Muscle prestimulation tunes velocity preflex in simulated perturbed hopping

• Published in: Scientific reports Vol. 13; no. 1; p. 4559
• Main Authors: Izzi, Fabio, Mo, An, Schmitt, Syn, Badri-Spröwitz, Alexander, Haeufle, Daniel F. B.
• Format: Journal Article
• Language: English
• Published: London Nature Publishing Group UK 20.03.2023; Nature Publishing Group; Nature Portfolio
• Subjects: 631/114/2397; 692/698/1671/1668/1973; Computer Simulation; Elastic properties; Energy; Humanities and Social Sciences; Locomotion; Locomotion - physiology; Mathematical models; multidisciplinary; Muscle Contraction - physiology; Muscle Fibers, Skeletal; Muscle, Skeletal - physiology; Musculoskeletal System; Science; Science (multidisciplinary); Time Factors; Velocity
• ISSN: 2045-2322; 2045-2322
• DOI: 10.1038/s41598-023-31179-6

Muscle fibres possess unique visco-elastic properties, which generate a stabilising zero-delay response to unexpected perturbations. This instantaneous response—termed “preflex”—mitigates neuro-transmission delays, which are hazardous during fast locomotion due to the short stance duration. While the elastic contribution to preflexes has been studied extensively, the function of fibre viscosity due to the force–velocity relation remains unknown. In this study, we present a novel approach to isolate and quantify the preflex force produced by the force–velocity relation in musculo-skeletal computer simulations. We used our approach to analyse the muscle response to ground-level perturbations in simulated vertical hopping. Our analysis focused on the preflex-phase—the first 30 ms after impact—where neuronal delays render a controlled response impossible. We found that muscle force at impact and dissipated energy increase with perturbation height, helping reject the perturbations. However, the muscle fibres reject only 15% of step-down perturbation energy with constant stimulation. An open-loop rising stimulation, observed in locomotion experiments, amplified the regulatory effects of the muscle fibre’s force–velocity relation, resulting in 68% perturbation energy rejection. We conclude that open-loop neuronal tuning of muscle activity around impact allows for adequate feed-forward tuning of muscle fibre viscous capacity, facilitating energy adjustment to unexpected ground-level perturbations.