Global ETD Search

1	Determination of biomarkers for lipid peroxidation and oxidative stress : Development of analytical techniques and methods Claeson Bohnstedt, Kristina January 2005 (has links) <p>Oxidative stress can be defined as a state of disturbance in the pro-oxidant/antioxidant balance in favour of the former, leading to potential damage. Processes associated with oxidative stress involve reactive oxygen species and radicals and can result in elevated levels of oxidatively modified or toxic molecules that can cause cellular malfunction, and even cell death. Destruction of membrane lipids, lipid peroxidation, caused by reactive oxygen species and radicals has been coupled to many diseases and also normal ageing. </p><p>The measurement of low molecular weight biomarkers of oxidative stress present in complex matrices such as brain tissue, plasma, urine or cerebrospinal fluid is a delicate and difficult task and there is a need for improved analytical tools in this field of research. </p><p>The major foci of this thesis and the work underlying it are the development of analytical techniques and methods for determining biomarkers for oxidative stress and lipid peroxidation. Aspects of particular concern include the effects of sample treatments prior to analysis, evaluation of the developed methods with respect to possible artefacts, and the scope for results to be misinterpreted. The specific research goals and issues addressed are detailed in five papers, which this thesis is based upon.</p><p><b>Paper I</b> focuses on malondialdehyde, describing and evaluating two new simplified sample pre-treatment regimes for the determination of malondialdehyde in rat brain tissue by capillary electrophoresis with UV detection. The effects of sample storing and handling are also considered.</p><p><b>Paper II</b> describes the synthesis, characterization and implementation of a new internal standard for the determination of malondialdehyde in biological samples using electrophoretic or chromatographic separation techniques. The usefulness of the internal standard is demonstrated in analyses of rat brain tissue samples.</p><p><b>Paper III</b> presents a method for the determination of 4-hydroxynon-2-enal in brain tissue from rats employing micellar electrokinetic chromatography separation and laser-induced fluorescence detection. </p><p><b>Paper IV</b> is focused on the development of a new methodology for determining the stereoisomeric F2-isoprostanes in human urine samples employing chromatographic separation on porous graphitic carbon and detection by electrospray ionization-tandem mass spectrometry. The results from this study conflict with the hypothesis that peripheral isoprostanes are elevated in patients with Alzheimer’s disease.</p><p><b>Paper V</b> describes porous graphitic carbon chromatography-tandem mass spectrometry for the determination of isoprostanes in human cerebrospinal fluid. A new simplified sample pre-treatment regime, involving a column switching technique, is presented that allows direct injection of a relatively large volume of CSF into the chromatographic system.</p> capillary electrophoresis mass spectrometry electrospray porous graphitic carbon oxidative stress lipid peroxidation biomarker malondialdehyde hydroxynonenal isoprostane Analytical chemistry Analytisk kemi
2	Determination of biomarkers for lipid peroxidation and oxidative stress : Development of analytical techniques and methods Claeson Bohnstedt, Kristina January 2005 (has links) Oxidative stress can be defined as a state of disturbance in the pro-oxidant/antioxidant balance in favour of the former, leading to potential damage. Processes associated with oxidative stress involve reactive oxygen species and radicals and can result in elevated levels of oxidatively modified or toxic molecules that can cause cellular malfunction, and even cell death. Destruction of membrane lipids, lipid peroxidation, caused by reactive oxygen species and radicals has been coupled to many diseases and also normal ageing. The measurement of low molecular weight biomarkers of oxidative stress present in complex matrices such as brain tissue, plasma, urine or cerebrospinal fluid is a delicate and difficult task and there is a need for improved analytical tools in this field of research. The major foci of this thesis and the work underlying it are the development of analytical techniques and methods for determining biomarkers for oxidative stress and lipid peroxidation. Aspects of particular concern include the effects of sample treatments prior to analysis, evaluation of the developed methods with respect to possible artefacts, and the scope for results to be misinterpreted. The specific research goals and issues addressed are detailed in five papers, which this thesis is based upon. <b>Paper I</b> focuses on malondialdehyde, describing and evaluating two new simplified sample pre-treatment regimes for the determination of malondialdehyde in rat brain tissue by capillary electrophoresis with UV detection. The effects of sample storing and handling are also considered. <b>Paper II</b> describes the synthesis, characterization and implementation of a new internal standard for the determination of malondialdehyde in biological samples using electrophoretic or chromatographic separation techniques. The usefulness of the internal standard is demonstrated in analyses of rat brain tissue samples. <b>Paper III</b> presents a method for the determination of 4-hydroxynon-2-enal in brain tissue from rats employing micellar electrokinetic chromatography separation and laser-induced fluorescence detection. <b>Paper IV</b> is focused on the development of a new methodology for determining the stereoisomeric F2-isoprostanes in human urine samples employing chromatographic separation on porous graphitic carbon and detection by electrospray ionization-tandem mass spectrometry. The results from this study conflict with the hypothesis that peripheral isoprostanes are elevated in patients with Alzheimer’s disease. <b>Paper V</b> describes porous graphitic carbon chromatography-tandem mass spectrometry for the determination of isoprostanes in human cerebrospinal fluid. A new simplified sample pre-treatment regime, involving a column switching technique, is presented that allows direct injection of a relatively large volume of CSF into the chromatographic system. capillary electrophoresis mass spectrometry electrospray porous graphitic carbon oxidative stress lipid peroxidation biomarker malondialdehyde hydroxynonenal isoprostane Analytical chemistry Analytisk kemi
3	Stratégie analytique des tradimédicaments : établissement de profils chromatographiques des métabolites phytochimiques apolaires / Analytical strategy of traditional herbal medicines : establishing chromatographic profiles of non-polar phytochemical metabolites Bony, Nicaise françois 26 September 2013 (has links) Les médicaments traditionnels à base de plantes (tradimédicaments) sont très utilisés par les populations africaines. Mais leur qualité est difficile à maîtriser, car ce sont des mélanges complexes de plusieurs drogues végétales ou des préparations à base de drogues végétales d’origine souvent inconnue et/ou très variable. Le profil chromatographique des métabolites phytochimiques constitue un outil important pour l’évaluation de la qualité de ces produits.L'objectif de ce travail est de proposer un protocole de préparation des échantillons et d’établissement de profil par chromatographie liquide et chromatographie en phase gazeuse des métabolites apolaires, pour l’évaluation de la qualité des médicaments traditionnels à base de plantes.La méthodologie est basée sur le traitement chimiométrique des profils chromatographiques des métabolites apolaires issus de différents lots de feuilles de Combretum micranthum et Mitracarpus scaber.Le profilage métabolique s’est effectué par chromatographie liquide sur Carbone Graphite Poreux en milieu non-aqueux et par chromatographie en phase gazeuse à haute température, couplées à la spectrométrie de masse, après extraction au dichlorométhane et élimination de la chlorophylle adsorbée sur charbon actif.L'analyse chimiométrique des données utilisant l’analyse PLS-discriminante avec ou sans correction orthogonale du signal, appliquée aux profils chromatographiques des feuilles de Combretum micranthum et Mitracarpus scaber, a montré de faibles différences entre les lots de chaque drogue végétale, et une différenciation claire des deux drogues végétales.Les deux méthodes d'analyse par chromatographie liquide et chromatographie en phase gazeuse permettent de détecter la plupart des métabolites secondaires apolaires bioactifs ou non déjà identifiés dans les feuilles des deux espèces. / The traditional herbal medicines are widely used by African people. But their quality control is difficult, because they are complex mixtures of several herbal drugs or herbal drugs preparations. Their origin is often unknown and/or highly variable. The chromatographic profile of phytochemical metabolites is an important tool for quality assessment of these products.The objective of this work is to propose a protocol for sample preparation and liquid chromatographic and gas chromatographic profiling of non-polar metabolites for quality assessment of africain traditional herbal medicinal products.The methodology is based on the chemometric treatment of chromatographic profiles of non-polar metabolites from different batches of leaves of Combretum micranthum and Mitracarpus scaber.Metabolic profiling is carried out by non-aqueous liquid chromatography on Porous Graphitic Carbon and by high temperature gas chromatography, coupled with mass spectrometry, after extraction with dichloromethane and removal of chlorophyll adsorbed on activated charcoal.The chemometric data analysis using PLS-discriminant analysis with or without orthogonal signal correction applied to the chromatographic profiles of leaves of Combretum micranthum and Mitracarpus scaber showed small differences between batches of each herbal drug, and a clear differentiation two herbal drugs.Both analyses by liquid chromatography and gas chromatography methods detect most non-polar metabolites bioactive or/not already identified in the leaves of both species. Carbone Graphite Poreux Métabolites apolaires Chimiométrie Combretum micranthum Mitracarpus scaber Porous Graphitic Carbon Non-polar metabolites Chemometrics Traditional herbal medicines Combretum micranthum Mitracarpus scaber
4	Aspects of Porous Graphitic Carbon as Packing Material in Capillary Liquid Chromatography Törnkvist, Anna January 2003 (has links) <p>In this thesis, porous graphitic carbon (PGC) has been used as packing material in packed capillary liquid chromatography. The unique chromatographic properties of PGC has been studied in some detail and applied to different analytical challenges using both electrospray ionization-mass spectrometry (ESI-MS) and ultra violet (UV) absorbance detection. </p><p>The crucial importance of disengaging the conductive PGC chromatographic separation media from the high voltage mass spectrometric interface has been shown. In the absence of a grounded point between the column and ESI emitter, a current through the column was present, and changed retention behaviors for 3-O-methyl-DOPA and tyrosine were observed. An alteration of the chromatographic properties was also seen when PGC was chemically oxidized with permanganate, possibly due to an oxidation of the few surface groups present on the PGC material. </p><p>The dynamic adsorption of the chiral selector lasalocid onto the PGC support resulted in a useful and stable chiral stationary phase. Extraordinary enantioselectivity was observed for 1-(1-naphthyl)ethylamine, and enantioseparation was also achieved for other amines, amino acids, acids and alcohols. </p><p>Finally, a new strategy for separation of small biologically active compounds in plasma and brain tissue has been developed. With PGC as stationary phase it was possible to utilize a mobile phase of high content of organic modifier, without the addition of ion-pairing agents, and still selectively separate the analytes. </p> Analytical chemistry PGC porous graphitic carbon stationary phase packing material LC liquid chromatography miniaturized chiral enantiomer ESI electrospray ionization mass spectrometry polar compounds L-DOPA dopamine biological samples biological matrix Analytisk kemi PGC poröst grafitiserat kol stationärfas packningsmaterial LC vätskekromatografi miniatyriserade system kiral enantiomer ESI electrospray jonisation mass spektrometri polära föreningar L-DOPA dopmamine biologiska prover biologisk matris Analytical chemistry Analytisk kemi
5	Aspects of Porous Graphitic Carbon as Packing Material in Capillary Liquid Chromatography Törnkvist, Anna January 2003 (has links) In this thesis, porous graphitic carbon (PGC) has been used as packing material in packed capillary liquid chromatography. The unique chromatographic properties of PGC has been studied in some detail and applied to different analytical challenges using both electrospray ionization-mass spectrometry (ESI-MS) and ultra violet (UV) absorbance detection. The crucial importance of disengaging the conductive PGC chromatographic separation media from the high voltage mass spectrometric interface has been shown. In the absence of a grounded point between the column and ESI emitter, a current through the column was present, and changed retention behaviors for 3-O-methyl-DOPA and tyrosine were observed. An alteration of the chromatographic properties was also seen when PGC was chemically oxidized with permanganate, possibly due to an oxidation of the few surface groups present on the PGC material. The dynamic adsorption of the chiral selector lasalocid onto the PGC support resulted in a useful and stable chiral stationary phase. Extraordinary enantioselectivity was observed for 1-(1-naphthyl)ethylamine, and enantioseparation was also achieved for other amines, amino acids, acids and alcohols. Finally, a new strategy for separation of small biologically active compounds in plasma and brain tissue has been developed. With PGC as stationary phase it was possible to utilize a mobile phase of high content of organic modifier, without the addition of ion-pairing agents, and still selectively separate the analytes. Analytical chemistry PGC porous graphitic carbon stationary phase packing material LC liquid chromatography miniaturized chiral enantiomer ESI electrospray ionization mass spectrometry polar compounds L-DOPA dopamine biological samples biological matrix Analytisk kemi PGC poröst grafitiserat kol stationärfas packningsmaterial LC vätskekromatografi miniatyriserade system kiral enantiomer ESI electrospray jonisation mass spektrometri polära föreningar L-DOPA dopmamine biologiska prover biologisk matris Analytical chemistry Analytisk kemi

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