Skip to main content
Key Specialties
Cardiology Diabetology Endocrinology Gastroenterology Geriatrics and Gerontology Gynecology and Obstetrics Hematology Infectious Disease Internal Medicine Nephrology Neurology Oncology Pediatrics Respiratory Medicine Rheumatology Surgery
Congress Coverage
2024 ACC Congress 2023 ESMO Congress 2023 EASD Congress 2023 ERS Congress 2023 ESC Congress
Clinical Collections
Advances in Alzheimer’s

Keynote webinar | Spotlight on medication adherence

LIVE: Thursday 27th June 2024, 18:00-19:30 (CEST)
Join our expert panel to discover why you need to understand the drivers of non-adherence in your patients, and how you can optimize medication adherence in your clinics to drastically improve patient outcomes.
ADVANCED SEARCH
Log in
Top
Experimental Brain Research
Published in: Experimental Brain Research 2/2008

01-09-2008 | Research Article

Muscle cocontraction following dynamics learning

Authors: Mohammad Darainy, David J. Ostry

Published in: Experimental Brain Research | Issue 2/2008

Login to get access

Abstract

Coactivation of antagonist muscles is readily observed early in motor learning, in interactions with unstable mechanical environments and in motor system pathologies. Here we present evidence that the nervous system uses coactivation control far more extensively and that patterns of cocontraction during movement are closely tied to the specific requirements of the task. We have examined the changes in cocontraction that follow dynamics learning in tasks that are thought to involve finely sculpted feedforward adjustments to motor commands. We find that, even following substantial training, cocontraction varies in a systematic way that depends on both movement direction and the strength of the external load. The proportion of total activity that is due to cocontraction nevertheless remains remarkably constant. Moreover, long after indices of motor learning and electromyographic measures have reached asymptotic levels, cocontraction still accounts for a significant proportion of total muscle activity in all phases of movement and in all load conditions. These results show that even following dynamics learning in predictable and stable environments, cocontraction forms a central part of the means by which the nervous system regulates movement.
Literature
Bonato P, Roy SH, Knaflitz M, De Luca CJ (2001) Time–frequency parameters of the surface myoelectric signal for assessing muscle fatigue during cyclic dynamic contractions. IEEE Trans Biomed Eng 48:745–753PubMedCrossRef
Burdet E, Osu R, Franklin DW, Milner TE, Kawato M (2001) The central nervous system stabilizes unstable dynamics by learning optimal impedance. Nature 414:446–449PubMedCrossRef
Caithness G, Osu R, Bays P, Chase H, Klassen J, Kawato M, Wolpert DM, Flanagan JR (2004) Failure to consolidate the consolidation theory of learning for sensorimotor adaptation tasks. J Neurosci 24:8662–8671PubMedCrossRef
Darainy M, Malfait N, Gribble PL, Towhidkhoh F, Ostry DJ (2004) Learning to control arm stiffness under static conditions. J Neurophysiol 92:3344–3350PubMedCrossRef
Franklin DW, Burdet E, Osu R, Kawato M, Milner TE (2003a) Functional significance of stiffness in adaptation of multijoint arm movements to stable and unstable dynamics. Exp Brain Res 151:145–157PubMedCrossRef
Franklin DW, Osu R, Burdet E, Kawato M, Milner TE (2003b) Adaptation to stable and unstable dynamics achieved by combined impedance control and inverse dynamics model. J Neurophysiol 90:3270–3282PubMedCrossRef
Gomi H, Osu R (1998) Task-dependent viscoelasticity of human multijoint arm and its spatial characteristics f or interaction with environments. J Neurosci 18:8965–8978PubMed
Gribble PL, Ostry DJ (1998) Independent coactivation of shoulder and elbow muscles. Exp Brain Res 123:355–360PubMedCrossRef
Gribble PL, Mullin LI, Cothros N, Mattar A (2003) Role of cocontraction in arm movement accuracy. J Neurophysiol 89:2396–2405PubMedCrossRef
Hwang EJ, Donchin O, Smith MA, Shadmehr R (2003) A gain-field encoding of limb position and velocity in the internal model of arm dynamics. PLoS Biol 1:E25PubMedCrossRef
Lackner JR, DiZio P (1994) Rapid adaptation to Coriolis force perturbations of arm trajectory. J Neurophysiol 72:299–313PubMed
Milner TE, Cloutier C (1993) Compensation for mechanically unstable loading in voluntary wrist movement. Exp Brain Res 94:522–532PubMedCrossRef
Perreault EJ, Kirsch RF, Crago PE (2002) Voluntary control of static endpoint stiffness during force regulation tasks. J Neurophysiol 87:2808–2816PubMed
Shadmehr R, Mussa-Ivaldi FA (1994) Adaptive representation of dynamics during learning of a motor task. J Neurosci 14:3208–3224PubMed
Suzuki M, Shiller DM, Gribble PL, Ostry DJ (2001) Relationship between cocontraction, movement kinematics and phasic muscle activity in single joint arm movement. Exp Brain Res 140:171–181PubMedCrossRef
Thoroughman KA, Shadmehr R (1999) Electromyographic correlates of learning an internal model of reaching movements. J Neurosci 19:8574–8588
Metadata
Title
Muscle cocontraction following dynamics learning
Authors
Mohammad Darainy
David J. Ostry
Publication date
01-09-2008
Publisher
Springer-Verlag
Published in
Experimental Brain Research / Issue 2/2008
Print ISSN: 0014-4819
Electronic ISSN: 1432-1106
DOI
https://doi.org/10.1007/s00221-008-1457-y

Other articles of this Issue 2/2008

Experimental Brain Research 2/2008 Go to the issue

Research Article

Velocity storage activity is affected after sustained centrifugation: a relationship with spatial disorientation

Research Article

Cortical processing of lateral skin stretch stimulation in humans

Research Article

Motion sensitivity during fixation in straight-ahead and lateral eccentric gaze

Research Article

Visual temporal order judgment in profoundly deaf individuals

Research Article

Brain motor system function in a patient with complete spinal cord injury following extensive brain–computer interface training

Research Article

Somatosensory off-response in humans: an ERP study