Attention modulates adaptive motor learning in the 'broken escalator' paradigm.

Research output: Contribution to journalArticlepeer-review

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Attention modulates adaptive motor learning in the 'broken escalator' paradigm. / Patel, Mitesh; Kaski, Diego; Bronstein, Adolfo M.
In: Experimental Brain Research, Vol. 232, 09.04.2014.

Research output: Contribution to journalArticlepeer-review

HarvardHarvard

Patel, M, Kaski, D & Bronstein, AM 2014, 'Attention modulates adaptive motor learning in the 'broken escalator' paradigm.', Experimental Brain Research, vol. 232.

APA

Patel, M., Kaski, D., & Bronstein, A. M. (2014). Attention modulates adaptive motor learning in the 'broken escalator' paradigm. Experimental Brain Research, 232.

CBE

Patel M, Kaski D, Bronstein AM. 2014. Attention modulates adaptive motor learning in the 'broken escalator' paradigm. Experimental Brain Research. 232.

MLA

Patel, Mitesh, Diego Kaski and Adolfo M Bronstein. "Attention modulates adaptive motor learning in the 'broken escalator' paradigm.". Experimental Brain Research. 2014. 232.

VancouverVancouver

Patel M, Kaski D, Bronstein AM. Attention modulates adaptive motor learning in the 'broken escalator' paradigm. Experimental Brain Research. 2014 Apr 9;232.

Author

Patel, Mitesh ; Kaski, Diego ; Bronstein, Adolfo M. / Attention modulates adaptive motor learning in the 'broken escalator' paradigm. In: Experimental Brain Research. 2014 ; Vol. 232.

RIS

TY - JOUR

T1 - Attention modulates adaptive motor learning in the 'broken escalator' paradigm.

AU - Patel, Mitesh

AU - Kaski, Diego

AU - Bronstein, Adolfo M

PY - 2014/4/9

Y1 - 2014/4/9

N2 - The physical stumble caused by stepping onto a stationary (broken) escalator represents a locomotor aftereffect (LAE) that attests to a process of adaptive motor learning. Whether such learning is primarily explicit (requiring attention resources) or implicit (independent of attention) is unknown. To address this question, we diverted attention in the adaptation (MOVING) and aftereffect (AFTER) phases of the LAE by loading these phases with a secondary cognitive task (sequential naming of a vegetable, fruit and a colour). Thirty-six healthy adults were randomly assigned to 3 equally sized groups. They performed 5 trials stepping onto a stationary sled (BEFORE), 5 with the sled moving (MOVING) and 5 with the sled stationary again (AFTER). A ‘Dual-Task-MOVING (DTM)’ group performed the dual-task in the MOVING phase and the ‘Dual-Task-AFTEREFFECT (DTAE)’ group in the AFTER phase. The ‘control’ group performed no dual task. We recorded trunk displacement, gait velocity and gastrocnemius muscle EMG of the left (leading) leg. The DTM, but not the DTAE group, had larger trunk displacement during the MOVING phase, and a smaller trunk displacement aftereffect compared with controls. Gait velocity was unaffected by the secondary cognitive task in either group. Thus, adaptive locomotor learning involves explicit learning, whereas the expression of the aftereffect is automatic (implicit). During rehabilitation, patients should be actively encouraged to maintain maximal attention when learning new or challenging locomotor tasks.

AB - The physical stumble caused by stepping onto a stationary (broken) escalator represents a locomotor aftereffect (LAE) that attests to a process of adaptive motor learning. Whether such learning is primarily explicit (requiring attention resources) or implicit (independent of attention) is unknown. To address this question, we diverted attention in the adaptation (MOVING) and aftereffect (AFTER) phases of the LAE by loading these phases with a secondary cognitive task (sequential naming of a vegetable, fruit and a colour). Thirty-six healthy adults were randomly assigned to 3 equally sized groups. They performed 5 trials stepping onto a stationary sled (BEFORE), 5 with the sled moving (MOVING) and 5 with the sled stationary again (AFTER). A ‘Dual-Task-MOVING (DTM)’ group performed the dual-task in the MOVING phase and the ‘Dual-Task-AFTEREFFECT (DTAE)’ group in the AFTER phase. The ‘control’ group performed no dual task. We recorded trunk displacement, gait velocity and gastrocnemius muscle EMG of the left (leading) leg. The DTM, but not the DTAE group, had larger trunk displacement during the MOVING phase, and a smaller trunk displacement aftereffect compared with controls. Gait velocity was unaffected by the secondary cognitive task in either group. Thus, adaptive locomotor learning involves explicit learning, whereas the expression of the aftereffect is automatic (implicit). During rehabilitation, patients should be actively encouraged to maintain maximal attention when learning new or challenging locomotor tasks.

M3 - Article

VL - 232

JO - Experimental Brain Research

JF - Experimental Brain Research

SN - 0014-4819

ER -