Abstract
The vast majority of studies using functional magnetic resonance imaging (fMRI) are analyzed on the group level. Standard group-level analyses, however, come with severe drawbacks: First, they assume functional homogeneity within the group, building on the idea that we use our brains in similar ways. Second, group-level analyses require spatial warping and substantial smoothing to accommodate for anatomical variability across subjects. Such procedures massively distort the underlying fMRI data, which hampers the spatial specificity. Taken together, group statistics capture the effective overlap, rendering the modeling of individual deviations impossible – a major source of false positivity and negativity. The alternative analysis approach is to leave the data in the native subject space, but this makes comparison across individuals difficult. Here, we propose a new framework for visualizing group-level information, better preserving the information of individual subjects. Our proposal is to limit the use of invasive data procedures such as spatial smoothing and warping and rather extract regional information from the individuals. This information is then visualized for all subjects and brain areas at one glance – hence we term the method brainglance. Additionally, our method incorporates a means for clustering individuals to further identify common traits. We showcase our method on two publicly available data sets and discuss our findings.
Highlights
With more than 25000 published studies, functional magnetic resonance imaging is a core method for studying the human brain. fMRI measures brain activity indirectly by detecting signal changes caused by the blood oxygen level dependent effect (BOLD) with a spatial resolution ranging from 1 to 4 mm and below
We used the Midnight scan club (MSC) data set (Gordon et al, 2017), as this study was comprised of ten subjects that were each scanned for ten times, yielding very stable brain patterns within individuals
We briefly describe visualization with our new method of the two example datasets: (1) the midnight scan dataset, where 10 individuals were scanned for 10 sessions each, and (2) the human voice area dataset, where 216 subjects had been scanned while listening to human voice versus control auditory stimuli
Summary
With more than 25000 published studies, functional magnetic resonance imaging (fMRI) is a core method for studying the human brain. fMRI measures brain activity indirectly by detecting signal changes caused by the blood oxygen level dependent effect (BOLD) with a spatial resolution ranging from 1 to 4 mm and below. FMRI measures brain activity indirectly by detecting signal changes caused by the blood oxygen level dependent effect (BOLD) with a spatial resolution ranging from 1 to 4 mm and below This allows to localize cognitive functions and to chart structurefunction relationships. Standard group-level inference relies on the similarity of spatial patterns of brain activation across subjects (Stelzer et al, 2014). In other words, they count upon a very similar functional topography within the population for a given task. Performing voxel-level group analysis may fail to reveal the area as task-involved, because the active voxels do not overlap across subjects To mitigate such variability, spatial smoothing is often employed. We will introduce our method and showcase two exemplary fMRI studies
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