Brain-spinal cord interaction in long-term motor sequence learning in human: An fMRI study
Standard
Brain-spinal cord interaction in long-term motor sequence learning in human: An fMRI study. / Khatibi, Ali; Vahdat, Shahabeddin; Lungu, Ovidiu; Finsterbusch, Jurgen; Büchel, Christian; Cohen-Adad, Julien; Marchand-Pauvert, Veronique; Doyon, Julien.
In: NEUROIMAGE, Vol. 253, 119111, 06.2022.Research output: SCORING: Contribution to journal › SCORING: Journal article › Research › peer-review
Harvard
APA
Vancouver
Bibtex
}
RIS
TY - JOUR
T1 - Brain-spinal cord interaction in long-term motor sequence learning in human: An fMRI study
AU - Khatibi, Ali
AU - Vahdat, Shahabeddin
AU - Lungu, Ovidiu
AU - Finsterbusch, Jurgen
AU - Büchel, Christian
AU - Cohen-Adad, Julien
AU - Marchand-Pauvert, Veronique
AU - Doyon, Julien
N1 - Copyright © 2022 The Author(s). Published by Elsevier Inc. All rights reserved.
PY - 2022/6
Y1 - 2022/6
N2 - The spinal cord is important for sensory guidance and execution of skilled movements. Yet its role in human motor learning is not well understood. Despite evidence revealing an active involvement of spinal circuits in the early phase of motor learning, whether long-term learning engages similar changes in spinal cord activation and functional connectivity remains unknown. Here, we investigated spinal-cerebral functional plasticity associated with learning of a specific sequence of visually-guided joystick movements (sequence task) over six days of training. On the first and last training days, we acquired high-resolution functional images of the brain and cervical cord simultaneously, while participants practiced the sequence or a random task while electromyography was recorded from wrist muscles. After six days of training, the subjects' motor performance improved in the sequence compared to the control condition. These behavioral changes were associated with decreased co-contractions and increased reciprocal activations between antagonist wrist muscles. Importantly, early learning was characterized by activation in the C8 level, whereas a more rostral activation in the C6-C7 was found during the later learning phase. Motor sequence learning was also supported by increased spinal cord functional connectivity with distinct brain networks, including the motor cortex, superior parietal lobule, and the cerebellum at the early stage, and the angular gyrus and cerebellum at a later stage of learning. Our results suggest that the early vs. late shift in spinal activation from caudal to rostral cervical segments synchronized with distinct brain networks, including parietal and cerebellar regions, is related to progressive changes reflecting the increasing fine control of wrist muscles during motor sequence learning.
AB - The spinal cord is important for sensory guidance and execution of skilled movements. Yet its role in human motor learning is not well understood. Despite evidence revealing an active involvement of spinal circuits in the early phase of motor learning, whether long-term learning engages similar changes in spinal cord activation and functional connectivity remains unknown. Here, we investigated spinal-cerebral functional plasticity associated with learning of a specific sequence of visually-guided joystick movements (sequence task) over six days of training. On the first and last training days, we acquired high-resolution functional images of the brain and cervical cord simultaneously, while participants practiced the sequence or a random task while electromyography was recorded from wrist muscles. After six days of training, the subjects' motor performance improved in the sequence compared to the control condition. These behavioral changes were associated with decreased co-contractions and increased reciprocal activations between antagonist wrist muscles. Importantly, early learning was characterized by activation in the C8 level, whereas a more rostral activation in the C6-C7 was found during the later learning phase. Motor sequence learning was also supported by increased spinal cord functional connectivity with distinct brain networks, including the motor cortex, superior parietal lobule, and the cerebellum at the early stage, and the angular gyrus and cerebellum at a later stage of learning. Our results suggest that the early vs. late shift in spinal activation from caudal to rostral cervical segments synchronized with distinct brain networks, including parietal and cerebellar regions, is related to progressive changes reflecting the increasing fine control of wrist muscles during motor sequence learning.
KW - Brain/physiology
KW - Brain Mapping
KW - Humans
KW - Learning/physiology
KW - Magnetic Resonance Imaging
KW - Spinal Cord
U2 - 10.1016/j.neuroimage.2022.119111
DO - 10.1016/j.neuroimage.2022.119111
M3 - SCORING: Journal article
C2 - 35331873
VL - 253
JO - NEUROIMAGE
JF - NEUROIMAGE
SN - 1053-8119
M1 - 119111
ER -