Metabolic characterization of primary human colorectal cancers using high resolution magic angle spinning1H magnetic resonance spectroscopy

## Abstract The application of new gradient, high‐resolution, magic angle spinning (MAS) ^1^H nuclear magnetic resonance (NMR) spectroscopy to the study of intact undifferentiated and differentiated NIH 3T3 F442A cells demonstrated improved spectral resolution and sensitivity compared with static s

## Abstract The recently developed technique of gradient, high‐resolution magic‐angle spinning NMR (g‐hr‐MAS‐NMR) spectroscopy was applied to the study of __ex vivo__ human lipoma and liposarcoma tissue. Compared with conventional ^1^H‐NMR, the g‐hr‐MAS method yielded a large improvement in spectra

## Abstract High‐resolution NMR spectra of materials subject to anisotropic broadening are usually obtained by rotating the sample about the magic angle, which is 54.7° to the static magnetic field. In projected magic angle spinning (p‐MAS), the sample is spun about two angles, neither of which is

## Abstract High‐resolution magic angle spinning (HRMAS) ^1^H NMR spectroscopy has been applied to the biochemical characterization of specific brain regions in rats in order to establish baseline levels of tissue metabolite profiles with which to compare models of neuropathology or toxic lesion. C