Abstract
BackgroundDuring rapid serial visual presentation (RSVP), observers often miss the second of two targets if it appears within 500 ms of the first. This phenomenon, called the attentional blink (AB), is widely held to reflect a bottleneck in the processing of rapidly sequential stimuli that arises after initial sensory registration is complete (i.e., at a relatively late, post-perceptual stage of processing). Contrary to this view, recent fMRI studies have found that activity in the primary visual area (V1), which represents the earliest cortical stage of visual processing, is attenuated during the AB. Here we asked whether such changes in V1 activity during the AB arise in the initial feedforward sweep of stimulus input, or instead reflect the influence of feedback signals from higher cortical areas.Methodology/Principal FindingsEEG signals were recorded while participants monitored a sequential stream of distractor letters for two target digits (T1 and T2). Neural responses associated with an irrelevant probe stimulus presented simultaneously with T2 were measured using an ERP marker – the C1 component – that reflects initial perceptual processing of visual information in V1. As expected, T2 accuracy was compromised when the inter-target interval was brief, reflecting an AB deficit. Critically, however, the magnitude of the early C1 component evoked by the probe was not reduced during the AB.Conclusions/SignificanceOur finding that early sensory processing of irrelevant probe stimuli is not suppressed during the AB is consistent with theoretical models that assume that the bottleneck underlying the AB arises at a post-perceptual stage of processing. This suggests that reduced neural activity in V1 during the AB is driven by re-entrant signals from extrastriate areas that regulate early cortical activity via feedback connections with V1.
Highlights
Our capacity to process information about the external environment is restricted to only a small portion of the inputs provided by our sensory organs [1]
These findings strongly implicate post-perceptual processes as the source of capacity limitations underlying the attentional blink (AB). At odds with this suggestion, are the findings of a recent Functional magnetic resonance imaging (fMRI) study by Williams, Visser, Cunnington and Mattingley [6] which measured blood oxygen level dependent (BOLD) responses in V1 evoked by T2 stimuli presented during the AB. Such a task is complicated by poor temporal resolution of fMRI, as BOLD responses evoked by T2 stimuli are difficult to disentangle from those evoked by neighbouring items within the rapid serial visual presentation (RSVP) stream
A potential challenge to this assumption has been provided by recent fMRI studies [6,34], which reported AB-related reductions in neural responses to stimuli presented during the AB in early cortical areas, including V1
Summary
Our capacity to process information about the external environment is restricted to only a small portion of the inputs provided by our sensory organs [1]. A possible reconciliation of these contrasting findings is provided by re-entrant feedback models of perception [35,36,37,38,39], which argue that perception consists of a feedforward sweep of information from lower perceptual areas to higher regions of cortex, and of feedback signals from higher back to lower areas of cortex These models are supported by anatomical studies demonstrating axonal tracts extending in both directions between higher and lower areas in the primate visual system [40], and by electrophysiological studies suggesting that spatial attention-related activity in extrastriate areas might occur earlier than in V1 [41,42]. We obtained a robust AB in behavioural testing, and a reliable C1 component for the irrelevant probe presented with T2, but found that the amplitude of the C1 component was unaltered during the AB
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