Lower limb suspension induces threshold-specific alterations of motor units properties that are reversed by active recovery

Giacomo Valli; Fabio Sarto; Andrea Casolo; Alessandro Del Vecchio; Martino V Franchi; Marco V Narici; Giuseppe De Vito

doi:10.1016/j.jshs.2023.06.004

Lower limb suspension induces threshold-specific alterations of motor units properties that are reversed by active recovery

J Sport Health Sci. 2024 Mar;13(2):264-276. doi: 10.1016/j.jshs.2023.06.004. Epub 2023 Jun 17.

Authors

Giacomo Valli¹, Fabio Sarto², Andrea Casolo², Alessandro Del Vecchio³, Martino V Franchi², Marco V Narici², Giuseppe De Vito²

Affiliations

¹ Department of Biomedical Sciences, University of Padova, Padova 35131, Italy. Electronic address: giacomo.valli@phd.unipd.it.
² Department of Biomedical Sciences, University of Padova, Padova 35131, Italy.
³ Department Artificial Intelligence in Biomedical Engineering, Friedrich-Alexander University, Erlangen-Nürnberg 91052, Germany.

Abstract

Purpose: This study aimed to non-invasively test the hypothesis that (a) short-term lower limb unloading would induce changes in the neural control of force production (based on motor units (MUs) properties) in the vastus lateralis muscle and (b) possible changes are reversed by active recovery (AR).

Methods: Ten young males underwent 10 days of unilateral lower limb suspension (ULLS) followed by 21 days of AR. During ULLS, participants walked exclusively on crutches with the dominant leg suspended in a slightly flexed position (15°-20°) and with the contralateral foot raised by an elevated shoe. The AR was based on resistance exercise (leg press and leg extension) and executed at 70% of each participant's 1 repetition maximum, 3 times/week. Maximal voluntary isometric contraction (MVC) of knee extensors and MUs properties of the vastus lateralis muscle were measured at baseline, after ULLS, and after AR. MUs were identified using high-density electromyography during trapezoidal isometric contractions at 10%, 25%, and 50% of the current MVC, and individual MUs were tracked across the 3 data collection points.

Results: We identified 1428 unique MUs, and 270 of them (18.9%) were accurately tracked. After ULLS, MVC decreased by 29.77%, MUs absolute recruitment/derecruitment thresholds were reduced at all contraction intensities (with changes between the 2 variables strongly correlated), while discharge rate was reduced at 10% and 25% but not at 50% MVC. Impaired MVC and MUs properties fully recovered to baseline levels after AR. Similar changes were observed in the pool of total as well as tracked MUs.

Conclusion: Our novel results demonstrate, non-invasively, that 10 days of ULLS affected neural control predominantly by altering the discharge rate of lower-threshold but not of higher-threshold MUs, suggesting a preferential impact of disuse on motoneurons with a lower depolarization threshold. However, after 21 days of AR, the impaired MUs properties were fully restored to baseline levels, highlighting the plasticity of the components involved in neural control.

Keywords: Disuse; High-density EMG; Muscle disuse; Neural impairment; Neuromuscular degeneration.

MeSH terms

Electromyography
Humans
Knee* / physiology
Lower Extremity*
Male
Motor Neurons / physiology
Quadriceps Muscle / physiology