Primary Visual Cortex Lecture 10

Question 1

Where does the primary visual pathway originate?

Answer 1

In the retina

Question 2

Describe the primary visual pathway:

Answer 2

Retina
Optic nerve
Nasal fibres cross at optic chasm
Primary relay station: LGN in thalamus.
Optic radiations spread into the primary visual cortices

Question 3

Where are the left and right sides of the retinas processed?

Answer 3

Left sides of retinas are processed by the the left LGN and Left primary visual cortex. Opposite for right.

Question 4

What visual fields are processed in what part of the brain?

Answer 4

left retina receives right visual hemisphere input, so the left side of the brain deals with info from the right visual field. and vice versa

Question 5

What do retinal ganglion cells have in terms of receptive field?

Answer 5

A classic centre-surround receptive field.

Horizontal cell inhibitor of centre bipolar cell, if surround has light on it.

Question 6

Are the centre and surround receptive fields distinct?

Answer 6

No there is plenty of overlap and it is more of a blurry outline i.e not distinct.

Question 7

How do retinal cells acquire a receptive field?

Answer 7

Due to the different types of ganglion cells and their SELECTIVE interconnectivity BETWEEN CELLS within the retina, developing the receptive field i.e horizontal cell and amacrine cell input.

Question 8

What are the types of retinal ganglion cells?

Answer 8

Midget
Parasol
Bistratified

Question 9

Describe the receptive field of the midget cell?

Answer 9

The midget cells have a very small receptive field and therefore do not receive much input.

Question 10

Describe the receptive field for the parasol cells.

Answer 10

Moderately sized receptive field with moderate amounts of input

Question 11

Describe the receptive field of the bistratified cells

Answer 11

large receptive field with extensive interconnections, receiving a lot of input.

Question 12

What connects each ganglion with photoreceptors?

Answer 12

Horiztonal and amacrine cells create the connectivity and therefore receptive field.

Question 13

What are the relative amounts of ganglions cells?

Answer 13

80% Midget cells
10% Parasol
10% Bistratified

Question 14

What is the function of retinal ganglion cells?

Answer 14

They respond to edges of images, and emphasise this to the brain.

Question 15

Where do majority of ganglion cells project to?

Answer 15

The LGN

Question 16

What sort of structure is the LGN?

Answer 16

Laminar, therefore is divided into six layers.

Question 17

What is the input of the LGN layers?

Answer 17

Each layer only receives input from one eye.

Question 18

Describe the LGN layers input:

Answer 18

1,4,6 receive input from the contralateral eye.

2,3,5 receive input from the ipsilateral eye

Question 19

What is the function of the LGN?

Answer 19

It is a relay station

Question 20

How else is the LGN layers specific in input?

Answer 20

Eat LGN layer is specific as to which eye it receives input from and what type of ganglion cell inputs there.

Question 21

Which layers of the LGN do midget ganglion cells send axons to?

Answer 21

Midget Ganglion Cells send axons to LGN layers 3-6. These are known as parvocellular layers. (p cells)

Miget cells have small cell bodies and this is observed in these layers.

Question 22

Which layers of the LGN do parasol ganglion cells send axons to?

Answer 22

Parasol Ganglion Cells send axons to LGN layers 1 and 2. This is known as the magnocellular layers (m cells)

Big cell bodies

Question 23

Which layers of the LGN do bistratified ganglion cells send their axons to?

Answer 23

Bistratified Ganglion cells send their axons to small sublayers between all six LGN layers. Known as the koniocellular layers. K cells.

Very small cell bodies

Question 24

Draw the LGN showing input from which eye and what type of cell, referring to layers to.

Answer 24

Do it now to show understanding.

This will be examined!!!!!!!!!

Question 25

The distinct inputs of the LGN i.e types of ganglions, layers, eyes is preserved in the visual pathway, whats the implication of this?

Answer 25

Each cell type has its own unique function to add to the perception of the visual field and this is maintained in the visual pathway structures

Question 26

What is the function of the Midget ganglion cells+p cells (parvoceullar pathway)?

Answer 26

Colour (differences-few cone input)
Fine detail (small receptive field)
Poor temporal sensitivity (poor for motion)(take long time to switch on and off)

Question 27

What is the function of the Parasol ganglion cells + M cells (magnocellular pathway)?

Answer 27

High temporal sensitivity (good for motion) (respond rapidly)
Achromatic (don't colour) (too much cone input)
Course detail (large receptive fields)

Question 28

Whats the function of the bistratified ganglion cells + K cells (koniocellular pathway)?

Answer 28

Short wavelengths
Large receptive fields

Not understood well

Question 29

What happens to the magnocellular, parvocellular and koniocellular pathways in the visual pathway?

Answer 29

They are preserved and run PARALLEL to the primary visual cortex.

Question 30

What is another name for the primary visual cortex and why?

Answer 30

Striate cortex because it appears striated.

or V1

Question 31

What can the layers of the straite cortex be grouped into?

Answer 31

Three groups:

• Output to higher cortical areas 1-4b
• Primary input from LGN 4C
• Output to thalamic areas 5,6 (back to LGN)

Question 32

What inputs into 4C?

Answer 32

Primary input of LGN
So mainly:
- Magnocellular layer (4C alpha) and Parvocellular layer (4C beta)

Question 33

What v1 areas does the koniocellular pathway project to?

Answer 33

1,2,3

Question 34

What v1 areas does the magnocellular pathway project to?

Answer 34

4 A, 4 B, 4C alpha and 6

Question 35

What v1 areas does the parvocellular pathway project to?

Answer 35

4c beta and 6

Question 36

What sort of mapping is in v1?

Answer 36

Retinotopic Mapping

Question 37

What is retinotopic mapping?

Answer 37

The right visual field end ups on left retina and in the left visual field.

The v1 is divided by the calcarine sulcus and the mapping is such that the lower visual field, maps to the upper side of the calcarine sulcus and conversely is true.

Also as you move from the back of v1 i.e post to ant, you move from mapping of the fovea to the peripheral vision mapping.

Question 38

What does retinotopic mapping allow?

Answer 38

To make predictions of visual field loss based on region of damage.

Question 39

What is selective loss of vision called?

Answer 39

Scartoma

Question 40

What is it called if you lose half of v1 in one hemisphere?

Answer 40

Quadrantopia

Question 41

What is it called if you lose all of v1 in one hemisphere?

Answer 41

Hemianopia

Question 42

Where in the visual pathway are there cells with binocularity?

Answer 42

Not until the primary visual cortex, most cells have monocular dominance / preference

Question 43

In v1 where are strictly monocular cells found?

Answer 43

IN layer 4c

Question 44

Outside of layer 4c do cells have a monocular preference?

Answer 44

Yes they have a monocular preference but can receive input from either eye.

Question 45

Describe ocular dominance in layer 4c and its projections:

Answer 45

Cells in layer 4c form ocular dominance columns that alternate between ipsilateral and contralateral eyes.

The outputs from these columns are combined in layers 2 and 3.

However OD columns appear to extend through the layers.

Question 46

Describe the density of the retinotopic map for the visual field in v1:

Answer 46

The retinotopic map becomes sparser as you move towards the peripheral visual field. It is more densely packed in the fovea.

Question 47

What is a log polar retintopic map?

Answer 47

The mathematical representation of the retinotopic map dedicated to parts of the visual field. i.e fovea has the most mapping and is also the most detailed part of your vision.

Question 48

How are receptive fields in the LGN mapped?

Answer 48

Very similar to receptive fields in the retina. i.e prefer dots of light

Question 49

What happens to receptive fields in v1?

Answer 49

Cells in v1 now also prefer orientation of light as well as light or dark (centre vs surround)

Question 50

What is the striate cortex, simple cell selectivity?

Answer 50

This property describes how cells in the v1 prefer light to be of a certain orientation (light bars) and as the bars of light rotate they start to overlap inhibitory regions (centre surround concept except parallel bars) an the overall response of the cell decreases. (as opposed to light bar, correct orientation and dark surround/parrallel bars = max response)

The change in orientation = change in response = tuning response (assuming initially light is only on light cell bar (i.e centre)

Question 51

Describe orientation tuning in v1:

Answer 51

Orientation tuning progresses in an orderly manner throughout v1

Common orientation preference is columnar

Electrode tack perpendicular to surface= little change in orientation

electrode tack oblique to surface = gradual change in orientation preference.

Question 52

What does optical imaging of orientation preference in the cortex reveal?

Answer 52

Smooth progression in orientation across the cortex.

Except point called pinwheel fractures where lots of orientations are represented closely to one another.

Question 53

What do the pinwheels fall close to?

Answer 53

The ocular dominance columns

orientation contours tend to cross OD columns at right angles

Question 54

What do orientation contours show us?

Answer 54

Each orientation contours servers both eyes for that specific region of visual space.

Question 55

What are CO blobs?

Answer 55

Cytochrome oxidase stains cells in the cortex with a high metabolic rate.

Question 56

What cortical layers in v1 have CO blobs?

Answer 56

2,3,5,6

Question 57

What are the arrangement of CO blobs in v1?

Answer 57

0.5mm apart uniform staining

Question 58

Neurones that have blobs in v1 receive input from?

Answer 58

• Get LGN input from K cells (kinocellular cells, bistratified ganglions)
• sensitive to colour
• NO orientation tuning
• Have centre surround receive fields

Question 59

What are hyper columns?

Answer 59

Made up of;

• Columns that share a common 180 degrees orientation preference
• OD column for each eye
• CO blobs across the cortex

Question 60

What is the function of a hyper column?

Answer 60

Theory is that a hyper column processes all possible combinations of information i.e orientation OD etc for a specific region of visual space