Lower complexity of motor primitives ensures robust control of high-speed human locomotion

Alessandro Santuz, Antonis Ekizos, Yoko Kunimasa, Kota Kijima, Masaki Ishikawa, Adamantios Arampatzis

doi:10.1016/j.heliyon.2020.e05377

<jats:title>Abstract</jats:title><jats:p>Walking and running are mechanically and energetically different locomotion modes. For selecting one or another, speed is a parameter of paramount importance. Yet, both are likely controlled by similar low-dimensional neuronal networks that reflect in patterned muscle activations called muscle synergies. Here, we investigated how humans synergistically activate muscles during locomotion at different submaximal and maximal speeds. We analysed the duration and complexity (or irregularity) over time of motor primitives, the temporal components of muscle synergies. We found that the challenge imposed by controlling high-speed locomotion forces the central nervous system to produce muscle activation patterns that are wider and less complex relative to the duration of the gait cycle. The motor modules, or time-independent coefficients, were redistributed as locomotion speed changed. These outcomes show that robust locomotion control at challenging speeds is achieved by modulating the relative contribution of muscle activations and producing less complex and wider control signals, whereas slow speeds allow for more irregular control.</jats:p>

Lower complexity of motor primitives ensures robust control of high-speed human locomotion

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