Modulation of cutaneous reflexes during sidestepping in adult humans

A common neural control mechanism coordinates various types of rhythmic locomotion performed in the sagittal plane, but it is unclear whether frontal plane movements show similar neural patterning in adult humans. The purpose of this study was to compare cutaneous reflex modulation patterns evoked d...

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Bibliographic Details
Published in:Experimental brain research 2020-10, Vol.238 (10), p.2229-2243
Main Authors: Madsen, Leif P., Kitano, Koichi, Koceja, David M., Zehr, E. Paul, Docherty, Carrie L.
Format: Article
Language:English
Subjects:
Adults
Ankle
Biomedical and Life Sciences
Biomedicine
Computer peripherals industry
Electrical stimuli
Electromyography
Gait
Kinematics
Latency
Locomotion
Muscles
Neurology
Neurosciences
Pattern formation
Reflexes
Research Article
Rhythms
Sural nerve
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Summary:A common neural control mechanism coordinates various types of rhythmic locomotion performed in the sagittal plane, but it is unclear whether frontal plane movements show similar neural patterning in adult humans. The purpose of this study was to compare cutaneous reflex modulation patterns evoked during sagittal and frontal plane rhythmic movements. Eight healthy, neurologically intact adults (three males, five females) walked and sidestepped on a treadmill at approximately 1 Hz. The sural nerve of the dominant (and lead) limb was stimulated randomly every 3–7 steps at eight phases of each gait cycle. Ipsilateral electromyographic recordings from four lower leg muscles and kinematic data from the ankle were collected continuously throughout both tasks. Data from unstimulated gait cycles were used as control trials to calculate middle-latency reflex responses (80–120 ms) and kinematic changes (140–220 ms) following electrical stimulation. Results show that the cutaneous reflex modulation patterns were similar across both tasks despite significant differences in background EMG activity. However, increased reflex amplitudes were observed during the late swing and early stance phases of sidestepping, which directly altered ankle kinematics. These results suggest that the neural control mechanisms responsible for coordinating sagittal locomotion are flexibly modified to coordinate frontal plane activities even with very different foot landing mechanics.
ISSN:0014-4819
1432-1106
DOI:10.1007/s00221-020-05877-w