Deck 4: Central Visual Pathways

A) "between."
B) "cross."
C) "together."
D) "separate."

A) temporal; optic chiasm
B) nasal; optic disk
C) nasal; optic chiasm
D) temporal; optic disk

A) right; left
B) frontal; right
C) left; left
D) right; central

A) optic chiasm.
B) lateral geniculate nucleus.
C) superior colliculus.
D) none of these

A) is in guiding eye movements.
B) is in visual orienting reflexes.
C) is neither is in guiding eye movements nor is in visual orienting reflexes
D) are both is in guiding eye movements and is in visual orienting reflexes

A) the presence of auditory cells in the optic nerve.
B) multisensory cells in the superior colliculus.
C) visual cells' output to the temporal lobe.
D) multisensory cells in the lateral geniculate nucleus.

A) thalamus.
B) midbrain.
C) cerebral cortex.
D) where pathway.

A) six
B) five
C) four
D) two

A) magnocellular
B) parvocellular
C) retinotopic
D) all of these

A) The surround is as inhibitory as the surround of a retinal ganglion cell.
B) They amplify or accentuate differences in illumination.
C) They prefer borders or contours of particular orientations.
D) all of these

A) contralateral layers.
B) ipsilateral layers.
C) all layers.
D) the first two layers.

A) circular shape.
B) rectangular shape.
C) orientation-specific layout.
D) diagonal layout.

A) the shapes of their receptive fields.
B) the eye from which they receive input.
C) their response selectivity for color.
D) all of these

A) differentially sensitive to color
B) have smaller receptive fields than those of cells in the magnocellular layers
C) respond to rapid fluctuations of light intensity
D) give little response to uniform illumination

A) complex cells
B) parvocellular cells
C) hypercomplex cells
D) magnocellular cells

A) receives input from the visual cortex.
B) receives input from the reticular activating system.
C) both receives input from the visual cortex and receives input from the reticular activating system
D) neither receives input from the visual cortex nor receives input from the reticular activating system

A) occipital lobe.
B) frontal lobe.
C) temporal lobe.
D) all of these

A) visual voids.
B) visual windows.
C) scotomas.
D) retinal blanks.

A) periphery; cortical misrepresentation
B) fovea; cortical magnification
C) inferior portion; cortical magnification
D) nasal part; visual amplification
E) all of these

A) striate cortex.
B) V1.
C) Area 17.
D) all of these

A) integration of input from the two eyes
B) orientation selectivity
C) direction selectivity
D) all of these

A) one million cells (1 x 106).
B) 125 million cells (1.25 x 108).
C) 250 million cells (2.5 x 108).
D) one billion cells (1 x 109).

A) phosphenes.
B) the ambiguity problem.
C) integration of local features.
D) none of these

A) cortically blind people's ability to use sound cues for orienting.
B) cortically blind people's ability to identify the location of a light they can't see because of cortical damage.
C) residual visual abilities following retinal damage.
D) visual illusions in cortically blind people.
E) all of these.

A) orientation.
B) direction of motion.
C) both orientation and direction of motion
D) neither orientation nor direction of motion

A) orientation.
B) direction of motion.
C) both orientation and direction of motion
D) neither orientation nor direction of motion

A) orientation selectivity.
B) direction selectivity.
C) receptive field shape.
D) none of the these.

A) simple
B) damaged but viable
C) complex
D) miniature

A) ± 5 degrees.
B) ± 10 degrees.
C) ± 15 degrees.
D) ± 20 degrees.

A) obliquely oriented lines.
B) horizontally oriented lines.
C) vertically oriented lines.
D) all of these.

A) vision for moving stimuli.
B) color sensitivity of cortical cells.
C) visual loss that cannot be corrected optically.
D) visual distortion associated with ambling.

A) hypercolumn.
B) binocular disparity.
C) ocular dominance.
D) none of these.

A) binocular integration.
B) monocular separation.
C) ocular dominance.
D) both monocular separation and ocular dominance

A) monocular.
B) binocular.
C) different in their left and right eye preference for orientation and direction.
D) both monocular and different in their left and right eye preference for orientation and direction

A) are specialized for processing color information.
B) receive input from the magnocellular pathway.
C) show strong preference for contour orientation.
D) are unresponsive to visual stimulation.

A) hypercolumn.
B) binocular disparity.
C) ocular dominance.
D) none of these

A) direction.
B) motion.
C) size.
D) orientation.

A) movement of activity across the cortex as the gratings' bars move.
B) orientation columns whose width corresponds to the spatial frequency of the gratings.
C) activity in patches consistent with the size of hypercolumns.
D) all of these

A) the constant position of a region of visual space in different layers of the LGN.
B) the location of a part of the visual scene being isomorphic in different retinotopic maps.
C) the location of V1 being constant in different individuals' brains.
D) the constant response to a stimulus from anywhere within a cell's receptive field.

A) ventral stream.
B) temporal stream.
C) dorsal stream.
D) parietal stream.

A) color.
B) texture.
C) acuity.
D) flicker.

A) prosopagnosia.
B) achromatopsia.
C) akinetopsia.
D) aphasia.

A) eccentricity
B) prosopagnosia
C) Purkinje shift
D) none of these

A) there are not enough neurons to handle every possible feature.
B) individual cells cannot signal the presence of a particular stimulus feature with certainty.
C) both there are not enough neurons to handle every possible feature and individual cells cannot signal the presence of a particular stimulus feature with certainty
D) neither there are not enough neurons to handle every possible feature nor individual cells cannot signal the presence of a particular stimulus feature with certainty; visual cortical cells can act as "feature detectors"

A) phosphenes.
B) the ambiguity problem.
C) integration of local features.
D) none of these

A) tilt aftereffect.
B) adaptation.
C) prosopagnosia.
D) none of these

A) tilt aftereffect.
B) ambiguity problem.
C) direction selectivity.
D) perimetry.

A) the high metabolic demands of V1 cells.
B) the ambiguity problem.
C) the small number of axons in the optic nerve.
D) the regularities of the visual scene.