Multiple oscillatory rhythms determine the temporal organization of perception

• Published in: Proceedings of the National Academy of Sciences - PNAS Vol. 114; no. 51; pp. 13435 - 13440
• Main Authors: Ronconi, Luca, Oosterhof, Nikolaas N., Bonmassar, Claudia, Melcher, David
• Format: Journal Article
• Language: English
• Published: United States National Academy of Sciences 19.12.2017
• Subjects: Alpha Rhythm; Biological Sciences; Brain - physiology; Channels; Cortex; Decoding; EEG; Electroencephalography; Excitability; Female; Humans; Integration; Interstimulus interval; Male; Oscillations; Perception; Reaction Time; Sensory perception; Social Sciences; Stimuli; Theta Rhythm; Theta rhythms; Visual Perception; Young Adult; vision; oscillations; theta; MVPA; alpha
• ISSN: 0027-8424; 1091-6490; 1091-6490
• DOI: 10.1073/pnas.1714522114

Incoming sensory input is condensed by our perceptual system to optimally represent and store information. In the temporal domain, this process has been described in terms of temporal windows (TWs) of integration/segregation, in which the phase of ongoing neural oscillations determines whether two stimuli are integrated into a single percept or segregated into separate events. However, TWs can vary substantially, raising the question of whether different TWs map onto unique oscillations or, rather, reflect a single, general fluctuation in cortical excitability (e.g., in the alpha band). We used multivariate decoding of electroencephalography (EEG) data to investigate perception of stimuli that either repeated in the same location (two-flash fusion) or moved in space (apparent motion). By manipulating the interstimulus interval (ISI), we created bistable stimuli that caused subjects to perceive either integration (fusion/apparent motion) or segregation (two unrelated flashes). Training a classifier searchlight on the whole channels/frequencies/times space, we found that the perceptual outcome (integration vs. segregation) could be reliably decoded from the phase of prestimulus oscillations in right parieto-occipital channels. The highest decoding accuracy for the two-flash fusion task (ISI = 40 ms) was evident in the phase of alpha oscillations (8–10 Hz), while the highest decoding accuracy for the apparent motion task (ISI = 120 ms) was evident in the phase of theta oscillations (6–7 Hz). These results reveal a precise relationship between specific TW durations and specific oscillations. Such oscillations at different frequencies may provide a hierarchical framework for the temporal organization of perception.