• DocumentCode
    1082517
  • Title

    Estimation of force-activation, force-length, and force-velocity properties in isolated, electrically stimulated muscle

  • Author

    Durfee, William K. ; Palmer, Karen I.

  • Author_Institution
    Dept. of Mech. Eng., Minnesota Univ., Minneapolis, MN, USA
  • Volume
    41
  • Issue
    3
  • fYear
    1994
  • fDate
    3/1/1994 12:00:00 AM
  • Firstpage
    205
  • Lastpage
    216
  • Abstract
    Designing advanced controllers for motor neural prosthesis applications requires appropriate models for electrically stimulated muscle. A nonlinear nonisometric muscle model based on a Hill-type structure is presented. Estimation algorithms were derived to parameterize the passive force-length, the passive force-velocity, the active force-length, and the active force-velocity properties, the isometric recruitment curve, and the linear contraction dynamics of the model. All parameters were based on experimental measurements rather than on values taken from the literature. The estimation methods were validated experimentally using isolated hind-limb muscles in two acute animal model preparations. The results demonstrated that the parameterized model is capable of predicting force output with reasonable accuracy for a wide range of simultaneously varying kinematic and stimulation inputs.
  • Keywords
    bioelectric phenomena; biomechanics; muscle; physiological models; Hill-type structure; acute animal model preparations; estimation algorithms; force output prediction; force-activation properties; force-length properties; force-velocity properties; isolated electrically stimulated muscle; isolated hind-limb muscles; isometric recruitment curve; linear contraction dynamics; muscle biomechanics; nonlinear nonisometric muscle model; parameterized model; Animal structures; Context modeling; Error correction; Force control; Mathematical model; Mechanical engineering; Muscles; Predictive models; Prosthetics; Recruitment; Algorithms; Animals; Cats; Electric Stimulation; Isometric Contraction; Models, Biological; Muscles; Nonlinear Dynamics; Predictive Value of Tests; Prostheses and Implants; Sensitivity and Specificity;
  • fLanguage
    English
  • Journal_Title
    Biomedical Engineering, IEEE Transactions on
  • Publisher
    ieee
  • ISSN
    0018-9294
  • Type

    jour

  • DOI
    10.1109/10.284939
  • Filename
    284939