干扰物抑制的统计学习下调早期视觉皮层刺激前神经兴奋性

O. Ferrante, A. Zhigalov, C. Hickey, O. Jensen
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引用次数: 12

摘要

视觉注意力受过去经历的影响很大。最近的行为研究表明,对搜索数组中干扰物的空间位置的期望是隐式学习的,预期的干扰物变得越来越少。人们对支持这种统计学习的神经机制知之甚少。在这里,我们使用脑磁图(MEG)来测量人脑活动,以测试主动机制是否参与分心物位置的统计学习。具体来说,我们使用了一种称为快速不可见频率标记(RIFT)的新技术来评估早期视觉皮层在分心物抑制统计学习期间的神经兴奋性,同时研究了后α带活动(8-12 Hz)的调节。男性和女性参与者执行一项视觉搜索任务,其中一个目标偶尔会与一个单一颜色的分心物一起出现。参与者不知道的是,分散注意力的刺激在两个半脑区以不同的概率呈现。RIFT分析显示,早期视觉皮层在刺激前间隔表现出神经兴奋性降低,这与高分心概率相关的视网膜位置有关。相比之下,我们没有发现任何证据表明期望驱动的分心物抑制α带活动。这些发现表明,前瞻性注意机制参与了预测干扰物抑制,并且这些机制与早期视觉皮层神经兴奋性的改变有关。此外,我们的研究结果表明,裂谷和α带活动可能遵循不同的和可能独立的注意机制。我们过去的经历会影响我们对未来外部世界的感知。例如,如果我们事先知道一个恼人的闪光通常出现在哪里,我们可能会更好地忽略它。这种从环境中提取规律的能力被称为统计学习。在这项研究中,我们探索了神经元机制,允许注意系统忽略基于其空间分布的明确分散注意力的项目。通过使用MEG记录大脑活动,同时使用一种名为RIFT的新技术探测神经兴奋性,我们发现早期视觉皮层的神经元兴奋性在刺激出现之前就降低了,而在刺激出现之前,分散注意力的事物更有可能出现。
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Statistical Learning of Distractor Suppression Downregulates Prestimulus Neural Excitability in Early Visual Cortex
Visual attention is highly influenced by past experiences. Recent behavioral research has shown that expectations about the spatial location of distractors within a search array are implicitly learned, with expected distractors becoming less interfering. Little is known about the neural mechanism supporting this form of statistical learning. Here, we used magnetoencephalography (MEG) to measure human brain activity to test whether proactive mechanisms are involved in the statistical learning of distractor locations. Specifically, we used a new technique called rapid invisible frequency tagging (RIFT) to assess neural excitability in early visual cortex during statistical learning of distractor suppression while concurrently investigating the modulation of posterior alpha band activity (8–12 Hz). Male and female human participants performed a visual search task in which a target was occasionally presented alongside a color-singleton distractor. Unbeknown to the participants, the distracting stimuli were presented with different probabilities across the two hemifields. RIFT analysis showed that early visual cortex exhibited reduced neural excitability in the prestimulus interval at retinotopic locations associated with higher distractor probabilities. In contrast, we did not find any evidence of expectation-driven distractor suppression in alpha band activity. These findings indicate that proactive mechanisms of attention are involved in predictive distractor suppression and that these mechanisms are associated with altered neural excitability in early visual cortex. Moreover, our findings indicate that RIFT and alpha band activity might subtend different and possibly independent attentional mechanisms. SIGNIFICANCE STATEMENT What we experienced in the past affects how we perceive the external world in the future. For example, an annoying flashing light might be better ignored if we know in advance where it usually appears. This ability of extracting regularities from the environment is called statistical learning. In this study, we explore the neuronal mechanisms allowing the attentional system to overlook items that are unequivocally distracting based on their spatial distribution. By recording brain activity using MEG while probing neural excitability with a novel technique called RIFT, we show that the neuronal excitability in early visual cortex is reduced in advance of stimulus presentation for locations where distracting items are more likely to occur.
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