Abstract
Decision-making requires the accumulation of sensory evidence. However, in everyday life, sensory information is often ambiguous and contains decision-irrelevant features. This means that the brain must disambiguate sensory input and extract decision-relevant features. Sensory information processing and decision-making represent two subsequent stages of the perceptual decision-making process. While sensory processing relies on occipito-parietal neuronal activity during the earlier time window, decision-making lasts for a prolonged time, involving parietal and frontal areas. Although perceptual decision-making is being actively studied, its neuronal mechanisms under ambiguous sensory evidence lack detailed consideration. Here, we analyzed the brain activity of subjects accomplishing a perceptual decision-making task involving the classification of ambiguous stimuli. We demonstrated that ambiguity induced high frontal θ-band power for 0.15 s post-stimulus onset, indicating increased reliance on top-down processes, such as expectations and memory. Ambiguous processing also caused high occipito-parietal β-band power for 0.2 s and high fronto-parietal β-power for 0.35–0.42 s post-stimulus onset. We supposed that the former component reflected the disambiguation process while the latter reflected the decision-making phase. Our findings complemented existing knowledge about ambiguous perception by providing additional information regarding the temporal discrepancy between the different cognitive processes during perceptual decision-making.
Highlights
Perceptual decision-making represents choosing a course of action based on available sensory evidence (Heekeren et al, 2008)
Earlier studies on perceptual decision-making in rodents and monkeys used implanted micro-electrodes and identified spatially localized neuronal activity correlated with their behavioral performance
They specified that the localized γ -band activity in the sensorimotor cortex reflected information encoding and motor planning, while the large-scale β-band activity across widespread cortical areas coordinated the activity of these local networks
Summary
Perceptual decision-making represents choosing a course of action based on available sensory evidence (Heekeren et al, 2008) This process implies the evaluation of sensory information to make a decision and translate it into behavior. After reviewing a large number of neuroimaging studies, Siegel et al (2011) concluded that perceptual decisions in humans relied on neuronal activity in the high-frequency γ (>50 Hz) and low-frequency β (15–30 Hz) bands. They specified that the localized γ -band activity in the sensorimotor cortex reflected information encoding and motor planning, while the large-scale β-band activity across widespread cortical areas coordinated the activity of these local networks
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