Attention to visual motion suppresses neuronal and behavioral sensitivity in nearby feature space

BMC Biol. 2022 Oct 5;20(1):220. doi: 10.1186/s12915-022-01428-7.

Abstract

Background: Feature-based attention prioritizes the processing of the attended feature while strongly suppressing the processing of nearby ones. This creates a non-linearity or "attentional suppressive surround" predicted by the Selective Tuning model of visual attention. However, previously reported effects of feature-based attention on neuronal responses are linear, e.g., feature-similarity gain. Here, we investigated this apparent contradiction by neurophysiological and psychophysical approaches.

Results: Responses of motion direction-selective neurons in area MT/MST of monkeys were recorded during a motion task. When attention was allocated to a stimulus moving in the neurons' preferred direction, response tuning curves showed its minimum for directions 60-90° away from the preferred direction, an attentional suppressive surround. This effect was modeled via the interaction of two Gaussian fields representing excitatory narrowly tuned and inhibitory widely tuned inputs into a neuron, with feature-based attention predominantly increasing the gain of inhibitory inputs. We further showed using a motion repulsion paradigm in humans that feature-based attention produces a similar non-linearity on motion discrimination performance.

Conclusions: Our results link the gain modulation of neuronal inputs and tuning curves examined through the feature-similarity gain lens to the attentional impact on neural population responses predicted by the Selective Tuning model, providing a unified framework for the documented effects of feature-based attention on neuronal responses and behavior.

Keywords: Attentional surround suppression; Feature-based attention; Motion processing; Selective Tuning model.

Publication types

  • Research Support, Non-U.S. Gov't

MeSH terms

  • Humans
  • Motion Perception* / physiology
  • Neurons / physiology
  • Photic Stimulation / methods
  • Temporal Lobe / physiology