Double-Quantum-Filtered NMR Signals in Inhomogeneous Magnetic Fields

The effects of magnetic fields B 0 and B 1 inhomogeneities on either by a 180Њ pulse in the middle of the creation time in techniques which are commonly used for the measurements of the standard TQF sequence (Fig. 1a) (6) or by selecting a triple-quantum-filtered (TQF) NMR spectroscopy of 23 Na in b

A theory of the NMR signal dephasing due to the presence of tissue-specific magnetic field inhomogeneities is developed for a two-compartment model. Randomly distributed magnetized objects of finite size embedded in a given media are modeled by ellipsoids of revolution (prolate and oblate spheroids)

The possibility of exciting and filtering various multipolar spin states in proton NMR like dipolar encoded longitudinal magnetization (LM), double-quantum (DQ) coherences, and dipolar order (DO) in strongly inhomogeneous static and radio-frequency magnetic fields is investigated. For this purpose p

In this study we address the question of quantification of muscle lactate using double quantum filtered (DQF) 1 H NMR spectroscopy where dipolar and scalar coupled spectra are acquired. For this, lactate content in muscle samples was independently determined using a conventional enzymatic assay and

The 2H double-quantum-filtered (DQF) NMR spectrum of isolated rat sciatic nerve, equilibrated with deuterated saline, is composed of three quadrupolar-split water signals. On the basis of the time course of their shift by Co-EDTA2- and CoCl2, the signals with quadrupolar splittings of about 120, 470

## Double-quantum filtration under rotational resonance MAS NMR conditions where the chemical shielding anisotropies involved exceed the differences in isotropic chemical shielding is considered by means of numerical simulations and 13 C MAS NMR experiments. The responses of two different pulse se