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7.9 KiB
title, docid, authors, breadcrumbs, category, documentVersionId, imageCount, lastUpdated, pageDescription, pageKeywords, pageTitle, enhancedTitle, type, references, breadcrumbs
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| Visual Network | 404625d9-3125-4923-9f9d-53d0f81c3542 |
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Brain | 6e469918-0145-4a20-93a5-2cc5da2e3cac | 1 | 02/23/21 | Visual Network | Brain, Anatomy, Brain Network Anatomy, Visual Network | Visual Network | STATdx | Visual Network | ANATOMY | true |
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title: "Visual Network" docid: "404625d9-3125-4923-9f9d-53d0f81c3542" authors:
- key: "15a1b74a-5576-4e3a-a193-2d84e315fbd0" value: "Jeffrey S. Anderson, MD, PhD" breadcrumbs:
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- name: "Brain Network Anatomy" slug: "brain-network-anatomy" treeNodeId: "95c502bb-ba84-4fbc-be46-f1f2600ce4dd"
- name: "Visual Network" slug: "visual-network" treeNodeId: null category: "Brain" documentVersionId: "6e469918-0145-4a20-93a5-2cc5da2e3cac" imageCount: 1 lastUpdated: "02/23/21" pageDescription: "Visual Network" pageKeywords: "Brain, Anatomy, Brain Network Anatomy, Visual Network" pageTitle: "Visual Network | STATdx" enhancedTitle: "Visual Network" type: "ANATOMY" references: true breadcrumbs:
- "Brain"
- "Anatomy"
- "Brain Network Anatomy"
- "Visual Network"
IMAGING ANATOMY
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Overview
- Visual cortex consumes virtually all of the occipital lobe, from primary sensory areas along the calcarine sulcus and occipital pole through the posterior parietal and temporal lobes
- 2 primary sensory processing streams - Dorsal pathway ("where" pathway) extends from V1/V2 to V3 and into medial posterior parietal lobe - Processes localization of stimuli in space, visual attention, spatial awareness, coordination of reaching and grasping - Ventral pathway ("what" pathway) extends from V1/V2 to V4, V5/MT, and anterior inferior temporal lobe (AIT) - Processes complex feature detection in visual stimuli, motion perception
- Multiple bilateral visual processing areas, each with a complete retinotopic map of visual space (V1, V2, V3, V4, V5/MT, V6, IPS regions)
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Primary (Striate) Visual Cortex (V1)
- 1st visual area receiving sensory input in the cortex
- Located along margins of the calcarine sulcus
- Foveal vision near occipital pole, with more peripheral vision extending anteriorly
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Extrastriate Visual Cortex (V2, V3, V4, V5/MT)
- V2 (Brodmann area 18): Immediately borders V1, with inverted retinotopic maps
- V3 (Brodmann area 19): Superior and anterior area V2, part of dorsal stream - Processes progressively more abstract feature extraction - V3A and V3B retinotopic maps
- V4 (Brodmann area 19 ): Anterior to V2 in lateral occipital cortex, part of ventral stream - Lateral occipital: LO-1, LO-2 retinotopic maps along lateral occipital cortex anterior to V3 - Ventral occipital, human V4: VO-1, VO-2, hV4 retinotopic maps along inferomedial occipital cortex anterior to V3
- V5 (Brodmann area 19): Middle temporal gyrus at temporooccipital junction; processes motion, color, and attention perception; part of ventral stream
- V6 (Brodmann area 19): Along parietooccipital sulcus (medial motion area, analogue to primate mediodorsal area), part of dorsal stream
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Lateral Geniculate Nuclei of Thalamus
- Visualized on axial slice through superior colliculus at posterior lateral margin of the thalamus
- Endpoint of optic tracts
- Postsynaptic fibers extend anteromedial along Meyer loop, then posteriorly along optic radiations through visual cortex
- Additional fibers likely extend through lingual gyrus of occipital lobe to reach primary visual cortex layer 4
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Intraparietal Sulcus (IPS0/V7, IPS1, IPS2, IPS3, IPS4)
- Posterior parietal regions processing stimulus attention
- Visual attentional regions along medial aspect of intraparietal sulcus
- Multiple areas with complete retinotopic map of visual space (IPS0, IPS1, IPS2, IPS3, IPS4)
ANATOMY IMAGING ISSUES
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Imaging Recommendations
- Expanding ring, rotating hemifield tasks for visual field mapping
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Imaging Pitfalls
- Should check visual acuity prior to fMRI visual field mapping
CLINICAL IMPLICATIONS
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Clinical Importance
- Vascular loops (P1 segment) can compress optic tracts and result in otherwise unexplained quadrantanopsia
- Presurgical visual field mapping usually focused on preserving V1/V2 retinotopic maps and foveal vision, optic radiations
- DTI best for imaging course of optic radiations for presurgical mapping
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References
Selected References
- Ko H et al: The emergence of functional microcircuits in visual cortex. Nature. 496(7443):96-100, 2013
- Baldassarre A et al: Individual variability in functional connectivity predicts performance of a perceptual task. Proc Natl Acad Sci U S A. 109(9):3516-21, 2012
- Gaglianese A et al: Evidence of a direct influence between the thalamus and hMT+ independent of V1 in the human brain as measured by fMRI. Neuroimage. 60(2):1440-7, 2012
- Chadick JZ et al: Differential coupling of visual cortex with default or frontal-parietal network based on goals. Nat Neurosci. 14(7):830-2, 2011
- Wandell BA et al: Imaging retinotopic maps in the human brain. Vision Res. 51(7):718-37, 2011
- Wendt J et al: The functional connectivity between amygdala and extrastriate visual cortex activity during emotional picture processing depends on stimulus novelty. Biol Psychol. 86(3):203-9, 2011
- Yeo BT et al: The organization of the human cerebral cortex estimated by intrinsic functional connectivity. J Neurophysiol. 106(3):1125-65, 2011
- Zou Q et al: Functional connectivity between the thalamus and visual cortex under eyes closed and eyes open conditions: a resting-state fMRI study. Hum Brain Mapp. 30(9):3066-78, 2009
- Shmuel A et al: Neuronal correlates of spontaneous fluctuations in fMRI signals in monkey visual cortex: Implications for functional connectivity at rest. Hum Brain Mapp. 29(7):751-61, 2008
- Wandell BA et al: Visual field maps in human cortex. Neuron. 56(2):366-83, 2007
- Nir Y et al: Widespread functional connectivity and fMRI fluctuations in human visual cortex in the absence of visual stimulation. Neuroimage. 30(4):1313-24, 2006
- Hampson M et al: Changes in functional connectivity of human MT/V5 with visual motion input. Neuroreport. 15(8):1315-9, 2004
- Sereno MI et al: Borders of multiple visual areas in humans revealed by functional magnetic resonance imaging. Science. 268(5212):889-93, 1995
Images
Visual Network
The visual network cluster is shown from a 6-network parcellation of the brain based on whole-brain functional connectivity in 1,353 subjects. Regions within this cluster include striate and extrastriate visual cortex, medial parietal visual attentional regions, and lateral geniculate nuclei of the thalamus.