The Macaque Lateral Grasping Network: A Neural Substrate for Generating Purposeful Hand Actions

Overview

Journal Neurosci Biobehav Rev

Specialties Neurology
Psychology
Social Sciences

Date 2017 Jan 22

PMID 28108414

Citations 50

Authors

Elena Borra

Marzio Gerbella

Stefano Rozzi

Giuseppe Luppino

Affiliations

Soon will be listed here.

Abstract

In primates, neural mechanisms for controlling skilled hand actions primarily rely on sensorimotor transformations. These transformations are mediated by circuits linking specific inferior parietal with ventral premotor areas in which sensory coding of objects' features automatically triggers appropriate hand motor programs. Recently, connectional studies in macaques showed that these parietal and premotor areas are nodes of a large-scale cortical network, designated as "lateral grasping network," including specific temporal and prefrontal sectors involved in object recognition and executive functions, respectively. These data extend grasping models so far proposed in providing a possible substrate for interfacing perceptual, cognitive, and hand-related sensorimotor processes for controlling hand actions based on object identity, goals, and memory-based or contextual information and for the contribution of motor signals to cognitive motor functions. Human studies provided evidence for a possible counterpart of the macaque lateral grasping network, suggesting that in primate evolution the neural mechanisms for controlling hand actions described in the macaque have been retained and exploited for the emergence of human-specific motor and cognitive motor capacities.

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