WOROI: 160 - Sulcus
 
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WOROI: 160 - Sulcus


External databases

Taxonomy

ParentsSiblingsChildren
   Calcarine sulcus

Talairach coordinates

  x     y     z   Lobar anatomy WOBIB WOEXP
30 -56 44 Right intraparietal sulcus 3 6
-18 -62 45 Left intraparietal sulcus 3 6
36 -75 23 Right intraoccipital sulcus 3 6
-24 -95 19 Left intraoccipital sulcus 3 6
33 -76 -1 Right collateral sulcus 3 6
-24 -67 -7 Left collateral sulcus 3 6
18 -53 -2 Right lingual gyrus/anterior calcarine sulcus 3 7
-15 -53 -2 Left lingual gyrus/anterior calcarine sulcus 3 7
-25 -42 -10 Left anterior collateral sulcus 5 12
25 -39 -12 Right anterior collateral sulcus 5 12
26 38 44 Superior frontal gyrus/superior frontal sulcus 6 13
33 36 22 Inferior frontal sulcus/middle frontal gyrus 6 13
12 16 23 Cingulate sulcus 6 13
10 19 36 Cingulate sulcus/gyrus 6 13
-51 9 29 Left precentral sulcus 10 23
40 -40 46 Right intraparietal sulcus 10 25
36 -60 47 Right intraparietal sulcus 10 25
-40 -41 35 Left intraparietal sulcus 10 27
44 -52 47 Right intraparietal sulcus 10 27
40 -37 42 Right intraparietal sulcus 10 27
-36 -48 43 Left intraparietal sulcus 10 27
32 -60 36 Right intraparietal sulcus 10 27
32 -45 39 Right intraparietal sulcus 10 27
-19 38 46 Superior frontal gyrus/superior frontal sulcus 12 31
-23 28 44 Middle frontal gyrus/superior frontal sulcus 12 31
-4 20 40 Cingulate gyrus/sulcus 12 31
4 17 27 Cingulate sulcus 12 31
-19 37 45 Superior frontal gyrus/superior frontal sulcus 12 32
-4 19 38 Cingulate gyrus/sulcus 12 32
2 18 31 Cingulate sulcus 12 32
-29 22 55 Superior frontal gyrus/superior frontal sulcus 12 33
42 -32 44 Postcentral sulcus 16 47
-24 -34 32 Deep subparietal sulcus 16 49
-30 -50 20 Deep posterior superior, temporal sulcus 16 49
-40 -37 28 Left sulcus intraparietalis 21 190
53 -7 11 Right lateral sulcus 21 190
-14 15 38 Left sulcus callosomarginalis 21 190
44 -29 46 Right intraparietal sulcus 23 73
39 -38 63 Right intraparietal sulcus 24 77
33 -44 55 Right intraparietal sulcus 24 77
39 -38 52 Right intraparietal sulcus 24 77
-36 -41 57 Left intraparietal sulcus 24 77
-39 -33 46 Right intraparietal sulcus 24 77
-28 -60 47 Left intraparietal sulcus 25 78
28 -60 47 Right intraparietal sulcus 25 78
-28 -60 47 Left intraparietal sulcus 25 79
24 -64 47 Right intraparietal sulcus 25 79
-28 -60 47 Left intraparietal sulcus 25 80
24 -64 47 Right intraparietal sulcus 25 80
32 -60 47 Right intraparietal sulcus 25 81
-48 -29 46 Left postcentral sulcus/inferior parietal lobule 25 81
-40 -9 52 Left precentral gyrus/central sulcus 25 81
28 -64 47 Right intraparietal sulcus 25 82
-28 -60 47 Left intraparietal sulcus 25 83
36 -48 50 Right intraparietal sulcus 25 83
-24 -60 47 Left intraparietal sulcus 25 84
24 -52 54 Right intraparietal sulcus 25 84
-24 -60 47 Left intraparietal sulcus 25 85
24 -52 54 Right intraparietal sulcus 25 85
-28 -60 47 Left intraparietal sulcus 25 86
24 -60 47 Right intraparietal sulcus 25 86
-32 -66 42 Left intraparietal sulcus 28 90
26 -54 44 Right intraparietal sulcus 28 90
-43 -46 47 Left intraparietal sulcus 28 92
34 -44 53 Right intraparietal sulcus 28 92
0 -66 56 Subparietal sulcus, superior parietal lobule, precuneus 30 100
-54 -60 13 Posterior superior-temporal sulcus 33 111
44 -60 19 Posterior superior-temporal sulcus 33 111
-48 0 -17 Left superior temporal sulcus 39 132
58 6 -10 Anterior superior temporal sulcus 42 141
60 -1 -4 Anterior superior temporal sulcus 42 141
63 -13 -1 Middle superior temporal sulcus 42 141
56 -30 6 Posterior superior temporal sulcus 42 141
46 -44 6 Posterior superior temporal sulcus 42 141
-62 -14 0 Middle superior temporal sulcus 42 141
-62 -40 10 Posterior superior temporal sulcus 42 141
60 -1 -4 Anterior superior temporal sulcus 42 142
63 -13 -1 Middle superior temporal sulcus 42 142
56 -30 6 Posterior superior temporal sulcus 42 142
-62 -14 0 Middle superior temporal sulcus 42 142
63 -13 -1 Middle superior temporal sulcus 42 143
56 -30 6 Posterior superior temporal sulcus 42 143
-62 -14 0 Middle superior temporal sulcus 42 143
-62 -40 10 Posterior superior temporal sulcus 42 143
-30 -57 52 Intraparietal sulcus 46 149
27 -56 53 Intraparietal sulcus 46 149
-31 -52 48 Intraparietal sulcus 46 150
23 -59 51 Intraparietal sulcus 46 150
-26 -50 46 Left middle intraparietal sulcus 48 156
41 -68 42 Intraparietal sulcus/inferior parietal lobule 48 157
-31 -53 28 Intraparietal sulcus 48 158
44 -25 42 Intraparietal sulcus/postcentral sulcus 48 159
-9 34 -7 Left rostral cingulate sulcus 50 168
-26 28 -8 Left orbital sulcus 50 168
-28 5 53 Left superior frontal sulcus 51 170
24 1 50 Right superior frontal sulcus 51 170
-61 5 29 Left precentral sulcus 51 170
-30 -51 62 Left intraparietal sulcus 51 170
-16 5 51 Left superior frontal sulcus 51 171
-30 -1 50 Left superior frontal sulcus 51 171
20 5 51 Right superior frontal sulcus 51 171
20 18 41 Right superior frontal sulcus 51 171
46 -61 21 Right parallel sulcus/MT gyrus 54 177
40 -60 40 Right intraparietal sulcus 54 177
48 -29 54 Intraparietal sulcus 65 203
-51 -28 14 Left superior temporal sulcus 73 228
-20 32 52 Left superior frontal sulcus 74 229
-46 47 -2 Left middle frontal sulcus 74 229
24 -18 62 Right rolando sulcus 74 229
53 30 21 Inferior frontal sulcus 80 250
-39 21 21 Inferior frontal sulcus 80 250
30 -1 53 Right posterior superior frontal sulcus 81 253
42 3 29 Right middle frontal gyrus/precentral sulcus 81 253
-46 1 29 Left middle frontal gyrus/precentral sulcus 81 253
-28 0 44 Left posterior superior frontal sulcus 81 253
24 -24 33 Right deep central sulcus 89 286
22 -11 43 Right deep central sulcus 89 288
-2 -96 0 Calcarine sulcus 105 328
-50 -50 40 Lateral bank of the intraparietal sulcus 109 338
-54 -63 27 Left superior occipital sulcus 121 374
-33 -57 48 Left intraparietal sulcus 121 375
30 -76 35 Right intraparietal sulcus 121 375
39 -78 11 Right superior occipital sulcus 121 375
-54 -63 27 Left superior occipital sulcus 121 376
-33 -57 48 Left intraparietal sulcus 121 377
30 -76 35 Right intraparietal sulcus 121 377
29 17 46 Left superior frontal sulcus 121 379
-25 15 48 Right superior frontal sulcus 121 379
-33 -57 48 Left intraparietal sulcus 121 379
30 -76 35 Right intraparietal sulcus 121 379
40 11 25 Right inferior frontal sulcus 129 395
-44 3 26 Left inferior frontal sulcus 129 396
40 11 25 Right inferior frontal sulcus 129 396
-44 3 26 Left inferior frontal sulcus 129 397
38 0 24 Right precentral sulcus 135 417
-22 0 40 Left precentral sulcus/callosomarginal sulcus 135 417
-8 -78 8 Calcarine sulcus 135 418
-36 -8 44 Left precentral sulcus 135 419
28 -8 52 Right precentral sulcus 135 419
36 -34 -12 Fundus of the right collateral sulcus 146 449
37 -64 16 Superior temporal sulcus 150 462
50 -15 52 Posterior bank of central sulcus 151 465
47 -14 52 Posterior bank of central sulcus 151 466
-49 -50 9 Left superior temporal sulcus 154 472
48 -55 20 Right superior temporal sulcus 154 473
-53 -48 9 Left superior temporal sulcus 154 473
-49 -50 13 Left superior temporal sulcus 154 474
52 -38 7 Right superior temporal sulcus 168 515

Summary

  x     y     z   Description
-34 -27 31 Mean coordinate in left hemisphere
36 -31 32 Mean coordinate in right hemisphere
35 -29 32 Mean coordinate with ignored left/right
0 -96 -17 Minimum coordinate with ignored left/right
63 47 63 Maximum coordinate with ignored left/right
15 33 20 Standard deviation with ignored left/right
corner cube of WOROI: 160 - Sulcus

Text contexts

By contrast, faces with averted gaze (again, regardless of head orientation) yielded increased correlation between activity in the fusiform and the intraparietal sulcus, a region associated with shifting attention to the peripheryN. George; J. Driver; R. J. Dolan. Seen gaze-direction modulates fusiform activity and its coupling with other brain areas during face processing. NeuroImage 13(6 Pt 1):1102-12, 2001. PMID: 11352615. DOI: 10.1006/nimg.2001.0769. WOBIB: 18.
Cortical activation converged to demonstrate bilateral core regions in the superior and inferior parietal lobe (centered on the intraparietal sulcus), which were similarly activated during all three mental rotation tasksK. Jordan; H. J. Heinze; K. Lutz; M. Kanowski; L. Jancke. Cortical activations during the mental rotation of different visual objects. NeuroImage 13(1):143-52, 2001. PMID: 11133317. DOI: 10.1006/nimg.2000.0677. WOBIB: 25.
We also found category-related responses in the dorsal occipital cortex and in the superior temporal sulcusA. Ishai; L. G. Ungerleider; A. Martin; J. V. Haxby. The representation of objects in the human occipital and temporal cortex. Journal of Cognitive Neuroscience 12 Suppl 2:35-51, 2000. PMID: 11506646. DOI: 10.1162/089892900564055. FMRIDCID: 2-2000-1113D. WOBIB: 28.
The pattern of activation during viewing of biological motion was located within a small region on the ventral bank of the occipital extent of the superior-temporal sulcus (STS)E. Grossman; M. Donnelly; R. Price; D. Pickens; V. Morgan; G. Neighbor; R. Blake. Brain areas involved in perception of biological motion. Journal of Cognitive Neuroscience 12(5):711-20, 2000. PMID: 11054914. WOBIB: 33.
Here we show, using functional magnetic resonance imaging in human volunteers, that voice-selective regions can be found bilaterally along the upper bank of the superior temporal sulcus (STS)P. Belin; Robert J. Zatorre; P. Lafaille; P. Ahad; B. Pike. Voice-selective areas in human auditory cortex. Nature 403(6767):309-12, 2000. PMID: 10659849. DOI: 10.1038/35002078. WOBIB: 42.
Pursuit performance, relative to visual fixation, elicited activation in three areas known to contribute to eye movements in humans and in nonhuman primates: the frontal eye field, supplementary eye field, and intraparietal sulcusR. A. Berman; C. L. Colby; C. R. Genovese; J. T. Voyvodic; B. Luna; K. R. Thulborn; J. A. Sweeney. Cortical networks subserving pursuit and saccadic eye movements in humans: an FMRI study. Human Brain Mapping 8(4):209-25, 1999. PMID: 10619415. WOBIB: 46.
The only site activated during manipulation with the tool, compared with the fingers, with the right hand was the lateral edge of the right intraparietal sulcus (IPS)K. Inoue; R. Kawashima; Motoaki Sugiura; A. Ogawa; T. Schormann; Karl Zilles; Hiroshi Fukuda. Activation in the ipsilateral posterior parietal cortex during tool use: a PET study. NeuroImage 14(6):1469-75, 2001. PMID: 11707103. DOI: 10.1006/nimg.2001.0942. WOBIB: 48.
Maintenance of orientations involved a distributed fronto-parietal network, that is, left and right lateral superior frontal sulcus (SFSl), bilateral ventrolateral prefrontal cortex (VLPFC), bilateral precuneus, and right superior parietal lobe (SPL)L. Cornette; P. Dupont; E. Salmon; G. A. Orban. The neural substrate of orientation working memory. Journal of Cognitive Neuroscience 13(6):813-28, 2001. PMID: 11564325. DOI: 10.1162/08989290152541476. WOBIB: 51.
A more medial superior frontal sulcus region (SFSm) was identified as being instrumental in the manipulative operation of updating orientations retained in the WML. Cornette; P. Dupont; E. Salmon; G. A. Orban. The neural substrate of orientation working memory. Journal of Cognitive Neuroscience 13(6):813-28, 2001. PMID: 11564325. DOI: 10.1162/08989290152541476. WOBIB: 51.
Conjunction analysis revealed a network of brain areas jointly activated during conscious REST as compared to the nine cognitive tasks, including the bilateral angular gyrus, the left anterior precuneus and posterior cingulate cortex, the left medial frontal and anterior cingulate cortex, the left superior and medial frontal sulcus, and the left inferior frontal cortexB. Mazoyer; L. Zago; E. Mellet; S. Bricogne; O. Etard; O. Houde; F. Crivello; M. Joliot; L. Petit; N. Tzourio-Mazoyer. Cortical networks for working memory and executive functions sustain the conscious resting state in man. Brain Research Bulletin 54(3):287-298, 2001. PMID: 11287133. WOBIB: 74.
Frontal activations were found in a region that seems implicated in visual short-term memory (posterior parts of the superior sulcus and the middle gyrus)Claus Bundesen; Axel Larsen; Soren Kyllingsbaek; Olaf B. Paulson; Ian Law. Attentional effects in the visual pathways: a whole-brain PET study. Experimental Brain Research 147(3):394-406, 2002. PMID: 12428147. DOI: 10.1007/s00221-002-1243-1. WOBIB: 81.
The ACC site of reduced rCBF was in areas 8 and 32 and that in the PCC included much of areas 29/30 in the callosal sulcus, areas 23b and 31 on the cingulate gyral surface and parietal area 7mBrent A. Vogt; Stuart Derbyshire; Anthony K. Jones. Pain processing in four regions of human cingulate cortex localized with co-registered PET and MR imaging. European Journal of Neuroscience 8(7):1461-73, 1996. PMID: 8758953. WOBIB: 100.
There were activations during both conditions in the supplementary motor area (stronger and more inferior in the active condition) and inferior parietal cortex (on the convexity during active movements and in the depth of the central sulcus during passive movements)C. Weiller; M. Juptner; S. Fellows; M. Rijntjes; G. Leonhardt; S. Kiebel; S. Muller; H. C. Diener; A. F. Thilmann. Brain representation of active and passive movements. NeuroImage 4(2):105-110, 1996. PMID: 9345502. FMRIDCID: . WOBIB: 151.
This strategy identified an area of heteromodal cortex in the left superior temporal sulcus that exhibited significant supra-additive response enhancement to matched audio-visual inputs and a corresponding sub-additive response to mismatched inputsGemma A. Calvert; Ruth Campbell; Michael J. Brammer. Evidence from functional magnetic resonance imaging of crossmodal binding in the human heteromodal cortex. Current Biology 10(11):649-657, 2000. PMID: 10837246. FMRIDCID: . WOBIB: 154.
Phonological processing of words and pseudowords in a syllable-counting task resulted in activation of the dorsal aspect of the left inferior frontal gyrus near the inferior frontal sulcus (BA 44/45) compared to a perceptual control task, with greater activation for nonwords compared to wordsRussell A. Poldrack; Anthony D. Wagner; Matthew W. Prull; John E. Desmond; Gary H. Glover; John D. E. Gabrieli. Functional Specialization for Sematic and Phonological Processing in the Left Inferior Prefrontal Cortex. NeuroImage 10(1):15-35, 1999. PMID: 10385578. DOI: 10.10061/nimg.1999.0441. FMRIDCID: . WOBIB: 178.
Duringimmediate pointingthere was additional activation of left inferior parietal lobule close to the intraparietal sulcus, and when compared withpointing to the previous,dorsolateral prefrontal cortex bilaterallyF. Lacquaniti; Daniela Perani; E. Guigon; V. Bettinardi; M. Carrozzo; F. Grassi; Yves Rossetti; F. Fazio. Visuomotor Transformations for Reaching to Memorized Targets: A PET study. NeuroImage 5(2):129-146, 1997. PMID: 9345543. DOI: 10.1006.nimg.1996.0254. FMRIDCID: . WOBIB: 182.
In particular, the specific activation of intraparietal sulcus and prefrontal cortex inimmediate pointingappears characteristic of a network for visuospatial working memoryF. Lacquaniti; Daniela Perani; E. Guigon; V. Bettinardi; M. Carrozzo; F. Grassi; Yves Rossetti; F. Fazio. Visuomotor Transformations for Reaching to Memorized Targets: A PET study. NeuroImage 5(2):129-146, 1997. PMID: 9345543. DOI: 10.1006.nimg.1996.0254. FMRIDCID: . WOBIB: 182.

Text count

Bib -> Asymmetry | Author | ICA | NMF | Novelty | Statistics | SVD | Title | WOBIB ]
Roi -> Alphabetic | Hammers | Tzourio-Mazoyer | Svarer | Top | Functional areas | Brodmann areas ]
[ Brede Database ]
Automatically constructed by Brede Toolbox through brede_roi_roi2html, 2006-10-05T16:04:51