vision Flashcards

Question

Describe the micro-region architecture of V1

Answer 1

V1 - primary visual cortex * Each micro-region of V1, called a hypercolumn, is about 1 mm on a side, receives about 10,000 LGN axons, and possesses the same basic structure * LGN axons terminate in layer 4

Answer 2

color information, which is separated out from spatial information in the retina, is handled in central regions of the hypercolumns called blobs.

Answer 3

a simple cell might have an ON area that is a narrow line at some preferred orientation that is flanked on each side by OFF areas *(imagine a convergence of LGN cells with slightly different on-center or off-center RFs that allow for orientation determination) * Such a cell is best stimulated by a narrow line of light covering all of the center ON area * diffuse light is ineffective * the spatial position and orientation of the line is crucial

Answer 4

Visual cortex discussion: *In summary, simple cells have receptive fields with antagonistic flanking regions; the shape of the field is a straight line (the longer the line the better, up to a maximum length, beyond which no further change occurs), and the orientation of the line is crucial.

Answer 5

Imagine several overlapping ON-center LGN (and ganglion cell) receptive fields, lined up along a diagonal. * Suppose three of those cells converge on one cortical cell in area V1, and that each input is excitatory. * The cortical cell will then have a receptive field that is the sum of the LGN cells' receptive fields * In this example, its ON-center will be a diagonal line, with flanking OFF regions.

Answer 6

This is called hierarchical processing: Several cells with similar but spatially offset receptive fields converge on a higher order cell to create an altogether new type of receptive field

Answer 7

In about half of the cells recorded from V1, the cell receives input from the LGN on one side (monocularly driven by contra or ipsi eye, Fig 9). The other half receive inputs from the LGN from both eyes (binocular), and the receptive fields of the two eyes are virtually identical - same orientation, same region of retina, same width of line, same on-off organization. Binocular cells tend to be found at the boarders of the occular dominance columns (Fig 9). Binocular cell are sensitive to and mediate depth perception.

Answer 8

“Complex” cells have receptive fields like simple cells, with one big exception: they abstract for position. * That is, while simple cells require a line or edge (of a specific orientation, with specific ON and OFF regions) at a particular position in the visual field, complex cells are not so finicky about the position. * The line or edge can be anywhere within the RF, and these cells especially like to see lines or edges moving across the field.

Answer 9

The answer is: by convergence of several simple cells whose positions are slightly offset (Fig 11). The converging simple cells make excitatory synapses on the complex cell, and any single simple cell can cause the complex cell to fire. *Simple cells send axons up and down in the same hypercolumn to higher and to lower cortical layers, creating complex cells.

Answer 10

The output of each hypercolumn, which contains about five times more axons that does the LGN input, exits from layers 3 and 6 to higher order visual areas.

Answer 11

simple and complex cells

Answer 12

simple and complex cells

Answer 13

photoreceptor ganglion cell simple cell NOT complex cell

Answer 14

Photoreceptor - tiny spot Ganglion cell - donut Simple cell - bar Complex - edge

Answer 15

It is from the relative activities of the 3 cone types by single wavelengths of light that the nervous system extracts the information it needs to create cells in the cortex that respond only to particular colors.

Answer 16

In addition to red-green opponents, there are blue-yellow opponent cells, thereby spanning the entire spectrum (the yellow selectivity is created by converging both red and green cones).

Answer 17

In the fovea, where color discrimination is best because all of the photoreceptors there are cones, most of the bipolar cells are connected directly to one kind of cone in the field center (e.g., a red cone) and indirectly (via horizontal cells) to cones with a different color preference (e.g., green cones) in the field surround, thereby creating a RED ON-center and GREEN OFF-surround receptive field, which is passed along to the ganglion cells.

Answer 18

The Dorsal Pathway travels from V1 dorsally to the parietal lobe and is generally believed to be responsible for spatial vision, including motion and depth perception.

Answer 19

Dorsal and Ventral Pathway * dorsal - spatial, motion, depth * ventral - object, color, form, pattern * Although these two pathways are separated out spatially in area V2, they have their beginnings in the retina – the magnocellular and parvocellular pathways project to separate layers in LGN and from LGN project to different layers in V1 * These pathways remain segregated in the output pathways from V1 to V2 (Fig 13).

Answer 20

The Ventral Pathway travels ventrally from V1 to the temporal lobe and is generally believed to be responsible for object vision, including color, form, and pattern vision.

Answer 21

V5 is often called MT (middle temporal). 95% of cells in MT are selective for the direction of visual motion, and many of those neurons are also sensitive to visual depth. * Lesions of area MT result in impaired motion and depth perception. * Recent studies have shown that the activity of neurons in MT correlates directly with the perception of visual motion and/or depth.

Answer 22

Blobs in V1. cells in the blob areas do not care about shape, only color. *These cells do not have center-surround anatomy, but are simpler: their receptive fields comprise a uniform area of retina within which light of one color excites the cell and light of another color inhibits the cells.

Answer 23

Color- only blob cells receive input from many color-opponent neurons. For example, a red-ON green- OFF cell gets excitatory synaptic inputs from both red ON-center green OFF-surround cells and from green OFF-center red ON-surround cells, as well as inhibitory synaptic inputs from green ON-center red OFF-surround cells and red OFF-center green ON-surround cells. *The positions of all of these fields overlap entirely, so there is no spatial information in the color-only blob cell's response.

Answer 24

V4, anterior and inferior to the primary visual cortex (V1), cells have relatively large receptive fields in the central areas of the retina (where cones predominate) and respond only to fairly narrow bands of wavelengths over the visible spectrum, some as narrow as 10 nm. Given a little lateral inhibition at a higher level of color processing, color cells with bandwidth selectivities as narrow as our perceptions are (~3 nm) could easily exist. Lesions in V4 can result in impairments in color discrimination.

Answer 25

cases have been reported in which patients lose the ability to recognize specific faces, , while retaining the ability to recognize parts of a face - nose, lips, and so forth. (proposagnosia

Answer 26

* category 1 cells are driven only by the eye that is contralateral to the cortical cell that is being recorded from; * category 4 cells are driven equally by both eyes; * category 7 cells are driven only by the eye that is ipsilateral to the cell being studied. * Thus, categories 1 and 7 contain monocularly driven cells, while all other categories contain binocular cells of varying eye preference.

Answer 27

* uh, both. Newborns have ocular dominance pathways in place from birth * however, depriving the experience of binocular vision rewires these cortical cells

Answer 28

No, it does not recover. The connections, once lost, are gone for good.

Answer 29

*imagine deprived eye is reopened, the other eye is deprived (still during the critical period) * the reopened eye recovers, and the newly deprived eye loses its connections with the cortex. * This experiment further illustrates the competition - active suppression by the active eye - that occurs between converging inputs from each eye in the cortex.

Answer 30

* during the sensitive period kittens had one eye's medial rectus muscle cut * the end result is cortical cells only monocularly driven, by one eye or the other * neurons that fire together wire together * normally there is synchronous stimulation in eyes with overlapping visual fields, but not in this case so one eye wins everything in the competition

Answer 31

At birth, LGN axon terminals commingle, and a broad white stripe marks layer 4. *Over time, the LGN terminals sort themselves into discreet bands characteristic of the adult animal, and layer 4 shows a banded appearance *These are the ocular dominance columns of the adult animal, and the technique provides striking confirmation of the electrophysiological experiments.

Answer 32

* TTX block of optic chiasm - no stimulus and thus cortical columns reflect blindness * TTX block with upstream synchronous stimulation - results in normal cortical map * TTX block with asynchronous upstream stimulation - results in strabismus profile of all cortical columns monocularly driven

Answer 33

Indeed, blocking NMDA receptors chronically during the critical period interferes with the normal emergence of ocular dominance. The coincidence of pre- and postsynaptic firing activates NMDA receptors, and calcium ions enter the postsynaptic cell, where they trigger processes that lead to strengthening of those synapses. Evidence suggests that the postsynaptic cell releases a trophic factor that diffuses back across the synapse to the presynaptic terminal. The presynaptic terminal needs the trophic factor to survive, but evidently can take it up only if it has been recently active. Thus, terminals that do not fire in synchrony miss out on the opportunity, wither, and die.

Answer 34

When bright light shines on the retina, the muscles in the iris contract, reducing the size of the pupil and therefore reducing the amount of light entering the eye. *Action potentials in ganglion cells excite CNS neurons that diverge to and excite preganglionic parasympathetic motor neurons on both sides of the brain, which leads to excitation of the muscles in the iris.

Answer 35

* right eye visual field is fully lost | * left eye visual field is maintained

Answer 36

the peripheral vision of both eyes is lost | *only the midline vision of each eye is retained

Answer 37

* right eye visual field loses its medial field but retains everything lateral * the opposite for the left eye, which loses lateral vision but maintains medial vision

Answer 38

Here you are starting to get to higher order cells, so it's not that simple * example given was the left eye loses the top-lateral field and the right eye loses the top medial field * the point is that there is segregation of the visual system even to higher order structures * in the optic radiation information is from one certain area of the entire shared visual field (in this case persons top left field)

Answer 39

* a "hemisphere" of the entire shared visual field is lost | * the left eye loses the lateral vision field, the right eye loses the medial visual field

Answer 40

It has to do with what fibers cross the midline * in the right eye, the lateral field of vision shines on the medial retina * the medial retina fibers cross the midline at the optic chiasm to join the lateral retinal fibers of the left eye * the brain wants to preserve the visual fields to higher order vision centers

vision Flashcards

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