Abstract
The perception of an object as a single entity within a visual scene requires that its features are bound together and segregated from the background and/or other objects. Here, we used magnetoencephalography (MEG) to assess the hypothesis that coherent percepts may arise from the synchronized high frequency (gamma) activity between neurons that code features of the same object. We also assessed the role of low frequency (alpha, beta) activity in object processing. The target stimulus (i.e. object) was a small patch of a concentric grating of 3c/°, viewed eccentrically. The background stimulus was either a blank field or a concentric grating of 3c/° periodicity, viewed centrally. With patterned backgrounds, the target stimulus emerged – through rotation about its own centre – as a circular subsection of the background. Data were acquired using a 275-channel whole-head MEG system and analyzed using Synthetic Aperture Magnetometry (SAM), which allows one to generate images of task-related cortical oscillatory power changes within specific frequency bands. Significant oscillatory activity across a broad range of frequencies was evident at the V1/V2 border, and subsequent analyses were based on a virtual electrode at this location. When the target was presented in isolation, we observed that: (i) contralateral stimulation yielded a sustained power increase in gamma activity; and (ii) both contra- and ipsilateral stimulation yielded near identical transient power changes in alpha (and beta) activity. When the target was presented against a patterned background, we observed that: (i) contralateral stimulation yielded an increase in high-gamma (>55Hz) power together with a decrease in low-gamma (40–55Hz) power; and (ii) both contra- and ipsilateral stimulation yielded a transient decrease in alpha (and beta) activity, though the reduction tended to be greatest for contralateral stimulation. The opposing power changes across different regions of the gamma spectrum with ‘figure/ground’ stimulation suggest a possible dual role for gamma rhythms in visual object coding, and provide general support of the binding-by-synchronization hypothesis. As the power changes in alpha and beta activity were largely independent of the spatial location of the target, however, we conclude that their role in object processing may relate principally to changes in visual attention.
Highlights
The primate brain contains over 30 distinct visual areas (Van Essen, 2004), we experience a unified perceptual view of the world in the blink of an eye
Using MEG and functional magnetic resonance imaging retinotopic mapping, we reliably identified visual areas associated with rhythmic activity in the ventral cortex at the border of areas V1 and V2, and based our analyses on virtual electrodes at this position
Overlaid in red are the areas where maximal gamma band activity (30 – 90 Hz) was detected using Synthetic Aperture Magnetometry (SAM) from MEG responses to the target patches presented against a blank background in either the left or right visual field
Summary
The primate brain contains over 30 distinct visual areas (Van Essen, 2004), we experience a unified perceptual view of the world in the blink of an eye. A binding solution based entirely on hierarchical (feedforward) processing is not feasible as the number of neurons required to process each unique view of every object would be unacceptably large. Such a theory disregards the multitude of feedback projections within the visual system that may be vital for the generation of global percepts (Bullier, 2001; Halgren, Mendola, Chong, & Dale, 2003; Thielscher, Kolle, Neumann, Spitzer, & Gron, 2008)
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