Visual Sensation - PowerPoint PPT Presentation

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Visual Sensation

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Visual Sensation & Perception How do we see? – PowerPoint PPT presentation

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Title: Visual Sensation


1
Visual Sensation Perception
  • How do we see?

2
Structure of the eye
3
The Retina
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Visual Receptors
  • Rods
  • Slowly adapting
  • Black White vision
  • 120 million None in fovea
  • Cones
  • Rapidly adapting
  • Color vision
  • 6 million 50,000 in fovea

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Chemistry of the photoreceptor
  • Light-sensitive protein retinal (a pigment)
    absorbs a photon, causing the retinal to change
    shape.
  • Through a series of enzyme-based chemical
    reactions, this causes a closing of the Na
    channels in the receptor.
  • This has the effect of hyperpolarizing the cell,
    since sodium can no longer enter.
  • This inhibits the latent activity of the cell,
    releasing less glutamate into the next layer of
    the retina - the bipolar cells.
  • This causes one set of bipolar cells to be
    hyperpolarized (those that had excitatory
    connections with the receptor) and one set to be
    depolarized (those that had inhibitory
    connections).

10
Retinal Ganglion cells
  • Gather information from many rods and cones
    across an area of the retina.
  • How many rods and cones depends on the size of
    the ganglion cells receptive field
  • The closer to the fovea, the smaller the
    receptive field.
  • Project out of the eye through the optic nerve,
    creating a blind spot.
  • 1 million retinal ganglion cells (receiving
    signals from 125 million receptors).

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Receptive fields of retinal ganglion cells
  • Center-surround
  • Most are excitatory center, inhibitory surround.
  • Some are the opposite

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Out of the retina
  • Signals from the two eyes cross over to the
    opposite brain hemisphere at the optic chiasm.
  • Not all signals from an eye go to contra-lateral
    hemisphere.
  • Which hemisphere the signal goes to is based on
    which visual hemifield the ganglion cell receives
    information from.

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Into the brain
  • Ganglion cells synapse in the lateral geniculate
    nucleus (LGN) of the thalamus.
  • For comparison, the auditory nerve synapses in
    the medial geniculate nucleus.
  • The LGN divides the signals into layers depending
    on which eye they come from, and whether they
    come from the fovea or not.
  • 1, 4, 6 from the contralateral eye 2, 3, and 5
    from the ipsilateral eye.
  • 1 and 2 (magnocellular levels) from the fovea.
  • Other layers (parvocellular) from extra-foveal
    regions.
  • 400,000 cells leave the LGN

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V1
  • From the LGN, the signals are sent to area V1 in
    the very back of the occipital lobe.
  • Signals are organized into a retinotopic map
    based on where on the retina they come from, and
    which eye they come from.
  • All cells project to layer IV of striate cortex,
    but M and P cells project to slightly different
    parts.
  • Furthermore, P cells project from layer IV into
    layers II and III, creating blob and interblob
    areas.

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Feature detectors in V1
  • The retinotopic map is not simply a light/dark
    detector. Signals are beginning to be combined
    into simple feature detectors that can detect
    lines at various orientations.
  • All of the feature detectors for a particular
    area of the retina are anatomically organized
    into a column.
  • A hypercolumn is two columns from corresponding
    parts of both retinas.

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Beyond V1
  • From V1, signals go to area V2 where the combine
    into more complex features (corners and simple
    shapes).
  • After V2, the signal splits into two streams of
    information.
  • The what stream passes through V3 (which does
    color detection) into the temporal lobe.
  • The where stream passes through V4 (which aids
    with motion detection) into the parietal lobe.

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