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Analysis of Small Biomolecules by Esi- and Maldi-Mass SpectrometryPilus, Rashidah 02 1900 (has links)
This thesis describes the use of mass spectrometric methods based upon electrospray ionization, ESI, and (matrix-assisted) laser desorption/ionization, (MA)LDI, for the quantitative analysis of small biomolecules. Structure analysis when required, was obtained through tandem mass spectrometry (MS/MS). The Girard type reagent, 4-hydrazino-4-oxobutyl tris(2,4,6 trimethoxy)phenyl phosphonium bromide, in combination with the solid phase derivatization technique, is used to selectively prepare a pre-ionized malondialdehyde derivative to be analyzed by MALDI or LDI. The in situ derivatization and isolation minimize interferences from other components in biological samples. The combination of pre-ionization and aromatic functionalities allows for laser induced ionization without the need of matrix. The combination of these techniques provides an avenue for development of automation to produce a high throughput method of analysis. Chapter 3 involves the study of the complexation of diols to the oxovanadium ion. The oxovanadium (IV) complex of ethylene glycol is used as a reference to study the complexation of other diols and amines with the vanadyl ion. The ES spectra of various diols studied produce intense signals for the mixed and the analyte complexes, indicating effective complexation of the analytes with the vanadyl ion. Oxovanadium (IV) is observed to be more selective for complexation to diols than amines. This eliminates the possibility of interference from N-containing ligands to the detection of diols by the reference complex. The electrospray spectrum is used for quantitation and the tandem mass spectrometry spectrum for structure confirmation. The MS/MS spectrum also assists the identification of the diols by the structural differences within their isomers. The equilibrium constant of a set of diols was determined and its calibration curve were constructed. This study produces an alternative method to detect and quantify diols in aqueous solutions and blood samples. / Thesis / Master of Science (MSc)
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Detection and enrichment of cytochrome P450s using bespoke affinity chromatography and proteomic techniques : development of chemical immobilisation and novel affinity chromatography methods, with subsequent proteomic analysis, for the characterisation of cytochrome P450s important in cancer researchBateson, Hannah January 2012 (has links)
Introduction: Cellular membrane proteins, such as the cytochrome P450 enzyme superfamily (P450), have important roles in the physiology of the cell. P450s are important in metabolising endogenous molecules, as well as metabolising xenobiotic substances for detoxification and excretion. P450s are also implicated in cancer as they can act to 'negatively' de-activate or 'positively' activate cancer therapeutics. Identifying specific P450s that are highly up-regulated at the tumour site could be used to predict drug response and formulate targeted cancer therapy to help diminish systemic side-effects. Methods: Previous enrichment strategies have been unable to isolate the full complement of the P450 superfamily. To develop enrichment procedures for the P450s, a proteomic strategy was developed so that compounds could be screened for their effectiveness as general P450 probes. A standardised work-flow was created, encompassing affinity chromatography, protein concentration/desalting, followed by sodium dodecyl sulphate polyacrylamide gel electrophoresis (SDS-PAGE) and high performance liquid chromatography-mass spectrometry (HPLC-MS). A ketoconazole analogue and a 2-EN analogue, with known P450 inhibition, were immobilised on a solid support for comparison to immobilised histamine. Co-factor removal, competitive elution and DTT cleavage of disulfide bonds of probes were utilised to elute bound proteins. Results/Discussion: Inhibitor-beads bound a large range of proteins, including P450's, of which some were eluted by co-factor removal, some by competitive elution. Specificity of binding was improved by optimising buffer conditions and solid supports, however non-specific binding was not totally eradicated. All human P450s from spiked samples and 18 P450s from more complex mouse liver samples were recovered using one or more ligands.
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New Directions in Catalyst Design and Interrogation: Applications in Dinitrogen Activation and Olefin MetathesisBlacquiere, Johanna M. 09 May 2011 (has links)
A major driving force for development of new catalyst systems is the need for more efficient synthesis of chemical compounds essential to modern life. Catalysts having superior performance offer significant environmental and economic advantages, but their discovery is not trivial. Well-defined, homogeneous catalysts can offer unparalleled understanding of ligand effects, which proves invaluable in directing redesign strategies. This thesis work focuses on the design of ruthenium complexes for applications in dinitrogen activation and olefin metathesis. The complexes developed create new directions in small-molecule activation and asymmetric catalysis by late-metal complexes.
Also examined are the dual challenges, ubiquitous in catalysis, of adequate interrogation of catalyst structure and performance. Insight into both is essential to enable correlation of ligand properties with catalyst activity and/or selectivity. Improved methods for accelerated assessment of catalyst performance are described, which expand high-throughput catalyst screening to encompass parallel acquisition of kinetic data. A final aspect focuses on direct examination of metal complexes, both as isolated species, and under catalytic conditions. Applications of charge-transfer MALDI mass spectrometry to structural elucidation in organometallic chemistry is described, and the technique is employed to gain insight into catalyst decomposition pathways under operating conditions.
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New Directions in Catalyst Design and Interrogation: Applications in Dinitrogen Activation and Olefin MetathesisBlacquiere, Johanna M. 09 May 2011 (has links)
A major driving force for development of new catalyst systems is the need for more efficient synthesis of chemical compounds essential to modern life. Catalysts having superior performance offer significant environmental and economic advantages, but their discovery is not trivial. Well-defined, homogeneous catalysts can offer unparalleled understanding of ligand effects, which proves invaluable in directing redesign strategies. This thesis work focuses on the design of ruthenium complexes for applications in dinitrogen activation and olefin metathesis. The complexes developed create new directions in small-molecule activation and asymmetric catalysis by late-metal complexes.
Also examined are the dual challenges, ubiquitous in catalysis, of adequate interrogation of catalyst structure and performance. Insight into both is essential to enable correlation of ligand properties with catalyst activity and/or selectivity. Improved methods for accelerated assessment of catalyst performance are described, which expand high-throughput catalyst screening to encompass parallel acquisition of kinetic data. A final aspect focuses on direct examination of metal complexes, both as isolated species, and under catalytic conditions. Applications of charge-transfer MALDI mass spectrometry to structural elucidation in organometallic chemistry is described, and the technique is employed to gain insight into catalyst decomposition pathways under operating conditions.
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New Directions in Catalyst Design and Interrogation: Applications in Dinitrogen Activation and Olefin MetathesisBlacquiere, Johanna M. 09 May 2011 (has links)
A major driving force for development of new catalyst systems is the need for more efficient synthesis of chemical compounds essential to modern life. Catalysts having superior performance offer significant environmental and economic advantages, but their discovery is not trivial. Well-defined, homogeneous catalysts can offer unparalleled understanding of ligand effects, which proves invaluable in directing redesign strategies. This thesis work focuses on the design of ruthenium complexes for applications in dinitrogen activation and olefin metathesis. The complexes developed create new directions in small-molecule activation and asymmetric catalysis by late-metal complexes.
Also examined are the dual challenges, ubiquitous in catalysis, of adequate interrogation of catalyst structure and performance. Insight into both is essential to enable correlation of ligand properties with catalyst activity and/or selectivity. Improved methods for accelerated assessment of catalyst performance are described, which expand high-throughput catalyst screening to encompass parallel acquisition of kinetic data. A final aspect focuses on direct examination of metal complexes, both as isolated species, and under catalytic conditions. Applications of charge-transfer MALDI mass spectrometry to structural elucidation in organometallic chemistry is described, and the technique is employed to gain insight into catalyst decomposition pathways under operating conditions.
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New Directions in Catalyst Design and Interrogation: Applications in Dinitrogen Activation and Olefin MetathesisBlacquiere, Johanna M. January 2011 (has links)
A major driving force for development of new catalyst systems is the need for more efficient synthesis of chemical compounds essential to modern life. Catalysts having superior performance offer significant environmental and economic advantages, but their discovery is not trivial. Well-defined, homogeneous catalysts can offer unparalleled understanding of ligand effects, which proves invaluable in directing redesign strategies. This thesis work focuses on the design of ruthenium complexes for applications in dinitrogen activation and olefin metathesis. The complexes developed create new directions in small-molecule activation and asymmetric catalysis by late-metal complexes.
Also examined are the dual challenges, ubiquitous in catalysis, of adequate interrogation of catalyst structure and performance. Insight into both is essential to enable correlation of ligand properties with catalyst activity and/or selectivity. Improved methods for accelerated assessment of catalyst performance are described, which expand high-throughput catalyst screening to encompass parallel acquisition of kinetic data. A final aspect focuses on direct examination of metal complexes, both as isolated species, and under catalytic conditions. Applications of charge-transfer MALDI mass spectrometry to structural elucidation in organometallic chemistry is described, and the technique is employed to gain insight into catalyst decomposition pathways under operating conditions.
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SURFACE LAYER MATRIX-ASSISTED LASER DESORPTION IONIZATION TIME OF FLIGHT MASS SPECTROMETRY (SL-MALDI-TOF MS) ANALYSIS OF POLYMER BLEND SURFACE COMPOSITIONHill, Jacob A., Hill January 2017 (has links)
No description available.
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Characterization of the Munc13 - CaM Interaction / Charakterisierung der Munc13-CaM-WechselwirkungDimova, Kalina 04 May 2009 (has links)
No description available.
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