Central Visual Processing Chapter 10 PDF
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This document details visual processing, learning objectives, and the visual pathways of the brain. It covers concepts like retinal inputs, LGN layers, receptive fields, and parallel processing, while providing relevant diagrams and figures illustrating these concepts..
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Central Visual Processing Chapter 10 Discuss the complex processing pathways of visual information in the brain Eye LGN Learning V1 / striate cortex objectives Beyond V1 (dorsal/ventral streams)...
Central Visual Processing Chapter 10 Discuss the complex processing pathways of visual information in the brain Eye LGN Learning V1 / striate cortex objectives Beyond V1 (dorsal/ventral streams) Focus on major anatomical landmarks as key “stations” along the pathway Know what new vocab words actually mean! Introduction Introduction Introduction Vision Perception combines individually identified properties of visual objects: color, form, movement Achieved by simultaneous, parallel processing in several visual pathways Parallel processing More like the sound produced by an orchestra than by individual musicians Neurons in the visual system Neural processing results in perception. Pathway serving conscious visual perception originates in the Central visual retina. processing Progresses to lateral geniculate nucleus, primary visual cortex, pathway and higher order visual areas in occipital, temporal, and parietal lobes Overlapping receptive fields Sensitive to different facets of visual input Left hemifield projects to right side of brain. (& vice versa) Ganglion cell axons from nasal retina cross in optic chiasm. Right & left visual hemifields Left hemifield projects to right side of brain. (& vice versa) Ganglion cell axons from nasal retina cross in optic chiasm. Right & left visual hemifields Left hemifield projects to right side of brain. (& vice versa) Ganglion cell axons from nasal retina cross in optic chiasm. Right & left visual hemifields Hypothalamus: role in biological rhythms, including sleep and wakefulness Nonthalamic Pretectum: control size of the pupil, certain types of eye targets of movement optic tract Superior colliculus: orients the eyes in response to new stimuli— move fovea to objects of interest Six layers in the lateral geniculate nucleus of the Retinal inputs thalamus to LGN layers Not random – top layers and bottom layers have different functions! Inputs segregated by eye and ganglion cell type Parvocellular layers for color vision processing Magnocellular layers for non-color vision processing Koniocellular layers function are a bit of a mystery Organization of the LGN Receptive fields of LGN neurons: almost identical to the ganglion cells that feed them LGN Magnocellular LGN neurons: receptive large center-surround receptive fields with transient response fields Parvocellular LGN cells: small center-surround receptive fields with sustained response Primary visual cortex (also called V1, striate cortex, or Brodmann area 17) provides 80% of the synaptic input to Nonretinal the LGN—role not clearly identified. inputs to the “Top–down” modulation may gate “bottom-up” input LGN from LGN back to cortex. Brain stem neurons provide modulatory influence on neuronal activity. Primary visual cortex (also called V1, striate cortex, or Brodmann area 17) provides 80% of the synaptic input to Nonretinal the LGN—role not clearly identified. inputs to the “Top–down” modulation may gate “bottom-up” input LGN from LGN back to cortex. Brain stem neurons provide modulatory influence on neuronal activity. Retinotopic map of the visual field onto a target structure (retina, LGN, superior colliculus, striate cortex) Central visual field (fovea) overrepresented in map Discrete point of light can activate many cells in the target structure due to overlapping receptive fields. Perception is based on the brain’s interpretation of distributed patterns of activity—not a literal map as in a picture. Retinotopy Striate cortex (V1, primary visual cortex) has six layers as well Layers of the striate cortex Layers I to VI Spiny stellate cells: spine-covered Layers of the dendrites—layer IVC striate cortex Pyramidal cells: spines and thick apical dendrite—layers III, IVB, V, VI Inhibitory neurons: lack spines—all cortical layers—form local connections Magnocellular LGN neurons project primarily to layer IVC. Inputs to the Parvocellular LGN neurons project to striate cortex layer IVC. Koniocellular LGN axons make synapses primarily in layers I and III. Studied with transneuronal autoradiography from retina, to LGN, to striate cortex Preferential information processing from one eye Unsure if bug or feature evolutionarily! Ocular dominance columns Studied with transneuronal autoradiography from retina, to LGN, to striate cortex Preferential information processing from one eye Unsure if bug or feature evolutionarily! Binocular deprivation can make them go away! Ocular dominance columns Mixing First binocular neurons information found in striate cortex— most layer III neurons are from both binocular (but not layer IV). eyes Layer II, III, and IVB cells project to other cortical areas. Outputs of the Layer V cells project to the superior striate cortex colliculus and pons. Layer VI cells project back to the LGN. Cytochrome oxidase: mitochondrial enzyme used for cell metabolism Blobs: cytochrome oxidase- stained pillars in striate cortex Cytochrome Each blob centered on an ocular dominance column in layer IV. oxidase blobs Receive koniocellular inputs from LGN Likely important for color vision processing since they are made of color wavelength-sensitive cells Monocular receptive fields Layer IVC: similar to LGN cells Layer IVC: insensitive to the wavelength Physiology of Layer IVC: center- surround color opponency striate cortex Binocular receptive fields – orientation Most neurons in layers superficial to IVC are selectivity binocular. Two receptive fields—one for each eye Receptive fields help distinguish orientation selectivity Receptive fields help to distinguish motion & direction selectivity Neuron fires action potentials in direction-dependent response to moving bar of light. Physiology of striate cortex – direction selectivity Simple cells: binocular, orientation-selective, elongated ON or OFF area flanked with antagonistic surround Not necessarily restricted to 1 V1 layer, but most ly found in layers 4 and 6 Receptive field may be composed of three LGN inputs from cells with aligned center-surround receptive fields. Simple cell Great for edge/border/shape detection receptive fields Complex cells: binocular, orientation-selective, ON and OFF responses to the bar of light but unlike simple cells, no distinct ON and OFF regions Also not confined to a single V1 layer, many found in layer 3 Better for movement/rotation detection Complex cell receptive fields Some blob fields Monocular No direction selectivity Likely orientation selectivity Variety of color opponency and surround organization Specialized for analysis of color Blob receptive fields? Magnocellular, blob, and parvo-interblob pathways all simultaneously contribute to visual perception Parallel processing More like the sound produced by an orchestra than by individual musicians Parallel processing pathways “Chunk” of striate cortex containing all the layers and cells needed to process a full spectrum of visual information Each module capable of analyzing every aspect of a portion of the visual field Cortical modules Occipital cortex contains many Visual areas visual processing areas that add of the brain onto the depth of information coming from V1 beyond V1 Adding on details like texture, color gradients, etc Dorsal stream Dorsal and Analysis of visual motion and the visual control of action ventral visual Ventral stream streams Perception of the visual world and the recognition of objects V1, V2, V3, MT, MST, other dorsal areas Area MT (temporal lobe) Most cells are direction-selective, respond more to the motion of objects Dorsal visual than their shape. stream Beyond area MT—three roles proposed for cells in area MST (parietal lobe) Navigation Directing eye movements Motion perception V1, V2, V3, V4, IT, other ventral areas Area V4—shape and color perception Achromatopsia: clinical syndrome caused by damage to area V4—partial or complete loss of color vision Ventral visual Area IT stream Major output of V4 Receptive fields respond to a wide variety of colors and abstract shapes. May be important for both visual perception and visual memory (such as faces) Visual perception Identifying and assigning meaning to objects Hierarchy of complex receptive fields In retinal ganglion cells: center-surround structure, sensitive to contrast and wavelength of light In striate cortex: orientation selectivity, direction selectivity, and Parallel binocularity Extrastriate cortical areas: selective responsive to complex shapes processing & (faces) and motion perception The “Grandmother cells” / “Halle Berry” cells? neuroscience Specific face-selective of vision is neurons in area IT? Probably not: perception very complex; not based on the activity of individual cells be wary of Parallel processing and reductive perception Groups of cortical areas descriptions contribute to the perception of color, motion, and object of it! meaning. Optical illusions “hack” our visual processing quirks Quiz hint! LGN layers & cell types Questions?