Rhythmic Information Sampling in the Brain during Visual Recognition

Laurent Caplette, K. Jerbi, F. Gosselin
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Abstract

When we fixate an object, visual information is continuously received on the retina. Several studies observed behavioral oscillations in perceptual sensitivity across such stimulus time, and these fluctuations have been linked to brain oscillations. However, whether specific brain areas show oscillations across stimulus time (i.e., different time points of the stimulus being more or less processed, in a rhythmic fashion) has not been investigated. Here, we revealed random areas of face images at random moments across time and recorded the brain activity of male and female human participants using MEG while they performed two recognition tasks. This allowed us to quantify how each snapshot of visual information coming from the stimulus is processed across time and across the brain. Oscillations across stimulus time (rhythmic sampling) were mostly visible in early visual areas, at theta, alpha, and low beta frequencies. We also found that they contributed to brain activity more than previously investigated rhythmic processing (oscillations in the processing of a single snapshot of visual information). Nonrhythmic sampling was also visible at later latencies across the visual cortex, either in the form of a transient processing of early stimulus time points or of a sustained processing of the whole stimulus. Our results suggest that successive cycles of ongoing brain oscillations process stimulus information incoming at successive moments. Together, these results advance our understanding of the oscillatory neural dynamics associated with visual processing and show the importance of considering the temporal dimension of stimuli when studying visual recognition. SIGNIFICANCE STATEMENT Several behavioral studies have observed oscillations in perceptual sensitivity over the duration of stimulus presentation, and these fluctuations have been linked to brain oscillations. However, oscillations across stimulus time in the brain have not been studied. Here, we developed an MEG paradigm to quantify how visual information received at each moment during fixation is processed through time and across the brain. We showed that different snapshots of a stimulus are distinctly processed in many brain areas and that these fluctuations are oscillatory in early visual areas. Oscillations across stimulus time were more prevalent than previously studied oscillations across processing time. These results increase our understanding of how neural oscillations interact with the visual processing of temporal stimuli.
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视觉识别过程中大脑的节奏信息采样
当我们注视一个物体时,视网膜会不断地接收视觉信息。几项研究观察到知觉敏感性在这种刺激时间内的行为振荡,这些波动与大脑振荡有关。然而,特定的大脑区域是否在刺激时间内显示振荡(即,刺激的不同时间点或多或少以有节奏的方式被处理)尚未被研究。在这里,我们揭示了随机时刻的随机面部图像区域,并使用MEG记录了男性和女性参与者在执行两项识别任务时的大脑活动。这使我们能够量化来自刺激的视觉信息的每个快照是如何在不同的时间和大脑中处理的。在刺激时间的振荡(有节奏的采样)主要可见于早期视觉区域,在θ, α和低β频率。我们还发现,它们对大脑活动的贡献比之前研究的节奏处理(处理单个视觉信息快照时的振荡)更大。非节律性采样在视觉皮层的后期潜伏期也可见,要么以对早期刺激时间点的短暂处理的形式出现,要么以对整个刺激的持续处理的形式出现。我们的结果表明,持续的大脑振荡的连续周期处理在连续时刻传入的刺激信息。总之,这些结果促进了我们对与视觉处理相关的振荡神经动力学的理解,并显示了在研究视觉识别时考虑刺激的时间维度的重要性。一些行为研究已经观察到知觉敏感性在刺激呈现的持续时间内的振荡,这些波动与大脑振荡有关。然而,大脑中刺激时间的振荡尚未被研究过。在这里,我们开发了一种脑磁图范式来量化在注视过程中每个时刻接收到的视觉信息是如何随着时间和大脑的变化而被处理的。我们发现,刺激的不同快照在许多大脑区域被明显地处理,这些波动在早期视觉区域是振荡的。刺激时间的振荡比先前研究的加工时间的振荡更为普遍。这些结果增加了我们对神经振荡如何与时间刺激的视觉处理相互作用的理解。
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