Spectral Editing and Water Suppression in Double-Quantum Experiments

Water suppression is typically performed in vivo by exciting the longitudinal magnetization in combination with dephasing, or by using frequency-selective coherence generation. MEGA, a frequency-selective refocusing technique, can be placed into any pulse sequence element designed to generate a Hahn

corresponds to the length of the gradient plus a recovery time. The three {SQ} is created by the long-range H 2 O dipole-dipole inter-MAGs are magic-angle gradients for efficient solvent suppression, but can actions which are not averaged out by the spatial diffusion be also z PFGs. The strengths of

Conventional double quantum (DQ) editing techniques recover resonances of one metabolite at a time and are thus inefficient for monitoring metabolic changes involving several metabolites. A DQ coherence transfer double editing sequence using a dual-band DQ coherence read pulse is described here. The

Phase-sensitive and absolute-value 'H doublequantum (DQ) experiments recorded with magic angle pulsed field gradients (PFGs) result in spectra with substantial multiple solvent suppression. Although this method also results in the suppression of singlet peaks of the molecule of interest, it neverthe

Spectral editing using gradient selected double-quantum (DQ) coherence transfer is often used for the selective observation of metabolites in vivo. In attempting to optimize the detection sensitivity of a conventional DQ spectral editing sequence, the effects of using radiofrequency (RF) pulses that

The suppression of water signals in in vivo proton spectra by means of multiple-quantum filtering can be brought about in several ways. This communication exposes the shortcomings of using purely subtractive filtering techniques to observe signals from metabolites that contain proton couplings of th