Sensitivity and Specificity of the Action Observation Network to Kinematics, Target Object, and Gesture Meaning

Overview

Journal Hum Brain Mapp

Publisher Wiley

Specialty Neurology

Date 2024 Jul 22

PMID 39037079

Authors

Francesca Simonelli

Giacomo Handjaras

Francesca Benuzzi

Giulio Bernardi

Andrea Leo

Davide Duzzi

Luca Cecchetti

Paolo F Nichelli

Carlo A Porro

Pietro Pietrini

Emiliano Ricciardi

Fausta Lui

Affiliations

Soon will be listed here.

Abstract

Hierarchical models have been proposed to explain how the brain encodes actions, whereby different areas represent different features, such as gesture kinematics, target object, action goal, and meaning. The visual processing of action-related information is distributed over a well-known network of brain regions spanning separate anatomical areas, attuned to specific stimulus properties, and referred to as action observation network (AON). To determine the brain organization of these features, we measured representational geometries during the observation of a large set of transitive and intransitive gestures in two independent functional magnetic resonance imaging experiments. We provided evidence for a partial dissociation between kinematics, object characteristics, and action meaning in the occipito-parietal, ventro-temporal, and lateral occipito-temporal cortex, respectively. Importantly, most of the AON showed low specificity to all the explored features, and representational spaces sharing similar information content were spread across the cortex without being anatomically adjacent. Overall, our results support the notion that the AON relies on overlapping and distributed coding and may act as a unique representational space instead of mapping features in a modular and segregated manner.

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