Spectral Editing with Adiabatic Pulses

Spectral-spatial RF (SSRF) pulses allow simultaneous selection in both frequency and spatial domains. These pulses are particularly important for clinical and research MR spectroscopy (MRS) applications for suppression of large water and lipid resonances. Also, the high bandwidth of the subpulses (5

The response of a spin 1 2 ensemble, at thermal equilibrium and experiencing chemical shift anisotropy (CSA), to the application of adiabatic inversion pulses has been studied under magic-angle spinning (MAS). Numerical simulations and experimental studies on such systems, carried out under slow spi

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

## Abstract Proton magnetic resonance spectroscopic imaging (^1^H MRSI) is a useful technique for measuring metabolite levels in vivo, with Choline (Cho), Creatine (Cre), and __N__‐Acetyl‐Aspartate (NAA) being the most prominent MRS‐detectable brain biochemicals. ^1^H MRSI at very high fields, such

it places relatively high demands on B 0 -gradient hardware The sensitivity of magnetic resonance imaging (MRI) exand RF power deposition. periments can be enhanced with surface coil (1) signal detec-Here we propose an alternative method for multislice imtion. However, the high B 1 inhomogeneity of

## Abstract A proton magnetic resonance spectral editing technique is presented that uses PRESS excitation to achieve spatially localized measurements of brain gamma‐aminobutyric acid (GABA). The homonuclear difference spectroscopy technique employs a frequency selective inversion pulse to suppress