Modern Magnetic Resonance Part 1: Applications in Chemistry, Biological and Marine Sciences, Part 2: Applications in Medical and Pharmaceutical Sciences, Part 3: Applications in Materials Science and Food Science

Modern Magnetic Resonance provides a unique and comprehensive resource on up-to-date uses and applications of magnetic resonance techniques in the sciences, including chemistry, biology, materials, food, medicine, pharmaceuticals and marine sciences.

The widespread appeal of MMR methods for revealing information at the molecular and microscopic levels is noted and examples are provided from the chemical and other sciences.

Until now, there has been no single publication that covers all the areas encompassed by "Modern Magnetic Resonance", by bringing together the various techniques and their applications in many scientific areas, the internationally renowned Editors have created a resource of broad appeal to the scientific community.

The book includes:

- High resolution solid and liquid state NMR

- Low resolution NMR

- Solution State NMR

- Magnetic Resonance Imaging

- Electron Spin Resonance

- Many applications taken from all of the chemical and related sciences

PART I: APPLICATIONS IN CHEMISTRY, BIOLOGICAL & MARINE SCIENCES

· Amyloids

o Kinetics of Amyloid Fibril Formation of Human Calcitonin.

o Polymorphism of Alzheimer’s A-beta Amyloid Fibrils.

· Chemical Shifts and Spin-Couplings.

o ¹³C, ¹⁵N, ¹H, ²H, and ¹⁷O NMR Chemical Shift NMR for Hydrogen Bonds.

o NMR Chemical Shift Map.

o NMR Chemical Shifts Based on Band Theory.

o Modeling NMR Chemical Shifts.

o Ab Initio Calculation of NMR Shielding Constants.

o Crystal Structure Refinement Using Chemical Shifts.

o The Theory of Nuclear Spin–Spin Couplings.

· Fibrous Proteins.

o Investigation of Collagen Dynamics by Solid-State NMR Spectroscopy.

o Solid-State NMR Studies of Elastin and Elastin Peptides.

o Structural Analysis of Silk Fibroins using NMR.

· Field Gradient NMR.

o NMR Diffusometry.

o Field Gradient NMR of Liquid Crystals.

o Field Gradient NMR for Polymer Systems with Cavities.

o NMR Measurements Using Field Gradients and Spatial Information.

o Theory and Application of NMR Diffusion Studies.

· Host–Guest Chemistry.

o Solid-State NMR in Host–Guest Chemistry.

· Imaging.

o Mapping of Flow and Acceleration with NMR Microscopy Techniques.

o Industrial Application of In situ NMR Imaging Experiments to Steel-Making Process.

o Biomedical NMR Spectroscopy and Imaging.

o Electron Spin Resonance Imaging in Polymer Research.

o NMR Imaging: Monitoring of Swelling of Environmental Sensitive Hydrogels.

· Inorganic Materials and Catalysis.

o Exploiting ¹Hà ²⁹Si Cross-Polarization Features for Structural Characterization of Inorganic Materials.

o Solid State NMR Characterization of Solid Surface of Heterogeneous Catalysts.

· Isotope Labeling.

o Recent Developments in Stable-Isotope-Aided Methods for Protein NMR Spectroscopy.

o Structural Glycobiology by Stable-isotope-assisted NMR Spectroscopy.

· Lipid Bilayer and Bicelle.

o Development and Application of Bicelles for Use in Biological NMR and Other Biophysical Studies.

o Nuclear Magnetic Resonance of Oriented Bilayer Systems.

o Solid-State Deuterium NMR Spectroscopy of Membranes.

o Solid State ¹⁹F-NMR Analysis of Oriented Biomembranes.

· Membrane-Associated Peptides.

o Solid-State NMR Studies of the Interactions and Structure of Antimicrobial Peptides in Model Membranes.

o Anisotropic Chemical Shift Perturbation Induced by Ions in Conducting Channels.

o NMR Studies of Ion-Transporting Biological Channels.

· Membrane Proteins.

o Site-Directed NMR Studies on Membrane Proteins.

o Structure of Membrane-Binding Proteins Revealed by Solid-State NMR.

o Solid-State NMR of Membrane-Active Proteins and Peptides.

o Magnetic Resonance Spectroscopic Studies of the Integral Membrane Protein Phospholamban.

o NMR Studies of the Interactions Between Ligands and Membrane-Embedded. Receptors: New Methods for Drug Discovery.

o Photosynthetic Antennae and Reaction Centers.

o Insight into Membrane Protein Structure from High-Resolution NMR.

· New Developments.

o Fast Multidimensional NMR: New Ways to Explore Evolution Space.

o High-Sensitivity NMR Probe Systems.

o CRAMPS.

o Mobile NMR.

o Rheo-NMR.

o Analytical Aspects of Solid-State NMR Spectroscopy.

o ³H NMR and Its Application.

o On-line SEC–NMR.

· NOE and Chemical Exchange.

o The Nuclear Overhauser Effect.

o Solute–Solvent Interactions Examined by the Nuclear Overhauser Effect.

o Chemical Exchange.

· NQR & ESR.

o Separated Detection of H-Transfer Motions in Multi-H-Bonded Systems Studied by Combined ¹H NMR and ³⁵Cl NQR Measurements.

o EPR: Principles.

o Zero Field NMR: NMR and NQR in Zero Magnetic Field.

· Organo Metallic Chemistry.

o Organoboron Chemistry.

o Organogermanium Chemistry.

o Organotin Chemistry.

· Paramagnetic Effects.

o ¹H and ¹³C High-Resolution Solid-State NMR of Paramagnetic Compounds Under Very Fast Magic Angle Spinning.

o Paramagnetic Effects of Dioxygen in Solution NMR—Studies of Membrane Immersion Depth, Protein Topology, and Protein Interactions.

· Protein Structure.

o TROSY NMR for Studies of Large Biological Macromolecules in Solution.

o NMR Insight of Structural Stability and Folding of Calcium-Binding Lysozyme.

o NMR Investigation of Calmodulin.

o Analytical Framework for Protein Structure Determination by Solid-State NMR of Aligned Samples.

o Determining Protein 3D Structure by Magic Angle Spinning NMR.

o ¹⁹F NMR Study of b-Type Haemoproteins.

· Polymer Structure.

o NMR in Dry or Swollen Temporary or Permanent Networks.

o Crystalline Structure of Ethylene Copolymers and Its Relation to the Comonomer Content.

o Isomorphism in Bacterially Synthesized Biodegradable Copolyesters.

o Two-Dimensional NMR Analysis of Stereoregularity of Polymers.

o Quantitative Analysis of Conformations in Disordered Polymers by Solid-State Multiple-Quantum NMR.

o Polymer Microstructure: The Conformational Connection to NMR.

o Solid-State NMR Characterization of Polymer Interfaces.

o The Structure of Polymer Networks.

o ¹H CRAMPS NMR of Polypeptides in the Solid State.

· Polymer Dynamics.

o Dynamics of Amorphous Polymers.

o Molecular Motions of Crystalline Polymers by Solid-State MAS NMR.

o Dynamics in Polypeptides by Solid State 2H NMR.

· Polymer Blends.

o Polymer Blends.

o Configurational Entropy and Polymer Miscibility: New Experimental Insights From Solid-State NMR.

· Quantum Information Processing.

o Quantum Information Processing as Studied by Molecule-Based Pulsed ENDOR Spectroscopy.

· Residual Dipolar Couplings and Nucleic Acids.

o New Applications for Residual Dipolar Couplings: Extending the Range of NMR in Structural Biology.

o Refinement of Nucleic Acid Structures with Residual Dipolar Coupling Restraints in Cartesian Coordinate.

o Conformational Analysis of DNA and RNA.

· Solid-State NMR Technique.

o Analytical and Numerical Tools for Experiment Design in Solid-State NMR Spectroscopy.

o Homonuclear Shift-Correlation Experiment in Solids.

o Two-Dimensional ¹⁷O Multiple-Quantum Magic-Angle Spinning NMR of Organic Solids.

o A Family of PISEMA Experiments for Structural Studies of Biological Solids.

· Structural Constraints in Solids.

o Rotational-Echo, Double-Resonance NMR.

o REDOR in Multiple Spin System.

o Torsion Angle Determination by Solid-State NMR.

o Secondary Structure Analysis of Proteins from Angle-Dependent Interactions.

· Telomeric DNA Complexes.

o Comparison of DNA-Binding Activities Between hTRF2 and hTRF1 with hTRF2 Mutants.

o Optimization of MRI Contrast for Pre-Clinical Studies at High Magnetic Field.

o The Application of In Vivo MRI and MRS in Phenomic Studies of Murine Models of Disease.

o Experimental Models of Brain Disease: MRI Contrast Mechanisms for the Assessment of Pathophysiological Status.

o Experimental Models of Brain Disease: MRI Studies.

o Application of MRS in Cancer in Pre-clinical Models.

o Experimental Cardiovascular MR in Small Animals.

o Application of Pharmacological MRI to Preclin

Graham A. Webb has been actively engaged in research involving many aspects of NMR for about 25 years both at University College London and the University of Surrey, where he became a Professor of Physical Chemistry. During this time he has authored more than 400 published primary research papers, given presentations at about 200 international conferences dealing with NMR and supervised about 70 Ph.D. theses. He has been Editor of Annual Reports on NMR since 1975; the latest Volume to appear is number 55. In addition, he has edited The Royal Society of Chemistry Specialist Periodical Reports on NMR since 1978; the latest Volume is number 35. Professor Webb has also organised the biennial international conferences on Applications of NMR in Food Science since 1984.