Dynamic motor practice improves movement accuracy, force control and leads to increased corticospinal excitability compared to isometric motor practice

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Standard

Dynamic motor practice improves movement accuracy, force control and leads to increased corticospinal excitability compared to isometric motor practice. / Norup Stolpe, Malene; Bjørndal, Jonas Rud; Nielsen, August Lomholt; Wiegel, Patrick; Lundbye-Jensen, Jesper.

I: Frontiers in Human Neuroscience, Bind 16, 1019729, 2023.

Publikation: Bidrag til tidsskriftTidsskriftartikelfagfællebedømt

Harvard

Norup Stolpe, M, Bjørndal, JR, Nielsen, AL, Wiegel, P & Lundbye-Jensen, J 2023, 'Dynamic motor practice improves movement accuracy, force control and leads to increased corticospinal excitability compared to isometric motor practice', Frontiers in Human Neuroscience, bind 16, 1019729. https://doi.org/10.3389/fnhum.2022.1019729

APA

Norup Stolpe, M., Bjørndal, J. R., Nielsen, A. L., Wiegel, P., & Lundbye-Jensen, J. (2023). Dynamic motor practice improves movement accuracy, force control and leads to increased corticospinal excitability compared to isometric motor practice. Frontiers in Human Neuroscience, 16, [1019729]. https://doi.org/10.3389/fnhum.2022.1019729

Vancouver

Norup Stolpe M, Bjørndal JR, Nielsen AL, Wiegel P, Lundbye-Jensen J. Dynamic motor practice improves movement accuracy, force control and leads to increased corticospinal excitability compared to isometric motor practice. Frontiers in Human Neuroscience. 2023;16. 1019729. https://doi.org/10.3389/fnhum.2022.1019729

Author

Norup Stolpe, Malene ; Bjørndal, Jonas Rud ; Nielsen, August Lomholt ; Wiegel, Patrick ; Lundbye-Jensen, Jesper. / Dynamic motor practice improves movement accuracy, force control and leads to increased corticospinal excitability compared to isometric motor practice. I: Frontiers in Human Neuroscience. 2023 ; Bind 16.

Bibtex

@article{f0cbcba246474b44af81cc922be61cb5,
title = "Dynamic motor practice improves movement accuracy, force control and leads to increased corticospinal excitability compared to isometric motor practice",
abstract = "The central nervous system has a remarkable ability to plan motor actions, to predict and monitor the sensory consequences during and following motor actions and integrate these into future actions. Numerous studies investigating human motor learning have employed tasks involving either force control during isometric contractions or position control during dynamic tasks. To our knowledge, it remains to be elucidated how motor practice with an emphasis on position control influences force control and vice versa. Furthermore, it remains unexplored whether these distinct types of motor practice are accompanied by differential effects on corticospinal excitability. In this study, we tested motor accuracy and effects of motor practice in a force or position control task allowing wrist flexions of the non-dominant hand in the absence of online visual feedback. For each trial, motor performance was quantified as errors (pixels) between the displayed target and the movement endpoint. In the main experiment, 46 young adults were randomized into three groups: position control motor practice (PC), force control motor practice (FC), and a resting control group (CON). Following assessment of baseline motor performance in the position and force control tasks, intervention groups performed motor practice with, augmented visual feedback on performance. Motor performance in both tasks was assessed following motor practice. In a supplementary experiment, measures of corticospinal excitability were obtained in twenty additional participants by application of transcranial magnetic stimulation to the primary motor cortex hot spot of the flexor carpi radialis muscle before and following either position or force control motor practice. Following motor practice, accuracy in the position task improved significantly more for PC compared to FC and CON. For the force control task, both the PC and FC group improved more compared to CON. The two types of motor practice thus led to distinct effects including positive between-task transfer accompanying dynamic motor practice The results of the supplementary study demonstrated an increase in corticospinal excitability following dynamic motor practice compared to isometric motor practice. In conclusion, dynamic motor practice improves movement accuracy, and force control and leads to increased corticospinal excitability compared to isometric motor practice.",
keywords = "Faculty of Science, Motor learning, Position control, Force control, Corticospinal excitability, Visual feedback",
author = "{Norup Stolpe}, Malene and Bj{\o}rndal, {Jonas Rud} and Nielsen, {August Lomholt} and Patrick Wiegel and Jesper Lundbye-Jensen",
note = "CURIS 2023 NEXS 010",
year = "2023",
doi = "10.3389/fnhum.2022.1019729",
language = "English",
volume = "16",
journal = "Frontiers in Human Neuroscience",
issn = "1662-5161",
publisher = "Frontiers Research Foundation",

}

RIS

TY - JOUR

T1 - Dynamic motor practice improves movement accuracy, force control and leads to increased corticospinal excitability compared to isometric motor practice

AU - Norup Stolpe, Malene

AU - Bjørndal, Jonas Rud

AU - Nielsen, August Lomholt

AU - Wiegel, Patrick

AU - Lundbye-Jensen, Jesper

N1 - CURIS 2023 NEXS 010

PY - 2023

Y1 - 2023

N2 - The central nervous system has a remarkable ability to plan motor actions, to predict and monitor the sensory consequences during and following motor actions and integrate these into future actions. Numerous studies investigating human motor learning have employed tasks involving either force control during isometric contractions or position control during dynamic tasks. To our knowledge, it remains to be elucidated how motor practice with an emphasis on position control influences force control and vice versa. Furthermore, it remains unexplored whether these distinct types of motor practice are accompanied by differential effects on corticospinal excitability. In this study, we tested motor accuracy and effects of motor practice in a force or position control task allowing wrist flexions of the non-dominant hand in the absence of online visual feedback. For each trial, motor performance was quantified as errors (pixels) between the displayed target and the movement endpoint. In the main experiment, 46 young adults were randomized into three groups: position control motor practice (PC), force control motor practice (FC), and a resting control group (CON). Following assessment of baseline motor performance in the position and force control tasks, intervention groups performed motor practice with, augmented visual feedback on performance. Motor performance in both tasks was assessed following motor practice. In a supplementary experiment, measures of corticospinal excitability were obtained in twenty additional participants by application of transcranial magnetic stimulation to the primary motor cortex hot spot of the flexor carpi radialis muscle before and following either position or force control motor practice. Following motor practice, accuracy in the position task improved significantly more for PC compared to FC and CON. For the force control task, both the PC and FC group improved more compared to CON. The two types of motor practice thus led to distinct effects including positive between-task transfer accompanying dynamic motor practice The results of the supplementary study demonstrated an increase in corticospinal excitability following dynamic motor practice compared to isometric motor practice. In conclusion, dynamic motor practice improves movement accuracy, and force control and leads to increased corticospinal excitability compared to isometric motor practice.

AB - The central nervous system has a remarkable ability to plan motor actions, to predict and monitor the sensory consequences during and following motor actions and integrate these into future actions. Numerous studies investigating human motor learning have employed tasks involving either force control during isometric contractions or position control during dynamic tasks. To our knowledge, it remains to be elucidated how motor practice with an emphasis on position control influences force control and vice versa. Furthermore, it remains unexplored whether these distinct types of motor practice are accompanied by differential effects on corticospinal excitability. In this study, we tested motor accuracy and effects of motor practice in a force or position control task allowing wrist flexions of the non-dominant hand in the absence of online visual feedback. For each trial, motor performance was quantified as errors (pixels) between the displayed target and the movement endpoint. In the main experiment, 46 young adults were randomized into three groups: position control motor practice (PC), force control motor practice (FC), and a resting control group (CON). Following assessment of baseline motor performance in the position and force control tasks, intervention groups performed motor practice with, augmented visual feedback on performance. Motor performance in both tasks was assessed following motor practice. In a supplementary experiment, measures of corticospinal excitability were obtained in twenty additional participants by application of transcranial magnetic stimulation to the primary motor cortex hot spot of the flexor carpi radialis muscle before and following either position or force control motor practice. Following motor practice, accuracy in the position task improved significantly more for PC compared to FC and CON. For the force control task, both the PC and FC group improved more compared to CON. The two types of motor practice thus led to distinct effects including positive between-task transfer accompanying dynamic motor practice The results of the supplementary study demonstrated an increase in corticospinal excitability following dynamic motor practice compared to isometric motor practice. In conclusion, dynamic motor practice improves movement accuracy, and force control and leads to increased corticospinal excitability compared to isometric motor practice.

KW - Faculty of Science

KW - Motor learning

KW - Position control

KW - Force control

KW - Corticospinal excitability

KW - Visual feedback

U2 - 10.3389/fnhum.2022.1019729

DO - 10.3389/fnhum.2022.1019729

M3 - Journal article

C2 - 36684837

VL - 16

JO - Frontiers in Human Neuroscience

JF - Frontiers in Human Neuroscience

SN - 1662-5161

M1 - 1019729

ER -

ID: 332042019