Lesions of Retinostriate Pathway Lesions (usually due to stroke) cause a region of blindness called a scotoma Identified using perimetry note macular sparing.

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Lesions of Retinostriate Pathway Lesions (usually due to stroke) cause a region of blindness called a scotoma Identified using perimetry note macular sparing X

Retinocollicular Pathway independently mediates orienting Blindsight patients have since been shown to posses a surprising range of “residual” visual abilities –better than chance at detection and discrimination of some visual features such as direction of motion These go beyond simple orienting - how can this be?

Retinocollicular Pathway independently mediates orienting Recall that the feed-forward sweep is not a single wave of information and that it doesn’t only go through V1 In particular, MT seems to get very early and direct input

Retinocollicular Pathway independently mediates orienting Recall that the feed-forward sweep in not a single wave of information and that it doesn’t only go through V1 In particular, MT seems to get very early and direct input Information represented in dorsal pathway guides behaviour but doesn’t support awareness

Searching for the NCC What is needed is a situation in which a perceiver’s state can alternate between aware and unaware in ways that we can correlate with neural events One such situation is called Binocular Rivalry

Rivalrous Images A rivalrous image is one that switches between two mutually exclusive percepts

Binocular Rivalry What would happen if each eye receives incompatible input? Left EyeRight Eye

Binocular Rivalry What would happen if each eye receives incompatible input? The percept is not usually the amalgamation of the two images. Instead the images are often rivalrous. –Percept switches between the two possible images

Binocular Rivalry Rivalry does not entail suppression of one eye and dominance of another – it is based on parts of objects: Left EyeRight Eye Stimuli: Percept:Or

Binocular Rivalry Percept alternates randomly (not regularly) between dominance and suppression - on the order of seconds –What factors affect dominance and suppression? Time ->

Binocular Rivalry Percept alternates randomly (not regularly) between dominance and suppression - on the order of seconds –What factors affect dominance and suppression? –Several features tend to increase the time one image is dominant (visible) Higher contrast Brighter Motion

Binocular Rivalry Percept alternates randomly (not regularly) between dominance and suppression - on the order of seconds –What factors affect dominance and suppression? –Several features tend to increase the time one image is dominant (visible) Higher contrast Brighter Motion What are the neural correlates of Rivalry?

Neural Correlates of Rivalry What Brain areas “experience” rivalry? Clever fMRI experiment by Tong et al. (1998) –Exploit preferential responses by different regions –Present faces and buildings in alternation

Neural Correlates of Rivalry What Brain areas “experience” rivalry? Clever fMRI experiment by Tong et al. (1998) –Exploit preferential responses by different regions –Present faces to one eye and buildings to the other

Neural Correlates of Rivalry What Brain areas “experience” rivalry? Apparently activity in areas in ventral pathway correlates with awareness But at what stage is rivalry first manifested? For the answer we need to look to single-cell recording

Neural Correlates of Rivalry Neurophysiology of Rivalry –Monkey is trained to indicate which of two images it is perceiving (by pressing a lever) –One stimulus contains features to which a given recorded neuron is “tuned”, the other does not –What happens to neurons when their preferred stimulus is present but suppressed?

Neural Correlates of Rivalry The theory is that Neurons in the LGN mediate Rivalry

Neural Correlates of Rivalry The theory is that Neurons in the LGN mediate Rivalry NO – cells in LGN respond similarly regardless of whether their input is suppressed or dominant

Neural Correlates of Rivalry V1? V4? V5? YES – cells in primary and early extra-striate cortex respond with more action potentials when their preferred stimulus is dominant relative to when it is suppressed However, –Changes are small –Cells never stop firing altogether

Neural Correlates of Rivalry Inferior Temporal Cortex (Ventral Pathway)? YES – cells in IT are strongly correlated with percept

Neural Correlates of Rivalry Inferior Temporal Cortex (Ventral Pathway)? YES – cells in IT are strongly correlated with percept Why does area IT sound familiar to you?

Neural Mechanisms of Consciousness? So how far does that get us? Not all that far – we still don’t know what is the mechanism that causes consciousness But we do know that it is probably distributed rather than at one locus Thus the question is: what is special about the activity of networks of neurons that gives rise to consciousness? – that’s still a very hard problem