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How does orientation-tuned normalization spread across the visual field?

Michaela Klímová1,2,3, Ilona M Bloem4, Sam Ling1,2

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Summary
This summary is machine-generated.

Gain control mechanisms regulate visual cortex responses. This study found orientation-tuned surround suppression is stronger when stimuli are collinear, impacting neural responses in early visual areas.

Keywords:
contrast response functionsdivisive normalizationfMRIsurround suppressionvision

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Area of Science:

  • Neuroscience
  • Visual Perception
  • Computational Neuroscience

Background:

  • Visuocortical responses rely on gain control, including surround suppression.
  • Suppression strength varies with stimulus features like orientation similarity.
  • The impact of orientation-tuned suppression on contrast responses is understudied.

Purpose of the Study:

  • To investigate the role of orientation-tuned suppression in modulating contrast response functions (CRFs) in early visual cortex.
  • To determine how feature similarity, specifically collinearity versus orthogonality, affects suppression strength.
  • To examine the spatial spread of this tuned suppression across the visual field.

Main Methods:

  • Used functional magnetic resonance imaging (fMRI) to measure brain activity in visual areas V1-V3.
  • Presented observers with center-surround gratings where center and surround orientations were either collinear or orthogonal.
  • Measured population contrast response functions (CRFs) across a range of center stimulus contrasts.

Main Results:

  • Stronger suppression was observed when the surround grating was collinear with the center grating compared to orthogonal.
  • This orientation-tuned suppression caused significant shifts in the population CRFs.
  • The magnitude of the CRF shift was dependent on voxel spatial preference, primarily affecting voxels near the center-surround boundary.

Conclusions:

  • Orientation similarity significantly influences the strength of surround suppression in early visual cortex.
  • Tuned suppression primarily impacts neural populations with receptive fields at the center-surround boundary.
  • These findings elucidate the feature-tuned gain control mechanisms shaping visual processing and perception.