High-intensity interval training after stroke: An opportunity to promote functional recovery, cardiovascular health, and neuroplasticity

Jennifer Crozier; Marc Roig; Janice J. Eng; Marilyn MacKay-Lyons; Joyce Fung; Michelle Ploughman; Damian M. Bailey; Shane N. Sweet; Nicholas Giacomantonio; Alexander Thiel; Michael Trivino; Ada Tang

doi:10.1177/1545968318766663

High-intensity interval training after stroke: An opportunity to promote functional recovery, cardiovascular health, and neuroplasticity

Jennifer Crozier, Marc Roig, Janice J. Eng, Marilyn MacKay-Lyons, Joyce Fung, Michelle Ploughman, Damian M. Bailey, Shane N. Sweet, Nicholas Giacomantonio, Alexander Thiel, Michael Trivino, Ada Tang

Medicine

Résultat de recherche: Article › examen par les pairs

101 Citations (Scopus)

Résumé

Introduction. Stroke is the leading cause of adult disability. Individuals poststroke possess less than half of the cardiorespiratory fitness (CRF) as their nonstroke counterparts, leading to inactivity, deconditioning, and an increased risk of cardiovascular events. Preserving cardiovascular health is critical to lower stroke risk; however, stroke rehabilitation typically provides limited opportunity for cardiovascular exercise. Optimal cardiovascular training parameters to maximize recovery in stroke survivors also remains unknown. While stroke rehabilitation recommendations suggest the use of moderateintensity continuous exercise (MICE) to improve CRF, neither is it routinely implemented in clinical practice, nor is the intensity always sufficient to elicit a training effect. High-intensity interval training (HIIT) has emerged as a potentially effective alternative that encompasses brief high-intensity bursts of exercise interspersed with bouts of recovery, aiming to maximize cardiovascular exercise intensity in a time-efficient manner. HIIT may provide an alternative exercise intervention and invoke more pronounced benefits poststroke. Objectives. To provide an updated review of HIIT poststroke through (a) synthesizing current evidence; (b) proposing preliminary considerations of HIIT parameters to optimize benefit; (c) discussing potential mechanisms underlying changes in function, cardiovascular health, and neuroplasticity following HIIT; and (d) discussing clinical implications and directions for future research. Results. Preliminary evidence from 10 studies report HIIT-associated improvements in functional, cardiovascular, and neuroplastic outcomes poststroke; however, optimal HIIT parameters remain unknown. Conclusion. Larger randomized controlled trials are necessary to establish (a) effectiveness, safety, and optimal training parameters within more heterogeneous poststroke populations; (b) potential mechanisms of HIIT-associated improvements; and (c) adherence and psychosocial outcomes.

Langue d'origine	English
Pages (de-à)	543-556
Nombre de pages	14
Journal	Neurorehabilitation and Neural Repair
Volume	32
Numéro de publication	6-7
DOI	https://doi.org/10.1177/1545968318766663
Statut de publication	Published - juin 1 2018

Note bibliographique

Funding Information:
The authors disclosed receipt of the following financial support for the research, authorship, and/or publication of this article: This research was supported by the Canadian Stroke Trials for Optimized Results (CaSTOR), a joint initiative of the Canadian Stroke Consortium and HSF Canadian Partnership for Stroke Recovery. MR was supported with funds from the Reseau Provincial de Recherche en Adaptation-Readaptation (Recherche Clinique), the Canada Foundation for Innovation (John R. Evans Leaders Fund) and the Montreal Centre for Interdisciplinary Research in Rehabilitation (New Investigator Fund). AT was supported by a personnel award from the Heart and Stroke Foundation, Ontario Provincial Office (CS I 7468). DMB is supported by a Royal Society Wolfson Research Merit Award (No. WM170007) and has also received support from the Higher Education Funding Council of Wales. MP is funded by the Canada Research Chairs program. We acknowledge support from the Canada Research Chair Program (to JJE).

Publisher Copyright:
© The Author(s) 2018.

ASJC Scopus Subject Areas

Rehabilitation
Neurology
Clinical Neurology

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10.1177/1545968318766663

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Crozier, J., Roig, M., Eng, J. J., MacKay-Lyons, M., Fung, J., Ploughman, M., Bailey, D. M., Sweet, S. N., Giacomantonio, N., Thiel, A., Trivino, M., & Tang, A. (2018). High-intensity interval training after stroke: An opportunity to promote functional recovery, cardiovascular health, and neuroplasticity. Neurorehabilitation and Neural Repair, 32(6-7), 543-556. https://doi.org/10.1177/1545968318766663

Crozier, J, Roig, M, Eng, JJ, MacKay-Lyons, M, Fung, J, Ploughman, M, Bailey, DM, Sweet, SN, Giacomantonio, N, Thiel, A, Trivino, M & Tang, A 2018, 'High-intensity interval training after stroke: An opportunity to promote functional recovery, cardiovascular health, and neuroplasticity', Neurorehabilitation and Neural Repair, vol. 32, n° 6-7, pp. 543-556. https://doi.org/10.1177/1545968318766663

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abstract = "Introduction. Stroke is the leading cause of adult disability. Individuals poststroke possess less than half of the cardiorespiratory fitness (CRF) as their nonstroke counterparts, leading to inactivity, deconditioning, and an increased risk of cardiovascular events. Preserving cardiovascular health is critical to lower stroke risk; however, stroke rehabilitation typically provides limited opportunity for cardiovascular exercise. Optimal cardiovascular training parameters to maximize recovery in stroke survivors also remains unknown. While stroke rehabilitation recommendations suggest the use of moderateintensity continuous exercise (MICE) to improve CRF, neither is it routinely implemented in clinical practice, nor is the intensity always sufficient to elicit a training effect. High-intensity interval training (HIIT) has emerged as a potentially effective alternative that encompasses brief high-intensity bursts of exercise interspersed with bouts of recovery, aiming to maximize cardiovascular exercise intensity in a time-efficient manner. HIIT may provide an alternative exercise intervention and invoke more pronounced benefits poststroke. Objectives. To provide an updated review of HIIT poststroke through (a) synthesizing current evidence; (b) proposing preliminary considerations of HIIT parameters to optimize benefit; (c) discussing potential mechanisms underlying changes in function, cardiovascular health, and neuroplasticity following HIIT; and (d) discussing clinical implications and directions for future research. Results. Preliminary evidence from 10 studies report HIIT-associated improvements in functional, cardiovascular, and neuroplastic outcomes poststroke; however, optimal HIIT parameters remain unknown. Conclusion. Larger randomized controlled trials are necessary to establish (a) effectiveness, safety, and optimal training parameters within more heterogeneous poststroke populations; (b) potential mechanisms of HIIT-associated improvements; and (c) adherence and psychosocial outcomes.",

author = "Jennifer Crozier and Marc Roig and Eng, {Janice J.} and Marilyn MacKay-Lyons and Joyce Fung and Michelle Ploughman and Bailey, {Damian M.} and Sweet, {Shane N.} and Nicholas Giacomantonio and Alexander Thiel and Michael Trivino and Ada Tang",

note = "Funding Information: The authors disclosed receipt of the following financial support for the research, authorship, and/or publication of this article: This research was supported by the Canadian Stroke Trials for Optimized Results (CaSTOR), a joint initiative of the Canadian Stroke Consortium and HSF Canadian Partnership for Stroke Recovery. MR was supported with funds from the Reseau Provincial de Recherche en Adaptation-Readaptation (Recherche Clinique), the Canada Foundation for Innovation (John R. Evans Leaders Fund) and the Montreal Centre for Interdisciplinary Research in Rehabilitation (New Investigator Fund). AT was supported by a personnel award from the Heart and Stroke Foundation, Ontario Provincial Office (CS I 7468). DMB is supported by a Royal Society Wolfson Research Merit Award (No. WM170007) and has also received support from the Higher Education Funding Council of Wales. MP is funded by the Canada Research Chairs program. We acknowledge support from the Canada Research Chair Program (to JJE). Publisher Copyright: {\textcopyright} The Author(s) 2018.",

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AU - Crozier, Jennifer

AU - Roig, Marc

AU - Eng, Janice J.

AU - MacKay-Lyons, Marilyn

AU - Fung, Joyce

AU - Ploughman, Michelle

AU - Bailey, Damian M.

AU - Sweet, Shane N.

AU - Giacomantonio, Nicholas

AU - Thiel, Alexander

AU - Trivino, Michael

AU - Tang, Ada

N1 - Funding Information: The authors disclosed receipt of the following financial support for the research, authorship, and/or publication of this article: This research was supported by the Canadian Stroke Trials for Optimized Results (CaSTOR), a joint initiative of the Canadian Stroke Consortium and HSF Canadian Partnership for Stroke Recovery. MR was supported with funds from the Reseau Provincial de Recherche en Adaptation-Readaptation (Recherche Clinique), the Canada Foundation for Innovation (John R. Evans Leaders Fund) and the Montreal Centre for Interdisciplinary Research in Rehabilitation (New Investigator Fund). AT was supported by a personnel award from the Heart and Stroke Foundation, Ontario Provincial Office (CS I 7468). DMB is supported by a Royal Society Wolfson Research Merit Award (No. WM170007) and has also received support from the Higher Education Funding Council of Wales. MP is funded by the Canada Research Chairs program. We acknowledge support from the Canada Research Chair Program (to JJE). Publisher Copyright: © The Author(s) 2018.

PY - 2018/6/1

Y1 - 2018/6/1

N2 - Introduction. Stroke is the leading cause of adult disability. Individuals poststroke possess less than half of the cardiorespiratory fitness (CRF) as their nonstroke counterparts, leading to inactivity, deconditioning, and an increased risk of cardiovascular events. Preserving cardiovascular health is critical to lower stroke risk; however, stroke rehabilitation typically provides limited opportunity for cardiovascular exercise. Optimal cardiovascular training parameters to maximize recovery in stroke survivors also remains unknown. While stroke rehabilitation recommendations suggest the use of moderateintensity continuous exercise (MICE) to improve CRF, neither is it routinely implemented in clinical practice, nor is the intensity always sufficient to elicit a training effect. High-intensity interval training (HIIT) has emerged as a potentially effective alternative that encompasses brief high-intensity bursts of exercise interspersed with bouts of recovery, aiming to maximize cardiovascular exercise intensity in a time-efficient manner. HIIT may provide an alternative exercise intervention and invoke more pronounced benefits poststroke. Objectives. To provide an updated review of HIIT poststroke through (a) synthesizing current evidence; (b) proposing preliminary considerations of HIIT parameters to optimize benefit; (c) discussing potential mechanisms underlying changes in function, cardiovascular health, and neuroplasticity following HIIT; and (d) discussing clinical implications and directions for future research. Results. Preliminary evidence from 10 studies report HIIT-associated improvements in functional, cardiovascular, and neuroplastic outcomes poststroke; however, optimal HIIT parameters remain unknown. Conclusion. Larger randomized controlled trials are necessary to establish (a) effectiveness, safety, and optimal training parameters within more heterogeneous poststroke populations; (b) potential mechanisms of HIIT-associated improvements; and (c) adherence and psychosocial outcomes.

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High-intensity interval training after stroke: An opportunity to promote functional recovery, cardiovascular health, and neuroplasticity

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