Visual System - Essential Concepts

Question 1

What are the key tasks for the visual system (2)?

Answer 1

To gather information about the spatial & temporal distribution of light reflected from objects & the surrounding scene AND Reconstruct this information to form meaningful representations (perceptions) of the visual world.

Question 2

What are the different methods of studying the visual system?

Answer 2

To study the anatomy via a microscope.

To study the anatomy via pathway tracing

To study via Functional imaging

To study Clinical neurology

Single Cell electrophysiology

Question 3

What is functional imaging?

Answer 3

To examine brain activity in neurologically-intact (i.e., healthy) people while they perform specific visual tasks (e.g., functional Magnetic Resonance Imaging; fMRI)

Question 4

What does clinical neurology involve?

Answer 4

Identifying the specific visual deficit(s) that the brain-damaged subjects experience & relating these to the location of the lesion (damage) site.

Question 5

What concept is clinical neurology based on?

Answer 5

‘Loss-of-function’ is due to loss of the brain region specialized to carry out that function. (Idea different functions of the brain carry out different tasks)

Question 6

What is the theory behind focusing on microscopic anatomy to study the visual system?

Answer 6

Neurons with different structures & function occupy different layers of the given tissue. Thus by learning and identifying these we can learn more about different parts of the visual system.

Question 7

What is this?

Answer 7

A cross section of the retina.

[you should be able to label the cross section]

Question 8

What happens in pathway tracing?

Answer 8

You inject a substance into a local region of the visual pathway & examine where the neurons there transport it to down their axons, thus revealing their connections with other parts of the system.

[Not usually done in humans]

Question 9

What is the theory behind pathway tracing of the visual system?

Answer 9

Visual Pathways/Processing occurs in sequence: PhR (Photoreceptors)-to-Ganglion Cells-to-LGN (lateral geniculate nucleus) -to-Cortex

Question 10

Do neurones with different structures have the same function?

Answer 10

No they have different functions

Question 11

Do neurones of similar functions cluster together?

Answer 11

Yes they will do this for example in the same cell layer, vertical column or area.

Question 12

What is over-represented in MAPS of the visual field?

Answer 12

The high acuity central (~15 degrees of vision) as it has the most photoreceptors (from which most stimuli is recieved).

[E.g. 66-75% of V1 processes information from the fovea and macula]

Question 13

What does every neurone in your central nervous system have?

What does every visual neurone possess?

[same answer for both]

Answer 13

A Receptive Field

Question 14

What do serial (step by step) processing/pathways in the visual system do?

Answer 14

Reconstruct the image.

“•Serial (step-by-step, sequential) pathways (e.g., cones-bipolar cells-ganglion cells-LGN-visual cortex) = Reconstructing the Image”

Question 15

What do parallel (side by side) processing/pathways in the visual system do?

Answer 15

Allow for functional specialisation/division of labour

(In the visual system this would happen for things like colour or motion)

Question 16

What is the primary visual pathway?

Answer 16

By definition the primary visual pathway involves the ganglion cells of your retina, that give rise to the axons that travel down the optic nerve, pass through the optic chiasm into the optic tract and by defintion make connections with neurons in the Lateral geniculate nucleus of the thalamus. Neurones in the lateral geniculate nuclei then give rise to axons of their own which travel in the optic radiations (this is white matter under the occipital lobes of the cerebral cortex) and end up making connections with neurones in the primary visual cortex (otherwise known as V1).

Question 17

What happens at the optic chiasm?

Answer 17

Nasal axons cross but Temporal axons remain uncrossed

Question 18

What does right V1 cortex damage result in and why?

Answer 18

Left Hemianopia.

At the optic chiasm nasal axons cross but temporal axons remain uncrossed. This means after the chiasm the Left hemi-field is represented on the right side of the brain (& vice versa). So right V1 cortex damage causes left hemi-anopia (& vice versa).

Question 19

True or false - the fovea and macula contain the highest density of retinal neurones.

Answer 19

True

Question 20

How does the retina of the macula compare to more periphery retina?

Answer 20

More ganglion cells (blobs in the picture represent the cell bodies) in the macula than in the periphery. (this directly corresponds with the over-representation of the macula in Visual MAPS)

Question 21

Describe a Receptive Field

Answer 21

They are only (1) RECEPTIVE (respond) to specific features of the visual image in (2) a particular, spatially restricted, region of the visual FIELD……the clues are in the name!

Question 22

What are photoreceptor receptive fields determined by (2)?

Answer 22

(1) The luminance (brightness) & wavelength-sensitivity of the particular rhodopsin (visual pigment) they contain in their outer segment
(2) Their position in the retina: i.e., where they are ‘looking’ in space

Question 23

What are the receptive fields of all visual neurones except photoreceptors determined by (2)?

Answer 23

(1) The excitatory & inhibitory synaptic inputs they receive
(2) Their position in the visual field map in tissue in which they reside

Question 24

Elaborate on receptive fields.

Take the scenerio of a red photo receptor.

Answer 24

Question 25

What is single cell electrophysiology?

Answer 25

A process that involves recording the electrical activity of single neurons at different levels of the system in animals (with similar visual functions to our own) & determine the specific type of stimulus that the neuron is excited by

Question 26

What theory is single cell electrophysiology based on?

Answer 26

Visual neurons are only excited by specific features of the visual image

Question 27

Define eccentricity

Answer 27

a maths concept to express the idea of distancing from a point

Question 28

When do receptive fields increase in size?

Answer 28

With Eccentricity - smaller receptive fields exist in central vision whereas larger receptive fields exist in the periphery (this relates to the idea of higher acuity in central vision).

They Increase in size at increasingly higher levels of the Visual System-

• e.g., cones have tiny RFs, but those of bipolar cells are larger, and those of ganglion cells are larger still
• with single cells in the highest visual cortical areas having RFs that cover more than 20o of visual space!
• Due to convergent inputs & spatial summation at each successive (serial) step in the visual pathway

Question 29

When do receptive fields increase in complexity?

Answer 29

At increasingly higher levels of the Visual System

• e.g., cone responses depend on the intensity of the light in their Receptive Field (RF), but bipolar & ganglion cell responses depend on luminance-contrasts in different parts of their RF
• Most single cells in the primary V1 cortex having RFs that respond to lines/edges (e.g., contours) & those in the highest visual cortical areas having RFs that respond only to real objects: like a face!

Question 30

What is the problem with photoreceptors from the perspective of the Visual system?

Why do Receptive Fields (RFs) get bigger as you go up the visual system?

Answer 30

Theres 126 million photoreceptors in one eye (that recieve input from about 0.01 degrees of the real world) each sending a message of whether there is light being picked up by that receptor or not.

Thus the Visual system has to RE-BUILD the visual image (via serial processing) to create meaningful representations of real-world objects.

Hence: RFs increase in size so that cells analyze progressively larger regions of the image & in complexity so that what they analyze increasingly resembles objects that we actually perceive

[should know the slide attached]

Question 31

What is parallel image processing?

Answer 31

Parallel image processing is when:

Different aspects of the visual image are processed by different anatomically & functionally specialized neurons at all levels of the visual system.

Question 32

What is an example of parallel image processing?

Answer 32

Rods and cones as they are an example of functional specialisation.

Question 33

What are the three different types of retinal ganglion cells and what type of vision are they involved in?

Answer 33

Midget ganglion cells - high acuity & red green colour vision

Parasol ganglion cells- low acuity and motor vision

Small bi-stratified cells - blue/yellow colour vision

Question 34

Does parallel processing of rods and cones contiue across the visual system?

Answer 34

Yes and it even goes as far as involving different cortical cells .

Question 35

How does parallel processing continue into ‘higher’ areas of the visual cortex?

[you don’t need to specifically know this just a general idea]

Answer 35

Question 36

What does damage to V1 cause?

Answer 36

Anopia - loss of all vision

Question 37

What does damage to the Fusiform Gyrus cause?

Answer 37

Face blindness - also known as prosop-agnosia

Question 38

What does damage to area V4 and the Lingual Gyrus cause visually?

Answer 38

Those areas are responsbile for colour vision thus loss to them causes

a-chromat-opsia.

(Colour blindness)

Question 39

What does damage to the Lacteral Occiptal area (LO) cause visually?

Answer 39

This area is responsible for Form/object perception.

Damage to this area causes agnosia (inability to make out objects)

Question 40

What does isolated damage to Functionally specialised ‘higher’ cortical areas beyond V1 cause?

Answer 40

Selective vision losses.

(What type of vision loss this is depends on the area affected e.g. if V4 and Lingual gyrus is affected then colour blindness is experienced).

Question 41

Which of these is NOT a misconception?

a) Visual ‘sensitivity’ and ‘acuity’ are the same thing
b) Damage to right primary (V1) cortex causes loss of vision only in the left eye
c) Blockage of the posterior cerebral artery will not affect the primary (V1) cortex, because arteries have nothing to do with visual perception
d) The next lectures on this Module will consider the organization of the primary visual pathway in more detail

Answer 41

D

Visual sensitivity is sensitivity to light. Acuity is spatial and visual resolution.

Damage to the primary visual cortex causes loss of vision in the left eye and in the right eye - this is in the opposite half of the visual fields seen by the right and left eye.

Blockage of the artery causes infarction of the primary visual cortex meaning visual perception will be lost.