Improving the accuracy of musculotendon models for the simulation of active lengthening

Millard, Matthew<sup>1,2,3</sup>; Kempter, Fabian<sup>2</sup>; Stutzig, Norman<sup>1</sup>; Siebert, Tobias<sup>1,3</sup>; Fehr, Jörg<sup>2,3</sup>

Affiliations

¹Institute for Sport and Movement Science at the University of Stuttgart, Stuttgart, Germany

²Institute of Engineering and Computational Mechanics at the University of Stuttgart, Stuttgart, Germany

³Stuttgart Center of Simulation Science at the University of Stuttgart, Stuttgart, Germany

Abstract and keywords

Vehicle accidents can cause neck injuries which are costly for individuals and society. Safety systems could be designed to reduce the risk of neck injury if it were possible to accurately simulate the tissue-level injuries that later lead to chronic pain. During a crash, reflexes cause the muscles of the neck to be actively lengthened. Although the muscles of the neck are often only mildly injured, the forces developed by the neck’s musculature affect the tissues that are more severely injured. In this work, we compare the forces developed by MAT_156, LSDYNA’s Hill-type model, and the newly proposed VEXAT muscle model during active lengthening. The results show that Hill-type muscle models underestimate forces developed during active lengthening, while the VEXAT model can more faithfully reproduce experimental measurements.

Keywords: active lengthening; muscle model; neck injury; titin; active human body model

Links

URL: http://www.ircobi.org/wordpress/downloads/irc23/pdf-files/2363.pdf

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