Diffusion-weighted three-dimensional MP-RAGE MR imaging

## Abstract The application of three‐dimensional (3D) magnetization‐prepared rapid‐gradientecho (MP‐RAGE) imaging to the acquisition of T2‐weighted 3D data sets has been investigated, with a 90~x~°–180~y~°−90~−x~° pulse set (driven equilibrium) for the T2 contrast preparation. A theoretical model w

## Abstract The authors investigated the application of three‐dimensional (3D) magnetization‐prepared rapid gradient‐echo (MP‐RAGE) imaging to the acquisition of small (32 × 128 × 256) T1‐weighted 3D data sets with imaging times of approximately 1 minute. A theoretical model was used to study the c

## Abstract Fluid‐attenuated inversion recovery (FLAIR) is a pulse sequence used for acquiring T2‐weighted images of the brain and spine in which the normally high signal intensity of CSF is greatly attenuated. The CSF‐sup pressed T2‐weighted contrast of this technique may be more sensitive to a va

## Abstract Diffusion‐weighted magnetic resonance (MR) images obtained with conventional spin‐echo techniques are known to be sensitive to subject motion because of long image acquisition times. To reduce the acquisition time, use of a magnetization‐prepared rapid gradient‐echo (MP‐RAGE) sequence m

## Abstract Three‐dimensional (3D) MP‐RAGE (magnetization‐prepared rapid gradient‐echo) imaging was evaluated as a high‐resolution 3D T1‐weighted brain imaging technique for patients with suspected neurologic disease. Fourteen patients were studied. In five, 3D MP‐RAGE images were compared with 3D