Logo image
Back
Speed-dependent locomotor adjustments following staggered thoracic lateral hemisections in adult cats
Journal article   Peer reviewed

Speed-dependent locomotor adjustments following staggered thoracic lateral hemisections in adult cats

Sirine Yassine, Johannie Audet, Charly G Lecomte, Stephen Mari, Angèle N Merlet, Jonathan Harnie, Ilya A Rybak, Boris I Prilutsky and Alain Frigon
Journal of neurophysiology, v 134(5), pp 1359-1377
01 Nov 2025
DOI: https://doi.org/10.1152/jn.00331.2025
PMID: 40987535
Featured in Collection :   UN Sustainable Development Goals @ Drexel

Abstract

Adaptation, Physiological Animals Biomechanical Phenomena Cats Female Functional Laterality - physiology Hindlimb - physiopathology Locomotion - physiology Male Muscle, Skeletal - physiopathology Spinal Cord Injuries - physiopathology Thoracic Vertebrae Electromyography
Animals adjust their locomotor pattern to increased speed demands by decreasing stance/extensor phase duration while the swing/flexor phase remains relatively unchanged, which we refer to here as "stance/extensor dominance." The control of locomotor speed involves dynamic interactions between spinal circuits, supraspinal drive, and somatosensory feedback. Whereas complete spinal cord injuries abolish brain-spinal cord interactions, incomplete lesions, such as lateral hemisections, preserve some connectivity between brain and spinal circuits. In this study, we investigated adjustments in the locomotor pattern at different treadmill speeds before and after staggered lateral thoracic hemisections performed on opposite sides of the spinal cord (first at right T5-T6 and then at left T10-T11). We collected kinematic and electromyographic data during treadmill locomotion from 0.4 to 0.8 m/s before and 8 wk after each spinal lesion in eight adult cats. Our main results show left-right asymmetries in hindlimb phase durations after each lesion, with prolonged swing on the ipsilesional side and prolonged stance on the contralesional side across speeds. Hindlimb stance dominance was also weakened on the side of each lesion, first on the right and then on the left after the first and second hemisections, respectively. In contrast to phase durations, hindlimb stride lengths remained symmetrical after both injuries across speeds. Using our recent computational models and experimental data of the present study, we provide predictions of altered interactions between supraspinal drive and somatosensory feedback onto flexor and extensor half-centers to explain left-right changes in hindlimb phase durations across speeds after staggered lateral thoracic hemisections. Staggered lateral thoracic hemisections reversibly altered the temporal structure of the hindlimb locomotor cycle by reducing stance/extensor phase dominance in the ipsilesional hindlimb in favor of the swing/flexor phase. The contralateral hindlimb compensated by prolonging stance and reducing swing. The forelimbs started taking more steps within a hindlimb cycle independently of speed or lesion side. These results can be explained by reorganized sensorimotor interactions based on network architecture from recently published computational models.

Metrics

2 Record Views

Details

UN Sustainable Development Goals (SDGs)

This publication has contributed to the advancement of the following goals:

#3 Good Health and Well-Being

InCites Highlights

Data related to this publication, from InCites Benchmarking & Analytics tool:

Collaboration types
Domestic collaboration
International collaboration
Web of Science research areas
Neurosciences
Physiology
Logo image