Cerebellar Subjects Show Impaired Adaptation of Anticipatory EMG During Catching
1 Program in Physical Therapy and 2 Department of Anatomy and Neurobiology, Washington University School of Medicine, St. Louis, Missouri 63108 Lang, Catherine E. and Amy J. Bastian. Cerebellar Subjects Show Impaired Adaptation of Anticipatory EMG During Catching. J. Neurophysiol. 82: 2108-2119,...
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| Published in | Journal of neurophysiology Vol. 82; no. 5; pp. 2108 - 2119 |
|---|---|
| Main Authors | , |
| Format | Journal Article |
| Language | English |
| Published |
United States
Am Phys Soc
01.11.1999
|
| Subjects | |
| Online Access | Get full text |
| ISSN | 0022-3077 1522-1598 |
| DOI | 10.1152/jn.1999.82.5.2108 |
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| Abstract | 1 Program in Physical Therapy and
2 Department of Anatomy and Neurobiology,
Washington University School of Medicine, St. Louis, Missouri 63108
Lang, Catherine E. and
Amy J. Bastian.
Cerebellar Subjects Show Impaired Adaptation of Anticipatory EMG
During Catching. J. Neurophysiol. 82: 2108-2119, 1999. We evaluated the role of the cerebellum in adapting
anticipatory muscle activity during a multijointed catching task.
Individuals with and without cerebellar damage caught a series of balls
of different weights dropped from above. In Experiment 1
(light-heavy-light), each subject was required to catch light balls
( baseline phase ), heavy balls ( adaptation
phase ), and then light balls again ( postadaptation phase ). Subjects were not told when the balls would be
switched, and they were required to keep their hand within a vertical
spatial "window" during the catch. During the series of trials, we
measured three-dimensional (3-D) position and electromyogram (EMG) from the catching arm. We modeled the adaptation process using an
exponential decay function; this model allowed us to dissociate
adaptation from performance variability. Results from the position data
show that cerebellar subjects did not adapt or adapted very slowly to
the changed ball weight when compared with the control subjects. The
cerebellar group required an average of 30.9 ± 8.7 trials (mean ± SE) to progress approximately two-thirds of the way
through the adaptation compared with 1.7 ± 0.2 trials for the
control group. Only control subjects showed a negative aftereffect
indicating storage of the adaptation. No difference in performance
variability existed between the two groups. EMG data show that control
subjects increased their anticipatory muscle activity in the flexor
muscles of the arm to control the momentum of the ball at impact.
Cerebellar subjects were unable to differentially increase the
anticipatory muscle activity across three joints to perform the task
successfully. In Experiment 2 (heavy-light-heavy), we
tested to see whether the rate of adaptation changed when adapting to a
light ball versus a heavy ball. Subjects caught the heavy balls
(baseline phase), the light balls (adaptation phase), and then heavy
balls again (postadaptation phase). Comparison of rates of adaptation
between Experiment 1 and Experiment 2
showed that the rate of adaptation was unchanged whether adapting to a
light ball or a heavy ball. Given these findings, we conclude that the
cerebellum is important in generating the appropriate anticipatory
muscle activity across multiple muscles and modifying it in response to
changing demands though trial-and-error practice. |
|---|---|
| AbstractList | We evaluated the role of the cerebellum in adapting anticipatory muscle activity during a multijointed catching task. Individuals with and without cerebellar damage caught a series of balls of different weights dropped from above. In Experiment 1 (light-heavy-light), each subject was required to catch light balls (baseline phase), heavy balls (adaptation phase), and then light balls again (postadaptation phase). Subjects were not told when the balls would be switched, and they were required to keep their hand within a vertical spatial "window" during the catch. During the series of trials, we measured three-dimensional (3-D) position and electromyogram (EMG) from the catching arm. We modeled the adaptation process using an exponential decay function; this model allowed us to dissociate adaptation from performance variability. Results from the position data show that cerebellar subjects did not adapt or adapted very slowly to the changed ball weight when compared with the control subjects. The cerebellar group required an average of 30.9 plus or minus 8.7 trials (mean plus or minus SE) to progress approximately two-thirds of the way through the adaptation compared with 1.7 plus or minus 0.2 trials for the control group. Only control subjects showed a negative aftereffect indicating storage of the adaptation. No difference in performance variability existed between the two groups. EMG data show that control subjects increased their anticipatory muscle activity in the flexor muscles of the arm to control the momentum of the ball at impact. Cerebellar subjects were unable to differentially increase the anticipatory muscle activity across three joints to perform the task successfully. In Experiment 2 (heavy-light-heavy), we tested to see whether the rate of adaptation changed when adapting to a light ball versus a heavy ball. Subjects caught the heavy balls (baseline phase), the light balls (adaptation phase), and then heavy balls again (postadaptation phase). Comparison of rates of adaptation between Experiment 1 and Experiment 2 showed that the rate of adaptation was unchanged whether adapting to a light ball or a heavy ball. Given these findings, we conclude that the cerebellum is important in generating the appropriate anticipatory muscle activity across multiple muscles and modifying it in response to changing demands though trial-and-error practice. We evaluated the role of the cerebellum in adapting anticipatory muscle activity during a multijointed catching task. Individuals with and without cerebellar damage caught a series of balls of different weights dropped from above. In Experiment 1 (light-heavy-light), each subject was required to catch light balls (baseline phase), heavy balls (adaptation phase), and then light balls again (postadaptation phase). Subjects were not told when the balls would be switched, and they were required to keep their hand within a vertical spatial "window" during the catch. During the series of trials, we measured three-dimensional (3-D) position and electromyogram (EMG) from the catching arm. We modeled the adaptation process using an exponential decay function; this model allowed us to dissociate adaptation from performance variability. Results from the position data show that cerebellar subjects did not adapt or adapted very slowly to the changed ball weight when compared with the control subjects. The cerebellar group required an average of 30.9 +/- 8.7 trials (mean +/- SE) to progress approximately two-thirds of the way through the adaptation compared with 1.7 +/- 0.2 trials for the control group. Only control subjects showed a negative aftereffect indicating storage of the adaptation. No difference in performance variability existed between the two groups. EMG data show that control subjects increased their anticipatory muscle activity in the flexor muscles of the arm to control the momentum of the ball at impact. Cerebellar subjects were unable to differentially increase the anticipatory muscle activity across three joints to perform the task successfully. In Experiment 2 (heavy-light-heavy), we tested to see whether the rate of adaptation changed when adapting to a light ball versus a heavy ball. Subjects caught the heavy balls (baseline phase), the light balls (adaptation phase), and then heavy balls again (postadaptation phase). Comparison of rates of adaptation between Experiment 1 and Experiment 2 showed that the rate of adaptation was unchanged whether adapting to a light ball or a heavy ball. Given these findings, we conclude that the cerebellum is important in generating the appropriate anticipatory muscle activity across multiple muscles and modifying it in response to changing demands though trial-and-error practice.We evaluated the role of the cerebellum in adapting anticipatory muscle activity during a multijointed catching task. Individuals with and without cerebellar damage caught a series of balls of different weights dropped from above. In Experiment 1 (light-heavy-light), each subject was required to catch light balls (baseline phase), heavy balls (adaptation phase), and then light balls again (postadaptation phase). Subjects were not told when the balls would be switched, and they were required to keep their hand within a vertical spatial "window" during the catch. During the series of trials, we measured three-dimensional (3-D) position and electromyogram (EMG) from the catching arm. We modeled the adaptation process using an exponential decay function; this model allowed us to dissociate adaptation from performance variability. Results from the position data show that cerebellar subjects did not adapt or adapted very slowly to the changed ball weight when compared with the control subjects. The cerebellar group required an average of 30.9 +/- 8.7 trials (mean +/- SE) to progress approximately two-thirds of the way through the adaptation compared with 1.7 +/- 0.2 trials for the control group. Only control subjects showed a negative aftereffect indicating storage of the adaptation. No difference in performance variability existed between the two groups. EMG data show that control subjects increased their anticipatory muscle activity in the flexor muscles of the arm to control the momentum of the ball at impact. Cerebellar subjects were unable to differentially increase the anticipatory muscle activity across three joints to perform the task successfully. In Experiment 2 (heavy-light-heavy), we tested to see whether the rate of adaptation changed when adapting to a light ball versus a heavy ball. Subjects caught the heavy balls (baseline phase), the light balls (adaptation phase), and then heavy balls again (postadaptation phase). Comparison of rates of adaptation between Experiment 1 and Experiment 2 showed that the rate of adaptation was unchanged whether adapting to a light ball or a heavy ball. Given these findings, we conclude that the cerebellum is important in generating the appropriate anticipatory muscle activity across multiple muscles and modifying it in response to changing demands though trial-and-error practice. We evaluated the role of the cerebellum in adapting anticipatory muscle activity during a multijointed catching task. Individuals with and without cerebellar damage caught a series of balls of different weights dropped from above. In Experiment 1 (light-heavy-light), each subject was required to catch light balls (baseline phase), heavy balls (adaptation phase), and then light balls again (postadaptation phase). Subjects were not told when the balls would be switched, and they were required to keep their hand within a vertical spatial "window" during the catch. During the series of trials, we measured three-dimensional (3-D) position and electromyogram (EMG) from the catching arm. We modeled the adaptation process using an exponential decay function; this model allowed us to dissociate adaptation from performance variability. Results from the position data show that cerebellar subjects did not adapt or adapted very slowly to the changed ball weight when compared with the control subjects. The cerebellar group required an average of 30.9 +/- 8.7 trials (mean +/- SE) to progress approximately two-thirds of the way through the adaptation compared with 1.7 +/- 0.2 trials for the control group. Only control subjects showed a negative aftereffect indicating storage of the adaptation. No difference in performance variability existed between the two groups. EMG data show that control subjects increased their anticipatory muscle activity in the flexor muscles of the arm to control the momentum of the ball at impact. Cerebellar subjects were unable to differentially increase the anticipatory muscle activity across three joints to perform the task successfully. In Experiment 2 (heavy-light-heavy), we tested to see whether the rate of adaptation changed when adapting to a light ball versus a heavy ball. Subjects caught the heavy balls (baseline phase), the light balls (adaptation phase), and then heavy balls again (postadaptation phase). Comparison of rates of adaptation between Experiment 1 and Experiment 2 showed that the rate of adaptation was unchanged whether adapting to a light ball or a heavy ball. Given these findings, we conclude that the cerebellum is important in generating the appropriate anticipatory muscle activity across multiple muscles and modifying it in response to changing demands though trial-and-error practice. 1 Program in Physical Therapy and 2 Department of Anatomy and Neurobiology, Washington University School of Medicine, St. Louis, Missouri 63108 Lang, Catherine E. and Amy J. Bastian. Cerebellar Subjects Show Impaired Adaptation of Anticipatory EMG During Catching. J. Neurophysiol. 82: 2108-2119, 1999. We evaluated the role of the cerebellum in adapting anticipatory muscle activity during a multijointed catching task. Individuals with and without cerebellar damage caught a series of balls of different weights dropped from above. In Experiment 1 (light-heavy-light), each subject was required to catch light balls ( baseline phase ), heavy balls ( adaptation phase ), and then light balls again ( postadaptation phase ). Subjects were not told when the balls would be switched, and they were required to keep their hand within a vertical spatial "window" during the catch. During the series of trials, we measured three-dimensional (3-D) position and electromyogram (EMG) from the catching arm. We modeled the adaptation process using an exponential decay function; this model allowed us to dissociate adaptation from performance variability. Results from the position data show that cerebellar subjects did not adapt or adapted very slowly to the changed ball weight when compared with the control subjects. The cerebellar group required an average of 30.9 ± 8.7 trials (mean ± SE) to progress approximately two-thirds of the way through the adaptation compared with 1.7 ± 0.2 trials for the control group. Only control subjects showed a negative aftereffect indicating storage of the adaptation. No difference in performance variability existed between the two groups. EMG data show that control subjects increased their anticipatory muscle activity in the flexor muscles of the arm to control the momentum of the ball at impact. Cerebellar subjects were unable to differentially increase the anticipatory muscle activity across three joints to perform the task successfully. In Experiment 2 (heavy-light-heavy), we tested to see whether the rate of adaptation changed when adapting to a light ball versus a heavy ball. Subjects caught the heavy balls (baseline phase), the light balls (adaptation phase), and then heavy balls again (postadaptation phase). Comparison of rates of adaptation between Experiment 1 and Experiment 2 showed that the rate of adaptation was unchanged whether adapting to a light ball or a heavy ball. Given these findings, we conclude that the cerebellum is important in generating the appropriate anticipatory muscle activity across multiple muscles and modifying it in response to changing demands though trial-and-error practice. We evaluated the role of the cerebellum in adapting anticipatory muscle activity during a multijointed catching task. Individuals with and without cerebellar damage caught a series of balls of different weights dropped from above. In Experiment 1(light-heavy-light), each subject was required to catch light balls ( baseline phase), heavy balls ( adaptation phase), and then light balls again ( postadaptation phase). Subjects were not told when the balls would be switched, and they were required to keep their hand within a vertical spatial “window” during the catch. During the series of trials, we measured three-dimensional (3-D) position and electromyogram (EMG) from the catching arm. We modeled the adaptation process using an exponential decay function; this model allowed us to dissociate adaptation from performance variability. Results from the position data show that cerebellar subjects did not adapt or adapted very slowly to the changed ball weight when compared with the control subjects. The cerebellar group required an average of 30.9 ± 8.7 trials (mean ± SE) to progress approximately two-thirds of the way through the adaptation compared with 1.7 ± 0.2 trials for the control group. Only control subjects showed a negative aftereffect indicating storage of the adaptation. No difference in performance variability existed between the two groups. EMG data show that control subjects increased their anticipatory muscle activity in the flexor muscles of the arm to control the momentum of the ball at impact. Cerebellar subjects were unable to differentially increase the anticipatory muscle activity across three joints to perform the task successfully. In Experiment 2 (heavy-light-heavy), we tested to see whether the rate of adaptation changed when adapting to a light ball versus a heavy ball. Subjects caught the heavy balls (baseline phase), the light balls (adaptation phase), and then heavy balls again (postadaptation phase). Comparison of rates of adaptation between Experiment 1 and Experiment 2showed that the rate of adaptation was unchanged whether adapting to a light ball or a heavy ball. Given these findings, we conclude that the cerebellum is important in generating the appropriate anticipatory muscle activity across multiple muscles and modifying it in response to changing demands though trial-and-error practice. |
| Author | Lang, Catherine E Bastian, Amy J |
| Author_xml | – sequence: 1 fullname: Lang, Catherine E – sequence: 2 fullname: Bastian, Amy J |
| BackLink | https://www.ncbi.nlm.nih.gov/pubmed/10561391$$D View this record in MEDLINE/PubMed |
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| Snippet | 1 Program in Physical Therapy and
2 Department of Anatomy and Neurobiology,
Washington University School of Medicine, St. Louis, Missouri 63108
Lang,... We evaluated the role of the cerebellum in adapting anticipatory muscle activity during a multijointed catching task. Individuals with and without cerebellar... |
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| SubjectTerms | Adult Aged Atrophy Cerebellum - pathology Cerebellum - physiology Cerebellum - physiopathology Cerebral Hemorrhage - pathology Cerebral Hemorrhage - physiopathology Cerebral Hemorrhage - psychology Electromyography Female Humans Male Middle Aged Motor Activity Psychomotor Performance - physiology Reference Values Regression Analysis |
| Title | Cerebellar Subjects Show Impaired Adaptation of Anticipatory EMG During Catching |
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