Accelerating BOLD fMRI: Comparing k-t BLAST / k-t SENSE with conventional SENSE

## Abstract ## Purpose: To compare k‐t BLAST (broad‐use linear‐acquisition speedup technique)/k‐t SENSE (sensitivity encoding) with conventional SENSE applied to a simple fMRI paradigm. ## Materials and Methods: Blood oxygen level‐dependent (BOLD) functional magnetic resonance imaging (fMRI) was

## Abstract Conventional phase‐contrast velocity mapping in the ascending aorta was combined with __k‐t__ BLAST and __k‐t__ SENSE. Up to 5.3‐fold net acceleration was achieved, enabling single breath‐hold acquisitions. A standard phase‐contrast (PC) sequence with interleaved acquisition of the velo

## Abstract Dynamic images of natural objects exhibit significant correlations in __k__‐space and time. Thus, it is feasible to acquire only a reduced amount of data and recover the missing portion afterwards. This leads to an improved temporal resolution, or an improved spatial resolution for a gi

## Abstract In the __k‐t__ sensitivity encoding (__k‐t__ SENSE) method spatiotemporal data correlations are exploited to accelerate data acquisition in dynamic MRI studies. The present study demonstrates the feasibility of applying __k‐t__ SENSE to contrast‐enhanced myocardial perfusion MRI and usi

## Abstract In __k__‐__t__ BLAST and __k__‐__t__ SENSE, data acquisition is accelerated by sparsely sampling __k__‐space over time. This undersampling in __k__‐__t__ space causes the object signals to be convolved with a point spread function in __x__‐__f__ space (__x__ = spatial position, __f__ =