disulphonate (DNDS) was found under alkaline conditions. Therefore, a novel CL system for ozone detection was established. The CL signal of the CL system is weak, and the CL signal is enhanced by adding nonionic surfactants. It was found that adding 16.4 g/l Triton X-100 can enhance the CL signal. The CL reagent activated by ultraviolet (UV) light produced a CL signal was nearly 10 times stronger than the CL reagent not activated by UV light; the CL signal was enhanced by adding 8 g/l NaHCO₃ to the CL reagent irradiated by UV light. Through the optimization of these test conditions, a high-selectivity, high-sensitivity online detection method for ozone CL was established. The linear range was 0.5–150 ppbv, and the limit of detection (LOD) was 0.092 ppbv (S/N = 3).     

Natural catalyst for luminol chemiluminescence: application to validate peroxide levels in commercial hair dyes

Here, we report a hydrothermally treated green leaves (Moringa oleifera) extract exploited as an efficient and highly sensitive catalyst to catalyze the chemiluminescence (CL) reaction of luminol. In the absence of enhancer, this green and hydrothermally treated catalyst was found to significantly enhance the CL intensity ~3.5-fold compared with the traditionally used K₃Fe(CN)₆ catalyst. The structure and surface morphology of the catalyst was elucidated using X-ray photoelectron spectroscopy, scanning electron microscopy, X-ray diffraction, and Raman spectroscopy. The synergistic effect of the catalyst in the CL reaction was systematically investigated in the presence of hydrogen peroxide using ultraviolet–visible and CL spectroscopy. Studies showed that the sensitivity of the catalyst could be amplified by adjusting several parameters such as pH of the medium and concentrations of the base and luminol. The sensitivity of the novel-type catalyst was examined through the validation of hydrogen peroxide levels in commercial hair dye samples. Markedly, the catalyst displayed ultrasensitivity to hydrogen peroxide as the limit of detection of hydrogen peroxide using this catalyst was determined to be 0.02 μM under optimized conditions. In general, the proposed inexpensive, ecofriendly, and nontoxic catalyst could enable the determination of hydrogen peroxide for diverse analytical applications.     

Analysis of Hydrogen Peroxide in an Aqueous Extract of Cigarette Smoke and Effect of pH on the Yield

An analysis of hydrogen peroxide in an aqueous extract of cigarette smoke, which contains many redox-active compounds, requires a method with high selectivity. An aqueous extract of the particulate phase of cigarette smoke was analyzed by HPLC with an electrochemical detector (ECD). Samples were prepared by collecting the particulate phase of the cigarette smoke on a glass fiber filter and extracting it with a phosphate buffer. The obtained solution was purified by using a Waters Oasis MCX cation-exchange cartridge, and then analyzed by an HPLC-ECD system with a Shodex KS-801 mixed-mode resin column. Pre-injecting hydrogen peroxide at a high concentration into the HPLC instrument stabilized the analytical results. The recovery of hydrogen peroxide by using an extract of the particulate phase of the cigarette smoke was more than 80%. An increase in the amount of hydrogen peroxide was observed during extraction with the phosphate buffer at higher pH values. In contrast, extraction with phosphoric acid did not increase the amount of hydrogen peroxide during extraction.     

Acetylcholine and Choline in Neuronal Tissue Measured by HPLC with Electrochemical Detection

Abstract: A simple, rapid method is presented for the determination of acetylcholine (ACh) and choline (Ch) in neuronal tissue using HPLC with electrochemical detection. The method is based on the separation of ACh and Ch by reverse-phase HPLC and mixing the effluent as it emerges from the column with acetylcholinesterase and Ch oxidase, which converts endogenous Ch and Ch produced by the hydrolysis of ACh to betaine and hydrogen peroxide. Production of hydrogen peroxide is continuously monitored electrochemically. The sensitivity of the procedure is 1 pmol for Ch and 2 pmol for ACh. Specificity of the method is based on HPLC, two specific enzymatic reactions, and the detection of hydrogen peroxide.     

Chemiluminescent derivatization of adenyl compounds with glyoxal derivatives in the presence of heteropoly acids and its application to the simple and sensitive determination of DNA

A chemiluminescence (CL) determination of adenyl compounds is described. CL derivatization of adenyl compounds with methylglyoxal dimethyl acetal was performed in the presence of tungstosilicic acid and propan-2-ol. CL from adenyl compounds was produced by hydrogen peroxide and L -cysteine ethyl ester in DMF and water. The proposed method is highly sensitive and specific to compounds containing adenine. Adenine was determined in the range 1.0 × 10⁻³ −5.0 × 10⁻⁸ M with the detection limit of 3.0 × 10⁻⁸ M (150 fmol per assay). The method was applied to the determination of DNA and detection limits of a few nanograms of DNA achieved. © 1998 John Wiley & Sons, Ltd.     

Peroxide induced chemiluminescence in an in vitro proline hydroxylation system.

This communication describes a hydrogen peroxide (HOOH) induced chemiluminescence (CL) in an in vitro aromatic (proline) hydroxylation system. The reactive components of the system are ascorbic (AA), ethylene diamine tetraacetic disodium salt (EDTA), ferrous sulfate, and HOOH. The CL is (1) nearly dissipated within three minutes, (2) enhanced and/or sustained by proline and polylysine to a greater degree than by alanine, (3) partially inhibited by a,a' dipyridyl, EDTA, and ethanol, (4) most dependent upon the presence of Fe2+, AA, and HOOH. The in vitro proline hydroxylation system is more effective than ground state oxygen in terms of the CL produced and the percent of hydroxyproline formed.     

Development of a FIA system with immobilized enzymes for specific post-column detection of purine bases and their nucleosides separated by HPLC column.

A sensitive and highly selective method for the simultaneous determination of purine bases and their nucleosides is proposed. An amperometric flow-injection system with the two immobilized enzyme reactors (guanase immobilized reactor and purine nucleoside phosphorylase/xanthine oxidase co-immobilized reactor) is used as the specific post-column detection system of HPLC, to convert compounds separated by a reversed-phase. HPLC column to electroactive species (hydrogen peroxide and uric acid) which can be detected at a flow-through platinum electrode. The proposed detection system is specific for a group of purine bases and purine nucleosides and does not respond for purine nucleotides and pyrimidine bases. The linear determination ranges are from 10 pmol to 5 nmol for four purine bases (hypoxanthine, xanthine, guanine, and adenine) and four purine nucleosides (inosine, xanthosine, guanosine, and adenosine). The detection limits are 1.2-5.5 pmol.     

Oxidized phospholipids as biomarkers of tissue and cell damage with a focus on cardiolipin

Oxidized phospholipid species are important, biologically relevant, lipid signaling molecules that usually exist in low abundance in biological tissues. Along with their inherent stability issues, these oxidized lipids present themselves as a challenge in their detection and identification. Often times, oxidized lipid species can co-chromatograph with non-oxidized species making the detection of the former extremely difficult, even with the use of mass spectrometry. In this study, a normal-phase and reverse-phase two dimensional high performance liquid chromatography (HPLC)-mass spectrometric system was applied to separate oxidized phospholipids from their non-oxidized counterparts, allowing unambiguous detection in a total lipid extract. We have utilized bovine heart cardiolipin as well as commercially available tetralinoleoyl cardiolipin oxidized with cytochrome c (cyt c) and hydrogen peroxide as well as with lipoxygenase to test the separation power of the system. Our findings indicate that oxidized species of not only cardiolipin, but other phospholipid species, can be effectively separated from their non-oxidized counterparts in this two dimensional system. We utilized three types of biological tissues and oxidative insults, namely rotenone treatment of lymphocytes to induce mitochondrial damage and cell death, pulmonary inhalation exposure to single walled carbon nanotubes, as well as total body irradiation, in order to identify cardiolipin oxidation products, critical to the cell damage/cell death pathways in these tissues following cellular stress/injury. Our results indicate that selective cardiolipin (CL) oxidation is a result of a non-random free radical process. In addition, we assessed the ability of the system to identify CL oxidation products in the brain, a tissue known for its extreme complexity and diversity of CL species. The ability of the two dimensional HPLC-mass spectrometric system to detect and characterize oxidized lipid products will allow new studies to be formulated to probe the answers to biologically important questions with regard to oxidative lipidomics and cellular insult. This article is part of a Special Issue entitled: Oxidized phospholipids - their properties and interactions with proteins.     

A highly sensitive and temporal visualization system for gaseous ethanol with chemiluminescence enhancer

A two‐dimensional gaseous ethanol visualization system has been developed and demonstrated using a horseradish peroxidase–luminol–hydrogen peroxide system with high‐purity luminol solution and a chemiluminescence (CL) enhancer. This system measures ethanol concentrations as intensities of CL via the luminol reaction. CL was emitted when the gaseous ethanol was injected onto an enzyme‐immobilized membrane, which was employed as a screen for two‐dimensional gas visualization. The average intensity of CL on the substrate was linearly related to the concentration of standard ethanol gas. These results were compared with the CL intensity of the CCD camera recording image in the visualization system. This system is available for gas components not only for spatial but also for temporal analysis in real time. A high‐purity sodium salt HG solution (L‐HG) instead of standard luminol solution and an enhancer, eosin Y (EY) solution, were adapted for improvement of CL intensity of the system. The visualization of gaseous ethanol was achieved at a detection limit of 3 ppm at optimized concentrations of L‐HG solution and EY. Copyright © 2011 John Wiley & Sons, Ltd.     

Formation of Nitrated and Hydroxylated Aromatic Compounds from Benzene and Peroxynitrite, A Possible Mechanism of Benzene Genotoxicity

Peroxynitrite, the reaction product of nitric oxide (NO*) and superoxide anion (O*-) produced during immune activation by a variety of inflammatory cells, may contribute to genotoxicity of benzene through its ability to carry out hydroxylation and nitration. After exposure of benzene to synthesised peroxynitrite, phenol, nitrophenols (p-nitrophenol, o-nitrophenol and m-nitrophenol) and nitrobenzene were identified in the reaction mixture by HPLC separation and single UV wavelength and diode array detection. The formation of phenol, nitrophenols and nitrobenzene showed a linear relationship with both benzene and peroxynitrite concentrations. The molar ratio for phenol/(nitrobenzene and nitrophenols) was approximately 9/5 with a total product yield of 14% hydroxylated and nitrated products as based on peroxynitrite. The physiological relevance of the chemical reaction between benzene and peroxynitrite was tested by detecting the reaction products in human neutrophils (2.5 ± 10⁷ cells/ml) incubated with 10 mM benzene for 25 min. The concentration of phenol and p-nitrophenol were found to be 1.29 ± 0.22 and 1.56 ± 0.61 μM mean ± SD) in the incubation medium of the neutrophils pretreated with phorbol myristate acetate (500 nM) for 5 min, respectively, whereas no metabolites were detected if the neutrophils were not pretreated. Nitrated aromatic compounds are known to be more carcinogenic than the parent compounds. It is reported that acute and chronic infection increases the risk of cancer at various sites; and that anti-inflammatory agents decrease benzene myelotoxicity. We suggest that the increased production of peroxynitrite during chronic inflammation combined with benzene exposure may increase the carcinogenicity of benzene by a mechanism that includes the formation of metabolites from the chemical reaction between benzene and peroxynitrite. Thus, peroxynitrite mediated hydroxylation and nitration of benzene during immune activation represent a novel in vivo mechanism for generation of proximal carcinogens of benzene.     

A novel chemiluminescent flow injection analysis of trace amounts of rutin by its inhibition of the luminol–hydrogen peroxide reaction catalyzed by tetrasulfonated colbalt phthalocyanine

Based on the inhibition effect of rutin on the luminol–hydrogen peroxide chemiluminescence (CL) system catalyzed by tetrasulfonated colbalt phthalocyanine (CoTSPc), a sensitive flow‐injection CL method has been developed for the determination of rutin. The CL reaction mechanism was carefully investigated by examining CL emission spectra, UV–visible spectra and variation of reaction conditions. It was found that there existed a linear relationship between CL intensity and the concentration of rutin in the range of 8.0 × 10^?9 to 1.0 × 10^?6 mol L^?1, and the detection limit is 3.8 × 10^?9 mol L^?1. This proposed method is sensitive, convenient and simple, and has been applied to the determination of rutin in commercial rutin tablets with satisfactory results. Copyright © 2009 John Wiley & Sons, Ltd.     

Formation of hydrogen peroxide by VUV-photolysis of water and aqueous solutions with methanol

The hydrogen peroxide production upon vacuum ultraviolet (VUV) irradiation of water is reviewed, because published results from the last 10 years lead to conflicting mechanistic interpretations. This work confirms that in pure water, hydrogen peroxide is only produced in the presence of molecular oxygen. Mechanistic schemes explain these findings and confirm earlier statements that recombination of hydroxyl radicals is kinetically disfavoured. In agreement with other recent publications, this work confirms that enhanced hydrogen peroxide production takes place upon VUV irradiation of aqueous solutions of organic compounds. For these investigations, methanol was chosen as an organic model compound. During photolyses, hydrogen peroxide, dissolved molecular oxygen, pH-value of the reaction system, methanol and its products of oxidative degradation were analyzed, and kinetic studies were undertaken to explain the evolution of the concentrations of these components.