Found 76 images.
| ID | Name | Collection(s) | Description |
|---|---|---|---|
| 59076 | vmPFC MACM | Segregation of the human medial prefrontal cortex in social cognition | |
| 59077 | dmPFC MACM | Segregation of the human medial prefrontal cortex in social cognition | |
| 785690 | ACC-cog_rev | lara.maliske's temporary collection | |
| 785691 | ACC-int_rev | lara.maliske's temporary collection | |
| 11988 | Seed ROI -- Anterior cingulate cortex (ACC) | Definition and characterization of an extended social-affective default network | Anterior cingulate cortex (ACC) seed region derived from the conjunction DMN ∩ (EMO ∪ SOC). |
| 11989 | Seed ROI -- Dorsomedial prefrontal cortex (dmPFC) | Definition and characterization of an extended social-affective default network | Dorsomedial prefrontal cortex (dmPFC) seed region derived from the conjunction DMN ∩ (EMO ∪ SOC). |
| 11990 | Seed ROI -- Precuneus (PrC) | Definition and characterization of an extended social-affective default network | Precuneus (PrC) seed region derived from the conjunction DMN ∩ (EMO ∪ SOC). |
| 11991 | Seed ROI -- Subgenual cingulate cortex (SGC) | Definition and characterization of an extended social-affective default network | Subgenual cingulate cortex (SGC) seed region derived from the conjunction DMN ∩ (EMO ∪ SOC). |
| 11992 | Seed ROI -- Left amygdala (Amy) | Definition and characterization of an extended social-affective default network | Left amygdala (Amy) seed region derived from the conjunction DMN ∩ (EMO ∪ SOC). |
| 11993 | Seed ROI -- Right temporoparietal cortex (TPJ) | Definition and characterization of an extended social-affective default network | Right temporoparietal cortex (TPJ) seed region derived from the conjunction DMN ∩ (EMO ∪ SOC). |
| 11994 | Seed ROI -- Left temporoparietal cortex (TPJ) | Definition and characterization of an extended social-affective default network | Left temporoparietal cortex (TPJ) seed region derived from the conjunction DMN ∩ (EMO ∪ SOC). |
| 11995 | eSAD ROIs -- Left anterior middle temporal sulcus (aMTS) | Definition and characterization of an extended social-affective default network | Left anterior middle temporal sulcus (aMTS) component of the extended social-affective default (eSAD) network. These regions were derived from a consensus across MACM and RS-fMRI connectivity maps of the seed ROIs. |
| 11996 | eSAD ROIs -- Anterior cingulate cortex (ACC) | Definition and characterization of an extended social-affective default network | Anterior cingulate cortex (ACC) component of the extended social-affective default (eSAD) network. These regions were derived from a consensus across MACM and RS-fMRI connectivity maps of the seed ROIs. |
| 11997 | eSAD ROIs -- Left amygdala/hippocampus (Amy/Hipp) | Definition and characterization of an extended social-affective default network | Left amygdala/hippocampus (Amy/Hipp) component of the extended social-affective default (eSAD) network. These regions were derived from a consensus across MACM and RS-fMRI connectivity maps of the seed ROIs. |
| 11998 | eSAD ROIs -- Right amygdala/hippocampus (Amy/Hipp) | Definition and characterization of an extended social-affective default network | Right amygdala/hippocampus (Amy/Hipp) component of the extended social-affective default (eSAD) network. These regions were derived from a consensus across MACM and RS-fMRI connectivity maps of the seed ROIs. |
| 11999 | eSAD ROIs -- Left ventral basal ganglia (BG) | Definition and characterization of an extended social-affective default network | Left ventral basal ganglia (BG) component of the extended social-affective default (eSAD) network. These regions were derived from a consensus across MACM and RS-fMRI connectivity maps of the seed ROIs. |
| 12000 | eSAD ROIs -- Right ventral basal ganglia (BG) | Definition and characterization of an extended social-affective default network | Right ventral basal ganglia (BG) component of the extended social-affective default (eSAD) network. These regions were derived from a consensus across MACM and RS-fMRI connectivity maps of the seed ROIs. |
| 12001 | eSAD ROIs -- Dorsomedial prefrontal cortex (dmPFC) | Definition and characterization of an extended social-affective default network | Dorsomedial prefrontal cortex (dmPFC) component of the extended social-affective default (eSAD) network. These regions were derived from a consensus across MACM and RS-fMRI connectivity maps of the seed ROIs. |
| 12002 | eSAD ROIs -- Precuneus/posterior cingulate cortex (PrC/PCC) | Definition and characterization of an extended social-affective default network | Precuneus/posterior cingulate cortex (PrC/PCC) component of the extended social-affective default (eSAD) network. These regions were derived from a consensus across MACM and RS-fMRI connectivity maps of the seed ROIs. |
| 12003 | eSAD ROIs -- Subgenual cingulate cortex (SGC) | Definition and characterization of an extended social-affective default network | Subgenual cingulate cortex (SGC) component of the extended social-affective default (eSAD) network. These regions were derived from a consensus across MACM and RS-fMRI connectivity maps of the seed ROIs. |
| 12004 | eSAD ROIs -- Left temporoparietal junction (TPJ) | Definition and characterization of an extended social-affective default network | Left temporoparietal junction (TPJ) component of the extended social-affective default (eSAD) network. These regions were derived from a consensus across MACM and RS-fMRI connectivity maps of the seed ROIs. |
| 12005 | eSAD ROIs -- Right temporoparietal junction (TPJ) | Definition and characterization of an extended social-affective default network | Right temporoparietal junction (TPJ) component of the extended social-affective default (eSAD) network. These regions were derived from a consensus across MACM and RS-fMRI connectivity maps of the seed ROIs. |
| 12006 | eSAD ROIs -- Ventromedial prefrontal cortex (vmPFC) | Definition and characterization of an extended social-affective default network | Ventromedial prefrontal cortex (vmPFC) component of the extended social-affective default (eSAD) network. These regions were derived from a consensus across MACM and RS-fMRI connectivity maps of the seed ROIs. |
| 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). |
| 12096 | aMCC Seed | The role of anterior midcingulate cortex in cognitive motor control | The seed region was taken from a recent fMRI study which examined neural effects of self-initiated movements by letting subjects choose between left or right finger movements to be initiated at an freely chosen point in time [Hoffstaedter et al., 2013] |
| 12097 | MACM aMCC | The role of anterior midcingulate cortex in cognitive motor control | The VOI search in the BrainMap database revealed 656 experiments containing activation foci within the aMCC. The ALE maps reflecting the convergence of co-activations with the aMCC were family wise error (FWE) corrected at a cluster level threshold of p < 0.05 (cluster-forming threshold: p < 0.001 at voxel level; cluster extend threshold k = 211), and converted to Z-scores. |
| 12098 | MACM aMCC cognition | The role of anterior midcingulate cortex in cognitive motor control | 277 experiments in BrainMap featuring activation in the aMCC were attributed to the behavioral domain ‘cognition’. |
| 12099 | MACM aMCC action | The role of anterior midcingulate cortex in cognitive motor control | 222 experiments featuring activation in the aMCC were attributed to the behavioral domain ‘action’. |
| 12100 | RS aMCC | The role of anterior midcingulate cortex in cognitive motor control | The aMCC was used as seed VOI in the resting-state analysis in 100 subjects. Pearson correlation coefficients were computed between the representative time series of the VOI and those of all other grey matter voxels in the brain. Correlation coefficients were Fisher's Z transformed and tested for consistency in an ANOVA. The results of this random-effects analysis were family wise error (FWE) corrected at a threshold of p < 0.05. |
| 12101 | Conjunction RS and MACM aMCC | The role of anterior midcingulate cortex in cognitive motor control | Conjunction RS and MACM aMCC |
| 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 |