Nuclear magnetic resonance spectroscopy solid-state interactions

Oas TG, GriffinRG, Levitt MH (1988) Rotary resonance recoupling of dipolar interactions in solid-state nuclear magnetic resonance spectroscopy. J Chem Phys 89 692-695... 

Several interesting review articles have been recently published focusing on the use of NMR methods to study peptide-lipid and small molecular weight molecule interactions in model and natural membranes. Maler as well as Kang and Li highlighted the unique possibilities of solution-state NMR to investigate the structure, dynamics and location of proteins and peptides in artificial bilayers and peptide-lipid interactions. On the other hand, Renault et reviewed recent advances in cellular solid-state nuclear magnetic resonance spectroscopy (SSNMR) to follow the structure, function, and molecular interactions of protein-lipid complexes in their cellular context and at atomic resolution. 

The role of specific interactions in the plasticization of PVC between the carbonyl fimctionality of the plasticizer were proposed on the basis of results from Fourier transform infrared spectroscopy. Reported shifts in the absorption frequency of the carbonyl group of the plasticizer ester to lower wave number are indicative of a reduction in polarity. These ideas have been extended using newer analytical techniques, in particular molecular modeling and solid-state nuclear magnetic resonance spectroscopy (nmr). 

While XAS techniques focus on direct characterizations of the host electrode structure, nuclear magnetic resonance (NMR) spectroscopy is used to probe local chemical environments via the interactions of insertion cations that are NMR-active nuclei, for example lithium-6 or -7, within the insertion electrode. As with XAS, NMR techniques are element specific (and nuclear specific) and do not require any long-range structural order in the host material for analysis. Solid-state NMR methods are now routinely employed to characterize the various chemical components of Li ion batteries metal oxide cathodes, Li ion-conducting electrolytes, and carbonaceous anodes.Coupled to controlled electrochemical in-sertion/deinsertion of the NMR-active cations, the... 

Nuclear Magnetic Resonance (NMR) spectroscopy is a powerful method to determine the structure of biomacromolecules and their complexes in solution. It allows determination of the dynamics of proteins, RNA, DNA, and their complexes at atomic resolution. Therefore, NMR spectroscopy can monitor the often transient weak interactions in the interactome of proteins and the interaction between proteins and small-molecule ligands. In addition, intrinsically unstructured proteins can be investigated, and first reports of structure determination of membrane proteins in the immobilized state (solid state) are developing. This review will introduce the fundamental NMR observables as well as the methods to investigate structure and dynamics, and it will discuss several examples where NMR spectroscopy has provided valuable information in the context of Chemical Biology. 

Abstract Modern solid state nuclear magnetic resonance presents new powerful opportunities for the elucidation of medium range order in glasses in the sub-nanometer region. In contrast to standard chemical shift spectroscopy, the strategy presented here is based on the precise measurement and quantitative analysis of internuclear magnetic dipole-dipole interactions, which can be related to distance information in a straightforward manner. The... 

The enantiomer and the racemic compound possess different crystal structures, which correspond to different intermolecular interactions, as mentioned in Sec. 3. Therefore the enantiomer and the racemic compound exhibit different powder x-ray diffraction (PXRD) patterns, different infrared (IR) and Raman spectra, and different solid-state nuclear magnetic resonance (SSNMR) spectra. However, the opposite enantiomers give identical PXRD patterns, and identical IR, Raman, and SSNMR spectra. Consequently, the PXRD patterns and the above spectra of a conglomerate, which is a physical mixture of opposite enantiomers, are identical to that of the pure enantiomers. In contrast, the diffraction pattern and the various corresponding spectra of the racemic compound usually differ significantly from those of the pure enantiomers. Therefore the type of racemate can be easily determined by comparing the diffraction patterns or the various spectra of the racemic species with that of one of the pure enantiomers (Figs. 3 5). The enantiomeric composition in a racemic mixture may be determined by PXRD, or by IR or SSNMR spectroscopy. Quantitative PXRD has been applied to determine the relative... 

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