Impact of signal-to-noise on functional MRI

## Abstract An MRI detector is formed from a conducting strip separated by a dielectric substrate from a ground plane, and tuned to a quarter‐wavelength. By distributing discrete tuning elements along the strip, the geometric design may be adjusted to optimize the signal‐to‐noise ratio (SNR) for a

The high frequency k-space data in magnetic resonance imaging clinical field strengths of 1.5 T, 3D proton MRI of large is often poorly reproduced due to the finite dynamic range of an volumes can have k-space signal-to-noise ratios which exanalog-to-digital converter. The magnitude of this digitiza

## Abstract A magnetization transfer (MT)‐prepared echo‐planar imaging (EPI) pulse sequence was developed to study motor cortex activation, using a finger tapping paradigm. MT weighting resulted in a reduction of both the activated area and, in the majority of activated pixels, the functional MRI s

Some non-Fourier encoding methods such as wavelet and direct encoding use spatially localized bases. The spatial localization feature of these methods enables optimized encoding for improved spatial and temporal resolution during dynamically adaptive MR imaging. These spatially localized bases, howe

## Abstract A method is described for establishing an upper bound on the spatial encoding capabilities of coil arrays in parallel MRI. Ultimate intrinsic signal‐to‐noise ratio (SNR), independent of any particular conductor arrangement, is calculated by expressing arbitrary coil sensitivities in ter

## Abstract ## Purpose To investigate the source of native low‐frequency fluctuations (LFF) in functional MRI (fMRI) signal. ## Materials and Methods Phase analysis was performed on tissue‐segmented fMRI data acquired at systematically varying sampling rates. ## Results LFF in fMRI signal were