Complexity of Modular Neuromuscular Control Increases and Variability Decreases During Human Locomotor Development

Overview

Journal Commun Biol

Specialty Biology

Date 2022 Nov 17

PMID 36385628

Authors

Francesca Sylos-Labini

Valentina La Scaleia

Germana Cappellini

Arthur Dewolf

Adele Fabiano

Irina A Solopova

Vito Mondi

Yury Ivanenko

Francesco Lacquaniti

Affiliations

Soon will be listed here.

Abstract

When does modular control of locomotion emerge during human development? One view is that modularity is not innate, being learnt over several months of experience. Alternatively, the basic motor modules are present at birth, but are subsequently reconfigured due to changing brain-body-environment interactions. One problem in identifying modular structures in stepping infants is the presence of noise. Here, using both simulated and experimental muscle activity data from stepping neonates, infants, preschoolers, and adults, we dissect the influence of noise, and identify modular structures in all individuals, including neonates. Complexity of modularity increases from the neonatal stage to adulthood at multiple levels of the motor infrastructure, from the intrinsic rhythmicity measured at the level of individual muscles activities, to the level of muscle synergies and of bilateral intermuscular network connectivity. Low complexity and high variability of neuromuscular signals attest neonatal immaturity, but they also involve potential benefits for learning locomotor tasks.

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