Solid-state NMR studies of phospholipid model membranes and membrane-associated macromolecules

Lu, Jun-xia.

January 2007

Thesis (Ph. D.)--Miami University, Dept. of Chemistry and Biochemistry, 2007. / Title from second page of PDF document. Includes bibliographical references.

Human cardiac magnetic resonance spectroscopy

Clarke, William

January 2016

The status of the myocardial 'high energy phosphate' metabolism is a sensitive marker of the occurrence and progression of heart failure. Magnetic resonance spectroscopy enables non-invasive, direct and potentially quantitative measurements of the phosphate containing metabolites present in the human myocardium. This thesis is primarily concerned with the creation of measurement techniques for cardiac phosphorus magnetic resonance spectroscopy (³¹P-MRS) at the 7 tesla field strength. Chapter 1 provides an overview of the physical basis of magnetic resonance spectroscopy, the myocardial high energy phosphate metabolism, and the clinical relevance of the technique. Chapter 2 describes the advantage of 7 tesla scanners over lower field strengths. The radio frequency coil hardware is characterised experimentally. The multivoxel spectroscopy methods used throughout the thesis are described. Chapter 3 details the implementation of an open source spectroscopy fitting program. It is validated against previous closed-source implementations. The program's use is demonstrated in several clinical studies of heart failure, and to improve a previously implemented ¹H spectroscopy coil combination method. In Chapter 4 the measurement of inorganic phosphate in the presence of overlapping peaks is attempted. Suppression of overlapping peaks, originating from the blood, is tried using B_o gradients, then saturation transfer. The myocardial pH of hypertrophic cardiomyopathy patients is measured. Chapter 5 describes the effect of creatine kinase catalysed chemical exchange on the ³¹P-MRS spectrum. A survey of methods suitable for measuring creatine kinase kinetics at 7 tesla is made. Multi-parametric fitting of variable repetition time saturation transfer data is explored in simulation and experiment. Chapter 6 describes the re-implementation and extension, for dynamic measurements, of the triple repetition time saturation transfer method for two clinical studies at 3 tesla. The creatine kinase forward rate constant is measured in heart failure and healthy cohorts, at rest, and during cardiac stress. In Chapter 7 a Bloch-Siegert B₁ mapping sequence is implemented for ³¹P-MRS. An optimal Bloch-Siegert method for X-nuclear spectroscopy is calculated. B₁maps are validated in skeletal muscle and collected in 5 volunteer's hearts. Chapter 8 uses the Bloch-Siegert B₁ mapping sequence and the four angle saturation transfer method to implement creatine kinase rate measurement at 7 tesla. The first 3D localised creatine kinase rate measurements in the human myocardium are achieved in 10 volunteers.

Interrogating and potentiating energy metabolism in the human brain after traumatic brain injury

Jalloh, Ibrahim

January 2018

The pathophysiology of traumatic brain injury (TBI) includes perturbations to energy metabolism. Improving our understanding of cerebral energy metabolism will lead to strategies that improve clinical outcomes. For the studies in my thesis I used microdialysis to deliver carbon-13 labelled substrates to the human brain. I combined this with nuclear magnetic resonance (NMR) spectroscopy of interstitial fluid sampled from the brain to interrogate glucose, lactate and tricarboxylic acid (TCA) cycle metabolism. Study I: I defined the optimal parameters for quantitative proton and carbon-13 NMR of cerebral microdialysates. Study II: I measured baseline microdialysate metabolite concentrations for brain and muscle and investigated the influence of muscle activity and cerebral catheter placement in grey or white matter on metabolite concentrations. Study III: I used 1,2-13C2 glucose to measure glycolysis and pentose phosphate pathway activity. Glycolysis is the dominant lactate-producing pathway but the pentose phosphate pathway also contributes and is increased in some TBI patients. Study IV: I used arterio-venous gradients to measure glucose and lactate delivery to the brain. There are periods after injury when lactate is imported from the circulation despite relatively high brain lactate levels suggesting up-regulation of lactate transport. Study V: I followed the metabolism of 3-13C lactate and demonstrated that lactate is metabolised by the TCA cycle. This occurs in both normal and injured brain but not in muscle. Study VI: I used 2,3-13C2 succinate to investigate the role of the TCA cycle in producing metabolites that are exported into the interstitium. The TCA cycle is found to be a source of lactate. Succinate delivered to the brain improves redox and enhances glutamate uptake into cells. The implications of the findings in my thesis on existing knowledge of cerebral metabolism are discussed. Strategies that might potentiate cerebral metabolism and improve clinical outcomes are suggested.

Xenon porometry:a novel method for characterization of porous materials by means of ¹²⁹Xe NMR spectroscopy of xenon dissolved in a medium

Telkki, V.-V. (Ville-Veikko)

31 January 2006

Abstract The present thesis describes the development of a novel method, referred to as xenon porometry, for the determination of the structural properties of porous materials by means of xenon NMR spectroscopy. The method exploits the high sensitivity of the chemical shift of the ¹²⁹Xe isotope to its local environment. The purpose of the medium added to the sample is to slow down the diffusion of xenon so that the NMR signal of a xenon atom is characteristic of the properties of one pore, and the signals of all the atoms in the sample represent the distribution of the properties. Two types of porous materials (controlled pore glasses and silica gels) with well-known properties and three different media (acetonitrile, cyclohexane, and naphthalene) were used in the studies. The behavior of the medium and dissolved xenon at different temperatures around the melting point of the medium was explained. By varying the pore size of the material, three different correlations that make it possible to measure the pore sizes of unknown materials were experimentally determined. The chemical shift of xenon inside pockets built up in the pores during solidification of the medium turned out to be especially sensitive to pore size, and this correlation makes it possible to determine the pore size distribution. The curious behavior of the chemical shift as a function of pore size was explained by using a model based on the fast exchange between xenon adsorbed on the walls of the pockets and free xenon in the middle of the pockets. It was also proved that the porosity of the materials can be determined by comparing the intensities of two signals originating from xenon dissolved in a liquid medium. A comparison of the xenon porometry method with other methods used for pore size characterization leads to the following conclusions: The range of applications of the method is relatively wide, the measurements are fast and easy to do, the analysis of the spectra is simple on the basis of the information presented in this thesis, and the properties of the materials can be extracted from the spectral data with basic mathematical conversions. Because there are several different types of correlations available in the same spectra that represent the properties of the porous material, the complementary information of all the correlations make it possible to obtain a picture of the structures of very complex systems.

nuclear magnetic resonance spectroscopy

porous materials

xenon porometry

¹²⁹Xe

Chemical applications of magnetic resonance

Brown, F. F.

January 1970

No description available.

NMR studies on 2-oxoglutarate oxygenases

Leung, Ivanhoe K. H.

January 2012

No description available.

Bis(ethene)rhodium(I) [beta]-diketonates and related complexes, catalytic and ¹H NMR spectroscopic studies

Wickenheiser, Eugene Benedict

January 1988

A series of bis(ethene)rhodium(I) complexes of β-diketonates and similar ligands were prepared. The complexes were characterized by elemental analysis, ¹H NMR spectroscopy and mass spectrometry. Crystal structures are reported for bis(η²-ethene)-(1,3(1-ferrocenyl)butanedionato-0.0 ')rhodium(I), 13, (1,5-cyclooctadieiie)(2-acetylphen-oxy-0,0')rhodium(I),18, and some related molecules. [FORMULA OMITTED] The complexes are catalyst precursors for the homogeneous hydrogenation of olefins and the hydrosilylation of ketones. The generated hydrogenation catalysts are effective for the reduction of sterically unhindered carbon-carbon double bonds. These catalysts are active in the presence of alcohol, aromatic and carboxylic acid functional groups on the olefin substrate. The catalysts decompose to give a heterogeneously active rhodium precipitate when reducing olefinic substrates which are too sterically hindered. Study of the hydrosilylation reaction revealed that the complexes generate active hydrosilylation catalysts. A series of optically active ligands were tested for their ability to effect asymmetry in the silyl ether products. The bis(ethene)rhodium(I) complexes are fluxional in the NMR time scale due to the motion of the ethylene ligands. A detailed ¹H NMR study was conducted on one of the complexes, bis(η²-ethene)(2-acetylphenoxy-0,0 ')rhodium(I) 15 to explore the nature of the rearrangement. [FORMULA OMITTED] The ¹H NMR study revealed the presence of two different modes of fluxionality. The first type of motion is intramolecular in nature and is due to the rotation of the ethylene ligands about the rhodium-ethylene bond axis. The second type is intermolecular in nature and is due to exchange of the ethylene ligands. This exchange is a measure of the lability of the ethylene ligands. The system allowed the separate study of the ethylene ligands and ΔG‡ values were obtained for each ligand for both of the exchange processes. The results of the study indicate the independance of the ethylene ligands with respect to both fluxional processes. / Science, Faculty of / Chemistry, Department of / Graduate

Methyl ether

Rhodium

Ketones

Nuclear magnetic resonance spectroscopy

NMR of solutes in nematic liquid crystals : an investigation of the mechanisms of orientational ordering

Van der Est, Arthur James

January 1987

Dipolar and quadrupolar couplings measured from NMR experiments, and order parameters obtained from these couplings, are reported for a number of small solutes dissolved in several nematic liquid crystals. These results are discussed in terms of the solute-solvent interactions. It has been shown that the interaction between the solute molecular quadrupole moment and a mean external electric field gradient due to the liquid crystal accounts for most but not all of the ordering of molecular hydrogen. The remaining contribution to ordering is discussed in terms of possible mechanisms. The anisotropic couplings observed for methane and acetylene are discussed in terms of a model which takes into account the interaction between the vibrations and rotations of the solute. Excellent agreement between the observed and calculated dipolar couplings is obtained. Evidence is given that these two solutes experience the same field gradient as molecular hydrogen. In a mixture of 55wt per cent 1132 (Merck ZLI 1132) and 45wt per cent EBBA (N-(4-ethoxybenzylidene)-4'-n-butylaniline at 301.4K the deuterons in D₂ experience no external electric field gradient. The order parameters of a series of solutes in this mixture are calculated in terms of a simple model for the short range interactions which depend on the size and shape of the solute. These calculated order parameters are in very good agreement with the experimental results. In liquid crystals where the field gradient is not zero it is shown that the combination of the short range interaction model and the electric field gradient - molecular quadrupole moment mechanism predicts the order parameters very well. / Science, Faculty of / Chemistry, Department of / Graduate

Molecular dynamics

Nuclear magnetic resonance spectroscopy

Liquid crystals

Expression and purification of the novel protein domain DWNN

Lutya, Portia Thandokazi

January 2002

Magister Scientiae - MSC (Biochemistry) / Proteins play an important role in cells, as the morphology, function and activities of the cell depend on the proteins they express. The key to understanding how different proteins function lies in an understanding of the molecular structure. The overall aim of this thesis was the determination of the structure of DWNN domains. This thesis described the preparation of samples of human DWNN suitable for structural analysis by nuclear magnetic resonance spectroscopy (NMR), as well as NMR analysis. / South Africa

Proteins

Analysis

Structure

Amino acid sequence

Nuclear magnetic resonance spectroscopy

A fourier transform proton magnetic resonance study of the molecular conformation of S-adenosyl-L-methionine

Stolowitz, Mark Lewis

01 January 1979

Contrary to a previous report, S-adenosyl-L-methionine (SAM) affords stable solutions in D2O and the 1H NMR spectrum can be determined. Comparison with the spectra of the model compounds adenosine, L-methionine and L-methionine-S-methyl sulfonium iodide allows complete assignment of the proton resonances. Coupling constants were determined by homonuclear decoupling and graphical analysis and were confined by computer simulation. Details of the molecular conformation were determined by application of the Karplus equation and calculation of relative rotational isomer populations. Evidence indicates that the ribose ring is puckered preferentially in the C3'-exo conformation and that the C4'-C5' bond is constrained to a rotamer in which the sulfonium center is gauche to H4'. No conformational constraints were detected for the Cα-Cβ and Cβ-Cα bonds of the methionine side chain. The purine ring was shown to be oriented preferentially anti by intermolecular association studies with adenosine 5'-phosphate in the presence of MN(II). Spectra of samples of (-)S-adenosyl-L-methionine of biological origin, differing in activity, counter ion and commercial source, have consistently revealed the presence of a small amount of the (+) sulfonium diastereomer. Arguments are presented to explain the failure of previous workers to detect (+)S-adenosyl-L-methionine in biological preparations.

Methionine

Nuclear magnetic resonance spectroscopy

Physical Sciences and Mathematics