The diffusion sensitivity of fast steady-state free precession imaging

## Abstract The addition of a single, unbalanced diffusion gradient to the steady‐state free precession (SSFP) imaging sequence sensitizes the resulting signal to free diffusion. Unfortunately, the confounding influence of both longitudinal (__T__~__1__~) and transverse (__T__~__2__~) relaxation on

## Abstract Diffusion‐weighted steady‐state free precession (DW‐SSFP) accumulates signal from multiple echoes over several TRs yielding a strong sensitivity to diffusion with short gradient durations and imaging times. Although the DW‐SSFP signal is well characterized for isotropic, Gaussian diffus

## Abstract Various pulse sequences for fast proton spectroscopic imaging (SI) using the steady‐state free precession (SSFP) condition are proposed. The sequences use either only the FID‐like signal S~1~, only the echo‐like signal S~2~, or both signals in separate but adjacent acquisition windows.

## Abstract Steady‐state free precession (SSFP) methods have gained widespread recognition for their ability to provide fast scans at high signal‐to‐noise ratio. This paper demonstrates that such methods are also capable of reflecting functional information, particularly blood oxygenation state. It

## Abstract Recently, a new and fast three‐dimensional imaging technique for magnetization transfer ratio (MTR) imaging has been proposed based on a balanced steady‐state free precession protocol with modified radiofrequency pulses. In this study, optimal balanced steady‐state free precession MTR p

## Abstract We present an imaging technique that affords direct and noninvasive visualization of brain surface structure. This technique utilizes the signal before the rf pulse in steady‐state free precession. This signal highly reflects the spin‐spin relaxation time __T__~2~, as was studied in our