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1	Denatūrantų nustatymas hidrofilinės sąveikos chromatografijos metodu / Determination of denaturants by hydrophilic interaction chromatography Juknaitė, Ina 13 June 2006 (has links) A hydrophilic interaction chromatography (HILIC) technique has been developed and validated for determination of common denaturants (denatonium benzoate, crystal violet and methylene blue) in denaturated alcohol formulations. Among the three different polar stationary phases (i.e., aminopropyl, cyanoethyl and silica) studied the cyanoethyl phase provided much stronger retention for the organic cations. It was shown that high efficiencies were reached only with anionic ion-pairing reagent that reduces the interactions with the silanol groups. The anion ion-pairing strength under HILIC conditions was: acetate < formate << trifluoroacetate < perchlorate. This study also investigated the effect of various experimental factors on the retention of the cyanoethyl stationary phase, such as acetonitrile content, pH, ionic strength, and ion-pairing anion concentration in the mobile phase. The separation of three denaturants was achieved in about 8 min with a mobile phase containing 60% (v/v) acetonitrile and 10 mmol/l HClO4. The proposed method was validated and applied to the determination of danaturating agents in various Lithuanian denaturated alcohol formulations. Chemistry Hydrophilic interaction chromatography Denaturants Hidrofilinės sąveikos chromatografija Denatūrantai
2	Development of Monolithic Stationary phases for Cation-Exchange Capillary Liquid Chromatography of Peptides and Proteins Chen, Xin 22 February 2011 (has links) (PDF) This dissertation focuses on the preparation of polymeric monolithic capillaries for ion exchange chromatography of peptides and proteins, since polymeric monoliths have shown promise for providing improved protein separations. Characteristics of monolithic columns include low back pressure, simplicity of fabrication and biocompatibility. Preparation of strong and weak cation-exchange monolithic stationary phases in 75 μm I.D. capillaries by direct in situ copolymerization was achieved using various functional monomers including sulfopropyl methacrylate, phosphoric acid 2-hydroxyethyl methacrylate, bis[2-(methacryloyloxy)ethyl] phosphate and 2-carboxyethyl acrylate with polyethylene glycol diacrylate and other PEG materials. The resulting monoliths provided excellent ion exchange capillary LC of peptides and proteins with good run-to-run [relative standard deviation (RSD) < 1.99%] and column-to-column (RSD < 5.64%) reproducibilities. Narrow peaks were obtained and peak capacities of over 20 were achieved. Dynamic binding capacities of over 30 mg/mL of column volume for lysozyme were measured. A single monomer was used to synthesize a phosphoric acid containing monolith to improve its stability and reproducibility. The monolith was synthesized from only BMEP in 75 μm I.D. UV transparent fused-silica capillaries by photo-initiated polymerization. A dynamic binding capacity (lysozyme) of approximately 70 mg/mL of column volume was measured. Efficiencies of 52,900 plates/m for peptides and 71,000 plates/m for proteins were obtained under isocratic conditions. Good reproducibilities were achieved. Zwitterionic monolithic columns based on photo-initiated copolymerization of N,N-dimethyl-N-methacryloxyethyl-N-(3-sulfopropyl)ammonium betain and poly(ethylene glycol) diacrylate were prepared in 75 μm I.D. fused silica capillaries for hydrophilic interaction chromatography. Inverse size exclusion chromatography was used to characterize the pore structure of the resulting monolith. A typical hydrophilic interaction chromatography mechanism was observed when the organic content in the mobile phase was higher than 60%. Good separations of amides, phenols, and benzoic acids were achieved. The effects of mobile phase pH, salt concentration, and organic modifier content on retention were investigated. monolith ion exchange hydrophilic interaction liquid chromatography Biochemistry Chemistry
3	INVESTIGATION OF PHENYLEPHRINE SULFATION AND INHIBITION USING A NOVEL HILIC ASSAY METHOD Shah, Heta N 01 January 2015 (has links) Phenylephrine (PE) is the most commonly used over-the-counter nasal decongestant. The problem associated with phenylephrine is that it undergoes extensive first pass metabolism in the intestinal gut wall leading to its poor and variable oral bioavailability. This research project aims at developing strategies in order to increase the oral bioavailability of PE by co-administration of GRAS compounds. A HILIC assay method was developed to detect the parent drug, phenylephrine (PE) and its sulfate metabolite (PES).The enzyme kinetic studies were done with phenolic dietary or GRAS compounds using LS180 human intestinal cell model, recombinant SULT enzymes and human intestinal cytosol (HIC). From the screening studies done, one inhibitor was selected in order to study the mechanism of inhibition. In conclusion the studies done in vitro provided a basis in order to predict in vivo intrinsic clearance through the sulfation pathway. PE (phenylephrine) PES (phenylephrine-3-O-sulfate) Pharmaceutics and Drug Design
4	Investigations of the retention mechanisms in hydrophilic interaction chromatography Dinh, Ngoc Phuoc January 2013 (has links) Hydrophilic interaction chromatography is well known as a powerful technique separation of polar and ionizable compound nowadays. However the retention mechanism of the technique is still under debate. Understanding retention mechanism would facilitate the method development using the technique and its future improvement. This was inspiring and became the goal of this thesis. This work involves the characterization of the water enriched layer regarding to water and buffer salt accumulation. Twelve HILIC stationary phase with a diverse surface chemistry regarding to function groups and modification type were studied. Effect of water and salt on regarding to the retention mechanism was investigated by correlating the adsorption data to the retention of selected solutes This also involved the characterization of interactions involve in the separation of 21 HILIC columns. Interactions was probe by retention ratio of pair solutes which are characteristic for each specific interaction. The data was evaluate using principle component analysis – a multivariable data analysis method. The model was comprehensive and its outcomes were confirmed by the studies on adsorptions of water and salts. HILIC hydrophilic interaction chromatography adsorption isotherm water enriched layer multivariate data analysis retention mechanism separation
5	Simultan kvantifiering av metylmalonsyra och total homocystein : En kombinationsmetod baserad på hydrofil interaktion vätskekromatografi och elektrospray jonisationsmasspektrometri / Determination of methylmalonic acid and total homocysteine in human serum/plasma by hydrophilic interaction liquid chromatography (HILIC) and single-stage electrospray ionization- mass spektrometry (ESI-MS) Palm, Sindy January 2011 (has links) No description available. SeQuant™ ZIC®-HILIC masspektrometri Metylmalonsyra Homocystein B-vitaminbrist TCEP
6	Développement d'une méthode de séparation chromatographique couplée aux spectrométries de masse à source d'ionisation électrospray (ESI-MS) et à source plasma à couplage inductif (ICP-MS) : application à l'analyse de spéciation des lanthanides / Development of a chromatographic separation method hyphenated to electrospray ionization mass spectrometry (ESI-MS) and inductively coupled plasma mass spectrometry (ICP-MS) : application to the lanthanides speciation analysis Beuvier, Ludovic 12 October 2015 (has links) Ces travaux de thèse concernent les développements d'une méthode de séparation chromatographique couplée simultanément à l'ESI-MS et l'ICP-MS afin de réaliser l'analyse de spéciation exhaustive des lanthanides en phase aqueuse représentative des phases de désextraction des procédés de traitement du combustible usé. Cette méthode analytique permet de séparer, caractériser et quantifier des complexes de lanthanides à ligands polyaminocarboxyliques comme le DTPA et l'EDTA, utilisés comme agents complexants dans ces procédés. La méthode de séparation par chromatographie HILIC des complexes de lanthanides a été mise au point avec la phase stationnaire à fonctions amide. Un criblage d'une large gamme de compositions de phase mobile a permis de déterminer que le mécanisme d'adsorption est prédominant lors l'élution des complexes de lanthanides et d'obtenir des conditions de séparation optimisées. Des conditions d'analyse plus rapides obtenues avec une colonne à fonctions amide de granulométrie sub-2 µm et de longueur plus faible ont permis de réduire le temps d'analyse d'un facteur 2,5 et la consommation de solvant de 25 %. La caractérisation structurale et isotopique par HILIC ESI-MS a été réalisée ainsi que la mise au point d'une méthode d'étalonnage externe. Les performances analytiques de la méthode de quantification ont été déterminées. Enfin, le développement d'un système de couplage de l'HILIC à l'ESI-MS et l'ICP-MS a été réalisé. Une méthode de quantification simultanée par ESI-MS et par ICP-MS a permis de déterminer la distribution quantitative des espèces en solution ainsi que les performances analytiques associées. / This work focuses on the development of a chromatographic separation method coupled to both ESI-MS and ICP-MS in order to achieve the comprehensive speciation analysis of lanthanides in aqueous phase representative of back-extraction phases of advanced spent nuclear fuel treatment processes. This analytical method allowed the separation, the characterization and the quantitation of lanthanides complexes holding polyaminocarboxylic ligands, such as DTPA and ETDA, used as complexing agents in these processes. A HILIC separation method of lanthanides complexes has been developed with an amide bonded stationary phase. A screening of a wide range of mobile phase compositions demonstrated that the adsorption mechanism was predominant. This screening allowed also obtaining optimized separation conditions. Faster analysis conditions with shorter amide column packed with sub 2 µm particles reduced analysis time by 2.5 and 25% solvent consumption. Isotopic and structural characterization by HILIC ESI-MS was performed as well as the development of external calibration quantitation method. Analytical performances of quantitation method were determined. Finally, the development of the HILIC coupling to ESI-MS and ICP-MS was achieved. A simultaneous quantitation method by ESI-MS and ICP-MS was performed to determine the species quantitative distribution in solution. Analytical performances of quantitation method were also determined. Spéciation Lanthanides Complexes Hilic Esi-Ms Icp-Ms Lanthanides Speciation Hydrophilic interaction chromatography 541.3
7	DEVELOPMENT OF NOVEL LIQUID CHROMATOGRAPHY STATIONARY PHASES FOR IMPROVED CHARACTERIZATION OF BIOPHARMACEUTICALS Cameron C Schwartz (11209392) 30 July 2021 (has links) Monoclonal antibodies are large, complex biomolecules that can be difficult to characterize. Characterization is important because of the various post translational modifications that can occur during manufacturing, processing, and storage. Some modifications can lead to efficacy and safety issues and therefore are heavily monitored. A leading way to monitor various modifications is by using liquid chromatography. The high sensitivity, reproducibility, and ability to quantitate analytes makes it very attractive for monoclonal antibody characterization. The large molecular size of monoclonal antibodies (150 kDa) makes them challenging to separate efficiently and with high enough resolution to be helpful. New column technologies that would help improve protein separation efficiencies and slectivities would greatly help in this challenging process. In this thesis, three novel bonded phases are developed for the separation of monoclonal antibodies including a weak anion and cation exchanger (WAX, CEX) for the separation of charged species as well as a novel hydrophilic interaction chromatography (HILIC) for the separation of glycoforms. Column develop is achieved by optimizing selectivity and improving efficiency of separations by altering particle surface chemistry. Separation Science chromatography LC separation column Monoclonal Antibody Charge Variants Hydrophilic Interaction Chromatography Ion Exchange Chromatography
8	Polyhydroxyl and Polyphosphorylcholine functionalized Silica for Hydrophilic interaction liquid Chromatography- Synthesis, characterization and application Bui, Nhat Thi Hong January 2012 (has links) This thesis focuses on the development of new stationary phases for use in hydrophilic interaction liquid chromatography using TRIS-based and phosphorylcholine typed monomers and porous silica particles as starting substrates. In this thesis, several ways of polymerizing highly hydrophilic monomers onto pore surfaces of silica supports are described, based on several “grafting from” schemes. “Controlled/living” radical polymerizations including atom transfer radical polymerization (ATRP) and iniferter-mediated polymerization in conjunction with conventional free radical polymerization are demonstrated to be successful tools for grafting different hydrophilic monomers (polyhydroxyl and phosphorylcholine [meth]acrylamide/acrylates) onto the silica surfaces. Reaction solvents are proven to play an essential role to achieve efficient graft polymerization of activated silica surfaces with these amphiphilic vinylic monomers, which is difficult because of their restricted access to the activated surface in solvents that can be used because of solubility constraints. Two tentacle TRIS-based polymer grafted silica, namely TRIS-WAX – TRIS functionality bonded to silica via a C–N–C imine bond and TRIS-Amide – TRIS bonded to silica via an amide bond, prove to be useful as stationary phases for hydrophilic interaction chromatography (HILIC).The TRIS-WAX exhibits a mixed mode hydrophilic partitioning and weak anion exchange (HILIC/WAX) retention mechanism while retention by hydrophilic partitioning is the dominant mechanism on the neutral TRIS-Amide phase which lacks weak anion exchange (WAX) properties. Interestingly, both these phases have selectivities that are radically different from most commercial HILIC stationary phases. Finally, a method is demonstrated for synthesizing a stratified (graft-copolymerized) silica material based on N,N′-methylenebisacrylamide and 2-methacryloyloxyethyl phosphorylcholine (MPC) using a “controlled/living” photoiniferter-mediated polymerization from the N,N-diethyldithiocarbamate iniferter moiety immobilized silica surfaces. This polymerization method proves to be successful for graft-blockcopolymerization of different highly hydrophilic monomers onto the activated surfaces of porous silica. In this way, silica surfaces are grafted with a cross-linked amide-based hydrogel, on top of which a tentacle zwitterionic phosphorylcholine-typed layer is synthesized. The resulted material proves to be useful for HILIC separations and possesses different selectivity for the tested organic acids compared to that of commercial ZIC-cHILIC stationary phase. Hydrophilic Interaction Chromatography HILIC silica TRIS acrylamide/acrylate ATRP iniferter N N′-methylenebisacrylamide MPC stationary phase
9	Développement de nouvelles méthodes séparatives compatibles avec une détection par spectrométrie de masse et par électrochimie pour l'analyse de traces de catécholamines et molécules apparentées / Development of new chromatographic methods compatibles with mass spectrometric detection and electrochemical detection for catecholamines and related molecules Chirita, Raluca-Ioana 27 November 2009 (has links) Les catécholamines et les indolamines font partie de la famille des neurotransmetteurs. Un déséquilibre dans leur concentration peut être associé à différentes maladies telles les maladies de Parkinson et Alzheimer, la dépression ou la schizophrénie. C’est pourquoi le développement de méthodes de dosage spécifiques et très sensibles du fait de leurs très faibles teneurs dans les fluides biologiques est nécessaire. Dans un premier temps nous avons développé une méthode chromatographique en appariement d’ions (IP-LC) utilisant des colonnes C18 de nouvelle génération (monolithique et « fused core ») et l’acide nonafluoropentanoïque, comme agent d’appariement d’ions volatil. Cette méthode est compatible avec une détection SM en mode d’ionisation positive. Dans un deuxième temps, différents systèmes en mode HILIC ont été évalués. Le choix raisonné de la phase stationnaire offrant la meilleure séparation du mélange de catécholamines a pu être réalisé après avoir testé l’influence sur la séparation des différents groupements fonctionnels disponibles : groupement soit neutre (greffage diol, amide, ou cyano), soit positivement chargé (greffage amino ou triazole) soit négativement chargé (silice vierge avec particules totalement poreuses ou partiellement poreuses « fused core ») ou zwitterionique (greffage sulfobetaïne). La méthode HILIC présente l’avantage d’être compatible aussi bien avec une détection SM en mode d’ionisation positive que négative. Les deux méthodes (IP-LC et HILIC) ont été comparées en termes de résolution, efficacité et limites de détection (LOD), linéarité et répétabilité. Les LODs obtenues sont comprises entre 1 et 100 ng.mL-1. Pour pouvoir doser des teneurs plus faibles, une méthode de pré-concentration de l’échantillon a été développée en associant 2 supports différents (Oasis HLB et PGC). La méthode optimisée SPE-CPL-MS/MS a été enfin appliquée à un extrait de cerveau de mouton. / As neurotransmitters, catecholamines play an important role in the control and regulation of numerous brain functions. They are also believed to be implicated in different neurodegenerative disorders. First an ion pairing chromatography method using nonafluoropentanoic acid as volatile ion paring agent was developed on the new generation of C18 columns (monolith and fused core). This method is compatible with MS detection in positive ionization mode. Secondly an HILIC method was optimized using different commercially available HILIC supports, they can be classified as follows: neutral (diol, amide, and cyano bounded), positively charged (amino, triazole bounded), negatively charged (bare silica as wholly porous particles or fused core particles columns) and zwitterionic (sulfobetaine bounded). Our studies lead us to a better understanding of the HILIC retention mechanism and also to the selection of the most appropriated column for catecholamine analysis. Only the HILIC system was compatible with both positive and negative ionization modes. The two chromatographic systems were then compared in terms of resolution, efficiency, detection and quantification limits (LOD/LOQ), calibration linearity and repeatability. The LODs obtained were in the range of 1-100 ng.mL-1. A simple pre-concentration method using Oasis HLB and PGC solid phase extraction cartridges has been optimized in order to enhance the LODs. Finally the optimized SPE-LC-MS/MS method has been applied to the identification of these compounds present in brain extracts. Chromatographie d'appariement d'ions Chromatographie d'interaction hydrophile Extraction sur phase solide Ion pairing chromatography Solid phase extraction
10	Computational Methods in Biomolecules:Study of Hydrophilic Interactions in Protein Folding & Constant-pH Molecular Simulation of pH Sensitive Lipid MORC16 Zhang, Wei 01 January 2018 (has links) (PDF) Water molecules play a significant role in biological process and are directly involved with bio-molecules and organic compounds and ions. Recent research has focused on the thermal dynamics and kinetics of water molecules in solution, including experimental (infrared spectroscopy and Raman spectroscopy) and computational (Quantum Mechanics and Molecular Dynamics) approaches. The reason that water molecules are so unique, why they have such a profound influence on bio-activity, why water molecules show some anomalies compared to other small molecules, and where and how water molecules exert their influence on solutes are some of the areas under study. We studied some properties of hydrogen bond networks, and the relationship of these properties with solutes in water. Molecular dynamics simulation, followed by an analysis of “water bridges”, which represent protein-water interaction have been carried out on folded and unfolded proteins. Results suggest that the formation of transient water bridges within a certain distance helps to consolidate the protein, possibly in transition states, and may help further guide the correct folding of proteins from these transition states. This is supporting evidence that a hydrophilic interaction is the driving force of protein folding. Biological membranes are complex structures formed mostly by lipids and proteins. For this reason the lipid bilayer has received much attention, through computation and experimental studies in recent years. In this dissertation, we report results of a newly designed pH sensitive lipid MORC16, through all-atom and coarse-grained models. The results did not yield a MORC16 amphiphile which flips its conformation in response to protonation. This may be due to imperfect force field parameters for this lipid, an imperfect protonation definition, or formation of hydrogen bond does not responsible for conformation flip in our models. Despite this, some insights for future work were obtained. hydrophilic interaction lipid molecular simulation MORC16 pH protein folding physical chemistry pharmaceutical sciences computational chemistry Pharmacy and Pharmaceutical Sciences

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