Physics of NMR spectroscopy in biology and medicine: Varenna on Lake Como, Villa Monastero, 8-18, July, 1986
As a result of the recent expansion of nuclear magnetic resonance in biomedicine, a number of workshops and schools have been organized to introduce the NMR principles to a wider group of biologists, radiologists, neurologists, etc. The aim of most of these courses was to provide a common vocabulary and enough information about ``pulse sequences'', relaxation times, etc. in order to facilitate the use of the various types of NMR imaging systems. However, no courses were organized for the physicists who were responsible for the origin and evolution of the ideas in this area. This Enrico Fermi school was therefore organized. The topics discussed included the theoretical interpretation and prediction of NMR signals, the study of new imaging techniques up to the building of special r.f. coils and the study of new methods for analysing NMR data in the time domain.
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A Pines Lectures on pulsed NME 1 Introduction pag
Dipolar couplings and molecular structure
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amplitude axis Beson calculated centerband Chem chemical shift chemical-shift cholesterol coherence transfer component constant constraints correlation corresponding data points decay decoupling density matrix depends deuterium dipolar couplings distance distance geometry domain double-quantum echo edited effect energy equation excitation experiment experimental flip angle Fourier transform frequency gradient Hamiltonian heteronuclear HSVD intensity interactions isotropic Larmor frequency linear LPSVD Magn magnetic field MASS spectrum measurement membranes method model function molecular molecules multiple-quantum NME imaging NME spectra nuclear nuclei obtained operator orientation parameters peaks phospholipid Phys precession probe protein proton pulse sequence quadrupolar quantum r.f. field r.f. pulse ratio region relative relaxation resonance rotating frame rotor sample scaling selection shown in fig sidebands signal singular values sinusoids slice solid spatial spectra spectroscopy spectrum spin system spin-lattice relaxation structure surface coil symmetry tensor tissue transitions two-dimensional vector voxel Zeeman zero zero-field