Retina and Vision COPY Flashcards

1
Q

4 factors that are necessary for an object to be seen?

A
  1. Pattern of the object must fall on the vision receptors (rods and cones in the retina) - allows accommodation
  2. Amount of light entering the eye must be regulated (too much light will “bleach out” the signals)
  3. Energy from the waves of photons must be transduced into electrical signals
  4. Brain must receive and interpret the signals
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2
Q

Structure of the retina?

A

Inside-out laminar structure

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3
Q

Direct (vertical) pathway for signal transmission via the retina?

A

Photoreceptors to bipolar cells to ganglion cells

IMAGE

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4
Q

Importance of the lateral connection to the direct pathway?

A

Horizontal cells - receive input from photoreceptors and project to other photoreceptors and bipolar cells

Amacrine cells - receive input from bipolar cells and project to ganglion cells, bipolar cells and other amacrine cells

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5
Q

Function of the photoreceptors?

A

Converts electromagnetic radiation to neural signals (transduction)

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6
Q

4 main regions of the photoreceptors?

A
  • Outer segment
  • Inner segment
  • Cell body
  • Synaptic terminal
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7
Q

2 types of photoreceptors?

A

Rods

Cones

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8
Q

Resting membrane potential of a photoreceptor?

A

Have a DEPOLARISED rmp of -20 mV; compared to other neurons, the resting Vm is more positive

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9
Q

What happens to the membrane potential when there is light exposure?

A

Vm hyperpolarises

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10
Q

Why is the Vm +ve in a photoreceptor?

A

Due to the ‘dark current’ - a cGMP gated Na+ channel that is:
• OPEN in the DARK
• CLOSED in the LIGHT

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11
Q

Why is the ‘dark current’ important for vision?

A

Change in Na+ with light is the signal that enables the brain to perceive objects in the visual field

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12
Q

Action of the dark current in the dark?

A

Permeability of Na+ and K+ are equal and thus the Vm is between ENa and EK

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13
Q

Action of the dark current in response to light?

A

Na+ channels close so permeability decreases to below that of K+

Thus, hyperpolarisation occurs (driving the Vm towards the equlibrium potential of K+); this is local and graded (the more light there is, the more hyperpolarisation occurs?)

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14
Q

What are the visual pigment molecules?

A

Rhodopsin (for rods):
• 11-cis-Retinal (vitamin A derivate) + Opsin (GPCR)

These are present in the membrane folds

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15
Q

Action of light on rhodopsin?

A

Converts 11-cis-retinal to all-trans-retinal (activated form)

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16
Q

Mechanism of action of all-trans-retinal?

A

Activates transducin, causing a molecular cascade

cGMP decreases leading to closure of cGMP-gated Na+ channels

Lowered Na+ entry causes hyperpolarisation

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17
Q

Explain what is meant by high gain mechanism in phototransduction?

A

Amplification means that even minute changes in light can change the membrane potential of photoreceptors, i.e: 1 opsin leads to 1000 transducin OR 1 PDE leads to 1000 cGMP

18
Q

What is the basis of phototransduction?

A

Dark current channel which is a nucleotide-gated channel (opened by cGMP) and is permeable to Na+

It opens in the dark and closes in response to light

It keeps the photoreceptor Vm more positive than other neurons and there is a steady release of neurotransmitter (more glutamate in the dark and less in the light)

19
Q

Define visual acuity? How is it determined?

A

Ability to distinguish two nearby points; determined largely by photoreceptor spacing and refractive power

20
Q

What do rods and cones allows?

A

Rods - seeing in dim light

Cones - seeing in normal daylight

21
Q

Which photoreceptors have less acuity?

A

Rods - they have more convergence, allowing increased sensitivity but acuity is decreased; this is what allows sight in dim light

22
Q

What is meant by high convergence in peripheral rods?

A

They have larger spacing, i.e: there is a lower density of rods, allowing more convergence on a large ganglion cell

23
Q

What is meant by low convergence in foveal cones?

A

They have smaller spacing, i.e: there is a high density of cones; there is less convergence on the small ganglion cell but acuity is increased

24
Q

Basis of colour vision?

A

Light is comprised of discrete wavelengths and photoreceptor are only activated by a small portion (not infrared or UV)

25
Q

What is basis of different colours being seen?

A
Different opsins perceive different wavelength, e.g: there are 4 types of photoreceptors in the human retina:
• Short-wave cone (blue)
• Middle-wave cone (green)
• Long-wave cone (red)
• Rod

Different shades of colour be seen

26
Q

5 differences between rods and cones?

A
Rods:
• Achromatic
• Peripheral retina
• High convergence
• High light sensitivity
• Low visual acuity
Cones:
• Chromatic
• Central retina (fovea)
• Low convergence 
• Low light sensitivity
• High visual acuity
27
Q

In essence, what does out visual system actually perceive?

A

Local differences in light intensity, not the absolute amounts of light

28
Q

What does each eye see?

A

A part of the visual space, i.e: monocular visual field (+/- 45 degrees)
These overlap extensively to create a binocular visual field (+/- 45 degrees)

29
Q

How is the retina divided?

A

In half, relative to the fovea, into:
• Nasal hemiretina
• Temporal hemiretina

30
Q

Pathway of the nerve fibres and optic tract?

A

Nerve fibers from the nasal half of each retina cross over at the optic chiasm

Resulting 2 optic tracts allow right and left visual fields to reach the left and right hemispheres separately:
• 60% (nasal retina) cross
• 40% (temporal) do not

31
Q

What is meant by retinotopy?

A

Image is picked up at the photoreceptor and is NOT MIXED; it goes all the way to the striate cortex

32
Q

Where is the visual field mapped?

A

In the retina, lateral geniculate nucleus (LGN) and cortex

33
Q

Where are eye specific inputs segregated in the brain?

A

In the primary visual cortex, more specifically in layer 4

Both eyes project to each visual cortex but, at the primary visual area (17), they remain largely segregated into ocular dominance columns, i.e: each column is dominated by input from 1 of the 2 eyes

Cells outside of layer 4 receive input from both eyes

34
Q

How is visual perception shaped?

A

Based on the brain’s interpretation of distributed patterns of activity

Visual perception is shaped by early activity

35
Q

Consequences of congenital cataracts and treatment?

A

Opaque covering of lens results in impaired vision from birth; they are typically removed between 10-20 years of age

They have difficulty perceiving shape and form

36
Q

What is amblyopia?

A

AKA cortical blindness - variety of visual disorders where there is not issue with the eye but 1 eye has better vision than the other; causes include:
• Strabismus (wandering eye) if not corrected in infancy

37
Q

Treatment of wandering eye?

A

Often surgically corrected but delayed until the child is old enough

Until then, cover the infant’s better eye for a few hours each day, making the brain rely on signals from the affected eye; allows the brain to develop properly to process signals from both eyes

38
Q

What is Hebb’s postulate?

A

Axon of cell A is near enough to excite cell B, and repeatedly/persistently takes part in firing it, some growth process or metabolic change occurs in one/both cells

Results in cell A’s efficiency, as once of the cells firing cell B, increasing

Correlated activity between pre-synaptic and post-synaptic cells strengthens synaptic connections between them;
cells that fire together, wire together

39
Q

Describe long-term potentiation (LTP)

A

Hebb’s postulate is also important for learning and memory

40
Q

How are the terminal arborisation (branches) of LGN axons affected in monocular deprivation?

A

Lack of visual activity leads to less branching, i.e: there are less branches in the deprived eye