Brownian processes in human motor control support descending neural velocity commands

Tessari, Federico; Hermus, James; Sugimoto-Dimitrova, Rika; Hogan, Neville

doi:10.1038/s41598-024-58380-5

Sci Rep

2024

DOI: 10.1038/s41598-024-58380-5

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Brownian processes in human motor control support descending neural velocity commands

Federico Tessari,

James Hermus,

Rika Sugimoto-Dimitrova

et al.

Abstract: The motor neuroscience literature suggests that the central nervous system may encode some motor commands in terms of velocity. In this work, we tackle the question: what consequences would velocity commands produce at the behavioral level? Considering the ubiquitous presence of noise in the neuromusculoskeletal system, we predict that velocity commands affected by stationary noise would produce “random walks”, also known as Brownian processes, in position. Brownian motions are distinctively characterized by a… Show more

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References 83 publications

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Frequency-domain patterns in foot-force line-of-action: an emergent property of standing balance control

Sugimoto-Dimitrova,

Shiozawa,

Gruben

et al. 2024

Journal of Neurophysiology

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A recent line of work suggests that the net behavior of the foot-ground interaction force provides insight into quiet-standing-balance dynamics and control. Through human subject experiments, Boehm et al. found that the relative variations of the center of pressure and force orientation emerge as a distinct pattern in the frequency domain, termed the "intersection-point height." Subsequent empirical and simulation-based studies showed that different control strategies are reflected in the distribution of intersection-point height across frequency. To facilitate understanding of the strengths and limitations of the intersection-point height in describing the dynamics and control of standing, the present work establishes a spectral-based method that also enables derivation of a closed-form estimate of the intersection-point height from any linear model of quiet stance. This new method explained observations from prior work, including how the measure captures aspects of control and physiological noise. The analysis presented herein highlights the utility of the frequency-dependent foot-force dynamics in probing the balance controller and provides a tool for model development and validation to further our understanding of the neuromotor control of natural upright posture in humans.

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Frequency-domain patterns in foot-force line-of-action: an emergent property of standing balance control

Sugimoto-Dimitrova,

Shiozawa,

Gruben

et al. 2024

Journal of Neurophysiology

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show abstract

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Brownian processes in human motor control support descending neural velocity commands

Cited by 1 publication

References 83 publications

Frequency-domain patterns in foot-force line-of-action: an emergent property of standing balance control

Frequency-domain patterns in foot-force line-of-action: an emergent property of standing balance control

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