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Cards (196)

  • Sensation
    Registering of sensory information by the brain
  • Perception
    Assignment of meaning to that sensory information
  • How is sensory information implemented neurally?
    1. Sensory organs absorb energy
    2. Energy is transduced into a neural signal
    3. The neural signal is sent throughout the brain where further processing takes place
  • Light and the electromagnetic spectrum
    • Humans' sensory system is only responsive to a narrow wavelength called the visible spectrum
    • Wavelength = colour and amplitude = brightness
  • Cornea
    Transparent, involved in focusing an image onto the retina
  • Choroid (vascular tunic)

    Eyes' blood supply providing nutrients to keep tissue alive and discard waste
  • Iris
    Muscle that gives eye its colour
  • Pupil
    Opening between the iris allowing more or less light
  • Lens
    Focusing near and far - cataracts = cloudy lens
  • Retina
    Contains photoreceptors (rods and cones) that convert electromagnetic energy into a neural signal
  • Rods and cones
    • 120 million rods and 7 million cones
    • Perform transduction - converting electromagnetic energy into a neural signal
    • Cones detect colour and function in the day with high resolution
    • Rods don't detect colour, function at night and have low resolution
  • Bipolar cells and retinal ganglion cells

    Optic nerve, blind spot
  • Sensation
    Decreases
  • Perception
    Increases
  • Optic axis
  • Brain organisation
    • 4 lobes - frontal, parietal, occipital and temporal
    • Cortex - all the convulsions
    • Subcortex - everything below
  • Visual pathways
    1. Eyes → subcortex
    2. Eyes → lateral geniculate nucleus (LGN) - half of the fibres from each eye remain on the same side and half cross over
    3. Subcortex → cortex - LGN → primary visual cortex (V1) in the occipital lobe
  • Ventral stream
    Involved in pattern vision, also known as the 'what' pathway
  • Dorsal stream
    Involved in spatial vision, also known as the 'where' pathway
  • Electrophysiology studies

    • Drop wires into brain and listen to action potentials of neurons
    • All neurons (cells) fire at a baseline rate
    • If a cell is interested in something it will either increase or decrease its firing rate relative to baseline
  • From eyes to V1
    1. Rods and cones - changes in illumination
    2. Retinal ganglion (RG) cells - spots of light
    3. LGN cells - spots of light
    4. V1 cells - lines in different orientations
  • Grandmother cells
    Cells that respond to discrete features, also known as feature detectors
  • Retinotopic mapping
    • Point-to-point mapping of external world onto a brain area
    • V1 and before: there is retinotopic mapping
    • After V1: no retinotopic mapping
  • As you go higher into the visual system (away from eyes) the information becomes more complex
  • The features that drive a cell change from basic illumination levels - rods and cones to spots of light - RG cells, LGN cells to lines -V1 to complex features- IT cortex cells
  • Lateral inhibition
    • RGN likes dots- centre-surrounded architecture
    • Enhances contrast
    • Brightens contrast
  • Herman grid illusion arises out of centre-surrounded architecture of RG cells
  • If bathed in diffuse light or darkness, no information is sent to the brain
  • If presented with a light or dark dot, maximum signal
  • At the fovea, cones are more tightly packed so RG cell assembly is smaller and falls completely within the white lines
  • When you foveate the intersection
  • The right side of the brain looks at the left visual word-left side of brain looks at right visual field
  • Blindsight
    • Patient DB had surgical removal of a tumor in right occipital lobe
    • He suffers from left homonymous hemianopia
    • Can't identify a static visual image but can localise it in space
    • Can't identify a moving visual object but can localise it in space
  • Achromatopsia
    • Absence of colour vision
    • Damage to V4 or missing cone photoreceptors
    • People with achromatopsia are colour blind
    • Only see black, white and shades of grey
  • Akinetopsia
    • Absence of motion vision
    • Damage to V5 (MT)
    • Difficulty perceiving objects in motion
  • Appreciative agnosia
    • Failure of object recognition due to failure of visual perception
    • Preserved elementary visual function such as colour and motion perception
    • Poor matching and copying
    • Neuropathology: bilateral damage to V1
  • Dorsal simultagnosia
    • Failure of object recognition due to a spatial perceptual impairment
    • Preserved colour and motion perception
    • Can recognise objects but no more than one at a time
    • Neuropathology: bilateral damage to parietal lobes
  • Ventral simultagnosia
    • Failure of object recognition due to a complex perceptual impairment
    • Preserved colour and motion perception
    • Can recognise objects clearly but not more than one at a time
    • Can see multiple objects but not clearly
    • Neuropathology: ventral stream beyond V4
  • Associate agnosia
    • Failure of object recognition due to a higher order complex perceptual impairment
    • Preserved colour and motion perception
    • Seemingly normal copying - but it's not
    • Copying is accurate but "slavish"
  • Incomplete figures test and embedded figures test