Single scan spin-echo measurements of T1 and T2

## Abstract A rapid technique for mapping of __T__~2~ relaxation times is presented. The method is based on the conventional single‐echo spin echo approach but uses a much shorter pulse repetition time to accelerate data acquisition. The premise of the new method is the use of a constant difference

## Abstract A new pulse sequence for fast multislice __T__~1~ mapping is presented. This method is based on calculating __T__~1~ from spin echo (SE) and stimulated echo (STE) images obtained with different degrees of __T__~1~ weighting, and uses the interleaved acquisition scheme of the fast phase

The goal of this work is to provide regional T(1) and T(2) values at a field strength of 7 T for the normal mouse brain at 6 weeks and 1 year old. A novel segmented snapshot FLASH sequence was used to measure T(1) in the hippocampus, corpus callosum, and the retrosplenial granular (RSG) cortex; T(2)

## Abstract Measuring __T__~2~ at 7.0 T is not trivial due to RF inhomogeneity effects, however, gradient echo sampling of a spin echo is insensitive to RF pulse errors, does not suffer from significant distortions, and allows __T__′~2~ and __T__~2~ to be estimated simultaneously. Gradient echo sam

## Abstract To evaluate T2‐weighted fast spin‐echo (FSE) and conventional spin‐echo (CSE) magnetic resonance (MR) techniques in the assessment of brain myelination, 100 consecutive pediatric patients were imaged prospectively with both CSE and FSE sequences. All patients underwent a routine MR exam

## Abstract ## Purpose To compare the abilities of T2‐weighted (T2W) imaging using respiratory‐triggered fast spin‐echo (RT‐FSE), breathhold fast‐recovery FSE (BH‐FRFSE), and BH single‐shot FSE (BH‐SSFSE) sequences without an endorectal coil to detect rectosigmoid carcinomas. ## Materials and Met