WOROI: 294 - Vermis
 
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WOROI: 294 - Vermis

Medial part of the cerebellum

Abbreviation: Ver

Variation: Cerebellar vermis
Variation: Vermis of cerebellum
Variation: Vermis cerebelli

External databases

Wikipedia: Cerebellar vermis

Taxonomy

ParentsSiblingsChildren
Cerebellum
Cerebellar cortex
  Vermis of anterior lobe
Vermis of posterior lobe

Talairach coordinates

  x     y     z   Lobar anatomy WOBIB WOEXP
16 -64 -20 Vermis 1 1
-3 -65 -9 Left superior vermis 3 7
2 -55 -17 Right cerebellum (vermis) 17 50
2 -43 -5 Right cerebellum (vermis) 17 50
-2 -78 -28 Vermis 30 100
0 -61 -21 Vermis 45 148
-7 -59 -12 Vermis - left cerebellum 48 154
-4 -59 -21 Left vermis 54 176
-2 -45 -10 Cerebellar vermis 66 204
-2 -71 -17 Cerebellar vermis 81 253
0 -67 -13 Cerebellar vermis 81 255
-3 -56 -14 Cerebellar vermis 95 299
1 -51 -18 Cerebellar vermis 102 318
8 -53 -9 Cerebellar vermis 102 319
1 -49 -16 Cerebellar vermis 102 320
-8 -96 -24 Vermis of cerebellum 105 325
8 -78 -28 Vermis of cerebellum 105 326
4 -92 -20 Vermis of cerebellum 105 327
-8 -71 -11 Cerebellar vermis 118 367
10 -55 -9 Cerebellar vermis 118 367
-6 -55 -14 Cerebellar vermis 118 368
-8 -42 -20 Cerebellar vermis 118 368
26 -55 -18 Cerebellar vermis 118 368
4 -54 0 Cerebellar vermis 130 403
-2 -37 -7 Cerebellum (vermis) 137 424
2 -54 -20 Cerebellar vermis 177 541
0 -28 -20 Cerebellar vermis 177 544
2 -50 -20 Cerebellar vermis 177 547
4 -58 -24 Left cerebellar vermis 182 573
2 -60 -16 Cerebellar vermis 182 574
6 -64 -16 Cerebellar vermis 182 575

Summary

  x     y     z   Description
-4 -61 -16 Mean coordinate in left hemisphere
6 -58 -16 Mean coordinate in right hemisphere
5 -59 -16 Mean coordinate with ignored left/right
0 -96 -28 Minimum coordinate with ignored left/right
26 -28 0 Maximum coordinate with ignored left/right
5 14 7 Standard deviation with ignored left/right
corner cube of WOROI: 294 - Vermis

Text contexts

Significant rCBF increases were found for both groups in the frontal eye fields, supplementary eye fields, cerebellar vermis and putamina/thalamiIan Law; Claus Svarer; Egill Rostrup; Olaf B. Paulson. Parieto-occipital cortex activation during self-generated eye movements in the dark. Brain 121 ( Pt 11):2189-200, 1998. PMID: 9827777. WOBIB: 1.
Micturition versus rest was associated with bilateral activation of areas close to the postcentral gyrus, inferior frontal gyrus, globus pallidus, cortex cerebelli, vermis and midbrainS. Nour; Claus Svarer; J. K. Kristensen; O. B. Paulson; I. Law. Cerebral activation during micturition in normal men. Brain 123 ( Pt 4):781-9, 2000. PMID: 10734009. WOBIB: 17.
In the resting state of normal consciousness (compared with meditation as a baseline), differential activity was found in dorso-lateral and orbital frontal cortex, anterior cingulate gyri, left temporal gyri, left inferior parietal lobule, striatal and thalamic regions, pons and cerebellar vermis and hemispheres, structures thought to support an executive attentional networkH. C. Lou; Troels W. Kjaer; Lars Friberg; G. Wildschiodtz; Søren Holm; Markus Nowak. A 15O-H2O PET study of meditation and the resting state of normal consciousness. Human Brain Mapping 7(2):98-105, 1999. PMID: 9950067. WOBIB: 22.
The detected brain structures implicated in mental transformation of size were primarily located in the dorsal pathways, comprising structures in the occipital, parietal, and temporal transition zone (predominantly in the left hemisphere), posterior parietal cortex (bilaterally), area MT/V5 (left), and vermis (bilaterally)A. Larsen; C. Bundesen; S. Kyllingsbaek; O. B. Paulson; I. Law. Brain activation during mental transformation of size. Journal of Cognitive Neuroscience 12(5):763-74, 2000. PMID: 11054919. WOBIB: 30.
The war-related condition, as compared to the neutral, increased rCBF in the right sensorimotor areas (Brodmann areas 4/6), extending into the primary sensory cortex (areas 1/2/3), and the cerebellar vermisAnna Pissiota; Orjan Frans; Manuel Fernandez; Lars von Knorring; Hakan Fischer; Mats Fredrikson. Neurofunctional correlates of posttraumatic stress disorder: a PET symptom provocation study. European Archives of Psychiatry and Clinical Neuroscience 252(2):68-75, 2002. PMID: 12111339. DOI: 10.1007/s004060200014. WOBIB: 66.
Subcortical activations were found in cerebellum (particularly the vermis) and in the thalamus with the focus in a region comprising the lateral geniculate nucleus, the pulvinar, and adjacent parts of the reticular nucleusClaus 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.
These structures include the contralateral M1/S1 cortex, bilateral S2 and mid-insular cortex, contralateral VP thalamus, medial ipsilateral thalamus, and the vermis and paravermis of the cerebellumK. L. Casey; T. J. Morrow; J. Lorenz; S. Minoshima. Temporal and spatial dynamics of human forebrain activity during heat pain: analysis by positron emission tomography. Journal of Neurophysiology 85(2):951-9, 2001. PMID: 11160525. WOBIB: 95.
Significant increases in rCBF to the 43 degrees C stimuli were found in the contralateral ventral posterior thalamus, lenticular nucleus, medial prefrontal cortex (Brodmann's areas 10 and 32), and cerebellar vermisK. L. Casey; S. Minoshima; T. J. Morrow; R. A. Koeppe. Comparison of human cerebral activation pattern during cutaneous warmth, heat pain, and deep cold pain. Journal of Neurophysiology 76(1):571-81, 1996. PMID: 8836245. WOBIB: 102.
The ipsilateral premotor cortex and thalamus, and the medial dorsal midbrain and cerebellar vermis, also showed significant rCBF increasesK. L. Casey; S. Minoshima; T. J. Morrow; R. A. Koeppe. Comparison of human cerebral activation pattern during cutaneous warmth, heat pain, and deep cold pain. Journal of Neurophysiology 76(1):571-81, 1996. PMID: 8836245. WOBIB: 102.
Both genders showed a bilateral activation of premotor cortex in addition to the activation of a number of contralateral structures, including the posterior insula, anterior cingulate cortex and the cerebellar vermis, during heat painP. E. Paulson; S. Minoshima; T. J. Morrow; K. L. Casey. Gender differences in pain perception and patterns of cerebral activation during noxious heat stimulation in humans. Pain 76(1-2):223-9, 1998. PMID: 9696477. WOBIB: 118.
Compared withvisual detectionthere was activation of primary sensorimotor cortex, ventrolateral precentral gyrus, inferior frontal gyrus in the opercular region, supramarginal gyrus, and middle occipital gyrus, all these sites in the hemisphere (left) contralateral to the moving limb, and cerebellar vermis, during bothimmediate pointingandpointing to the previousF. 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

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