7. Vision

Question 1

3 layers of eye

(outer –> inner)

Answer 1

1. FIBROUS layer: sclera & cornea (outermost)
2. VASCULAR layer: choroid (uvea), ciliary body, iris
3. RETINAL layer: pigmented & neural/light-sensitive

Question 2

which is the light-sensitive layer of the eye?

Answer 2

innermost retinal layer;

which is pigmented and neural

Question 3

path of light (thru eye)

Answer 3

light from environment –>

thru cornea –>

pupil –>

lens

Question 4

line through fovea separates which 2 sections?

Answer 4

NASAL (hemi)retina and the TEMPORAL (hemi)retina

Question 5

which aspect of the eye is the NASAL hemiretina found?

Answer 5

medial aspect

Question 6

which aspect of the eye is the TEMPORAL hemiretina found?

Answer 6

LATERAL aspect

Question 7

in which hemi-retina is the optic disc/ optic nerve found?

Answer 7

in the NASAL (hemi)retina

Question 8

list the retinal layers

(innermost –> outermost, which is the path of information after light hits the retina)

Answer 8

1. PE - pigement epithelium
2. POS - photoreceptor outer segments
3. ONL - cell bodies of photoreceptors
4. OPL - outer plexiform layer
5. INL - inner nuclear layer
6. IPL - inner plexiform layer
7. GCL - ganglion cell layer
8. NFL - nerve fiber layer

Question 9

in which retinal layer are the outer segments of photoreceptors found?

Answer 9

photoreceptor outer segments

Question 10

in which retinal layer are the cell bodies of photoreceptors found?

Answer 10

outer nuclear layer

Question 11

in which retinal layer do the photoreceptor cells and bipolar cells synapse?

Answer 11

outer plexiform layer

Question 12

in which retinal layer are the cell bodies of bipolar cells found?

Answer 12

inner nuclear layer

Question 13

in which retinal layer is the synapse between bipolar cells and retinal ganglion cells?

Answer 13

inner plexiform layer

Question 14

what is the fovea?

Answer 14

shallow depression on the surface of retina;

w/in macula lutea

Question 15

what is the region of highest visual acuity in the eye, and why?

Answer 15

the fovea

very high density of photoreceptors (cones) in the center of fovea; w/ retinal ganglion cells in rest of fovea

Question 16

what is found in the CENTER of the fovea?

Answer 16

• very high density of cone photoreceptors in center
• no retinal ganglion cells, nor rod cells
• few inner nuclear layer cells

Question 17

principle behind high density of cones –> high visual acuity of fovea?

Answer 17

• high visual acuity results from ratio of 1 cone in central fovea : 1 bipolar cell: 1 retinal ganglion cell/ RGC (1:1:1); vs.
• outside the fovea –> where many rods converse to one biopolar cell –> and many bipolar cells converge to one RGC

Question 18

key layers of fovea vs. rest of retina

is fovea vascular or avascular?

Answer 18

• Fovea has pigment epithelium and outer nuclear layer;
• it is avascular

Question 19

distribution of ROD photoreceptors

Answer 19

• high density throughout retina
• SHARP DECLINE IN FOVEA; (very few to none in fovea)

Question 20

distribution of CONE photoreceptors

Answer 20

• LOW density throughout retina
• SHARP PEAK IN FOVEA

Question 21

in which direction do the total # of photoreceptors decrease, relative to the fovea?

Answer 21

as you move away from the fovea, the total number of photoreceptors decreases

Question 22

where/what is the blind spot?

how does the brain compensate?

Answer 22

• no vision is possible when light is on optic nerve head (disc)
• occurs bc there are NO CELL LAYERS, ONLY the optic nerve fiber layer
• brain “fills in” missing image

Question 23

two streams of visual information processing?

Answer 23

• magnocellular stream (location/ movement)
• parvocellular stream (form/ color)

Question 24

key characteristics of MAGNOCELLULAR (“where”) stream

Answer 24

• location/movement
• M type retinal ganglion cells
• LARGE cell bodies & axons
• LARGE dendritic cells & receptive fields
• mostly ROD INPUT, color insensitive
• predominates in RETINAL PERIPHERY

Question 25

key characteristics of PARVOCELLULAR (“what”) stream

Answer 25

• form/color
• P type retinal ganglion cells
• small cell bodies & axons
• small dendritic cells & receptive fields
• mostly CONE INPUT, color sensitive
• predominates in PARAFOVEAL region

Question 26

which stream of visual information processing predominates in the parafoveal region?

Answer 26

Parvocellular (Form/color)

Question 27

which stream of visual information processing predominates in the retinal periphery?

Answer 27

magnocellular (where) stream; w/ location and movement

Question 28

which stream of visual information processing is the basis of visual acuity?

Answer 28

• parvocellular stream;
• input mainly from cones, and is color SENSITIVE
• provides info on form and color

Question 29

pathway of magnocellular stream

Answer 29

• DORSAL pathway –> POSTERIOR PARIETAL cortex
• (includes V2 and MT)

Question 30

pathway of parvocellular stream

Answer 30

• VENTRAL pathway –> INFERIOR TEMPORAL cortex
• (includes V2 and V4)

Question 31

from which areas of the retinas are the following positions in the visual field (A-D) formed?

Answer 31

1. monocular at “A” from LEFT NASAL RETINA
2. binocular at “B” from RIGHT TEMPORAL and LEFT NASAL retinas
3. binocular at “C” from RIGHT NASAL and LEFT TEMPORAL RETINAS
4. monocular at “D” from RIGHT NASAL RETINA

Question 32

from which areas of the retinas is the RIGHT visual hemifield formed?

Answer 32

RIGHT NASAL and LEFT TEMPORAL

Question 33

which visual axons cross the midline?

Answer 33

NASAL ganglion cells axons cross the midline and go to opposite retinal tract

Question 34

on which side of the brain is the RIGHT hemifield processed?

Answer 34

on the LEFT side of the brain

(the visual hemifield is processed by the OPPOSITE brain hemisphere)

Question 35

optic chiasm

Answer 35

where the ganglion cell axons of the NASAL retinal cells DECUSSATE, whereas the temporal retinal cells continue towards the back of the same respective hemisphere

Question 36

what are the central targets of the Retinal ganglion cells?

Answer 36

• hypothalamus, pretectum, superior colliculus
• lateral geniculate nucleus of thalamus (main target to relay information to the cortex; critical to be consciously aware of this_

Question 37

central projections to thalamus

Answer 37

• optic tract:
  
  • retinal ganglion cell axons project mainly to the lateral geniculate nucleus (LGN)
  • –> then those neurons project to visual cortex
  • (Called optic radiation; includes sublenticular fibers forming “meyer’s loop)

Question 38

right visual field: inputs/pathway

Answer 38

1. right nasal retina
2. left temporal retina
3. left optic tract
4. left LGN

Question 39

central projections to cortex

Answer 39

• optic radiations:
  
  • left LGN axons project to the LEFT primary visual cortex

Question 40

images in the upper right visual field

Answer 40

upper right visual field: –>

L. sublenticular fibers (Meyer’s loop) –>

L. lingula of the visual cortex

Question 41

Images in the lower right visual field:

Answer 41

Images in the lower right visual field: –>

L. retrolenticular fibers –>

L. cuneus area of the visual cortex

Question 42

primary visual (striate) cortex

Answer 42

also known as area 17 or V1

• cuneus: upper bank of calcarine sulcus
• calcarine sulcus separates the cuneus and lingula
• lingula: lower bank of calcarine sulcus

Question 43

visual field projection to both retina and primary cortex:

track inferior visual field

Answer 43

inferior field –>

superior retina & to the superior bank/ cuneus

Question 44

what is the macular region of the retina?

Answer 44

represented most posteriorly in V1;

containing the fovea;

large volume of cortex is devoted to macular representation

Question 45

projections from LGN to primary visual cortex?

Answer 45

each LGN receives input from opposite visual hemifield, but input from each eye is segregated in individual layers;

input from two eyes in 1st integrated in area 17, which allows for 3D vision & stereopsis (depth perception)

Question 46

when is the information separated in projections from LGN to primary visual cortex?

Answer 46

only when the information, reaches the cortex that the information –>

allows for depth perception and 3D vision

(a person has monocular vision will have to use other cues in order to compensate and have depth perception)

Question 47

anopsia:

location of lesion; and visual disturbance

Answer 47

if you have a lesion on the optic nerve, you will lose vision in that eye

(loses vision in the one eye)

Question 48

bitemporal (heteronymous) hemianopsia:

location of lesion; and visual disturbance

Answer 48

• lesion at midpoint/ crossing point –> loses the nasal retinal crossing fibers which process images at the periphery of the visual
• results in tunnel vision (bitemporal vision loss –> losing temporal field, but diff’t hemifields in each eye/ heteronymous)

Question 49

contralateral (homonymous) hemianopsia:

location of lesion; and visual disturbance

Answer 49

• lesion eliminates activity coming from right temporal and left nasal (originate from left hemifield) –> right optic tract –> eliminates anything that would be seen with the left hemifield
• lesion on the right optic tract (contralateral) results in left field on both sides missing (homonymous)

Question 50

contralateral superior quadrantanopsia:

location of lesion; and visual disturbance

Answer 50

• Lesion at the optic radiation–>
• lose contralateral visual field, specific quadrant based on where lesion is in the optic radiation

Question 51

contralateral hemianopsia with macular sparing:

location of lesion; and visual disturbance

Answer 51

• if losing the entire optic radiation –>
• you would lost entire opposite visual field; there may be some “macula sparing” (due to anastomoses bc the area is so big –> so some retinal sparing occurs)

Question 52

accommodation or near reflex (triad):

process?

Answer 52

occurs when shifting gaze from distant –> near object

1. convergence of eyes
2. accomonation of lens
3. pupillary constriction

Question 53

how does convergence of the eyes occur during the accommodation or near reflex?

Answer 53

• involves left and right medial recti muscles
• left and right oculomotor nuclei and nerves
• accommodation center in midbrain

Question 54

which nerves are involved in accommodation of lens and the pupillary constriction?

Answer 54

parasympathetics in oculomotor nerve allow both the accommodation of lens and the pupillary constriction to occur

Question 55

what reflex is lost in oculomotor nerve lesion?

Answer 55

entire accommodation or near reflex (triad) results after oculomotor nerve lesion

Question 56

pupillary light reflex

and principle behind it

Answer 56

constriction of pupil in response to increased illumination; pupils DO NOT OPERATE INDEPENDENTLY –> so what one does (direct), the other should also (consensual)

1. direct reflex response in ipsilateral eye (pupil constricts)
2. consensual reflex response in contralateral eye

Question 57

pupillary light reflex pathway

Answer 57

1. pretectum on each side projects BILATERALLY to –>
2. Edinger-Westphal nucleus (EW nucleus) –>
3. EW neurons project to ciliary ganglion (preganglionic parasympathetics)

Question 58

lesion of motor limb of pupillary light reflex pathway:

Answer 58

lesion to L oculomotor nerve –>

• increased light level is detected normally by either eye
• BUT the Left pupil cannot respond