Physical Principles and Techniques of Protein Chemistry, Part 2Sydney J. Leach, Sidney J. Leach Physical Principles and Techniques of Protein Chemistry, Part B deals with the theories and application of selected physical methods in protein chemistry evaluation. This book is divided into seven chapters that cover the ultracentrifugal analysis, light scattering, infrared (IR) methods, nuclear magnetic resonance (NMR) spectroscopy, and differential thermal analysis of protein properties. This text first describes the fundamental ideas and methodology of sedimentation analysis of ideal noninteracting solutes and the problems of nonideality and solute-solute interaction. This book then deals ... |
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Page 257
... contribution from the other residue in the unit cell will have the orienta- tions depicted in Fig . 19 for the two ... contributions of the four amide groups in the unit cell are depicted in Fig . 20. The nonzero components of the ...
... contribution from the other residue in the unit cell will have the orienta- tions depicted in Fig . 19 for the two ... contributions of the four amide groups in the unit cell are depicted in Fig . 20. The nonzero components of the ...
Page 285
... contribution to the shield- ing coefficient is smallest for the proton ( 3 × 10-5 ) but increases with atomic weight . In polyatomic molecules , this effect still contributes to the shielding since deviations from the spherical symmetry ...
... contribution to the shield- ing coefficient is smallest for the proton ( 3 × 10-5 ) but increases with atomic weight . In polyatomic molecules , this effect still contributes to the shielding since deviations from the spherical symmetry ...
Page 326
... contribution from exchange broadening ( see Section II , D ) . At low temperatures , the contribution from the bound form to the line width becomes small because of incomplete averaging . As the temperature is increased , the rate of ...
... contribution from exchange broadening ( see Section II , D ) . At low temperatures , the contribution from the bound form to the line width becomes small because of incomplete averaging . As the temperature is increased , the rate of ...
Contents
Ultracentrifugal Analysis | 1 |
J H Coates Glossary of Symbols 23435 37 | 2 |
Fundamentals of the Method | 5 |
Copyright | |
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absorption acid amino anions atoms axial ratio band beam binding Biol bond Bradbury calculated capillary cell centrifugal chain changes Chem chemical shifts complex component concentration constant copper(II denaturation density gradient dependence determined dilution Doty effect electron ellipsoid enzyme equation extrapolation field Fraser frequency fringe Gurd histidine hydrogen ion imidazole imidazole groups instrument interaction intrinsic viscosity Jardetzky length light scattering light-scattering line width lysozyme macromolecule magnetic measured meniscus metal ion method molecular weight molecule myoglobin nuclei observed obtained optical density optical system partial specific volume particle PBLG peak peptide Phys plot Polymer Sci Proc protein solution protons random coil Rayleigh reference refractive index region relaxation residues resonance RNase rotation rotor sample schlieren Section sedimentation coefficient shearing stress slit solvent spectra spectrum speed structure studies Tanford technique temperature Timasheff tion transition ultracentrifuge values velocity Vinograd viscometer zero zone