The transition from invariant to action-dependent visual object representation in human dorsal pathway

The human brain can efficiently process action-related visual information, which supports our ability to quickly understand and learn others' actions. The visual information of goal-directed action is extensively represented in the parietal and frontal cortex, but how actions and goal-objects are represented within this neural network is not fully understood. Specifically, which part of this dorsal network represents the identity of goal-objects? Is such goal-object information encoded at an abstract level or highly interactive with action representations? Here, we used functional magnetic resonance imaging with a large number of participants (n = 94) to investigate the neural representation of goal-objects and actions when participants viewed goal-directed action videos. Our results showed that the goal-directed action information could be decoded across much of the dorsal pathway, but in contrast, the invariant goal-object information independent of action was mainly localized in the early stage of dorsal pathway in parietal cortex rather than the down-stream areas of the parieto-frontal cortex. These results help us to understand the relationship between action and goal-object representations in the dorsal pathway, and the evolution of interactive representation of goal-objects and actions along the dorsal pathway during goal-directed action observation.

Automated summary

The human brain efficiently processes action-related visual information, but the neural representation of actions and goal-objects in different parts of the brain is not fully understood. This study used functional magnetic resonance imaging to investigate how goal-objects and actions are represented in the dorsal pathway during goal-directed action observation. The results showed that action information could be decoded across much of the dorsal pathway, while invariant goal-object information was mainly localized in the early stage of the parietal cortex.