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Study: Cerebral Cortical Folding, Parcellation, and Connectivity
Figure 5C. Human resting-state networks and functional connectivity matrix
Study: Connectome Workbench v1.5 Tutorial
Annotations
Study: Connectome Workbench v1.5 Tutorial
7. tfMRI (2BK-0BK WM), R440, on surfaces and volume montage
Study: Connectome Workbench v1.5 Tutorial
9. Parcellation Borders displayed with parcellation labels on R440 surfaces
Study: Connectome Workbench v1.5 Tutorial
2. Individual vs Group Avg surfaces and volumes
Study: Connectome Workbench v1.5 Tutorial
1. Individual surfaces and volumes
Study: Connectome Workbench v1.5 Tutorial
Dynamic Connectivity
Study: Connectome Workbench v1.5 Tutorial
Matrix Chart
Study: Connectome Workbench v1.5 Tutorial
Dynamic Lines Chart
Study: Connectome Workbench v1.5 Tutorial
10. Foci displayed on R440 surfaces
Study: Connectome Workbench v1.5 Tutorial
Histogram Chart
Study: Connectome Workbench v1.5 Tutorial
Media (Image) in Left tab
Study: Connectome Workbench v1.5 Tutorial
Manual Tile Tabs Layout
Study: Connectome Workbench v1.5 Tutorial
4. Resting State fMRI Time Series surfaces, volume, and charting
Study: Connectome Workbench v1.5 Tutorial
6. fcMRI, MGT-regressed correlation, R468 surfaces and volume montage
Study: Connectome Workbench v1.5 Tutorial
Lines Chart
Study: Connectome Workbench v1.5 Tutorial
5. fcMRI, Full Correlation, R468 surfaces and volume montage
Study: Connectome Workbench v1.5 Tutorial
3. Individual vs Group Avg Myelin Maps on R440 Surfaces
Study: Connectome Workbench v1.5 Tutorial
8. Parcellated MGTR Connectivity, R196, RSN parcels: Surface and Matrix chart display
Study: Cortical-subcortical functional networks
Figure 1
Study: Cortical-subcortical functional networks
Figure 2
Study: Cortical-subcortical functional networks
Figure 6
Study: Cortical-subcortical functional networks
Figure 5
Study: Cortical-subcortical functional networks
Figure 3
Study: Cortical-subcortical functional networks
Figure 4
Study: Cortical-subcortical functional networks
Figure 7
Study: Cortical-subcortical functional networks
Figure 8
Study: Cortical-subcortical functional networks
Figure 9
Study: Neural responses to reward valence and magnitude from pre- to early adolescence
Figure7_Success_time_1470
Study: Neural responses to reward valence and magnitude from pre- to early adolescence
FigureS1a_Anticipation_time_1470
Study: Neural responses to reward valence and magnitude from pre- to early adolescence
FigureS2b_Failure_trialtype_1470
Study: Neural responses to reward valence and magnitude from pre- to early adolescence
FigureS2c_Failure_timextrialtype_1470
Study: Neural responses to reward valence and magnitude from pre- to early adolescence
Figure S4a_Anticipation_magnitude_valence_Fstat_gt_50
Study: Neural responses to reward valence and magnitude from pre- to early adolescence
Figure S4b_Failure_magnitude_valence_Fstat_gt_50
Study: Neural responses to reward valence and magnitude from pre- to early adolescence
Figure1a_Antic_trialtype_492
Study: Neural responses to reward valence and magnitude from pre- to early adolescence
Figure1b_Failure_trialtype_492
Study: Neural responses to reward valence and magnitude from pre- to early adolescence
Figure1c_Success_trialtype_492
Study: Neural responses to reward valence and magnitude from pre- to early adolescence
Figure2_Anticipation_magnitude-valence_1470
Study: Neural responses to reward valence and magnitude from pre- to early adolescence
FigureS3a_Success_time_1470
Study: Neural responses to reward valence and magnitude from pre- to early adolescence
Figure3_Anticipation_time_1470
Study: Neural responses to reward valence and magnitude from pre- to early adolescence
Figure4_Failure_magnitude-valence_1470
Study: Neural responses to reward valence and magnitude from pre- to early adolescence
Figure5_Failure_time_1470
Study: Neural responses to reward valence and magnitude from pre- to early adolescence
Figure6_Success_magnitude-valence_1470
Study: Neural responses to reward valence and magnitude from pre- to early adolescence
FigureS1b_Anticipation_trialtype_1470
Study: Neural responses to reward valence and magnitude from pre- to early adolescence
FigureS1c_Anticipation_timextrialtype_1470
Study: Neural responses to reward valence and magnitude from pre- to early adolescence
FigureS2a_Failure_time_1470
Study: Neural responses to reward valence and magnitude from pre- to early adolescence
FigureS3b_Success_trialtype_1470
Study: Neural responses to reward valence and magnitude from pre- to early adolescence
FigureS3c_Success_timextrialtype_1470
Study: Neural responses to reward valence and magnitude from pre- to early adolescence
Figure S4c_Success_magnitude_valence_Fstat_gt_50
Study: Extending the Human Connectome Project across ages: Imaging protocols for the Lifespan Development and Aging projects
Figure 1, tSNR maps
Study: Position coding in spatial working memory
Figure S2B. Dense whole-brain delay activity during individual task conditions.
Study: Position coding in spatial working memory
Figure S3. Average delay activity during individual task conditions based on analysis of parcellated data.
Study: Position coding in spatial working memory
Figure S5. Functional connectivity within the spatial working memory network during the delay period for each task condition in Experiment I.
Study: Position coding in spatial working memory
Figure 3. Differences in the delay activity between task conditions thought to promote either retrospective sensory or prospective motor coding, respectively.
Study: Position coding in spatial working memory
Figure 4. Differences in early and late phases of the delay activity between task conditions thought to promote either retrospective sensory or prospective motor coding, respectively.
Study: Position coding in spatial working memory
Figure 5A. ROIs used in functional connectivity analysis.
Study: Position coding in spatial working memory
Figure S4. Consistency of delay-related differences across different task conditions and experiments.
Study: Position coding in spatial working memory
Figure 2. Significant delay-related responses.