From Eye to Brain PDF

Summary

This document provides information on the visual pathway from the retina to the cortex, including the role of the lateral geniculate nucleus (LGN) and different types of visual cells and their roles. It also discusses visual processing and streams within the brain.

Full Transcript

From Eye to Brain

Retina to Cortex
Visual Pathway
From retina to the primary visual cortex (V1) through lateral geniculate
nucleus (LGN)
Optic nerves from each eye meet at the optic chiasm
◦ Left visual field of each eye go to the right LGN
◦ Right " " " " " " to the left LGN

LGN
Part of the thalamus
Arranged in layers
◦ 1 & 2: magnocellular layer from M (parasol) ganglion cells
◦ 3 - 6: parvocellular layers from P (midget) ganglion cells
◦ 1,4 & 6: receive input from the contralateral eye
◦ 2, 3 & 5: receive input from the ipsilateral eye
◦ Koniocellular layers may be involved in colour vision
◦ Get input from K type ganglion cells

Pathways
1. Dorsal: where or how pathway
2. Ventral: what pathway

The visual system maintains the pathways separate for processing different
information

Primary Visual Cortex (V1)
Aka striate cortex
Circular receptive fields are replaced by elongated (stripe) receptive fields

Topographic mapping
Retinotopic mapping: relative position of objects within the 2 halves of our
visual field
◦ Maintained in V1

Cortical magnification: relative amount of V1 dedicated to processing visual
information from the fovea
◦ relative size of the retinal image
◦ More neurons of V1 needed to process central vision than peripheral
vision
Visual crowding
Visual crowding: peripheral objects are hard to detect because of clutter
Objects in peripheral vision have lower resolution than central vision
Object can be discernable but those around can be missed

Spots to Stripes
Neurons in V1 respond best to bars of light vs spots

Types of V1 neurons
1. Simple cells: respond best to bars of light (or dark but not both) with a
particular orientation and location on the retina
Strong response to bars of a specific orientation
Less response to bars of similar orientation
Contrast has no effect the orientation
Contrast affects the magnitude of response

2. Complex cells: respond equally well to bars of light and dark with a particular
orientation anywhere within their receptive field
Orientation-tuned response but location of stimulus is not important
Highly responsive to moving bars within their receptive field
Receptive field is usually larger than simple cells

End-stopped cells: are selective for the length of the bar of light they are
stimulated with
In V1

V1 Organization
V1 Layers
V1 columns: information that have preferred ocular dominance (orientation)
Each ocular dominance column contains smaller columns with shared
orientation selectivity
Combining the 2 ocular dominance columns results in hypercolumns

Visual streams
Different visual processing streams are maintained in the layered structure of
V1

Selective Adaptation
Adaptation: reduction in response to prior or sustained stimulation

Selective adaptation: technique where we can selectively deactivate groups of
neurons through adaptation by presenting a stimulus for an extended period of time
Neurons in V1 have a preferred orientation
But still fire in response to other close orientations
Perception = center of overall response
Extrastriate Cortex
We can compare visual areas based on:
1. Types and distributions of neurons
2. Other areas of the brain they connect to
3. Properties to which the neurons are tuned
Motion, colour, orientation, form)
4. Retinotopoc map of visual field

Segregation occurs early and is maintained throughout the visual pathways

Dorsal stream
(Where or how pathway)
V1 > V2 > MT > parietal lobe
Represents properties that relate to objects' motion or location
Guided action

Ventral stream
(What pathway)
V1 > V2 > V4 > inferotemporal cortex
Represents properties that represent objects' identities
Shape, colour

Lesions
In dorsal stream = impaired performance in visually guided tasks (optic
ataxia)
In ventral stream = impaired performance in object recognition (visual form
agnosia)

Manual estimation: use the distance between index finger and thumb to estimate
the size of an object

Grasp calibration: adjust the distance between thumb and forefinger to match the
size of the object as you reach it

Functional modules
Functional areas
Beyond V1, visual areas become more specific in the type of information they
process
V4 = colour, edges, curvatures
Multiple simple cells
Slightly different orientation selectivity
Synapse onto a neuron in V4
Form a contour-selective receptive field
 LOC (lateral occipital cortex) & IT (inferotemportal cortex) = objects,
faces, places
Fusiform face area (FFA): responds best to faces, or context that
implies faces
Parahippocampal place area (PPA): responds best to places and
layouts (rooms)
Extrastriate body area (EBA): responds best to full bodies and body
parts

MT = motion

Grandmother cell hypothesis: a single neuron is responsible for recognizing your
grandmother
- not likely

Distributed coding
Distributed coding: where multiple neurons firing at specific rates will code for a
person or object
- with different firing rates for different faces