Ketosis and Epilepsy: 31P Spectroscopic Imaging at 4.1 T

## Abstract High field (4 Tesla) spectroscopic imaging offers the advantages of increased signal‐to‐noise ratio and the possibility of acquiring high resolution metabolite images. We have applied a three dimensional spectroscopic imaging sequence using a sparse Gaussian sampling method to acquire p

We performed proton magnetic resonance spectroscopic imaging (MRSI) at high magnetic field (4.1 T) to study N-acetylaspartate, creatine, and choline levels in the brains of normal control subjects and patients with intractable temporal lobe epilepsy. We compared the results of MRSI to those of other

## Abstract The authors report on high‐field (4.1 T) magnetic resonance ^1^H spectroscopic imaging studies on eight patients with relapsing remitting multiple sclerosis (mean expanded disability status scale (EDSS) 1.0) and eight normal controls. Using __T__~1~ weighted imaging to determine lesion

## Abstract A two‐dimensional spectroscopic imaging sequence consisting of an inversion recovery pulse, a plane selective prefocused pulse, and a semiselective water suppression pulse has been used to create ^1^H spectroscopic images of the human brain with nominal voxels of 0.5 cc. Due to the exce

In studies of 31P metabolite imaging in the human brain using a high-field 4.1 T NMR system, resolution and signal-to-noise ratios were measured to determine the potential for spatial-resolution improvements. The results suggest that spatial resolution of FWHM of 2 cm or less, similar to that of rad

## Abstract Brain glutamate and glutamine were detected in healthy human volunteers in spectroscopic images with a nominal voxel size of 2.25 cm^3^ at an echo time of 15 ms. Due to the increased frequency separation and simplification of __J__‐coupling patterns, the separate detection of brain glut