Analysis of encoding efficiency in MR imaging of velocity magnitude and direction

## Abstract Three encoding strategies for the measurement of flow velocities in arbitrary directions with phase‐contrast magnetic resonance imaging are presented; their noise and dynamic range performance are compared by means of theoretical analysis and computer simulation. A six‐point measurement

## Abstract The contrast of flow‐encoded magnetic resonance (MR) images obtained in vivo and the accuracy of velocity measurements are complicated by the presence of complex flow states. The effects of complex flow states on MR flow‐encoded images were studied and quantitative flow information was

## Abstract ## Purpose To develop a gradient insensitive, generic technique for recording of non‐MR signals by use of surplus scanner bandwidth. ## Materials and Methods Relatively simple battery driven hardware is used to transform one or more signals into radio waves detectable by the MR scann

## Abstract We show the importance of phase‐encoding order in ultra‐short TR (< 10 ms) snapshot MR imaging. Contrast is more heavily dictated by the contrast preparation phase early in the measurement phase than later. When the low spatial frequencies are measured first, the resultant image contras

## Abstract Magnetic resonance imaging maps of velocity were acquired with a 1.5‐T system in 10 subjects in a plane perpendicular to the main pulmonary artery. Velocity images were successively acquired with a method developed from Fourier‐encoding velocity imaging (FEVI) principles with eight grad

## Abstract ## Purpose To develop fast and robust procedures for a clinical evaluation of regional myocardial contractile function. ## Materials and Methods Parametric analysis of main motion was applied to steady‐state free‐precession (SSFP) cine MR images. From the time–signal intensity curve