Abstract
The conventional fMRI image analysis approach to associating stimuli to brain activation is performed by carrying out a massive number of parallel univariate regression analyses. fMRI blood-oxygen-level dependent (BOLD) signal, the basis of these analyses, is known for its low signal-noise-ratio and high spatial and temporal signal correlation. In order to ensure accurate localization of brain activity, stimulus administration in an fMRI session is often lengthy and repetitive. Real-time fMRI BOLD signal analysis is carried out as the signal is observed. This method allows for dynamic, real-time adjustment of stimuli through sequential experimental designs. We have developed a voxel-wise sequential probability ratio test (SPRT) approach for dynamically determining localization, as well as decision rules for stopping stimulus administration. SPRT methods and general linear model (GLM) approaches are combined to identify brain regions that are activated by specific elements of stimuli. Stimulus administration is dynamically stopped when sufficient statistical evidence is collected to determine activation status across regions of interest, following predetermined statistical error thresholds. Simulation experiments and an example based on real fMRI data show that scan volumes can be substantially reduced when compared with pre-determined, fixed designs while achieving similar or better accuracy in detecting activated voxels. Moreover, the proposed approach is also able to accurately detect differentially activated areas, and other comparisons between task-related GLM parameters that can be formulated in a hypothesis-testing framework. Finally, we give a demonstration of SPRT being employed in conjunction with a halving algorithm to dynamically adjust stimuli.
Highlights
Functional neuroimaging technology is widely used for clinical applications, such as determining early-stage disease by detecting abnormal functioning in specific brain regions [1,2], assessing treatment effectiveness [3], and for pre-surgical assessments to help prevent resectioning that can damage important cognitive and motor functions [3]
We propose an approach based on combining information obtained through parallel voxellevel sequential probability ratio test (SPRT) to inform real-time adjustments in fMRI experimental designs according to observed rtfMRI signal
In simulations we explore whether the proposed approach of conducting simultaneous voxelwise SPRTs is able to achieve similar accuracy compared to a fixed, pre-determined experimental design, with the conventional fMRI analyses method through general linear model (GLM), while at the same time significantly reducing scanning times
Summary
Functional neuroimaging technology is widely used for clinical applications, such as determining early-stage disease by detecting abnormal functioning in specific brain regions [1,2], assessing treatment effectiveness [3], and for pre-surgical assessments to help prevent resectioning that can damage important cognitive and motor functions [3]. Dynamic Adjustment of Stimuli in Real Time fMRI imaging (fMRI) provides neural images with high spatial resolution by non-invasively detecting task-related blood-oxygen-level-dependent (BOLD) signal changes which are associated with neural activity in the brain [4]. Conservative assumptions about potential variability may need to be made in order to help insure that an experimental design will provide sufficient information about localization of activation for a large proportion of subjects. This leads to inefficient designs and high costs for fMRI, and exposes the signal data to fatigue and learning effects
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