Designing long-T2 suppression pulses for ultrashort echo time imaging

## Abstract Ultrashort echo time (UTE) imaging is a technique that can visualize tissues with sub‐millisecond __T__~2~ values that have little or no signal in conventional MRI techniques. The short‐__T__~2~ tissues, which include tendons, menisci, calcifications, and cortical bone, are often obscur

## Abstract The application of 3D radial sampling of the free‐induction decay to proton ultrashort echo‐time (UTE) imaging is reported. The effects of __T__~2~ decay during signal acquisition on the 3D radial point‐spread function are analyzed and compared to 2D radial and 1D sampling. It is found

Imaging of short-T(2) species requires not only a short echo time but also efficient suppression of long-T(2) species in order to maximize the short-T(2) contrast and dynamic range. This paper introduces a method of long-T(2) suppression using two long adiabatic inversion pulses. The first adiabatic

## Abstract Assessment of lung effective transverse relaxation time (__T__~2~\*) may play an important role in the detection of structural and functional changes caused by lung diseases such as emphysema and chronic bronchitis. While __T__~2~\* measurements have been conducted in both animals and h

## Abstract A “half‐pulse” slice selection approach is used in the ultrashort echo time pulse sequence and is required to give minimal transverse relaxation in a two‐dimensional acquisition. This method splits the normal excitation radiofrequency pulse in half and acquires a pair of images, each us

## Abstract ## Purpose To evaluate a prototype fast spin echo (FSE) triple‐echo‐Dixon (fTED) technique for breath‐hold, fat‐suppressed, T2‐weighted abdominal imaging. ## Materials and Methods Forty patients underwent breath‐hold T2‐weighted abdominal imaging with fTED and conventional fast recov