Real-time motion correction for high-resolution larynx imaging

Several methods have been proposed for motion correction of high angular resolution diffusion imaging (HARDI) data. There have been few comparisons of these methods, partly due to a lack of quantitative metrics of performance. We compare two motion correction strategies using two figures of merit: d

In functional magnetic resonance imaging (fMRI) head motion can corrupt the signal changes induced by brain activation. This paper describes a novel technique called Prospective Acquisition CorrEction (PACE) for reducing motion-induced effects on magnetization history. Full three-dimensional rigid b

## Abstract Modern computational brain morphology methods require that anatomical images be acquired at high resolution and with a high signal‐to‐noise ratio. This often translates into long acquisition times (>20 minutes) and images susceptible to head motion. In this study we tested retrospective

## Abstract ## Purpose To evaluate the performance of the autofocusing (AF) motion correction technique in high‐resolution trabecular bone imaging where image signal‐to noise ratio (SNR) is limited. ## Materials and Methods Raw data from 26 clinical three‐dimensional (3D) wrist exams were motion

## Abstract Many MR‐guided interventional procedures rely on fast imaging sequences for providing images in real‐time with a precise relation between the target position in the image and its true position. Echo‐planar imaging (EPI) methods are very fast but prone to geometric distortions. Here, we