Changes in corticospinal drive to spinal motoneurones following tablet‐based practice of manual dexterity

Changes in corticospinal drive to spinal motoneurones following tablet‐based practice of manual dexterity

The use of touch screens, which require a high level of manual dexterity, has exploded since the development of smartphone and tablet technology. Manual dexterity relies on effective corticospinal control of finger muscles, and we therefore hypothesized that corticospinal drive to finger muscles can...

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Veröffentlicht in:Physiological reports 2016-01, Vol.4 (2), p.e12684-n/a
Hauptverfasser: Larsen, Lisbeth H., Jensen, Thor, Christensen, Mark S., Lundbye‐Jensen, Jesper, Langberg, Henning, Nielsen, Jens B.
Format: Artikel
Sprache:eng
Schlagworte:
coherence
Computers, Handheld
Cortex (motor)
corticomuscular
Cross-Over Studies
EEG
Electroencephalography
Electromyography
Female
Fingers
Fingers & toes
Humans
manual dexterity
Monkeys & apes
Motor ability
Motor Control
Motor Cortex - physiology
Motor neurons
Motor Neurons - physiology
Motor Skills - physiology
Motor task performance
Muscles
Neuromuscular Junction
Neuronal Plasticity and Repair
Original Research
Physiology
plasticity
Pyramidal tracts
Pyramidal Tracts - physiology
Rehabilitation
Stroke
Tablet‐based practice
Training
Young Adult
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container_issue 2
container_start_page e12684
container_title Physiological reports
container_volume 4
creator Larsen, Lisbeth H.
Jensen, Thor
Christensen, Mark S.
Lundbye‐Jensen, Jesper
Langberg, Henning
Nielsen, Jens B.
description The use of touch screens, which require a high level of manual dexterity, has exploded since the development of smartphone and tablet technology. Manual dexterity relies on effective corticospinal control of finger muscles, and we therefore hypothesized that corticospinal drive to finger muscles can be optimized by tablet‐based motor practice. To investigate this, sixteen able‐bodied females practiced a tablet‐based game (3 × 10 min) with their nondominant hand requiring incrementally fast and precise pinching movements involving the thumb and index fingers. The study was designed as a semirandomized crossover study where the participants attended one practice‐ and one control session. Before and after each session electrophysiological recordings were obtained during three blocks of 50 precision pinch movements in a standardized setup resembling the practiced task. Data recorded during movements included electroencephalographic (EEG) activity from primary motor cortex and electromyographic (EMG) activity from first dorsal interosseous (FDI) and abductor pollicis brevis (APB) muscles. Changes in the corticospinal drive were evaluated from coupling in the frequency domain (coherence) between EEG–EMG and EMG–EMG activity. Following motor practice performance improved significantly and a significant increase in EEG‐EMGAPB and EMGAPB‐EMGFDI coherence in the beta band (15–30 Hz) was observed. No changes were observed after the control session. Our results show that tablet‐based motor practice is associated with changes in the common corticospinal drive to spinal motoneurons involved in manual dexterity. Tablet‐based motor practice may be a motivating training tool for stroke patients who struggle with loss of dexterity. Operation of touch screen devices requires manual dexterity that relies on effective corticospinal control of the finger muscles. Here we demonstrate that 30 minutes of tablet‐based motor practice with a specialized application improves performance and is accompanied by changes in the central nervous system, that is, in the coupling between the motor cortex and the spinal level that is the α‐motoneuronal activity.
doi_str_mv 10.14814/phy2.12684
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Manual dexterity relies on effective corticospinal control of finger muscles, and we therefore hypothesized that corticospinal drive to finger muscles can be optimized by tablet‐based motor practice. To investigate this, sixteen able‐bodied females practiced a tablet‐based game (3 × 10 min) with their nondominant hand requiring incrementally fast and precise pinching movements involving the thumb and index fingers. The study was designed as a semirandomized crossover study where the participants attended one practice‐ and one control session. Before and after each session electrophysiological recordings were obtained during three blocks of 50 precision pinch movements in a standardized setup resembling the practiced task. Data recorded during movements included electroencephalographic (EEG) activity from primary motor cortex and electromyographic (EMG) activity from first dorsal interosseous (FDI) and abductor pollicis brevis (APB) muscles. Changes in the corticospinal drive were evaluated from coupling in the frequency domain (coherence) between EEG–EMG and EMG–EMG activity. Following motor practice performance improved significantly and a significant increase in EEG‐EMGAPB and EMGAPB‐EMGFDI coherence in the beta band (15–30 Hz) was observed. No changes were observed after the control session. Our results show that tablet‐based motor practice is associated with changes in the common corticospinal drive to spinal motoneurons involved in manual dexterity. Tablet‐based motor practice may be a motivating training tool for stroke patients who struggle with loss of dexterity. Operation of touch screen devices requires manual dexterity that relies on effective corticospinal control of the finger muscles. Here we demonstrate that 30 minutes of tablet‐based motor practice with a specialized application improves performance and is accompanied by changes in the central nervous system, that is, in the coupling between the motor cortex and the spinal level that is the α‐motoneuronal activity.</abstract><cop>United States</cop><pub>John Wiley &amp; Sons, Inc</pub><pmid>26811055</pmid><doi>10.14814/phy2.12684</doi><tpages>11</tpages><oa>free_for_read</oa></addata></record>
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subjects coherence
Computers, Handheld
Cortex (motor)
corticomuscular
Cross-Over Studies
EEG
Electroencephalography
Electromyography
Female
Fingers
Fingers & toes
Humans
manual dexterity
Monkeys & apes
Motor ability
Motor Control
Motor Cortex - physiology
Motor neurons
Motor Neurons - physiology
Motor Skills - physiology
Motor task performance
Muscles
Neuromuscular Junction
Neuronal Plasticity and Repair
Original Research
Physiology
plasticity
Pyramidal tracts
Pyramidal Tracts - physiology
Rehabilitation
Stroke
Tablet‐based practice
Training
Young Adult
title Changes in corticospinal drive to spinal motoneurones following tablet‐based practice of manual dexterity
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