Experimental evaluation of a computational shoulder musculoskeletal model

Abstract Background Many evaluations of shoulder biomechanical models have focused on static exertions in constrained postures, but few have considered tasks that are more complex. This study examines model performance in load delivery tasks for a range of target locations. Methods The study evaluat...

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Bibliographic Details
Published in:Clinical biomechanics (Bristol) 2008-08, Vol.23 (7), p.886-894
Main Authors: Dickerson, Clark R, Hughes, Richard E, Chaffin, Don B
Format: Article
Language:English
Subjects:
Adult
Biomechanical model
Computer Simulation
Electromyography
Female
Humans
Male
Model evaluation
Models, Biological
Movement - physiology
Muscle Contraction - physiology
Muscle, Skeletal - physiology
Optimization
Physical Exertion - physiology
Physical Medicine and Rehabilitation
Range of Motion, Articular - physiology
Shoulder biomechanics
Shoulder Joint - physiology
Task Performance and Analysis
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Summary:Abstract Background Many evaluations of shoulder biomechanical models have focused on static exertions in constrained postures, but few have considered tasks that are more complex. This study examines model performance in load delivery tasks for a range of target locations. Methods The study evaluated an optimization-based muscle force prediction model used to assess dynamic load transfer tasks. Model predictions were compared with experimental electromyographic data for two task phases: (1) static hold and (2) dynamic reach. Findings Predictions correlated positively over all subjects with electromyographic data for prime movers (deltoid [ r = 0.53]; infraspinatus [ r = 0.63]; biceps [ r = 0.61]), though variations in the correlation existed across subjects and tasks. Conversely, the model predicted electromyographic activity of secondary muscles somewhat less accurately. The model also predicted inactivity for electromyographic inactive muscles. Interpretation The model provides important insights into activity levels muscles that most actively respond to external moments during manual load transfer tasks.
ISSN:0268-0033
1879-1271
DOI:10.1016/j.clinbiomech.2008.04.004