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Abstract:
A growing body of literature suggests that feedback modulation of early visual processing is ubiquitous and central to cortical computation. In particular stimuli with high-level content have been shown to suppress early visual regions, typically interpreted in the framework of predictive coding. However, physical stimulus differences can preclude clear interpretations in terms of feedback.
Here we examined activity modulation in the early visual
cortex (V1 and V2) using fMRI during distinct perceptual states associated to the same physical input. This ensures in a unique way that observed signal modulations cannot be accounted for by changes in physical stimulus properties, and can therefore only be accounted for by percept-related feedback interactions from higher level regions. We used a dynamic stimulus consisting of moving dots that could either be perceived as corners of a large moving square (global Gestalt) or as distributed sets of locally
moving dots. We found that perceptual binding of local moving elements into an illusory Gestalt led to spatially segregated differential modulations, in both, V1 and V2: retinotopic representations of illusory lines and foreground were enhanced, while inducers and background suppressed. The results extend prior findings to the illusory-perceptual state of physically un-changed
stimuli, and show percept-driven background suppression in the human brain. Based on prior work, we hypothesize that parietal cortex is responsible for the modulations through recurrent connections in a predictive coding account of visual processing.
