Elimination of signal fluctuations in CARS of weak resonances in liquids

## 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

## Abstract The most important but still unresolved problem in bioelectromagnetics is the interaction of weak electromagnetic fields (EMFs) with living cells. Thermal and other types of noise pose restrictions in cell detection of weak signals. As a consequence, some extant experimental results tha

A general theory is developed for the effect of molecular diffufor the effects of diffusion to first order in D. A general sion on the NMR signal obtained from magnetically heterogeneous formulation is utilized that allows an arbitrary sequence of media in the limit of weak diffusion. The theory is

## Abstract Functional magnetic resonance imaging is sensitive to signal fluctuations due to physiological motion and system instability. In this paper, motion‐related signal fluctuations are studied, and a method that uses navigator echoes to monitor and compensate for signal fluctuations in a gra

## Abstract We present an analysis of how flow oblique to the frequency‐encoding direction generates displacement artifacts in MR imaging and show that for flow which has constant velocity between the start of the phase encoding and the center of the echo it is possible to eliminate these artifacts