ePoster

Share ePoster
Scan or copy the public World Wide URL.
EFFECTIVE CONNECTIVITY IN HUMAN PARIETO-FRONTAL NETWORKS DURING GRASPING WITH AND WITHOUT VISUAL FEEDBACK
Sapienza University of Rome
Uploaded media
Approved media files submitted with this ePoster.
Presenter and authors
Presenter
Michelangelo Tani
Sapienza University of Rome
Co-authors
Sara Ferruzzi; Raffaele Costanzo; Martina Perrone; Gaspare Galati
Abstract
Reach-to-grasp actions require continuous transformation of visuomotor signals within specialized parieto-frontal circuits. Neuroimaging can identify these networks, but dissociating motor execution from visual feedback of one’s own movements is challenging.
Here, we addressed this limitation using MOTUM (Motion Online Tracking Under MRI), a system combining real-time kinematic tracking with virtual reality during fMRI, enabling independent manipulation of motor execution and visual feedback. Twenty-four right-handed human participants performed and/or observed reach-to-grasp actions during fMRI, in a 2×2 factorial design with movement and visual feedback present or absent. In visual-only trials, they observed a replay of their own previous movement.
The sensorimotor cortex (M1-S1) was activated when moving and suppressed (vs. baseline) in visual-only trials. Dorsal extrastriate regions (hMT+, V3A) were activated by observation and suppressed when moving without visual feedback. The supplementary motor area was active only during movement. The premotor ventral and dorsal areas, the anterior intraparietal sulcus (aIPS) and the superior parietal lobule (SPL) responded to both movement execution and visual feedback. Critically, aIPS and SPL showed a sub-additive response when movement and visual feedback co-occurred.
Dynamic causal modelling with parametric empirical Bayes revealed excitatory connectivity across all conditions from SPL to PMd and from PMd to the sensorimotor cortex, with bidirectional connections between SPL-aIPS and aIPS-PMv (Figure 1). Crucially, observing hand movement produced strong excitatory modulation from SPL to PMd, whereas moving without visual feedback drove excitatory influence from PMd to both SPL and PMv, suggesting that this pathway conveys motor-based predictions of sensory consequences.