Lecture 10: Visual System

Question 1

What are the 3 layers of tissue in the eye?

Answer 1

• Retina
• Uveal tract
• Sclera

Question 2

Describe the retina.

Answer 2

• Contains all neural cells of the eye (e.g. neurons, photoreceptors)
• innermost layer
• Only part of eye that contains neurons sensitive to light and capable of transmitting visual signals to central targets

Question 3

Describe the uveal tract. What 3 structures is it made up of?

Answer 3

• 3 distinct but continuous structures
• Middle Layer
• Made of: choroid, ciliary body, and iris

Question 4

Describe the choroid.

Answer 4

• Largest component of uveal tract
• Rich capillary bed that nourishes photoreceptors (contains light-absorbing melanin in ‘pigment epithelium’)
• Keeps photoreceptors healthy

Question 5

Describe the ciliary body.

Answer 5

• Extends from choroid near front of eye
• Ring of tissue that circles the lens
• Muscular component (ciliary muscle) adjusts lens refractive power
• Vascular component (ciliary processes) produces aqueous humour

Question 6

Describe the iris.

Answer 6

• Most anterior component
• Coloured
• Contains 2 sets of muscles with opposing actions to adjust size of pupil (opening in its centre) with neural control

Question 7

Describe the sclera.

Answer 7

• Opaque ‘white of the eye’
• Continuous with transparent cornea at front of eye
• Outermost tissue layer
• Composed of tough, white fibrous tissue

Question 8

What are the 2 separate fluid environments between the cornea and retina?

Answer 8

• Aqueous humour
• Vitreous humour
• Light must pass through cornea and these fluid environments before reaching retina

Question 9

Describe the aqueous humour.

Answer 9

• In anterior chamber (behind cornea, in front of lens)
• Clear watery liquid
• Nourishes cornea and lens
• Produced by ciliary processes in posterior chamber and flows into anterior chamber through pupil
• Replaced about 12x a day
• Drained by meshwork of cells junction of iris/cornea
• Failure to drain leads to glaucoma

Question 10

Describe the vitreous humour.

Answer 10

• In posterior chamber
• Between back of lens and surface of retina
• Clear thick gelatinous substance
• 80% of eye volume
• Holds shape of eye
• Phagocytic cells clear debris (e.g. blood, old retinal cells) that might interfere with light transmission

Question 11

What is accommodation and what does it consist of?

Answer 11

• Change of lens shape that alters how light is refracted when it enters the eye
• Focusing on near objects: contraction of ciliary muscle, reduces tension in zonule fibers and allows elasticity of lens to increase its curvature
• Thin lens = distant object
• Thick lens = near object

Question 12

What are the 2 opposing forces that determine the shape of the lens?

Answer 12

• Elasticity of lens which tends to keep it rounded up

- Tension exerted by zonule fibers which tends to flatten it

Question 13

How does the eye accommodate to viewing distant objects?

Answer 13

• Force exerted by zonule fibers is greater (ciliary muscle is relaxed) than elasticity of lens
• Flatter shape for distance viewing
• Least refractive power

Question 14

How does the eye accommodate to viewing close objects?

Answer 14

• Contraction of the ciliary muscle relaxes tension of zonule fibers
• Allows inherent elasticity of lens to increase its curvature
• Highest refractive power

Question 15

What is the relationship between age and capacity for accommodation?

Answer 15

• As you age, capacity for accommodation is gradually diminished
• Lens weakens

Question 16

What is the fundus?

Answer 16

• Surface of the retina

Question 17

What is the optic disk/optic papilla?

Answer 17

• Site where retinal axons leave the eye
• Entry/exit point of blood supply
• Lies nasally
• Contains no photoreceptors
• ‘blind spot’ (scotoma, white matter pathway)
• Not dark, just can’t receive visual info here
• Travel through optic nerve to reach target structures in brain

Question 18

What is the macula lutea?

Answer 18

• On fundus/inner retina
• Circular region with yellow pigment
• 3mm
• Near centre of retina
• High visual acuity

Question 19

What is the fovea?

Answer 19

• Depression in retina located in centre of macula lutea
• 1.5mm
• Greatest visual acuity
• Dense concentration of small diameter cones
• 1:1 relationship b/n cones and bipolar ganglion cells

Question 20

What is the purpose of the optic nerve?

Answer 20

• Transmits signals from retina to brain

Question 21

What is the cornea?

Answer 21

• Specialized transparent tissue that permits light rays to enter the eye

Question 22

What are the primary functions of the optical components of the eye?

Answer 22

• Efficiently transmitting light energy

- Achieve focussed image on surface of retina

Question 23

What parts of the eye are primarily responsible for refraction/bending of light? What does this bending do?

Answer 23

• Cornea and lens

- Necessary for formation of focussed images on photoreceptors of retina

Question 24

What tool is useful for visualizing inner surface of retina (or fundus) through the pupil?

Answer 24

• Ophthalmoscope

Question 25

How are blood vessels organized on the inner surface of the retina?

Answer 25

• Fan out

- Arise from ophthalmic artery/vein

Question 26

Where do the ophthalmic artery and vein enter the eye?

Answer 26

• Through whitish circular area called optic disk/papilla

Question 27

Why must humans move their eyes and head around when looking at things?

Answer 27

• Direct fovea to objects of interest

- High acuity of vision is restricted to a very small portion of the retina

Question 28

What are saccades?

Answer 28

• Rapid/orienting movements of the eyes

Question 29

What do retinal bipolar cells consist of?

Answer 29

• Concentrated, few dendrites at one end
• Cell body
• Axon extending from other side of cell body

Question 30

What do retinal ganglion cells consist of?

Answer 30

• Widespread dendrites
• Cell body
• Axon extending from other side

Question 31

What do retinal amacrine cells consist of?

Answer 31

• Lots of dendrites interwoven
• Extend from cell body
• No axon

Question 32

What is the simplest path that retinal cells take?

Answer 32

Photoreceptors -> Retinal bipolar cells -> Retinal ganglion cells
- Horizontal and amacrine cells provide lateral interactions and maintain visual system sensitivity to contrasting light changes

Question 33

How many neuron classes can be seen in inner nuclear, outer nuclear and ganglion cell layers?

Answer 33

5

• Photoreceptors
• Retinal bipolar cells
• Retinal ganglion cells
• Horizontal
• Amacrine cells

Question 34

Where are retinal processes and synapses located?

Answer 34

• Inner plexiform and outer plexiform layers

Question 35

What kind of cells must light travel through in order to reach outer segments of photoreceptors?

Answer 35

• Non-light-sensitive cells

Question 36

What is phototransduction?

Answer 36

• Light absorption initiates intracellular cascade which changes membrane potential of receptor

Question 37

What are photoreceptors embedded in?

Answer 37

• Pigment epithelium
• Composed of disks to nourish photoreceptors
• Outermost layer of retina

Question 38

What do epithelial processes do?

Answer 38

• Extend down b/n outer segments of photoreceptors

Question 39

How long do the membranous disks in the pigment epithelium last?

Answer 39

• About 12 days

Question 40

Where are new outer segment disks being formed? What disks are removed and how?

Answer 40

• Formed near base, then grow outward toward pigment epithelium
• Oldest disks (those closest to outer pigment epithelium) are removed/phagocytosed

Question 41

How are the membranous disks phagocytosed?

Answer 41

• Disks curl
• Tip becomes spherical
• Tip separates from rod
• Tip is engulfed by pigment epithelium
• Broken down/recycled for parts

Question 42

Does light stimulation lead to depolarization or hyperpolarization?

Answer 42

• Hyperpolarization

Question 43

Do different levels of light stimulation lead to different effects on neurons? Why?

Answer 43

• Yes: more/less hyperpolarization
• Show a graded change, changes in light
• There is continuous ntx release because they have a higher resting MP
• More stimulus = less cell excitement

Question 44

What happens on the molecular level in the dark?

Answer 44

• cGMP levels in outer segment membrane are high
• cGMP binds to Na+-permeable channels in membrane, keeping them open
• Allows Na+ and other cations to enter, depolarizing cell

Question 45

What happens at the molecular level in the light?

Answer 45

• Absorption of photons leads to a decrease in cGMP levels
• Closes cation channels
• Results in receptor hyperpolarization

Question 46

What is seen dependent on light absorbed?

Answer 46

• Stimulation-specific graded change in how much ntx is being released

Question 47

Does the direction of K+ movement change with light absorption?

Answer 47

• NO

- Always an efflux

Question 48

What are the two types of photoreceptors?

Answer 48

• Rods and cones

Question 49

What does the outer segment of photoreceptors consist of?

Answer 49

• Membranous disks

- Contain light-sensitive photopigments

Question 50

What does the inner segment of photoreceptors consist of?

Answer 50

• Cell nucleus

- Gives rise to synaptic terminals that contact bipolar and horizontal cells

Question 51

What is phototransduction?

Answer 51

• Process of absorbing light and creating a response

- Change in amount of ntx released on target neurons

Question 52

What is the photopigment in rods? What does it consist of?

Answer 52

• Rhodopsin
• 7 transmembrane domains of protein portion (opsin) traverse membrane bilayer
• Opsin forms pocket where light absorbing portion (retinal molecule) resides

Question 53

How do rods and cones differ?

Answer 53

• Protein portion

Question 54

What do the different forms of retinal do?

Answer 54

• Absorb different wavelengths of light

Question 55

What does a photon do to retinal?

Answer 55

• Breaks its double bond, which leads to a cascade of events

Question 56

What does transducin look like in its inactivated state?

Answer 56

• Bound to GDP

Question 57

What happens when transducin is activated?

Answer 57

• Exchanges GDP for GTP
• Alpha subunit activates phosphodiesterase in disk membrane, which hydrolyzes cGMP thus lowering cGMP concentration in outer segment

Question 58

What happens when the concentration of cGMP falls?

Answer 58

• Molecule no longer binds to and holds open ion channels on surface of outer segment membrane

Question 59

What does the flow of cations in the dark look like?

Answer 59

• Ion channels are open
• Influx of Na+ and Ca2+ depolarizes cell
• Efflux of K+ opposes, as a hyperpolarizing influence
• Combined result = depolarization of photoreceptors
• Continuous release of NTX from synaptic terminals of photoreceptors

Question 60

How does light affect ion flow?

Answer 60

• Light reduces cGMP concentration
• Na+ channels close
• K+ flows out faster than Na+ or Ca2+ can flow in
• Hyperpolorization
• Decreases NTX release
• Enormous signal amplification
• Net change of about 1 mV per rhodopsin molecule

Question 61

What is responsible for limiting amplifying cascade and restoring molecules to inactivated state?

Answer 61

• Proteins in photoreceptor

Question 62

When are molecules converted back to a form that can absorb light again?

Answer 62

• In the dark

Question 63

What is the optic chiasm?

Answer 63

• 60% of fibres (nasal retina) cross to contralateral side
• 40% (temporal retina) continue ipsilaterally to thalamus and midbrain targets
• Anterior to stalk of pituitary gland

Question 64

What is the optic tract?

Answer 64

• Contains ganglion cell fibres from both eyes (contralateral and ipsilateral nerves)
• Major target is dorsolateral geniculate nucleus of thalamus (primary relay nucleus for visual processing by cerebral cortex)
• Secondary target of pretectum
• Information from left visual field is carried in right optic tract and vice versa

Question 65

What is optic radiation?

Answer 65

• Axons from lateral geniculate nucleus to the striate cortex (part of the primary visual cortex, or V1, in occipital cortex)

Question 66

What is the pretectum?

Answer 66

• Responsible for pupillary light reflex via circuitry interacting with oculomotor nerve (CNIII)
• Managed by projections from optic nerve
• Collection of neurons b/n thalamus and midbrain

Question 67

What are 2 other projections/targets of optic nerve?

Answer 67

• Suprachiasmatic nucleus of the hypothalamus
  
  • Retinohypothalamic pathway
  • Circadian rhythms (comes mostly from light sources)
• Superior colliculus
  
  • Coordination b/n head and eye to visual targets
  • Orienting toward/away from visual stimuli
• Includes ganglion cell types distinct from rod/cone light sensitivity

Question 68

How are images formed on the retinal surface?

Answer 68

• Light rays pass through pupil

- Results in images that are inverted and left-right reversed

Question 69

What is a visual field?

Answer 69

• Each eye sees a part of the visual space that defines its visual field
• Divisions of nasal v temporal and superior v inferior
• Portion of the world you can see without moving your head or eyes

Question 70

What does monocular mean?

Answer 70

• Only one eye can see

- Ex. peripheral vision

Question 71

What is the binocular field?

Answer 71

• Where left/right visual fields overlap (central portion)
• Projection of binocular field onto 2 retinas and its relation to the crossing of fibres in optic chiasm (topographical organization)
• Left half of visual world is represented in right half of brain and vice versa (regardless of what eye it originates in)

Question 72

Which part of the retina receives info from the right visual hemifield?

Answer 72

• Temporal left retina

- Nasal right retina

Question 73

What is periphery vision and what is it mediated by?

Answer 73

• Monocular

- Mediated by most medial portion of nasal retina

Question 74

What does the centre of the visual field project to?

Answer 74

• Foveal region of retina

Question 75

What does the right lateral geniculate nucleus receive information from?

Answer 75

• Left visual field
• Nasal left retina
• Temporal right retina

Question 76

How do axons containing info about the superior portion of the visual field travel?

Answer 76

• Sweep around lateral horn of ventricle in temporal lobe before reaching occipital lobe
• “Meyer’s loop”

Question 77

How do axons containing info about inferior portions of the visual field travel?

Answer 77

• Travel in parietal lobe

Question 78

Where is the fovea represented in the visual cortex?

Answer 78

• Posterior part
• Large portion
• Everything else (more peripheral) in anterior regions

Question 79

Do inputs of the two eyes converge?

Answer 79

• Yes, at cortical levels

Question 80

Where does the V1/striate cortex project to?

Answer 80

• Others of cerebral cortex (extrastriate) involved in complex visual perception

Question 81

Where does the dorsal stream travel?

Answer 81

• Leads from striate cortex to parietal lobe
• Spatial aspects of vision
• Analysis of motion and positional relationships

Question 82

Where does the ventral stream travel?

Answer 82

• From striate cortex to inferior part of temporal lobe

- Responsible for high resolution form vision and object recognition