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灵长类视觉皮层中边界所有权的柱状处理。

Columnar processing of border ownership in primate visual cortex.

机构信息

Systems Neurobiology Laboratory, The Salk Institute for Biological Studies, La Jolla, United States.

出版信息

Elife. 2021 Nov 30;10:e72573. doi: 10.7554/eLife.72573.

DOI:10.7554/eLife.72573
PMID:34845986
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8631947/
Abstract

To understand a visual scene, the brain segregates figures from background by assigning borders to foreground objects. Neurons in primate visual cortex encode which object owns a border (border ownership), but the underlying circuitry is not understood. Here, we used multielectrode probes to record from border ownership-selective units in different layers in macaque visual area V4 to study the laminar organization and timing of border ownership selectivity. We find that border ownership selectivity occurs first in deep layer units, in contrast to spike latency for small stimuli in the classical receptive field. Units on the same penetration typically share the preferred side of border ownership, also across layers, similar to orientation preference. Units are often border ownership-selective for a range of border orientations, where the preferred sides of border ownership are systematically organized in visual space. Together our data reveal a columnar organization of border ownership in V4 where the earliest border ownership signals are not simply inherited from upstream areas, but computed by neurons in deep layers, and may thus be part of signals fed back to upstream cortical areas or the oculomotor system early after stimulus onset. The finding that preferred border ownership is clustered and can cover a wide range of spatially contiguous locations suggests that the asymmetric context integrated by these neurons is provided in a systematically clustered manner, possibly through corticocortical feedback and horizontal connections.

摘要

为了理解一个视觉场景,大脑通过给前景物体分配边界来将其与背景区分开来。灵长类动物视觉皮层中的神经元对哪个物体拥有边界(边界所有权)进行编码,但基础电路尚不清楚。在这里,我们使用多电极探针记录猕猴视觉区域 V4 中不同层的边界所有权选择单元,以研究边界所有权选择性的分层组织和时间。我们发现,与经典感受野中小刺激的尖峰潜伏期相比,边界所有权选择性首先出现在深层单元中。同一探测中的单元通常共享边界所有权的首选侧,也跨越层,类似于方向偏好。对于一系列边界方向,单元通常是边界所有权选择的,其中边界所有权的首选侧在视觉空间中被系统地组织。我们的数据共同揭示了 V4 中边界所有权的柱状组织,其中最早的边界所有权信号不是简单地从上游区域继承而来,而是由深层神经元计算而来,因此可能是刺激后早期反馈给上游皮质区域或眼球运动系统的信号的一部分。偏好的边界所有权聚类并且可以覆盖广泛的空间连续位置的发现表明,这些神经元整合的不对称上下文是以系统聚类的方式提供的,可能通过皮质间反馈和水平连接。

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