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Abstract

One of the major issues to emerge from research on human-limb movement is the manner in which the central nervous system regulates electromyographic (EMG) activity to produce movements that differ in duration and distance. Different models of control predict different relations between EMC characteristics and movement kinematics, particularly with regard to the role of EMC burst duration and movement time. However, models have been evaluated with means averaged over individuals and across large numbers of practice trials. The goal of this study was to assess how well individual subjects' data conform to the predictions of the control models. Participants (n = 4) performed an elbow flexion and extension task over 45° in movement times between 90 and 260 msec. EMG amplitude and EMG burst duration from the right elbow flexors were correlated with movement time for each individual. As expected, movement time was positively correlated with EMG burst duration and negatively correlated with EMG amplitude, with wider ranges in the EMG burst duration–movement time correlations across participants. Data from all participants supported predictions of the impulse-timing control model, but the slopes of the studied relations varied across participants.

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References

Corcos

D. M.

Jaric

Gottlieb

G. L.

(1996) Electromyographic analysis of performance enhancement. In Zelaznik

H. N.

(Ed.), Advances in motor learning and control. Champaign, IL: Human Kinetics. Pp. 123–153.

Gabriel

D. A.

Boucher

J. P.

(2000) Practicing a maximal performance task: A cooperative strategy for muscle activity. Research Quarterly for Exercise and Sport, 71, 217–228.

Gottlieb

G. L.

Corcos

D. M.

Agarwal

G. C.

(1989a) Organizing principles for single joint movements: I. A speed-insensitive strategy. Journal of Neurophysiology, 62, 342–357.

Gottlieb

G. L.

Corcos

D. M.

Agarwal

G. C.

(1989b) Strategies for the control of single mechanical degree of freedom voluntary movements. Behavioral and Brain Sciences, 12, 189–210.

Hoffman

D. S.

Strick

P. L.

(1989) Force requirements and patterns of muscle activity. Behavioral and Brain Sciences, 12, 221–224.

Oldfield

R. C.

(1971) The assessment and analysis of handedness: The Edinburgh inventory. Neuropsychologia, 9, 97–113.

Pfann

K. D.

Hoffman

D. S.

Gottlieb

G. L.

Strick

P. L.

Corcos

D. M.

(1998) Common principles underlying the control of rapid, single degree-of-freedom movements at different joints. Experimental Brain Research, 118, 35–51.

Schmidt

R. A.

Lee

T. D.

(2005) Motor control and learning. Champaign, IL: Human Kinetics.

Schmidt

R. A.

Sherwood

D. E.

(1982) An inverted-U relation between spatial error and force requirements in rapid limb movements: Further evidence for the impulse-variability model. Journal of Experimental Psychology: Human Perception and Performance, 8, 158–170.

10.

Schmidt

R. A.

Sherwood

D. E.

Walter

C. B.

(1988) Rapid movements with reversals in direction: I. The control of movement time. Experimental Brain Research, 69, 344–354.

11.

Schmidt

R. A.

Zelaznik

H. N.

Frank

J. S.

(1978) Sources of inaccuracy in rapid movement. In Stelmach

G. E.

(Ed.), Information processing in motor control and learning. New York: Academic Press. Pp. 183–203.

12.

Schmidt

R. A.

Zelaznik

H. N.

Hawkins

Frank

J. S.

Quinn

J. T.

Jr. (1979) Motor-output variability: A theory for the accuracy of rapid motor acts. Psychological Review, 86, 415–451.

13.

Shapiro

D. C.

Walter

C. B.

(1986) An examination of rapid positioning movements with spatiotemporal constraints. Journal of Motor Behavior, 18, 373–395.

14.

Sherwood

D. E.

Enebo

B. A.

(2007) Trial-by-trial analysis or averaging: Implications for electromyographic models for rapid limb control. Research Quarterly for Exercise and Sport, 78, 307–317.

15.

Sherwood

D. E.

Schmidt

R. A.

(1980) The relation between force and force variability in minimal and near-maximal static and dynamic contractions. Journal of Motor Behavior, 12, 75–89.

16.

Sherwood

D. E.

Schmidt

R. A.

Walter

C. B.

(1988) Rapid movements with reversals in direction. II. Control of movement amplitude and inertial load. Experimental Brain Research, 69, 355–367.

17.

Wachholder

Altenburger

(1926) Beiträge zur Physiologie der willkürlichen Bewegund: X. Mitteilung. Einzelbewegungen [Contributions to the physiology of arbitrary movement. Report 10: Single movements]. Pflügers Archives, 214, 642–661.

18.

Walter

C. B.

(1984) Temporal quantification of electromyography with reference to motor control research. Human Movement Science, 3. 155–162.

Electromyographic Control of Movement Time in a Rapid Aiming Movement

Abstract

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