Automated brain extraction from T2-weighted magnetic resonance images

## Abstract Technical advances in T2‐weighted cardiovascular MR (CMR) imaging allow for accurate identification and quantification of tissue injuries that alter myocardial T2 relaxation. Of these, myocardial edema is of special relevance. Increased myocardial water content is an important feature o

## Abstract This paper describes a method that prepares the longitudinal magnetization with T~2~\* weighting for subsequent acquisition. The main advantage of our technique is its insensitivity to static: field inhomogeneity. We have combined this approach with, an ultrafast gradient‐echo (Turbo‐FL

## Abstract This work presents a new algorithm (nonuniform intensity correction; NIC) for correction of intensity inhomogeneities in T1‐weighted magnetic resonance (MR) images. The bias field and a bias‐free image are obtained through an iterative process that uses brain tissue segmentation. The al

The human brain can be subdivided many ways depending upon the criteria used. One of the most basic approaches is to subdivide the cortical regions into functional units composed of the frontal, occipital, parietal, and temporal lobes. To date, the process of reliably extracting measurements of the

## Abstract ## Purpose To correlate the integrity of single‐lumen silicone gel implants with chemical shift artifact (CSA) associated with infolding of the elastomer shell. ## Materials and Methods The T2‐weighted images of presurgical MRI examinations of 54 implants were retrospectively reviewe