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Literature DB >> 12691668

Receptive fields of disparity-tuned simple cells in macaque V1.

Doris Y Tsao¹, Bevil R Conway, Margaret S Livingstone.

Abstract

Binocular simple cells in primary visual cortex (V1) are the first cells along the mammalian visual pathway to receive input from both eyes. Two models of how binocular simple cells could extract disparity information have been put forward. The phase-shift model proposes that the receptive fields in the two eyes have different subunit organizations, while the position-shift model proposes that they have different overall locations. In five fixating macaque monkeys, we recorded from 30 disparity-tuned simple cells that showed selectivity to the disparity in a random dot stereogram. High-resolution maps of the left and right eye receptive fields indicated that both phase and position shifts were common. Single cells usually showed a combination of the two, and the optimum disparity was best correlated with the sum of receptive field phase and position shift.

Entities: Chemical

Mesh：

Year: 2003 PMID： 12691668 PMCID： PMC8143702 DOI： 10.1016/s0896-6273(03)00150-8

Source DB: PubMed Journal: Neuron ISSN： 0896-6273 Impact factor: 17.173

35 in total

Receptive fields of disparity-tuned simple cells in macaque V1.

1. Neural mechanisms for processing binocular information I. Simple cells.

2. Neural mechanisms for encoding binocular disparity: receptive field position versus phase.

3. Spatial structure of cone inputs to color cells in alert macaque primary visual cortex (V-1).

4. Joint-encoding of motion and depth by visual cortical neurons: neural basis of the Pulfrich effect.

5. Receptive fields, binocular interaction and functional architecture in the cat's visual cortex.

6. da Vinci stereopsis: depth and subjective occluding contours from unpaired image points.

7. Directional selectivity and spatiotemporal structure of receptive fields of simple cells in cat striate cortex.

8. A physiological model for motion-stereo integration and a unified explanation of Pulfrich-like phenomena.

9. Responses of primary visual cortical neurons to binocular disparity without depth perception.

10. An occlusion-related mechanism of depth perception based on motion and interocular sequence.

1. Measuring V1 receptive fields despite eye movements in awake monkeys.

2. Ocular dominance predicts neither strength nor class of disparity selectivity with random-dot stimuli in primate V1.

Review 3. Early computational processing in binocular vision and depth perception.

4. V1 partially solves the stereo aperture problem.

5. Spatial and temporal properties of cone signals in alert macaque primary visual cortex.

6. Contrast affects speed tuning, space-time slant, and receptive-field organization of simple cells in macaque V1.

7. Spatial and temporal features of synaptic to discharge receptive field transformation in cat area 17.

8. Binocular stereoscopy in visual areas V-2, V-3, and V-3A of the macaque monkey.

9. Understanding the cortical specialization for horizontal disparity.

10. Visual field biases for near and far stimuli in disparity selective columns in human visual cortex.