Coordination between upper- and lower-limb movements is different during overground and treadmill walking

Carpinella, Ilaria; Crenna, P.; Rabuffetti, Marco; Ferrarin, Maurizio

doi:10.1007/s00421-009-1168-5

Cited by 41 publications

(24 citation statements)

References 56 publications

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“…For comparison, we first evaluated walking speed effects on inter-extremity coordination when the nervous system is intact. Our results are consistent with studies showing speed influences arm amplitude and frequency; and inter-extremity coordination, or coupling between the arms and legs becomes tighter with increasing speed [2, 3, 18, 19]. Because spinal circuitry can contribute to automatic, rhythmical, and reciprocal patterns like stepping, we hypothesized arm and leg coordination would be tight in individuals with iSCI selecting CWSs similar to CWSs seen in individuals without neurological injury (1.0–1.3 m/s) [20].…”

Section: Introductionsupporting

confidence: 92%

Arm and leg coordination during treadmill walking in individuals with motor incomplete spinal cord injury: A preliminary study

et al. 2012

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Arm and leg coordination naturally emerges during walking, but can be affected by stroke or Parkinson’s disease. The purpose of this preliminary study was to characterize arm and leg coordination during treadmill walking at self-selected comfortable walking speeds (CWSs) in individuals using arm swing with motor incomplete spinal cord injury (iSCI). Hip and shoulder angle cycle durations and amplitudes, strength of peak correlations between contralateral hip and shoulder joint angle time series, the time shifts at which these peak correlations occur, and associated variability were quantified. Outcomes in individuals with iSCI selecting fast CWSs (range, 1.0–1.3 m/s) and speed-matched individuals without neurological injuries are similar. Differences, however, are detected in individuals with iSCI selecting slow CWSs (range, 0.25–0.65 m/s) and may represent compensatory strategies to improve walking balance or forward propulsion. These individuals elicit a 1:1, arm: leg frequency ratio versus the 2:1 ratio observed in non-injured individuals. Shoulder and hip movement patterns, however, are highly reproducible (coordinated) in participants with iSCI, regardless of CWS. This high degree of inter-extremity coordination could reflect an inability to modify a single movement pattern post-iSCI. Combined, these data suggest inter-extremity walking coordination may be altered, but is present after iSCI, and therefore may be regulated, in part, by neural control.

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Section: Introductionsupporting

confidence: 92%

Arm and leg coordination during treadmill walking in individuals with motor incomplete spinal cord injury: A preliminary study

et al. 2012

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“…1 km/h) and 1:1 at higher velocities (Donker et al, 2005). Furthermore, arm-leg coordination may be different between overground and treadmill walking in terms of both frequency coupling and relative phase between arm and thigh motion (Carpinella et al, 2010). Due to technical limitations we could not collect EMG data during overground walking, and therefore used a treadmill.…”

Section: Discussionmentioning

confidence: 99%

Activity of upper limb muscles during human walking

Kuhtz-Buschbeck

Jing

2012

Journal of Electromyography and Kinesiology

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“…Toutefois, la coordination peut être différente selon les activités, à cause des neuro-mécanismes spécifiques à certaines conditions [41][42][43][44].…”

Section: Couplage Neuronal Et Coordination Inter-membresunclassified

Interlimb neural coupling: Implications for poststroke hemiparesis

Arya

Pandian

2014

Annals of Physical and Rehabilitation Medicine

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Interlimb coordination is essential to perform goal-directed daily tasks and purposeful locomotion. The coordination occurs due to spatiotemporal coupling of movements, which also comprises interactions in segmental kinematics, joint dynamics, and muscle activity. Neuroanatomical and neurophysiological linkages at the spinal and brain level are responsible for the coordination. The linkage is termed "neural coupling". According to the task demand, the coupling may occur between two upper limbs or two lower limbs or all four limbs. Central pattern generators play a key role in interlimb coordination by regulating the rhythmic upper and lower limb movements. Neuroanatomically, multiple areas of both cerebral hemispheres via the corpus callosum interact and control the bimanual upper limb movements. There is an interhemispheric synchronization and disinhibition to control the coupled bimanual upper and lower limb movements. Movement of the upper limb also enhances neuromuscular recruitment of the lower limb. In stroke, bimanual motor impairments exist in the form of asymmetry and reduced coordination, which may be related to weakness of the ipsilateral body side lesser than the contralateral side. The aim of the present review was to understand the interlimb coordination and neural coupling and its implication in stroke rehabilitation. The review suggests incorporating the movements of bilateral upper and lower limbs either simultaneously or consecutively for hemiparetic subjects. Further, the conventional and contemporary rehabilitation methods need to be reconsidered while utilizing the coupling concept.

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Coordination between upper- and lower-limb movements is different during overground and treadmill walking

Cited by 41 publications

References 56 publications

Arm and leg coordination during treadmill walking in individuals with motor incomplete spinal cord injury: A preliminary study

Arm and leg coordination during treadmill walking in individuals with motor incomplete spinal cord injury: A preliminary study

Activity of upper limb muscles during human walking

Interlimb neural coupling: Implications for poststroke hemiparesis

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