Neuromotor Dynamics of Human Locomotion in Challenging Settings

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Authors

  • Alessandro Santuz
  • Leon Brüll
  • Antonis Ekizos
  • Arno Schroll
  • Nils Eckardt

External Research Organisations

  • Humboldt-Universität zu Berlin (HU Berlin)
  • Dalhousie University
  • Heidelberg University
  • University of Kassel
  • Carl von Ossietzky University of Oldenburg
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Details

Original languageEnglish
Article number100796
JournaliScience
Volume23
Issue number1
Publication statusPublished - 24 Dec 2019
Externally publishedYes

Abstract

Is the control of movement less stable when we walk or run in challenging settings? Intuitively, one might answer that it is, given that challenging locomotion externally (e.g., rough terrain) or internally (e.g., age-related impairments) makes our movements more unstable. Here, we investigated how young and old humans synergistically activate muscles during locomotion when different perturbation levels are introduced. Of these control signals, called muscle synergies, we analyzed the local stability and the complexity (or irregularity) over time. Surprisingly, we found that perturbations force the central nervous system to produce muscle activation patterns that are less unstable and less complex. These outcomes show that robust locomotion control in challenging settings is achieved by producing less complex control signals that are more stable over time, whereas easier tasks allow for more unstable and irregular control.

Keywords

    Behavioral Neuroscience, Biological Sciences, Neuroscience

ASJC Scopus subject areas

Cite this

Neuromotor Dynamics of Human Locomotion in Challenging Settings. / Santuz, Alessandro; Brüll, Leon; Ekizos, Antonis et al.
In: iScience, Vol. 23, No. 1, 100796, 24.12.2019.

Research output: Contribution to journalArticleResearchpeer review

Santuz, A, Brüll, L, Ekizos, A, Schroll, A, Eckardt, N, Kibele, A, Schwenk, M & Arampatzis, A 2019, 'Neuromotor Dynamics of Human Locomotion in Challenging Settings', iScience, vol. 23, no. 1, 100796. https://doi.org/10.1016/j.isci.2019.100796
Santuz, A., Brüll, L., Ekizos, A., Schroll, A., Eckardt, N., Kibele, A., Schwenk, M., & Arampatzis, A. (2019). Neuromotor Dynamics of Human Locomotion in Challenging Settings. iScience, 23(1), Article 100796. https://doi.org/10.1016/j.isci.2019.100796
Santuz A, Brüll L, Ekizos A, Schroll A, Eckardt N, Kibele A et al. Neuromotor Dynamics of Human Locomotion in Challenging Settings. iScience. 2019 Dec 24;23(1):100796. doi: 10.1016/j.isci.2019.100796
Santuz, Alessandro ; Brüll, Leon ; Ekizos, Antonis et al. / Neuromotor Dynamics of Human Locomotion in Challenging Settings. In: iScience. 2019 ; Vol. 23, No. 1.
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title = "Neuromotor Dynamics of Human Locomotion in Challenging Settings",
abstract = "Is the control of movement less stable when we walk or run in challenging settings? Intuitively, one might answer that it is, given that challenging locomotion externally (e.g., rough terrain) or internally (e.g., age-related impairments) makes our movements more unstable. Here, we investigated how young and old humans synergistically activate muscles during locomotion when different perturbation levels are introduced. Of these control signals, called muscle synergies, we analyzed the local stability and the complexity (or irregularity) over time. Surprisingly, we found that perturbations force the central nervous system to produce muscle activation patterns that are less unstable and less complex. These outcomes show that robust locomotion control in challenging settings is achieved by producing less complex control signals that are more stable over time, whereas easier tasks allow for more unstable and irregular control.",
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AU - Santuz, Alessandro

AU - Brüll, Leon

AU - Ekizos, Antonis

AU - Schroll, Arno

AU - Eckardt, Nils

AU - Kibele, Armin

AU - Schwenk, Michael

AU - Arampatzis, Adamantios

N1 - Funding information: We thank Juri Taborri for the tireless contribution to different parts of the measurements and are grateful to all the participants who showed great commitment and interest during the experiments and to DAAD for the financial support during the publication process. We disclose any professional relationship with companies or manufacturers who might benefit from the results of the present study. Conceptualization: A. Santuz, L.B. A.E. M.S. and A.A.; Data Curation: A. Santuz, A.E. N.E.; Formal Analysis: A. Santuz; Investigation: A. Santuz, L.B. A.E. and N.E.; Methodology: A. Santuz, A.E. A. Schroll, and A.A.; Project administration: A. Santuz, A.K. M.S. and A.A.; Resources: A. Santuz, L.B. N.E. A.K. M.S. and A.A.; Software: A. Santuz; Supervision: A. Santuz, and A.A.; Validation: A. Santuz; Visualization: A. Santuz; Writing – Original Draft: A. Santuz and A.A.; Writing – Review & Editing: A. Santuz, L.B. A.E. A. Schroll, N.E. A.K. M.S. and A.A. The authors declare no competing interests.

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