Found 106 images.
| ID | Name | Collection(s) | Description |
|---|---|---|---|
| 28871 | PPI analyses (amygdala seed) during socially appetitive block > socially aversive block | Letting the good times roll: adolescence as a period of reduced inhibition to appetitive social cues | |
| 42836 | NBACK tACS0vstACSOFF seedP4 PPI | Externally induced frontoparietal synchronization modulates network dynamics and enhances working memory performance | PPI - NBACK tACS0 > tACS OFF. Seed inferior frontal gyrus, P4 10-20 EEG International system. |
| 42838 | NBACK tACS180vstACSOFF seedP4 PPI | Externally induced frontoparietal synchronization modulates network dynamics and enhances working memory performance | PPI - NBACK tACS180 > tACS OFF. Seed inferior frontal gyrus, P4 10-20 EEG International system. |
| 42837 | NBACK tACS180vstACSOFF seedF4 PPI | Externally induced frontoparietal synchronization modulates network dynamics and enhances working memory performance | PPI - NBACK tACS180 > tACS OFF. Seed medial frontal gyrus, F4 10-20 EEG International system. |
| 64599 | Fronto-parietal intrinsic connectivity network from resting-state fMRI functional connectivity to a seed in dorso-lateral prefrontal cortex | Alpha-Band Phase Synchrony Is Related to Activity in the Fronto-Parietal Adaptive Control Network | |
| 64601 | Cingulo-opercular intrinsic connectivity network from resting-state fMRI functional connectivity to a seed in dorsal anterior cingulate cortex | Intrinsic Connectivity Networks, Alpha Oscillations, and Tonic Alertness: A Simultaneous Electroencephalography/Functional Magnetic Resonance Imaging Study | |
| 12037 | Figure 4E -- Cluster #1 | Tackling the multifunctional nature of Broca's region meta-analytically: Co-activation-based parcellation of area 44 | Cluster #1 for the K=5 cluster solution of cytoarchitectonic area 44. |
| 12038 | Figure 4E -- Cluster #2 | Tackling the multifunctional nature of Broca's region meta-analytically: Co-activation-based parcellation of area 44 | Cluster #2 for the K=5 cluster solution of cytoarchitectonic area 44. |
| 12039 | Figure 4E -- Cluster #3 | Tackling the multifunctional nature of Broca's region meta-analytically: Co-activation-based parcellation of area 44 | Cluster #3 for the K=5 cluster solution of cytoarchitectonic area 44. |
| 12040 | Figure 4E -- Cluster #4 | Tackling the multifunctional nature of Broca's region meta-analytically: Co-activation-based parcellation of area 44 | Cluster #4 for the K=5 cluster solution of cytoarchitectonic area 44. |
| 12041 | Figure 4E -- Cluster #5 | Tackling the multifunctional nature of Broca's region meta-analytically: Co-activation-based parcellation of area 44 | Cluster #5 for the K=5 cluster solution of cytoarchitectonic area 44. |
| 12042 | Figure 6B -- Cluster #1 | Tackling the multifunctional nature of Broca's region meta-analytically: Co-activation-based parcellation of area 44 | Conjunction of specific resting-state functional connectivity and specific MACM co-activation, for Cluster #1. Images were thresholded at p < 0.05 (FWE-corrected at cluster level; cluster-forming threshold at voxel-level p < 0.001). |
| 12043 | Figure 6B -- Cluster #2 | Tackling the multifunctional nature of Broca's region meta-analytically: Co-activation-based parcellation of area 44 | Conjunction of specific resting-state functional connectivity and specific MACM co-activation, for Cluster #2. Images were thresholded at p < 0.05 (FWE-corrected at cluster level; cluster-forming threshold at voxel-level p < 0.001). |
| 12044 | Figure 6B -- Cluster #3 | Tackling the multifunctional nature of Broca's region meta-analytically: Co-activation-based parcellation of area 44 | Conjunction of specific resting-state functional connectivity and specific MACM co-activation, for Cluster #3. Images were thresholded at p < 0.05 (FWE-corrected at cluster level; cluster-forming threshold at voxel-level p < 0.001). |
| 12045 | Figure 6B -- Cluster #4 | Tackling the multifunctional nature of Broca's region meta-analytically: Co-activation-based parcellation of area 44 | Conjunction of specific resting-state functional connectivity and specific MACM co-activation, for Cluster #4. Images were thresholded at p < 0.05 (FWE-corrected at cluster level; cluster-forming threshold at voxel-level p < 0.001). |
| 12046 | Figure 6B -- Cluster #5 | Tackling the multifunctional nature of Broca's region meta-analytically: Co-activation-based parcellation of area 44 | Conjunction of specific resting-state functional connectivity and specific MACM co-activation, for Cluster #5. Images were thresholded at p < 0.05 (FWE-corrected at cluster level; cluster-forming threshold at voxel-level p < 0.001). |
| 12047 | Figure 6A -- Cluster #1 | Tackling the multifunctional nature of Broca's region meta-analytically: Co-activation-based parcellation of area 44 | Regions significantly more co-activated with Cluster #1 than with any of the other four clusters, determined using a MACM analysis. Results are thresholded at a cluster-level FWE-corrected threshold of p < 0.05 (cluster-forming threshold at voxel-level p < 0.001). |
| 12048 | Figure 6A -- Cluster #2 | Tackling the multifunctional nature of Broca's region meta-analytically: Co-activation-based parcellation of area 44 | Regions significantly more co-activated with Cluster #2 than with any of the other four clusters, determined using a MACM analysis. Results are thresholded at a cluster-level FWE-corrected threshold of p < 0.05 (cluster-forming threshold at voxel-level p < 0.001). |
| 12049 | Figure 6A -- Cluster #3 | Tackling the multifunctional nature of Broca's region meta-analytically: Co-activation-based parcellation of area 44 | Regions significantly more co-activated with Cluster #3 than with any of the other four clusters, determined using a MACM analysis. Results are thresholded at a cluster-level FWE-corrected threshold of p < 0.05 (cluster-forming threshold at voxel-level p < 0.001). |
| 12050 | Figure 6A -- Cluster #4 | Tackling the multifunctional nature of Broca's region meta-analytically: Co-activation-based parcellation of area 44 | Regions significantly more co-activated with Cluster #4 than with any of the other four clusters, determined using a MACM analysis. Results are thresholded at a cluster-level FWE-corrected threshold of p < 0.05 (cluster-forming threshold at voxel-level p < 0.001). |
| 12051 | Figure 6A -- Cluster #5 | Tackling the multifunctional nature of Broca's region meta-analytically: Co-activation-based parcellation of area 44 | Regions significantly more co-activated with Cluster #5 than with any of the other four clusters, determined using a MACM analysis. Results are thresholded at a cluster-level FWE-corrected threshold of p < 0.05 (cluster-forming threshold at voxel-level p < 0.001). |
| 12052 | Figure 5A | Tackling the multifunctional nature of Broca's region meta-analytically: Co-activation-based parcellation of area 44 | Conjunction of specific co-activations, determined by MACM, across all five clusters. |
| 12053 | Figure 5B | Tackling the multifunctional nature of Broca's region meta-analytically: Co-activation-based parcellation of area 44 | Conjunction of specific resting-state connectivity across all five clusters. |
| 12054 | Figure S6 -- Cluster #1 | Tackling the multifunctional nature of Broca's region meta-analytically: Co-activation-based parcellation of area 44 | Specific resting-state connectivity for Cluster #1 (not masked by MACM), thresholded at a cluster-level FWE-corrected threshold of p < 0.05 (cluster-forming threshold at voxel-level p < 0.001). |
| 12055 | Figure S6 -- Cluster #2 | Tackling the multifunctional nature of Broca's region meta-analytically: Co-activation-based parcellation of area 44 | Specific resting-state connectivity for Cluster #2 (not masked by MACM), thresholded at a cluster-level FWE-corrected threshold of p < 0.05 (cluster-forming threshold at voxel-level p < 0.001). |
| 12056 | Figure S6 -- Cluster #3 | Tackling the multifunctional nature of Broca's region meta-analytically: Co-activation-based parcellation of area 44 | Specific resting-state connectivity for Cluster #3 (not masked by MACM), thresholded at a cluster-level FWE-corrected threshold of p < 0.05 (cluster-forming threshold at voxel-level p < 0.001). |
| 12057 | Figure S6 -- Cluster #4 | Tackling the multifunctional nature of Broca's region meta-analytically: Co-activation-based parcellation of area 44 | Specific resting-state connectivity for Cluster #4 (not masked by MACM), thresholded at a cluster-level FWE-corrected threshold of p < 0.05 (cluster-forming threshold at voxel-level p < 0.001). |
| 12058 | Figure S6 -- Cluster #5 | Tackling the multifunctional nature of Broca's region meta-analytically: Co-activation-based parcellation of area 44 | Specific resting-state connectivity for Cluster #5 (not masked by MACM), thresholded at a cluster-level FWE-corrected threshold of p < 0.05 (cluster-forming threshold at voxel-level p < 0.001). |
| 12059 | caudal-right cluster (cluster1) | Functional Segregation of the Human Dorsomedial Prefrontal Cortex | |
| 12060 | caudal-left cluster (cluster4) | Functional Segregation of the Human Dorsomedial Prefrontal Cortex | |
| 12061 | rostro-dorsal cluster (cluster3) | Functional Segregation of the Human Dorsomedial Prefrontal Cortex | |
| 12062 | rostro-ventral cluster (cluster2) | Functional Segregation of the Human Dorsomedial Prefrontal Cortex | |
| 12063 | MACM cluster 2 vs all other clusters | Functional Segregation of the Human Dorsomedial Prefrontal Cortex | Specific task-dependent connectivity with cluster 2 contrasted to connectivity patterns of all three other clusters |
| 12064 | MACM cluster1 vs all other clusters | Functional Segregation of the Human Dorsomedial Prefrontal Cortex | Specific task-dependent connectivity with cluster 1, contrasted to connectivity patterns of all three other clusters |
| 12065 | MACM cluster 4 vs all other clusters | Functional Segregation of the Human Dorsomedial Prefrontal Cortex | Specific task-dependent connectivity with cluster 4, contrasted to connectivity patterns of all three other clusters |
| 12066 | MACM cluster3 vs all other clusters | Functional Segregation of the Human Dorsomedial Prefrontal Cortex | Specific task-dependent connectivity with cluster 3, contrasted to connectivity patterns of all three other clusters |
| 12067 | RSFC cluster 1 vs all other clusters | Functional Segregation of the Human Dorsomedial Prefrontal Cortex | Specific resting-state connectivity with cluster 1, contrasted to connectivity patterns of all three other clusters |
| 12068 | RSFC cluster 3 vs all other clusters | Functional Segregation of the Human Dorsomedial Prefrontal Cortex | Specific resting-state connectivity with cluster 3, contrasted to connectivity patterns of all three other clusters |
| 12069 | RSFC cluster 2 vs all other clusters | Functional Segregation of the Human Dorsomedial Prefrontal Cortex | Specific resting-state connectivity with cluster 2, contrasted to connectivity patterns of all three other clusters |
| 12070 | RSFC cluster 4 vs all other clusters | Functional Segregation of the Human Dorsomedial Prefrontal Cortex | Specific resting-state connectivity with cluster 4, contrasted to connectivity patterns of all three other clusters |
| 12071 | Figure 1A | Meta-analytical definition and functional connectivity of the human vestibular cortex | Location of all 414 foci reported in the 28 functional neuroimaging studies on vestibular stimulation on the MNI single subject template. |
| 12072 | Figure 1B | Meta-analytical definition and functional connectivity of the human vestibular cortex | Meta-analysis results for all vestibular experiments following statistical comparison against a null-distribution of spatial independence across studies, ALE scores were thresholded at a cluster-level p<0.05. |
| 12073 | Figure 2A | Meta-analytical definition and functional connectivity of the human vestibular cortex | Significant convergence of activation reported in experiments employing caloric vestibular stimulation shown in a transversal view through the insular cortex, thresholded at a cluster-level p<0.05. |
| 12074 | Figure 2B | Meta-analytical definition and functional connectivity of the human vestibular cortex | Significant convergence of activation reported in experiments employing vestibular stimuli other than caloric irrigation, thresholded at a cluster-level p<0.05. |
| 12075 | Figure 4A | Meta-analytical definition and functional connectivity of the human vestibular cortex | Functional connectivity of the PIVC as indicated by significant (cluster-level p<0.05 corrected) correlation in resting state fMRI data. |
| 12076 | Figure 4B | Meta-analytical definition and functional connectivity of the human vestibular cortex | Significant convergence of activation reported in experiments that employed saccadic eye movements as retrieved through the BrainMap database. |
| 12077 | Figure 4C | Meta-analytical definition and functional connectivity of the human vestibular cortex | Conjunction between the functional connectivity of the PIVC and the meta-analysis on saccadic eye movements indicating regions that were significant in both analyses. |
| 12078 | Figure 3A | Meta-analytical definition and functional connectivity of the human vestibular cortex | Significant overlap between regions showing convergent activation following caloric and non-caloric stimulation (both thresholded at a cluster-level p<0.05) was found only in a single region on the right posterior parietal operculum. The result is shown as a projection onto the surface of the temporo-parietal cortex. |
| 12079 | Figure 3B | Meta-analytical definition and functional connectivity of the human vestibular cortex | Significant overlap between regions showing convergent activation following left and right unilateral cold caloric stimulation, respectively, (both thresholded at a cluster-level pb0.05) was also found only in a single region on the right posterior parietal operculum. |
| 12152 | Figure 1 - Multidemand Network (thres) | Interindividual differences in cognitive flexibility: influence of gray matter volume, functional connectivity and trait impulsivity | The core multiple-demand network, consisting of regions that showed significant convergence across studies in three different metaanalyses, including midcingulate cortex extending into supplementary motor area (MCC/SMA), left and right anterior insula (aINS), left and right inferior frontal junction/gyrus (IFJ/IFG), right middle frontal gyrus (MFG) as well as right inferior parietal cortex extending into intraparietal sulcus (IPC/IPS).Clusters were thresholded by excluding those with less than 50 voxels. |
| 12153 | Figure 1 - Multidemand Network (no thres) | Interindividual differences in cognitive flexibility: influence of gray matter volume, functional connectivity and trait impulsivity | The core multiple-demand network, consisting of regions that showed significant convergence across studies in three different metaanalyses, including midcingulate cortex extending into supplementary motor area (MCC/SMA), left and right anterior insula (aINS), left and right inferior frontal junction/gyrus (IFJ/IFG), right middle frontal gyrus (MFG) as well as right inferior parietal cortex extending into intraparietal sulcus (IPC/IPS). Clusters are unthresholded. |
| 12161 | Figure 1A | Multimodal connectivity mapping of the human left anterior and posterior lateral prefrontal cortex | Anterior lateral prefrontal cortex seed region (mask image) |
| 12162 | Figure 1B | Multimodal connectivity mapping of the human left anterior and posterior lateral prefrontal cortex | Posterior lateral prefrontal cortex seed region (mask image) |
| 12163 | Figure 2A | Multimodal connectivity mapping of the human left anterior and posterior lateral prefrontal cortex | MACM result for aLPFC |
| 12164 | Figure 2B | Multimodal connectivity mapping of the human left anterior and posterior lateral prefrontal cortex | MACM result for pLPFC |
| 12165 | Figure 2E | Multimodal connectivity mapping of the human left anterior and posterior lateral prefrontal cortex | VBM-based grey matter volume covariance of the aLPFC |
| 12166 | Figure 2F | Multimodal connectivity mapping of the human left anterior and posterior lateral prefrontal cortex | VBM-based grey matter volume covariance of the aLPFC |
| 12167 | Figure 2C | Multimodal connectivity mapping of the human left anterior and posterior lateral prefrontal cortex | Resting-state functional connectivity for aLPFC |
| 12168 | Figure 2D | Multimodal connectivity mapping of the human left anterior and posterior lateral prefrontal cortex | Resting-state functional connectivity for pLPFC |
| 12169 | Figure 3A | Multimodal connectivity mapping of the human left anterior and posterior lateral prefrontal cortex | Task-set working memory network, taken from Rottschy et al. (2012) |
| 12170 | Figure 3D | Multimodal connectivity mapping of the human left anterior and posterior lateral prefrontal cortex | Task-load working memory network, taken from Rottschy et al. (2012) |
| 12171 | Figure 2G | Multimodal connectivity mapping of the human left anterior and posterior lateral prefrontal cortex | Conjunction of all three modalities for the aLPFC (MACM ∩ RS-FC ∩ SC) |
| 12172 | Figure 2H | Multimodal connectivity mapping of the human left anterior and posterior lateral prefrontal cortex | Conjunction of all three modalities for the pLPFC (MACM ∩ RS-FC ∩ SC) |
| 12173 | Figure 4A | Multimodal connectivity mapping of the human left anterior and posterior lateral prefrontal cortex | Contrast for resting state BOLD: aLPFC > pLPFC |
| 12174 | Figure 4B | Multimodal connectivity mapping of the human left anterior and posterior lateral prefrontal cortex | Contrast for resting state BOLD: pLPFC > aLPFC |
| 12175 | Figure 5A | Multimodal connectivity mapping of the human left anterior and posterior lateral prefrontal cortex | Default mode network (DMN), taken from Schilbach et al. (2012) |
| 12176 | Figure 5B | Multimodal connectivity mapping of the human left anterior and posterior lateral prefrontal cortex | Conjunction of default mode network with emotional processing network (DMN ∩ EMO), taken from Schilbach et al. (2012) |
| 12177 | Figure 3C | Multimodal connectivity mapping of the human left anterior and posterior lateral prefrontal cortex | Conjunction of task-set WM network with the pLPFC conjunction of Figure 2H (task-set ∩ MACM ∩ RS-FC ∩ SC) |
| 12178 | Figure 3B | Multimodal connectivity mapping of the human left anterior and posterior lateral prefrontal cortex | Conjunction of task-set WM network with the aLPFC conjunction of Figure 2G (task-set ∩ MACM ∩ RS-FC ∩ SC) |
| 12179 | Figure 3E | Multimodal connectivity mapping of the human left anterior and posterior lateral prefrontal cortex | Conjunction of task-load WM network with the aLPFC conjunction of Figure 2G (task-load ∩ MACM ∩ RS-FC ∩ SC) |
| 12180 | Figure 3F | Multimodal connectivity mapping of the human left anterior and posterior lateral prefrontal cortex | Conjunction of task-load WM network with the pLPFC conjunction of Figure 2G (task-load ∩ MACM ∩ RS-FC ∩ SC) |
| 12181 | Figure 5C | Multimodal connectivity mapping of the human left anterior and posterior lateral prefrontal cortex | Resting-state BOLD anti-correlations for aLPFC |
| 12182 | Figure 5D | Multimodal connectivity mapping of the human left anterior and posterior lateral prefrontal cortex | Resting-state BOLD anti-correlations for pLPFC |
| 12183 | Figure 5E | Multimodal connectivity mapping of the human left anterior and posterior lateral prefrontal cortex | Conjunction of resting-state BOLD anti-correlations for aLPFC with the DMN |
| 12184 | Figure 5F | Multimodal connectivity mapping of the human left anterior and posterior lateral prefrontal cortex | Conjunction of resting-state BOLD anti-correlations for pLPFC with the DMN |
| 12185 | Figure 5G | Multimodal connectivity mapping of the human left anterior and posterior lateral prefrontal cortex | Conjunction of resting-state BOLD anti-correlations for aLPFC with the EMO network |
| 18863 | MACM-CBP_rostral_cluster | The Right Dorsal Premotor Mosaic: Organization, Functions, and Connectivity | MACM-CBP_rostral_cluster. Figure 2A. |
| 18864 | MACM_CBP_central_cluster | The Right Dorsal Premotor Mosaic: Organization, Functions, and Connectivity | MACM-CBP_central_cluster. Figure 2A. |
| 18865 | MACM_CBP_caudal_cluster | The Right Dorsal Premotor Mosaic: Organization, Functions, and Connectivity | MACM-CBP_caudal_cluster. Figure 2A. |
| 18866 | MACM-CBP_ventral_cluster | The Right Dorsal Premotor Mosaic: Organization, Functions, and Connectivity | MACM-CBP_ventral_cluster. Figure 2A. |
| 18867 | MACM-CBP_dorsal_cluster | The Right Dorsal Premotor Mosaic: Organization, Functions, and Connectivity | MACM-CBP_dorsal_cluster. Figure 2A. |
| 18868 | PDT-CBP_rostral_cluster | The Right Dorsal Premotor Mosaic: Organization, Functions, and Connectivity | PDT-CBP_rostral_cluster. Figure 2B. |
| 18869 | PDT-CBP_central_cluster | The Right Dorsal Premotor Mosaic: Organization, Functions, and Connectivity | PDT-CBP_central_cluster. Figure 2B. |
| 18870 | PDT-CBP_caudal_cluster | The Right Dorsal Premotor Mosaic: Organization, Functions, and Connectivity | PDT-CBP_caudal_cluster. Figure 2B. |
| 18871 | PDT-CBP_ventral_cluster | The Right Dorsal Premotor Mosaic: Organization, Functions, and Connectivity | PDT-CBP_ventral_cluster. Figure 2B. |
| 18872 | PDT-CBP_dorsal_cluster | The Right Dorsal Premotor Mosaic: Organization, Functions, and Connectivity | PDT-CBP_dorsal_cluster. Figure 2B. |
| 18873 | RSFC-CBP_rostral_cluster | The Right Dorsal Premotor Mosaic: Organization, Functions, and Connectivity | RSFC-CBP_rostral_cluster. Figure 2C. |
| 18874 | RSFC-CBP_central_cluster | The Right Dorsal Premotor Mosaic: Organization, Functions, and Connectivity | RSFC-CBP_central_cluster. Figure 2C. |
| 18875 | RSFC-CBP_caudal_cluster | The Right Dorsal Premotor Mosaic: Organization, Functions, and Connectivity | RSFC-CBP_caudal_cluster. Figure 2C. |
| 18876 | RSFC-CBP_ventral_cluster | The Right Dorsal Premotor Mosaic: Organization, Functions, and Connectivity | RSFC-CBP_ventral_cluster. Figure 2C. |
| 18877 | RSFC-CBP_dorsal_cluster | The Right Dorsal Premotor Mosaic: Organization, Functions, and Connectivity | RSFC-CBP_dorsal_cluster. Figure 2C. |
| 18878 | FC_MACM_specific_rostral | The Right Dorsal Premotor Mosaic: Organization, Functions, and Connectivity | Task functional connectivity rostral cluster. Figure 3A |
| 18879 | FC_MACM_specific_central | The Right Dorsal Premotor Mosaic: Organization, Functions, and Connectivity | Task functional connectivity central cluster. Figure 3A |
| 18880 | FC_MACM_specific_caudal | The Right Dorsal Premotor Mosaic: Organization, Functions, and Connectivity | Task functional connectivity caudal cluster. Figure 3A |
| 18881 | FC_MACM_specific_ventral | The Right Dorsal Premotor Mosaic: Organization, Functions, and Connectivity | Task functional connectivity ventral cluster. Figure 3A |
| 18882 | FC_MACM_specific_dorsal | The Right Dorsal Premotor Mosaic: Organization, Functions, and Connectivity | Task functional connectivity dorsal cluster. Figure 3A |
| 18883 | FC_RSFC_specific_rostral | The Right Dorsal Premotor Mosaic: Organization, Functions, and Connectivity | Resting state functional connectivity rostral cluster. Figure 3B |
| 18884 | FC_RSFC_specific_central | The Right Dorsal Premotor Mosaic: Organization, Functions, and Connectivity | Resting state functional connectivity central cluster. Figure 3B |
| 18885 | FC_RSFC_specific_caudal | The Right Dorsal Premotor Mosaic: Organization, Functions, and Connectivity | Resting state functional connectivity caudal cluster. Figure 3B |
| 18886 | FC_RSFC_specific_ventral | The Right Dorsal Premotor Mosaic: Organization, Functions, and Connectivity | Resting state functional connectivity ventral cluster. Figure 3B |
| 18887 | FC_RSFC_specific_dorsal | The Right Dorsal Premotor Mosaic: Organization, Functions, and Connectivity | Resting state functional connectivity dorsal cluster. Figure 3B |
| 18888 | FC_MACMandRSFC_specific_rostral | The Right Dorsal Premotor Mosaic: Organization, Functions, and Connectivity | Specific functional connectivity pattern (common to both task and resting state) of rostral cluster. Figure 3C. |
| 18889 | FC_MACMandRSFC_specific_central | The Right Dorsal Premotor Mosaic: Organization, Functions, and Connectivity | Specific functional connectivity pattern (common to both task and resting state) of central cluster. Figure 3C. |
| 18890 | FC_MACMandRSFC_specific_caudal | The Right Dorsal Premotor Mosaic: Organization, Functions, and Connectivity | Specific functional connectivity pattern (common to both task and resting state) of caudal cluster. Figure 3C. |
| 18891 | FC_MACMandRSFC_specific_ventral | The Right Dorsal Premotor Mosaic: Organization, Functions, and Connectivity | Specific functional connectivity pattern (common to both task and resting state) of ventral cluster. Figure 3C. |
| 18892 | FC_MACMandRSFC_specific_dorsal | The Right Dorsal Premotor Mosaic: Organization, Functions, and Connectivity | Specific functional connectivity pattern (common to both task and resting state) of dorsal cluster. Figure 3C. |