Compensation for effects of linear motion in MR imaging

## Abstract A motion‐detection method is described that is specifically suited for MR spectroscopic imaging (MRSI) studies. Information on in‐plane rotation and translation of the subject was obtained using external spatial reference markers that are uniquely identified via their chemical shift. Th

## Abstract A new approach to understanding and reducing motion artifacts in magnetic resonance imaging (MRI) is introduced. This paper presents a novel technique for correcting generalized motion artifacts arising from translation, rotation, dilation, and compression, or any combination thereof. W

## Abstract A method to reduce the effect of motion variability in MRI of the coronary arteries is proposed. It involves acquiring real‐time low‐resolution images in specific orthogonal orientations, extracting coronary motion from these images, and then using this motion information to guide high‐

## Abstract Magnetic resonance (MR) imaging can be performed on or below the time scale of most anatomic motion via echo‐planar imaging (EPI) techniques and their derivatives. The goal is to image rapidly and reduce artifacts that typically result from view‐to‐view changes in the spatial distributi

The accuracy of cine phasecontrast magnetic resonance (MR) imaging for motion analysis was evaluated. By using a rotating phantom and postproceseing algorithm for phase tracking, errors d i n g during data acquisition were identifled and compensation methods were developed. A spatially varying backg

## Abstract Two data sets for half‐Fourier imaging (HFI) can be collected in the same time as one data set for conventional full Fourier imaging (FFI). The hypothesis is that averaging twice as much data in HFI does not make ghost artifacts caused by motion have less signal intensity than in FFI. T