Found 47 images.
ID | Name | Collection(s) | Description |
---|---|---|---|
790819 | con | Group activation maps for an fMRI language localizer (listening to speech vs reversed speech) | |
790853 | Left frontal ROI | Group activation maps for an fMRI language localizer (listening to speech vs reversed speech) | ROI in the left inferior frontal gyrus derived from the group activation map thresholded at p(FWE)<.05, extent threshold k=5 voxels. |
798434 | IS-RSA | sebo's temporary collection | |
790833 | spmT | Group activation maps for an fMRI language localizer (listening to speech vs reversed speech) | |
790854 | Left temporal ROI | Group activation maps for an fMRI language localizer (listening to speech vs reversed speech) | This ROI (in the left superior and middle temporal gyri, extending to angular and supramarginal gyri, temporal pole, and planum temporale) was derived from the group activation map thresholded at p(FWE)<.05, extent threshold k=5 voxels. |
122233 | Francesca Branzi | fbranzi's temporary collection | |
64145 | Figure 2a | The neural basis of free language choice in bilingual speakers: Disentangling language choice and language execution | Univariate analysis: Activation differences between languages (German and English) during language execution. Regions that are more activated for English during execution are shown are positive in this image. |
64308 | Figure 3 | The neural basis of free language choice in bilingual speakers: Disentangling language choice and language execution | Multivariate Pattern Analysis: Brain regions encoding the chosen language during the language choice and maintenance phase. Chance level (50%) subtracted from the accuracy map. |
64309 | Figure 4 | The neural basis of free language choice in bilingual speakers: Disentangling language choice and language execution | Multivariate Pattern Analysis: Brain regions encoding the chosen language during the language execution phase. Chance level (50%) subtracted from the accuracy map. |
790835 | beta | Group activation maps for an fMRI language localizer (listening to speech vs reversed speech) | |
790855 | Right temporal ROI | Group activation maps for an fMRI language localizer (listening to speech vs reversed speech) | This ROI (in the right superior and middle temporal gyri, extending to supramarginal gyrus, temporal pole, planum temporale, and Heschl’s gyrus) was derived from the group activation map thresholded at p(FWE)<.05, extent threshold k=5 voxels. |
64146 | Figure 2b | The neural basis of free language choice in bilingual speakers: Disentangling language choice and language execution | Univariate analysis: Activation differences between languages (German and English) during language execution. Regions that are more activated for German during execution are shown are positive in this image. |
790847 | p (uncorrected) map | Group activation maps for an fMRI language localizer (listening to speech vs reversed speech) | A map of uncorrected voxel-wise p-values |
790848 | z map | Group activation maps for an fMRI language localizer (listening to speech vs reversed speech) | |
397 | Calculation and Sentence Listening Reading vs Button Press | Genetic Variants of FOXP2 and KIAA0319/TTRAP/THEM2 Locus Are Associated with Altered Brain Activation in Distinct Language-Related Regions | Calculation and sentence listening and reading vs button press: this captures high-level cognition versus motor |
398 | Sentence Listening or Reading | Genetic Variants of FOXP2 and KIAA0319/TTRAP/THEM2 Locus Are Associated with Altered Brain Activation in Distinct Language-Related Regions | Sentence listening or reading: this capture basic language |
402 | Calculation Visual Cue and Sentence Reading vs Checkerboard | Genetic Variants of FOXP2 and KIAA0319/TTRAP/THEM2 Locus Are Associated with Altered Brain Activation in Distinct Language-Related Regions | Calculation Visual Cue and Sentence Reading vs Checkerboard: this contrast isolates high-level processes by removing the low-level visual contribution of the cue |
405 | Sentence Reading vs checkerboard | Genetic Variants of FOXP2 and KIAA0319/TTRAP/THEM2 Locus Are Associated with Altered Brain Activation in Distinct Language-Related Regions | This contrast opposes sentence reading with visual checkerboards, both horizontal and vertical, thus highlighting the high-level reading and language networks |
409 | Calculation Visual Cue and Sentence Reading | Genetic Variants of FOXP2 and KIAA0319/TTRAP/THEM2 Locus Are Associated with Altered Brain Activation in Distinct Language-Related Regions | Calculation Visual Cue and Sentence Reading |
412 | Sentence listening | Genetic Variants of FOXP2 and KIAA0319/TTRAP/THEM2 Locus Are Associated with Altered Brain Activation in Distinct Language-Related Regions | Sentence listening |
413 | Calculation Auditory Cue and Sentence Listening | Genetic Variants of FOXP2 and KIAA0319/TTRAP/THEM2 Locus Are Associated with Altered Brain Activation in Distinct Language-Related Regions | Calculation Auditory Cue and Sentence Listening |
414 | Calculation Visual Cue vs Sentence Reading | Genetic Variants of FOXP2 and KIAA0319/TTRAP/THEM2 Locus Are Associated with Altered Brain Activation in Distinct Language-Related Regions | Calculation Visual Cue vs sentence reading |
417 | Calculation vs Sentences | Genetic Variants of FOXP2 and KIAA0319/TTRAP/THEM2 Locus Are Associated with Altered Brain Activation in Distinct Language-Related Regions | Calculation / computation vs Sentences with a mix of audio and visual stimuli. This contrast highlights the highl-level computation network |
419 | Sentence reading | Genetic Variants of FOXP2 and KIAA0319/TTRAP/THEM2 Locus Are Associated with Altered Brain Activation in Distinct Language-Related Regions | Sentence reading |
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). |
790851 | FWE-corrected p map | Group activation maps for an fMRI language localizer (listening to speech vs reversed speech) |