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Magnetic macromolecule

MFM cannot provide the magnetic property of a sample as a bulk evaluated by other magnetic measurements such as SQUID and ESR methods, but it can provide information on an individual magnetic macromolecule of nanometer size. [Pg.74]

Lipari G and Szabo A 1982 Model-free approach to the interpretation of nuclear magnetic resonance relaxation in macromolecules 1. Theory and range of validity J. Am. Chem. Soc. 104 4546-59... [Pg.1516]

The spectroscopic techniques that have been most frequently used to investigate biomolecular dynamics are those that are commonly available in laboratories, such as nuclear magnetic resonance (NMR), fluorescence, and Mossbauer spectroscopy. In a later chapter the use of NMR, a powerful probe of local motions in macromolecules, is described. Here we examine scattering of X-ray and neutron radiation. Neutrons and X-rays share the property of being found in expensive sources not commonly available in the laboratory. Neutrons are produced by a nuclear reactor or spallation source. X-ray experiments are routinely performed using intense synclirotron radiation, although in favorable cases laboratory sources may also be used. [Pg.238]

FIGURE 5A.2 A dialysis experiment. The solution of macromolecules to be dialyzed is placed in a semipermeable membrane bag, and the bag is immersed in a bathing solution. A magnetic stirrer gently mixes the solution to facilitate equilibrium of diffusible solutes between the dialysate and the solution contained in the bag. [Pg.154]

A field of application of MD that is beginning to bear fruit is the refinement of data from nuclear magnetic resonance (NMR) and from diffraction experiments. High-resolution NMR at frequencies around 500 MHz is able to resolve individual proton resonances of biological macromolecules in solution with molecular weights exceeding 10,000... [Pg.112]

Hadden, DA, Master of Science Thesis, Florida State University, Tallahassee, FL, 1999. Hadden, D Rill, RL McFadden, L Locke, BR, Oligonucleotide and Water Self-Diffusion in Pluronic Triblock Copolymer Gels and Solutions by Pulsed Field Gradient Nuclear Magnetic Resonance, Macromolecules 33, 4235, 2000. [Pg.612]

Holz, M Lucas, O Muller, C, NMR in the Presence of an Electric Current, Simultaneous Measurements of Ionic Mobilities, Transference Numbers, and Self-Diffusion Coefficients Using an NMR Pulsed-Gradient Experiment, Journal of Magnetic Resonance 58, 294, 1984. Hooper, HH Baker, JP Blanch, HW Prausnitz, JM, Swelling Equilibria for Positively Ionized Polyacrylamide Hydrogels, Macromolecules 23, 1096, 1990. [Pg.613]

Nuclear magnetic resonance (NMR) spectroscopy is, next to X-ray diffraction, the most important method to elucidate molecular structures of small molecules up to large bio macromolecules. It is used as a routine method in every chemical laboratory and it is not the aim of this article to give a comprehensive review about NMR in structural analysis. We will concentrate here on liquid-state applications with respect to drugs or drug-like molecules to emphasize techniques for conformational analysis including recent developments in the field. [Pg.208]

M. J. McCarthy, R. L. Powell 2001, (Polymer melt rheology by magnetic resonance imaging), Macromolecules 34, 5520. [Pg.454]

Part II Macromolecules Catalysis Colloid Science Electrochemistry Electron Spin Resonance Environmental Chemistry Genetal and Synthetic Methods Mass Spectrometry Nuclear Magnetic Reson n e Organometallic Chemistry Organophosphorus Chemistry Photochemistry... [Pg.452]

Metallophosphazenes are a new type of macromolecule designed to bridge the gap between polymers and metals. Although still at an exploratory stage of laboratory development, they may provide access to electronically-conducting polymers, magnetically-active polymers, macromolecular catalysts, electrode mediator systems, or polymers crosslinked by metal atoms. [Pg.261]

The application of magnetic resonance techniques to biological systems is a relatively new approach for the study of macromolecules. In this review we have presented the different approaches which have been made to study Bi2-enzymes. Clearly some progress has been made particularly from the application of ESR to a study of the enzymes ethanolamine ammonia-lyase and ribonucleotide reductase. Although 13C NMR is well in its developmental stages it is obvious that this technique will prove to be very useful for the examination of coenzyme-enzyme interactions. Studies of how corrinoids bind in enzymes and how sulfhydryl containing proteins are involved in enzyme catalysis comprise two major problems which must be overcome before realistic mechanisms can be presented for this group of enzymes. [Pg.104]

Volume 338. Nuclear Magnetic Resonance of Biological Macromolecules (Part A) Edited by Thomas L. James, Volker Dotsch, and Uli Schmitz... [Pg.32]

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See also in sourсe #XX -- [ Pg.75 ]



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