Abstract

BackgroundBinocular disparity provides a powerful cue for depth perception in a stereoscopic environment. Despite increasing knowledge of the cortical areas that process disparity from neuroimaging studies, the neural mechanism underlying disparity sign processing [crossed disparity (CD)/uncrossed disparity (UD)] is still poorly understood. In the present study, functional magnetic resonance imaging (fMRI) was used to explore different neural features that are relevant to disparity-sign processing.MethodsWe performed an fMRI experiment on 27 right-handed healthy human volunteers by using both general linear model (GLM) and multi-voxel pattern analysis (MVPA) methods. First, GLM was used to determine the cortical areas that displayed different responses to different disparity signs. Second, MVPA was used to determine how the cortical areas discriminate different disparity signs.ResultsThe GLM analysis results indicated that shapes with UD induced significantly stronger activity in the sub-region (LO) of the lateral occipital cortex (LOC) than those with CD. The results of MVPA based on region of interest indicated that areas V3d and V3A displayed higher accuracy in the discrimination of crossed and uncrossed disparities than LOC. The results of searchlight-based MVPA indicated that the dorsal visual cortex showed significantly higher prediction accuracy than the ventral visual cortex and the sub-region LO of LOC showed high accuracy in the discrimination of crossed and uncrossed disparities.ConclusionsThe results may suggest the dorsal visual areas are more discriminative to the disparity signs than the ventral visual areas although they are not sensitive to the disparity sign processing. Moreover, the LO in the ventral visual cortex is relevant to the recognition of shapes with different disparity signs and discriminative to the disparity sign.

Highlights

  • Binocular disparity provides a powerful cue for depth perception in a stereoscopic environment

  • The mean prediction accuracy of all regions of interest (ROI) was above chance levels

  • Neural mechanism underlying disparity processing Both general linear model (GLM) and multi-voxel pattern analysis (MVPA) analyses revealed that dorsal visual areas V3A, V3B and V7 produced significantly stronger activation for uncrossed disparity (UD)/crossed disparity (CD) compared to zero disparity (ZD), and showed a significantly high discriminative power for discriminating UD/CD and ZD

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Summary

Introduction

Binocular disparity provides a powerful cue for depth perception in a stereoscopic environment. Functional magnetic resonance imaging (fMRI) was used to explore different neural features that are relevant to disparity-sign processing. Binocular disparity is one of the powerful depth cues and is provided by the differences between the retinal images of the two eyes [1]. Single-unit studies in macaques identified neurons that are sensitive to binocular disparity in many cortical areas, including the V1, V2, V3, V4, VP, MT, and MST areas [5,6,7,8,9]. Most studies of the human visual cortex using functional magnetic resonance imaging (fMRI) reported that the. Li et al BMC Neurosci (2017) 18:80 dorsal visual cortical areas V3A and V7 produced disparity-evoked responses [10, 11]. Other studies reported that the lateral occipital cortex, IPS, hMT+/V5, V3B, V4v, V8, etc., responded to binocular disparity [12,13,14]

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