Global ETD Search

11	Rapid Detection of Biogenic Amines using Capillary Electrophoresis and Gradient Elution Isotachophoresis Vyas, Chandni Atul January 2010 (has links) The metabolism of amino acids produces important chemical signaling molecules called neurotransmitters, which are responsible for carrying out important actions within the human body. There are approximately one hundred identified neurotransmitters. Neurotransmitter study is important due to their involvement in biological, physiological, pharmacological, and pathological functions. Commonly employed methods for neurotransmitter detection are mainly based upon microdialysis. However, the methods suffer from disadvantages. Microdialysis fails to determine the absolute concentration of analytes and therefore requires it to be tied in with an analytical technique such as high performance liquid chromatography or capillary electrophoresis. Although high performance liquid chromatography is the most powerful analytical technique to date, it necessitates high maintenance and suffers from poor temporal resolution. While capillary electrophoresis affords more rapid separations than high performance liquid chromatography, it suffers from poor concentration limits of detection and requires large sample dilutions of highly conductive samples, such as biological fluids. Consequently, research is focused on detection of various amino acids and neurotransmitters employing novel analytical techniques along with traditional capillary electrophoresis. First, a method was developed using traditional capillary electrophoresis with laser induced fluorescence detection to detect two major excitatory neurotransmitters, glutamate and aspartate in planaria. The method was later applied to detect several biogenic amines using micellar electrokinetic chromatography with laser induced fluorescence detection in planaria to study the effect of feeding on the levels of biogenic amines within individual planaria homogenates. The concentration sensitivity issue of capillary electrophoresis led to the use of a new method for sensitive neurotransmitter measurements, gradient elution isotachophoresis. Gradient elution isotachophoresis is an efficient capillary-based enrichment and separation technique based on balancing hydrodynamic counter-flow against electrophoresis. Enrichment is achieved with the aid of high concentrations of leading electrolyte in the counter-flow solution that creates an ionic interface near the capillary inlet. Discrete electrolyte spacers or carrier ampholyte mixtures are used to separate analyte zones. The method was applied to the enrichment and separation of physiologically relevant concentrations of aspartate and glutamate labeled with dansyl chloride, phenyl isothiocyanate, or carboxyfluorescein, succinimidyl ester in artificial cerebrospinal fluid using ultraviolet absorbance detection. Finally, gradient elution isotachophoresis was combined with capillary zone electrophoresis to eliminate the use of spacers and provide rapid separations and enrichment. The technique was applied for the detection of biogenic amines in a glass microfluidic device. / Chemistry Chemistry, Analytical Biochemistry Neurosciences Amino Acids Capillary Electrophoresis Gradient Elution Isotachophoresis Microfluidics Neurotransmitters Pre-concentration Techniques
12	Electrophoretic focusing in microchannels combined with mass spectrometry : Applications on amyloid beta peptides Mikkonen, Saara January 2016 (has links) Analysis of low-abundance components in small samples remains a challenge within bioanalytical chemistry, and new techniques for sample pretreatments followed by sensitive and informative detection are required. In this thesis, procedures for preconcentration and separation of proteins and peptides in open microchannels fabricated on silicon microchips are presented. Analyte electromigration was induced by applying a voltage along the channel length, and detection was performed either by matrix-assisted laser desorption ionization mass spectrometry (MALDI-MS) within the open channel, or by sampling a nL fraction containing the preconcentrated analytes from the channel for subsequent nano-electrospray ionization- (nESI-) or MALDI-MS. Utilizing solvent evaporation from the open system during sample supply, sample volumes exceeding the 25-75 nL channel volume could be analyzed. For preconcentration/separation of components in the discrete channel volume a lid of inert fluorocarbon liquid was used for evaporation control. In Papers I and II, aqueous, carrier-free solutions of proteins and peptides were analyzed, and the method was successfully applied for fast and simple preconcentration of amyloid beta (Aβ) peptides, related to Alzheimer’s disease. The impact of possible impurities in the analysis of carrier-free solutions was investigated in Paper III with the 1D simulation software GENTRANS, and a method for open-channel isoelectric focusing in a tailor-made pH gradient was developed. The latter approach was used in Paper IV for preconcentration and purification of Aβ peptides after immunoprecipitation from cerebrospinal fluid and blood plasma, followed by MALDI-MS from a micropillar chip. Paper V includes simulations of an isotachophoretic strategy for selective enrichment of Aβ peptides. GENTRANS simulations were used to select the electrolyte composition, and 2D simulations in a geometry suitable for on-chip implementation were performed using COMSOL Multiphysics. / <p>QC 20160930</p> amyloid beta computer simulation electrophoresis electrospray ionization isoelectric focusing isotachophoresis MALDI mass spectrometry microchannel microchip nano-electrospray ionization preconcentration separation
13	Spojení mikro-elektromembránové extrakce s transientní kapilární izotachoforézou pro analýzu léčiv v biologicklých vzorcích / Coupling of micro-electromembrane extraction to transient capillary isotachophoresis for the analysis of drugs in biological samples Lučaj, Martin January 2020 (has links) The diploma thesis is focused on the development of in-line micro-electromembrane extraction (EME) coupled to capillary electrophoresis (CE) for the analysis of selected drugs in body fluids. Up to now, direct coupling of EME to CE has been demonstrated on diluted river samples only [1]. Although the published set-up has been implemented within a commercial CE it suffers from several drawbacks that can have a negative impact on the analysis of samples with higher complexity. The instrumental arrangement presented in this thesis eliminates these deficiencies. The experimental part is based on the optimization of fundamental extraction and separation conditions for the analysis of model basic drugs (nortriptyline, haloperidol, loperamide) with the use of transient isotachophoresis (tITP) principle. The extraction conditions were optimized for electro-driven transport of basic analytes from complex matrices (urine) through free liquid membrane followed by injection step utilized by electrokinetic supercharging (EKS), which focused target analytes into the CE capillary. Optimized conditions have been applied on blood in the form of dry blood spots, which are highly attractive samples in the current clinical analysis. The repeatability of the measurements was
14	DEVELOPMENT AND APPLICATION OF COUNTERFLOW METHODS: GEITP, GEITP-CZE, TGF, and TGDF Davis, Nejea I. January 2011 (has links) Extensive research on amino acids, and even other biochemical assays usually present in low concentration and volume face challenges using known analytical techniques for analysis of traces amounts. Some limiting factors are the achievable efficiency, sensitivity (resulting from instrument limit of detection and/or experimental methods), volume requirement, and total analysis time. Counterflow electrofocusing techniques combining forces of electrophoresis and bulk flow (pressure driven flow and/or electroosmotic flow) provides a basis for the development of alternative detection techniques geared towards improving peak efficiency, sensitivity and time. The work presented gives a vivid description of recently developed capillary counterflow techniques: gradient elution isotachophoresis (GEITP) using UV detection, GEITP coupled to Capillary Zonal Electrophoresis (GEITP-CZE), temperature gradient focusing (TGF), and temperature gradient denaturing focusing (TGDF). A first demonstration of GEITP using UV detection was applied to enrichment and separation of tyrosine and tryptophan under optimized conditions. Primarily, separation is achieved as the result of the difference in electrophoretic velocity of analytes in a discontinuous buffer system. First, a plug of sample is allowed to preconcentrate (or enrich) between high mobility leading electrolyte (LE) and low mobility trailing electrolyte (TE) under controlled hydrodynamic pressure and continuous injection. This preconcentration is initiated outside the capillary in a conductivity bubble. Although analyte focus according to their electrophoretic velocity, the inclusion of spacer molecule in sample matrix was instrumental in achieving separation with tradeoff between analyte resolution and enrichment. Gradient produced results from reduction in pressure as sample is loaded on column. Separation using this technique is a one step process. A hybrid method marking the first successful coupling of GEITP to CZE with laser induced fluorescence detection was used for separation of six fluorescently labeled amino acids (which formulates the Mars-7). An eleven minute separation was achieved under optimized conditions. A proof-of-concept demonstration of TGF with LIF detection showed focusing and separation of fluorescein and carboxyfluorescein dye molecules, and carboxyfluorescein-labeled glutamate and aspartate. The generation of null focusing points along the thermal separation column (set between 80-20oC) was produced in collaboration with continuous sample injection, discontinuous buffer system and balancing of counterflows (electrophoresis and bulk flow). Preliminary results showed stability in instrument. The TGDF method carried out on a TGF apparatus is a modification to the temperature gradient gel electrophoresis and denaturing gradient gel electrophoresis methods. In principle, TGDF primarily achieves focusing and separation on a thermal separation column (set between 20 to 80 oC) as a result of conformational changes. It is currently being developed for the detection and simultaneous separation of single and double stranded DNA. Preliminary results show enrichment of wildtype and mutant synthetic DNA strands (containing twenty-four base pairs in sequence) in different buffer matrices. / Chemistry Chemistry Amino Acids Capillary Zonal Electrophoresis Counterflow Gradient Elution Isotachophoresis Temperature Gradient Denaturing Focusing Temperature Gradient Focusing
15	Caractérisation de petits ions, de (bio)macromolécules et de nanoparticules par les méthodes électrophorétiques : charge effective et dépendance de la mobilité électrophorétique en force ionique / Characterization of small ions, (bio)macromolecules and nanoparticles by electrophoretic methods : effective charge and ionic strength dependence of the electrophoretic mobility Ibrahim, Amal 07 December 2012 (has links) L'objectif principal de cette thèse a été d'étudier et de développer les méthodes électrophorétiques pour la détermination de la charge effective de petits ions, de (bio)macromolécules et de nanoparticules. En effet, la charge effective est un paramètre physico-chimique qui contrôle les interactions électrostatiques et qui permet d'accéder aux taux de condensation des contre-ions dans le cas de polyélectrolytes. Dans une première partie, différents modèles sur la mobilité électrophorétique (Nernst-Einstein, O'Brien-White-Ohshima, Yoon-Kim) ont été comparés pour la détermination de la charge effective à partir des valeurs expérimentales de mobilité électrophorétique et de rayon hydrodynamique. Trois autres méthodes expérimentales basées sur la sensibilité de détection UV en mode indirect, sur la sensibilité de détection en conductimétrie et sur la longueur des zones isotachophorétiques ont été étudiées. Ces méthodes ont été appliquées en particulier à la détermination de la charge effective de dendrimères greffés de la lysine et de polymères utilisés en délivrance de principe actif.Une étude du comportement électrophorétique en fonction de la force ionique nous a mené à proposer une représentation graphique, appelée « slope-plot », permettant de distinguer les solutés en fonction de leur nature (petits ions, polyélectrolytes, nanoparticules). Cette représentation peut s'avérer très utile pour l'optimisation des séparations en électrophorèse capillaire en fonction de la force ionique. / The main objective of this thesis was to study and develop electrophoretic methods for effective charge determination of small ions, (bio)macromolecules and nanoparticles. Effective charge is a physical parameter that controls the electrostatic interactions and allows for the determination of condensed counter-ion fraction in the case of polyelectrolytes. In a first part, different models of electrophoretic mobility (Nernst-Einstein, O'Brien-White-Ohshima, Yoon-Kim) have been compared for effective charge determination from experimental values of electrophoretic mobility and hydrodynamic radius. Three other experimental methods based on the sensitivity of UV detection in indirect mode and in conductivity detection, or on the length of the isotachophoretic zones, were studied. These methods were applied to effective charge determination of dendrigraft poly-L-lysines and on drug delivery polymeric systems. A study of the ionic strength dependence of the electrophoretic mobility leads us to propose a graphical representation, called the slope-plot, allowing for the distinction between solutes according to their nature (small ions, polyelectrolytes, nanopaticles). The slop-plot can also be used for the optimization of electrophoretic separations according to the ionic strength. Charge effective Macromolécules Électrophorèse capillaire Mobilité électrophorétique Isotachophorèse Détection UV en mode indirect Effective charge Macromolecules Capillary electrophoresis Electrophoretic mobility Isotachophoresis Indirect UV detection
16	Nouvelle méthodologie analytique pour l'étude de l'activité antibactérienne des dendrimères greffés de la L-lysine par électrophorèse capillaire. / New analytical methodology for the screening of antibacterial activity of dendrigraft poly-L-lysines by capillary electrophoresis. Oukacine, Farid 09 December 2011 (has links) Ces travaux de thèse ont permis de mettre en œuvre une méthode de criblage de l'activité antibactérienne des dendrimères greffés de la L-lysine (DGL) par électrophorèse capillaire (EC). Le principe de la méthode est basé sur le suivi du profil électrophorétique des bactéries avant et après leur rencontre avec une bande de composé cationique dont on souhaite cribler l'activité. La mise en œuvre de cette méthode a nécessité plusieurs étapes. Dans la première étape, une nouvelle méthodologie permettant la focalisation, la mobilisation et la quantification des bactéries par EC a été développée. Cette méthode a été appliquée pour la quantification de la flore totale dans des eaux naturelles. Dans la seconde étape, plusieurs revêtements neutres de capillaire ont été comparés pour l'analyse simultanée de composés polycationiques et polyanioniques. Dans la dernière partie, la méthodologie de criblage a été mise en œuvre pour l'étude de l'activité des DGL. / In this work, a new analytical methodology has been implemented for the screening of antibacterial activity of dendrigraft poly-L-lysines (DGL) by capillary electrophoresis (CE). The principle of this methodology is based on the monitoring of the electrophoretic profile of bacteria before and after the meeting with a zone containing the cationic compound to be screened. The implementation of this methodology has required several steps. In a first experimental part, a new methodology has been developed for the focalization, mobilization and quantification of bacteria. This focusing mode has been applied for the quantification of bacteria in natural waters. In a second experimental part, several neutral capillary coatings were compared for the simultaneous CE analysis of polyanionic and polycationic compounds. In the last experimental part, the screening of antibacterial activity has been implemented on DGL. Électrophorèse capillaire Bactérie Isotachophorèse Activité antibactérienne Détection UV multi-points Capillary electrophoresis Bacteria Isotachophoresis Field amplified sample injection Antibacterial activity Multiple UV detection points
17	Analysis of Clinically Important Compounds Using Electrophoretic Separation Techniques Coupled to Time-of-Flight Mass Spectrometry Peterson, Zlatuse Durda 16 April 2004 (has links) Capillary electrophoretic (CE) separations were successfully coupled to time-of-flight mass spectrometric (TOFMS) detection for the analysis of three families of biological compounds that act as mediators and/or indicators of disease, namely, catecholamines (dopamine, epinephrine, norepinephrine) and their O-methoxylated metabolites (3-methoxytyramine, norepinephrine, and normetanephrine), indolamines (serotonin, tryptophan, and 5-hydroxytryptophan), and angiotensin peptides. While electrophoretic separation techniques provided high separation efficiency, mass spectrometric detection afforded specificity unsurpassed by other types of detectors. Both catecholamines and indolamines are present in body fluids at concentrations that make it possible for them to be determined by capillary zone electrophoresis coupled to TOFMS without employing any preconcentration scheme beyond sample work up by solid phase extraction (SPE). Using this hyphenated approach, submicromolar levels of catecholamines and metanephrines in normal human urine and indolamines in human plasma were detected after the removal of the analytes from their biological matrices and after preconcentration by SPE on mixed mode cation-exchange sorbents. The CE-TOFMS and SPE methods were individualized for each group of compounds. While catecholamines and metanephrines in urine samples were quantitated using 3,4-dihydroxybenzylamine as an internal standard, deuterated isotopes, considered ideal internal standards, were used for the quantitation of indolamines. Because the angiotensin peptides are present in biological fluids at much lower concentrations than the previous two families of analytes, their analysis required the application of additional preconcentration techniques. In this work, the coupling of either of two types of electrophoretic preconcentration methods - field amplified injection (FAI) and isotachophoresis (ITP) - to capillary zone electrophoresis with both UV and MS detection was evaluated. Using FAI-CE-UV, angiotensins were detected at ~1 nM concentrations. Using similar conditions but TOFMS detection, the detection limits were below 10 nM. ITP was evaluated in both single-column and two-column comprehensive arrangements. The detection limits achieved for the ITP-based techniques were approximately one order of magnitude higher than for the FAI-based preconcentration. While the potential usefulness of these techniques was demonstrated using angiotensins standards, substantial additional research would be required to allow these approaches to be applied to plasma as part of clinical assays. capillary electrophoresis field amplified injection isotachophoresis time-of-flight mass spectrometry electrospray ionization catecholamines dopamine epinephrine norepinephrine metanephrine normetanephrine indolamines serotonin tryptophan 5-hydroxytryptophan angiotensins plasma urine solid phase extraction Biochemistry Chemistry
18	Développement d'une plateforme analytique jetable basée sur l'isochophorèse pour la séparation et la caractérisation isotopique des lanthanides / Development of a micro total analytic system based on isotachophoresis for the separation and characterization of lanthanides Vio, Laurent 06 December 2010 (has links) La caractérisation juste et reproductible en isotopie et en concentration des radioéléments est l’une des thématiques essentielles des laboratoires d’analyse dans le domaine du nucléaire. Afin de minimiser les temps de manipulation en boite à gants des personnels et la production de déchets radioactifs liés à l’analyse de combustibles nucléaires, il est nécessaire de proposer des solutions efficaces et innovantes. Depuis quelques années, la miniaturisation des systèmes séparatifs constitue l’un des axes de développement majeurs de la chimie analytique et ces microsystèmes constituent certainement une des solutions pour répondre aux exigences de l’analyse nucléaire. Ce travail a pour objectif la conception d’une plateforme analytique miniaturisée et à usage unique, dédiée a la séparation des lanthanides, issus des combustibles usés, en amont de leur analyse par spectrométrie de masse. Destiné à remplacer une étape de séparation chromatographique au centre d’un processus analytique de trois étapes, le nouveau protocole basé sur l’isotachophorèse (ITP) doit satisfaire un cahier des charges précis. Les propriétés de complexation des lanthanides ont d’abord été exploitées afin d’obtenir avec un agent chélatant unique et rigoureusement sélectionné, l’acide 2-hydroxy-2-methylbutyrique (HMBA), la sélectivité intra période nécessaire à leur séparation complète par ITP. Basées sur des modèles théoriques existants, des études complémentaires, notamment des paramètres influençant la résolution, ont permis l’amélioration des performances globales du système ainsi que son dimensionnement. Pour réduire drastiquement le volume de déchets liquides secondaires (solutions de rinçage) et la manipulation de matériaux et de matériels radioactifs, le protocole a été implanté sur un microsystème polymérique jetable en COC, spécialement développé pour cette application. Ce microsystème a ensuite été couplé à un spectromètre de masse a multi collection et source à plasma à couplage inductif pour mesurer les rapports isotopiques / The accurate and reproducible characterization of radioactive solutions in isotope composition and concentration is an essential topic for analytical laboratories in the nuclear field. In order to reduce manipulation time in glove box and production of contaminated wastes, it is necessary to propose innovative and efficient solutions for these analyses. Since few years, microchips are a major field of development in analytical chemistry and those devices could provide a solution which fits the needs of nuclear industry. The aim of this work is to design a disposable analytical micro-device devoted to lanthanide separation from spent nuclear fuel before their analysis in mass spectrometry. Designed to be used in place of a separation process by liquid chromatography which is involved in a three step protocol, the new protocol based on isotachophoresis (ITP) keeps compatible with the other two steps. The complete separation of lanthanides by ITP was obtained by the use of only one chelating compound rigorously selected: the 2-hydroxy 2-methyl butyric acid (HMBA). The main parameters involved in solute resolution were defined from the theoretical models of ITP and experimental studies of the influence of these parameters allowed to optimize the geometry of the system and to improve its performances. To suppress cleaning of the system and, consequently, to strongly reduce both liquid waste volume and handling radioactive material, the ITP protocol was transferred in a polymeric (COC) disposable microchip especially developed for this purpose Isotachophorèse (ITP) Lanthanides Combustibles nucléaires usés Microsystèmes analytiques Copolymère d’oléfine cyclique (COC) Couplage ITP/ICP-MS Isotachophoresis (ITP) Lanthanides Spent nuclear fuel Analytical microchips Cyclic olefin copolymer (COC) 2-hydroxy-2-methylbutyric acid (HMBA) Hyphenation ITP/ICP-MS Isotopic ratio on transient signals 543

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