β Scribed by Norman J. Oppenheimer and Thomas L. James (Eds.)
No coin nor oath required. For personal study only.
This volume, as does Volume 177, provides a general background of modern NMR techniques, with a specific focus on NMR techniques that pertain to proteins and enzymology, and a ''snapshot'' of the current state of the art in NMR experimental techniques. These books enable the reader to understand a given technique, to evaluate its strengths and limitations, to decide which is the best approach, and, finally, to design an experiment using the chosen technique to solve a problem
Content:
Contributors to volume 176
Pages vii-viii
Preface
Page ix
Norman J. Oppenheimer, Thomas L. James
Volume in series
Pages xi-xxiv
[1] One-dimensional nuclear Overhauser effects and peak intensity measurements Original Research Article
Pages 3-11
James A. Ferretti, George H. Weiss
[2] Two-dimensional nuclear magnetic resonance spectroscopy of proteins: An overview Original Research Article
Pages 12-64
John L. Markley
[3] Solvent suppression Original Research Article
Pages 64-77
P.J. Hore
[4] Sample preparation Original Research Article
Pages 78-89
Norman J. Oppenheimer
[5] Heteronuclear nuclear magnetic resonance experiments for studies of protein conformation Original Research Article
Pages 93-113
Gerhard Wagner
[6] Multiple-quantum nuclear magnetic resonance Original Research Article
Pages 114-134
Mark Rance, Walter J. Chazon, Claudio Dalvit, Peter E. Wright
[7] Detection of insensitive nuclei Original Research Article
Pages 134-150
Ad Bax, Steven W. Sparks, Dennis A. Torchia
[8] Homonuclear Hartmann-Hahn experiments Original Research Article
Pages 151-168
Ad Bax
[9] Two-dimensional nuclear Overhauser effect: Complete relaxation matrix analysis Original Research Article
Pages 169-183
Brandan A. Borgias, Thomas L. James
[10] Selective relaxation techniques Original Research Article
Pages 184-199
Neri Niccolai, Claudio Rossi
[11] Rotating-frame nuclear Overhauser effect Original Research Article
Pages 199-216
L.R. Brown, B.T. Farmer II
[12] Modern spectrum analysis in nuclear magnetic resonance: Alternatives to the fourier transform Original Research Article
Pages 216-241
Jeffrey C. Hoch
[13] Solid-State nuclear magnetic resonance structural studies of proteins Original Research Article
Pages 242-275
S.J. Opella, P.L. Stewart
[14] Nuclear magnetic resonance line-shape analysis and determination of exchange rates Original Research Article
Pages 279-311
B.D. Nageswara Rao
[15] Applicability of magnetization transfer nuclear magnetic resonance to study chemical exchange reactions Original Research Article
Pages 311-329
Jens J. Led, Henrik Gesmar, Frits Abildgaard
[16] Two-dimensional nuclear magnetic resonance studies of enzyme kinetics and metabolites in vivo Original Research Article
Pages 330-341
Bruce A. Berkowitz, Robert S. Balaban
[17] Isotope exchange Original Research Article
Pages 342-358
Paul RoΠΠsch
[18] Interpreting protein dynamics with nuclear magnetic resonance relaxation measurements Original Research Article
Pages 358-375
Robert E. London
[19] Solid-state deuterium nuclear magnetic resonance spectroscopy of proteins Original Research Article
Pages 376-386
Max A. Keniry
[20] Protein rotational correlation times by carbon-13 rotating-frame spin-lattice relaxation in presence of off-resonance radiofrequency field Original Research Article
Pages 386-418
Thomas Schleich, Courtney F. Morgan, G. Herbert Caines
[21] Measurement of translational motion by pulse-gradient spin-echo nuclear magnetic resonance Original Research Article
Pages 418-446
Ronald L. Haner, Thomas Schleich
[22] Structural characterization of protein folding intermediates by proton magnetic resonance and hydrogen exchange Original Research Article
Pages 446-473
Heinrich Roder
Computer programs related to nuclear magnetic resonance: Availability, summaries, and critiques
Pages 477-489
Addendum to article [16]
Pages 493-494
Bruce A. Berkowitz, Robert S. Balaban
Author index
Pages 495-509
Subject index
Pages 511-530
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