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人类第二视觉区域中颜色、视差和自然纹理的中尺度功能组织与连通性。

Mesoscale functional organization and connectivity of color, disparity, and naturalistic texture in human second visual area.

作者信息

Ai Hailin, Lin Weiru, Liu Chengwen, Chen Nihong, Zhang Peng

机构信息

Department of Psychological and Cognitive Sciences, Tsinghua University, Beijing, China.

State Key Laboratory of Brain and Cognitive Science, Institute of Biophysics, Chinese Academy of Sciences, Beijing, China.

出版信息

Elife. 2025 Mar 20;13:RP93171. doi: 10.7554/eLife.93171.

DOI:10.7554/eLife.93171
PMID:40111254
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11925451/
Abstract

Although parallel processing has been extensively studied in the low-level geniculostriate pathway and the high-level dorsal and ventral visual streams, less is known at the intermediate-level visual areas. In this study, we employed high-resolution fMRI at 7T to investigate the columnar and laminar organizations for color, disparity, and naturalistic texture in the human secondary visual cortex (V2), and their informational connectivity with lower- and higher-order visual areas. Although fMRI activations in V2 showed reproducible interdigitated color-selective thin and disparity-selective thick 'stripe' columns, we found no clear evidence of columnar organization for naturalistic textures. Cortical depth-dependent analyses revealed the strongest color-selectivity in the superficial layers of V2, along with both feedforward and feedback informational connectivity with V1 and V4. Disparity selectivity was similar across different cortical depths of V2, which showed significant feedforward and feedback connectivity with V1 and V3ab. Interestingly, the selectivity for naturalistic texture was strongest in the deep layers of V2, with significant feedback connectivity from V4. Thus, while local circuitry within cortical columns is crucial for processing color and disparity information, feedback signals from V4 are involved in generating the selectivity for naturalistic textures in area V2.

摘要

尽管并行处理在低级膝状纹状体通路以及高级背侧和腹侧视觉流中已得到广泛研究,但在中级视觉区域的相关了解较少。在本研究中,我们采用7T高分辨率功能磁共振成像(fMRI)来研究人类次级视觉皮层(V2)中颜色、视差和自然纹理的柱状和层状组织,以及它们与低阶和高阶视觉区域的信息连接性。尽管V2中的fMRI激活显示出可重复的、相互交错的颜色选择性细条纹和视差选择性粗“条纹”柱状结构,但我们没有发现自然纹理存在柱状组织的明确证据。皮层深度依赖性分析显示,V2表层的颜色选择性最强,同时与V1和V4存在前馈和反馈信息连接。V2不同皮层深度的视差选择性相似,与V1和V3ab表现出显著的前馈和反馈连接。有趣的是,自然纹理的选择性在V2深层最强,且与V4存在显著的反馈连接。因此,虽然皮层柱内的局部回路对于处理颜色和视差信息至关重要,但来自V4的反馈信号参与了V2区域自然纹理选择性的产生。

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