, 1999) to maximize the probability that our ROI would be samplin

, 1999) to maximize the probability that our ROI would be sampling BA 45 cortex. For the ventral part of BA 6, we placed the center of the ROI in the rostral part of the ventral precentral gyrus, clearly caudal to the inferior precentral sulcus (around y = 6), at approximately

the same dorsal–ventral level as the ROI for BA 44 for that particular brain, i.e. between z = 10 and z = 20. We know that in the ventral half of the inferior precentral gyrus, the primary motor cortex (area 4) lies mostly within the anterior bank of the central sulcus and most of the crown of the ventral precentral Neratinib gyrus is occupied by BA 6. Thus, by placing the seed in the anterior part of the ventral precentral gyrus (but away from the inferior precentral sulcus to avoid overlap

with BA 44), we were maximizing the probability that the ROI would be sampling BA 6. For each participant, a mean BOLD time series was extracted for each of VE-821 datasheet the three ventrolateral frontal ROIs (BA 6, BA 44, BA 45) by averaging across all voxels within the ROI. We then used the AFNI program 3dfim+ to compute the correlation between each time series and every other voxel in the brain. Group-level maps of positive RSFC for each ROI were computed using a one-sample t-test (against 0), and corrected for multiple comparisons using the FSL program easythresh (Z > 2.3; cluster significance P < 0.05,

corrected). Direct comparisons between the maps were computed using paired t-tests, and were also corrected for multiple comparisons using the FSL program easythresh (Z > 2.3; cluster significance P < 0.05, corrected). In a second approach, we used data-driven clustering methods to verify distinctions between ventrolateral frontal areas 6, 44 and 45 on the basis of their RSFC (i.e. the results of the primary, hypothesis-driven seed-based analysis). Clustering algorithms are used to partition (classify) data into natural subsets (clusters) such that observations assigned to the same cluster are more similar Cell press to one another than they are to observations assigned to another cluster. In the context of RSFC, clustering algorithms have been used to partition the brain into subsets (clusters) of voxels or regions that are functionally connected with one another (e.g. van den Heuvel et al., 2008a), or that exhibit similar patterns of functional connectivity with the rest of the brain (Cohen et al., 2008). Here, we adopted the latter approach, and used spectral and hierarchical clustering algorithms to assign voxels within a ventrolateral frontal ROI (419 voxels in total) to clusters on the basis of a measure of the similarity between their whole-brain correlation maps (eta squared – η2).

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