Treadmill exercise activates subcortical neural networks and improves walking after a stroke
Treadmill exercise activates subcortical neural networks and improves walking after a stroke
BACKGROUND AND PURPOSE: Stroke often impairs gait thereby reducing mobility and fitness and promoting chronic disability. Gait is a complex sensorimotor function controlled by integrated cortical, subcortical, and spinal networks. The mechanisms of gait recovery after stroke are not well understood. This study examines the hypothesis that progressive task-repetitive treadmill exercise (T-EX) improves fitness and gait function in subjects with chronic hemiparetic stroke by inducing adaptations in the brain (plasticity).
METHODS: A randomized controlled trial determined the effects of 6-month T-EX (n=37) versus comparable duration stretching (CON, n=34) on walking, aerobic fitness and in a subset (n=15/17) on brain activation measured by functional MRI.
RESULTS: T-EX significantly improved treadmill-walking velocity by 51% and cardiovascular fitness by 18% (11% and -3% for CON, respectively; P<0.05). T-EX but not CON affected brain activation during paretic, but not during nonparetic limb movement, showing 72% increased activation in posterior cerebellar lobe and 18% in midbrain (P<0.005). Exercise-mediated improvements in walking velocity correlated with increased activation in cerebellum and midbrain.
CONCLUSIONS: T-EX improves walking, fitness and recruits cerebellum-midbrain circuits, likely reflecting neural network plasticity. This neural recruitment is associated with better walking. These findings demonstrate the effectiveness of T-EX rehabilitation in promoting gait recovery of stroke survivors with long-term mobility impairment and provide evidence of neuroplastic mechanisms that could lead to further refinements in these paradigms to improve functional outcomes.
exercise, rehabilitation, plasticity, locomotion, fitness
3341-3350
Luft, A.R.
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Macko, R.F.
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Forrester, L.W.
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Villagra, F.
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Ivey, F.
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Sorkin, J.D.
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Whitall, Jill
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McCombe-Waller, S.
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Katzel, L.
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Goldberg, A.P.
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Hanley, D.F.
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December 2008
Luft, A.R.
0ccb8d36-af5f-4ecd-892d-8358395e47dd
Macko, R.F.
b50febb0-5ccf-4787-a8ec-f9f51847fa79
Forrester, L.W.
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Villagra, F.
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Ivey, F.
01312c77-e9b2-4c5e-9d3e-b165ca6c0b0e
Sorkin, J.D.
539e1004-dbc6-4b88-9d90-e1a163a9a0e6
Whitall, Jill
9761aefb-be80-4270-bc1f-0e726399376e
McCombe-Waller, S.
45a597ea-62ef-47ca-83a1-5f97145f38a4
Katzel, L.
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Goldberg, A.P.
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Hanley, D.F.
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Luft, A.R., Macko, R.F., Forrester, L.W., Villagra, F., Ivey, F., Sorkin, J.D., Whitall, Jill, McCombe-Waller, S., Katzel, L., Goldberg, A.P. and Hanley, D.F.
(2008)
Treadmill exercise activates subcortical neural networks and improves walking after a stroke.
Stroke, 39 (12), .
(doi:10.1161/?STROKEAHA.108.527531).
(PMID:18757284)
Abstract
BACKGROUND AND PURPOSE: Stroke often impairs gait thereby reducing mobility and fitness and promoting chronic disability. Gait is a complex sensorimotor function controlled by integrated cortical, subcortical, and spinal networks. The mechanisms of gait recovery after stroke are not well understood. This study examines the hypothesis that progressive task-repetitive treadmill exercise (T-EX) improves fitness and gait function in subjects with chronic hemiparetic stroke by inducing adaptations in the brain (plasticity).
METHODS: A randomized controlled trial determined the effects of 6-month T-EX (n=37) versus comparable duration stretching (CON, n=34) on walking, aerobic fitness and in a subset (n=15/17) on brain activation measured by functional MRI.
RESULTS: T-EX significantly improved treadmill-walking velocity by 51% and cardiovascular fitness by 18% (11% and -3% for CON, respectively; P<0.05). T-EX but not CON affected brain activation during paretic, but not during nonparetic limb movement, showing 72% increased activation in posterior cerebellar lobe and 18% in midbrain (P<0.005). Exercise-mediated improvements in walking velocity correlated with increased activation in cerebellum and midbrain.
CONCLUSIONS: T-EX improves walking, fitness and recruits cerebellum-midbrain circuits, likely reflecting neural network plasticity. This neural recruitment is associated with better walking. These findings demonstrate the effectiveness of T-EX rehabilitation in promoting gait recovery of stroke survivors with long-term mobility impairment and provide evidence of neuroplastic mechanisms that could lead to further refinements in these paradigms to improve functional outcomes.
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e-pub ahead of print date: 28 August 2008
Published date: December 2008
Keywords:
exercise, rehabilitation, plasticity, locomotion, fitness
Organisations:
Faculty of Health Sciences
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Local EPrints ID: 358066
URI: http://eprints.soton.ac.uk/id/eprint/358066
ISSN: 0039-2499
PURE UUID: 21d15234-f23d-468e-bf9f-521e186c2097
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Date deposited: 03 Oct 2013 16:25
Last modified: 14 Mar 2024 15:00
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Contributors
Author:
A.R. Luft
Author:
R.F. Macko
Author:
L.W. Forrester
Author:
F. Villagra
Author:
F. Ivey
Author:
J.D. Sorkin
Author:
Jill Whitall
Author:
S. McCombe-Waller
Author:
L. Katzel
Author:
A.P. Goldberg
Author:
D.F. Hanley
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