从不平衡的视觉输入到不平衡的视觉注意：探寻短时程眼优势可塑性的神经机制

doi:10.3724/SP.J.1042.2023.01873

摘要/Abstract

摘要：

在个体视觉系统的发展过程中, 视觉系统的结构与功能会受到视觉经验和内外部环境的影响而发生改变, 这被称为视觉可塑性。视觉可塑性在出生后的发育关键期内达到峰值。虽然成年期视皮层神经环路的结构功能趋于稳定, 但有越来越多的研究表明成年人视皮层中仍保留着一定程度的可塑性, 其中的典型代表就是眼优势的可塑性。最近十几年的研究发现, 短时程操控成年人的各种视觉输入信息, 乃至调节两眼间注意资源的分配, 都可以引起成年人眼优势发生偏移。然而, 两者调节眼优势的神经机制可能并不相同。视觉输入对成年人眼优势的调节可能主要反映了视觉皮层的稳态可塑性机制; 而注意对眼优势的影响则是一种高级加工对初级视觉皮层的反馈调节, 目前可以用拮抗神经元的适应机制来作解释。未来研究可以寻找更加直接的证据来支持这一解释, 此外也应重点关注注意与视觉输入之间会如何交互影响成年人眼优势。

关键词: 眼优势, 可塑性, 单眼剥夺, 注意

Abstract:

During the development, the structure and functions of the visual system can be affected by visual experiences and environments. This is called visual plasticity which is most prominent during the critical period of development after birth. Although the structures and functions of neural circuits tend to be stable in adult visual cortex, mounting evidence has shown that adult visual cortex still retains a certain degree of plasticity, including ocular dominance plasticity.

Ocular dominance in humans refers to a phenomenon that one eye is functionally superior to the other eye. A common method for measuring perceptual ocular dominance is the binocular rivalry task. The typical stimuli in this task are two spatially overlapped but incompatible images, with one presented to each eye. At any moment, observer is usually aware of only one of the images which remains visible for a while before being consciously replaced by the other one. The ratio of dominance duration for each eye in a binocular rivalry task can be used to quantitatively assess observer’s ocular dominance.

One of the most commonly used ways to modulate ocular dominance in adults is monocular deprivation, which shifts ocular dominance to the deprived eye through the temporary occlusion of one eye. In recent decades, researchers have extensively investigated the monocular deprivation effect and its underlying mechanism by constantly changing the way of monocular deprivation, such as depriving the energy information (e.g. contrast) or phase information (e.g. contour) of monocular images. A consistent finding is that the imbalance of visual input between two eyes, whether achieved through complete or partial deprivation of visual information to one eye, leads to a shift of ocular dominance towards the deprived eye. The shift of ocular dominance may reflect neural plasticity in the early stages of visual processing, which is closely related to the reduction of GABA inhibition in the primary visual cortex. Meanwhile, one suggested mechanism for monocular deprivation is homeostatic plasticity, an inherent mechanism that stabilizes neuronal activity and prevents the neuronal system from becoming hyperactive or hypoactive. In the context of short-term monocular deprivation, an imbalance in visual input between the two eyes may trigger a homeostatic upregulation of neural response in the deprived eye to maintain a balance of neural activity within the visual system. This can lead to a shift in ocular dominance towards the deprived eye following the monocular deprivation.

More recently, it has been found that even in the absence of visual input deprivation, directing a greater amount of attention towards one eye can effectively induce an effect of ocular dominance shift. For example, a “dichoptic-backward-movie” adaptation paradigm was invented to study eye-based attention induced ocular dominance shift. The ocular dominance is biased in favor of the eye (unattended eye) that has viewed a backward movie for long during which time the opposite eye (attended eye) is presented with a regular movie. This phenomenon indicates that the neural mechanisms of short-term ocular dominance plasticity not only occur at the lower level of visual processing stage but also receive feedback regulations from higher cortical sites. Notably, the boost of the unattended eye was not observed when testing stimuli were binocularly compatible. Therefore, the attention-induced ocular dominance shift may not be explicable solely by means of the homeostatic plasticity mechanism, because the involvement of homeostasis is not specific to binocular rivalry. Given the crucial role of interocular competition in attention-induced ocular dominance shift, this effect is currently explained by the adaptation of ocular opponency neurons that represents interocular conflict by computing differences between the input signals from the two eyes.

Despite significant advancements in the investigation of short-term ocular dominance plasticity, there are many promising research directions for future studies, especially those that may further our understanding of the complicated mechanisms for short-term ocular dominance plasticity. The article then ends with the outlook in this regard.

Key words: ocular dominance, plasticity, monocular deprivation, attention

中图分类号:

B842

宋方兴, 王珏, 鲍敏. (2023). 从不平衡的视觉输入到不平衡的视觉注意：探寻短时程眼优势可塑性的神经机制. 心理科学进展 , 31(10), 1873-1882.

SONG Fangxing, WANG Jue, BAO Min. (2023). From imbalanced visual inputs to imbalanced visual attention: Seeking the neural mechanisms for short-term ocular dominance plasticity. Advances in Psychological Science, 31(10), 1873-1882.

图/表 2

图1 双眼竞争任务和双眼相位整合任务样例刺激。图a为双眼竞争任务的样例刺激, 是将两个不相容的图像刺激分别呈现给两只眼睛, 在一个时间点上, 被试可能会看到呈现给左眼的图像, 或是呈现给右眼的图像, 也可能会看到两者混合的图像。被试在任务中需要实时持续地报告当下看到的刺激, 以计算两眼刺激占据意识时长的相对长短, 从而分析得出被试眼优势的情况; 图b为双眼相位整合任务的样例刺激, 常用的刺激是两个水平朝向的光栅刺激, 其中呈现给一只眼的光栅相位是+22.5°, 呈现给另一只眼的光栅相位是-22.5°, 被试根据感知到的整合光栅, 将一条参考线上下移动到光栅中央最暗的部分。根据参考线的位置, 主试可以确定被试感知到的光栅所对应的相位大小, 进而判断哪只眼具有优势。

图2 在单眼相位信息剥夺实验中, 原图与相位被打乱的图像样例。左图是经过灰度处理的原图, 被呈现给非剥夺眼; 右图是将原图的相位规则剥夺后的图像, 被呈现给剥夺眼。

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