Short duration event related cerebellar TDCS enhances visuomotor adaptation
Transcranial direct current stimulation (TDCS) is typically applied before or during a task, for periods ranging from 5 to 30 min. We hypothesise that briefer stimulation epochs synchronous with individual task actions may be more effective. In two separate experiments, we applied brief bursts of ev...
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| Published in | Brain stimulation Vol. 16; no. 2; pp. 431 - 441 |
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| Main Authors | , , , , , |
| Format | Journal Article |
| Language | English |
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United States
Elsevier Inc
01.03.2023
Elsevier |
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| Abstract | Transcranial direct current stimulation (TDCS) is typically applied before or during a task, for periods ranging from 5 to 30 min.
We hypothesise that briefer stimulation epochs synchronous with individual task actions may be more effective.
In two separate experiments, we applied brief bursts of event-related anodal stimulation (erTDCS) to the cerebellum during a visuomotor adaptation task.
The first study demonstrated that 1 s duration erTDCS time-locked to the participants’ reaching actions enhanced adaptation significantly better than sham. A close replication in the second study demonstrated 0.5 s erTDCS synchronous with the reaching actions again resulted in better adaptation than standard TDCS, significantly better than sham. Stimulation either during the inter-trial intervals between movements or after movement, during assessment of visual feedback, had no significant effect. Because short duration stimulation with rapid onset and offset is more readily perceived by the participants, we additionally show that a non-electrical vibrotactile stimulation of the scalp, presented with the same timing as the erTDCS, had no significant effect.
We conclude that short duration, event related, anodal TDCS targeting the cerebellum enhances motor adaptation compared to the standard model. We discuss possible mechanisms of action and speculate on neural learning processes that may be involved.
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•Brief event-related TDCS (erTDCS) enhances visuomotor adaptation.•ErTDCS synchronous with reaching-to-target movement is most effective.•No effect of asynchronous erTDCS or during error feedback processing.•ErTDCS may be a useful new protocol to dissect task components of learning. |
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| AbstractList | Transcranial direct current stimulation (TDCS) is typically applied before or during a task, for periods ranging from 5 to 30 min.
We hypothesise that briefer stimulation epochs synchronous with individual task actions may be more effective.
In two separate experiments, we applied brief bursts of event-related anodal stimulation (erTDCS) to the cerebellum during a visuomotor adaptation task.
The first study demonstrated that 1 s duration erTDCS time-locked to the participants’ reaching actions enhanced adaptation significantly better than sham. A close replication in the second study demonstrated 0.5 s erTDCS synchronous with the reaching actions again resulted in better adaptation than standard TDCS, significantly better than sham. Stimulation either during the inter-trial intervals between movements or after movement, during assessment of visual feedback, had no significant effect. Because short duration stimulation with rapid onset and offset is more readily perceived by the participants, we additionally show that a non-electrical vibrotactile stimulation of the scalp, presented with the same timing as the erTDCS, had no significant effect.
We conclude that short duration, event related, anodal TDCS targeting the cerebellum enhances motor adaptation compared to the standard model. We discuss possible mechanisms of action and speculate on neural learning processes that may be involved.
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•Brief event-related TDCS (erTDCS) enhances visuomotor adaptation.•ErTDCS synchronous with reaching-to-target movement is most effective.•No effect of asynchronous erTDCS or during error feedback processing.•ErTDCS may be a useful new protocol to dissect task components of learning. BACKGROUNDTranscranial direct current stimulation (TDCS) is typically applied before or during a task, for periods ranging from 5 to 30 min. HYPOTHESISWe hypothesise that briefer stimulation epochs synchronous with individual task actions may be more effective. METHODSIn two separate experiments, we applied brief bursts of event-related anodal stimulation (erTDCS) to the cerebellum during a visuomotor adaptation task. RESULTSThe first study demonstrated that 1 s duration erTDCS time-locked to the participants' reaching actions enhanced adaptation significantly better than sham. A close replication in the second study demonstrated 0.5 s erTDCS synchronous with the reaching actions again resulted in better adaptation than standard TDCS, significantly better than sham. Stimulation either during the inter-trial intervals between movements or after movement, during assessment of visual feedback, had no significant effect. Because short duration stimulation with rapid onset and offset is more readily perceived by the participants, we additionally show that a non-electrical vibrotactile stimulation of the scalp, presented with the same timing as the erTDCS, had no significant effect. CONCLUSIONSWe conclude that short duration, event related, anodal TDCS targeting the cerebellum enhances motor adaptation compared to the standard model. We discuss possible mechanisms of action and speculate on neural learning processes that may be involved. Transcranial direct current stimulation (TDCS) is typically applied before or during a task, for periods ranging from 5 to 30 min. We hypothesise that briefer stimulation epochs synchronous with individual task actions may be more effective. In two separate experiments, we applied brief bursts of event-related anodal stimulation (erTDCS) to the cerebellum during a visuomotor adaptation task. The first study demonstrated that 1 s duration erTDCS time-locked to the participants' reaching actions enhanced adaptation significantly better than sham. A close replication in the second study demonstrated 0.5 s erTDCS synchronous with the reaching actions again resulted in better adaptation than standard TDCS, significantly better than sham. Stimulation either during the inter-trial intervals between movements or after movement, during assessment of visual feedback, had no significant effect. Because short duration stimulation with rapid onset and offset is more readily perceived by the participants, we additionally show that a non-electrical vibrotactile stimulation of the scalp, presented with the same timing as the erTDCS, had no significant effect. We conclude that short duration, event related, anodal TDCS targeting the cerebellum enhances motor adaptation compared to the standard model. We discuss possible mechanisms of action and speculate on neural learning processes that may be involved. Background: Transcranial direct current stimulation (TDCS) is typically applied before or during a task, for periods ranging from 5 to 30 min. Hypothesis: We hypothesise that briefer stimulation epochs synchronous with individual task actions may be more effective. Methods: In two separate experiments, we applied brief bursts of event-related anodal stimulation (erTDCS) to the cerebellum during a visuomotor adaptation task. Results: The first study demonstrated that 1 s duration erTDCS time-locked to the participants’ reaching actions enhanced adaptation significantly better than sham. A close replication in the second study demonstrated 0.5 s erTDCS synchronous with the reaching actions again resulted in better adaptation than standard TDCS, significantly better than sham. Stimulation either during the inter-trial intervals between movements or after movement, during assessment of visual feedback, had no significant effect. Because short duration stimulation with rapid onset and offset is more readily perceived by the participants, we additionally show that a non-electrical vibrotactile stimulation of the scalp, presented with the same timing as the erTDCS, had no significant effect. Conclusions: We conclude that short duration, event related, anodal TDCS targeting the cerebellum enhances motor adaptation compared to the standard model. We discuss possible mechanisms of action and speculate on neural learning processes that may be involved. |
| Author | Lin, Chin-Hsuan Sophie Lalji, Neeraj Jenkinson, Ned Galea, Joseph M. Miall, R. Chris Weightman, Matthew |
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| Keywords | Cerebellum Hebbian learning Visuomotor adaptation Transcranial electrical stimulation |
| Language | English |
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| Snippet | Transcranial direct current stimulation (TDCS) is typically applied before or during a task, for periods ranging from 5 to 30 min.
We hypothesise that briefer... BACKGROUNDTranscranial direct current stimulation (TDCS) is typically applied before or during a task, for periods ranging from 5 to 30 min. HYPOTHESISWe... Background: Transcranial direct current stimulation (TDCS) is typically applied before or during a task, for periods ranging from 5 to 30 min. Hypothesis: We... |
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| SubjectTerms | Adaptation, Physiological - physiology Cerebellum Cerebellum - physiology Hebbian learning Humans Learning - physiology Movement Transcranial Direct Current Stimulation - methods Transcranial electrical stimulation Visuomotor adaptation |
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| Title | Short duration event related cerebellar TDCS enhances visuomotor adaptation |
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