TY - JOUR
T1 - Reconstruction of the human gastrocnemius force-length curve in vivo
T2 - Part 1 - Model-based validation of method
AU - Winter, Samantha L.
AU - Challis, John H.
PY - 2008/8
Y1 - 2008/8
N2 - The muscle fiber force-length relationship has been explained in terms of the cross-bridge theory at the sarcomere level. In vivo, for a physiologically realistic range of joint motion, and therefore range of muscle fiber lengths, only part of the force-length curve may be used; that is, the section of the forcelength curve expressed can vary. The purpose of this study was to assess the accuracy of a method for determining the expressed section of the forcelength curve for biarticular muscles. A muscle model was used to simulate the triceps surae muscle group. Three model formulations were used so that the gastrocnemius operated over different portions of the force-length curve: the ascending limb, the plateau region, and the descending limb. Joint moment data were generated for a range of joint configurations and from this simulated data the region of the forcelength relationship that the gastrocnemius muscle operated over was successfully reconstructed using the algorithm of Herzog and ter Keurs (1988a). Further simulations showed that the correct region of the force-length curve was accurately reconstructed even in the presence of random and systematic noise generated to reflect the effects of sampling errors, and incomplete muscle activation.
AB - The muscle fiber force-length relationship has been explained in terms of the cross-bridge theory at the sarcomere level. In vivo, for a physiologically realistic range of joint motion, and therefore range of muscle fiber lengths, only part of the force-length curve may be used; that is, the section of the forcelength curve expressed can vary. The purpose of this study was to assess the accuracy of a method for determining the expressed section of the forcelength curve for biarticular muscles. A muscle model was used to simulate the triceps surae muscle group. Three model formulations were used so that the gastrocnemius operated over different portions of the force-length curve: the ascending limb, the plateau region, and the descending limb. Joint moment data were generated for a range of joint configurations and from this simulated data the region of the forcelength relationship that the gastrocnemius muscle operated over was successfully reconstructed using the algorithm of Herzog and ter Keurs (1988a). Further simulations showed that the correct region of the force-length curve was accurately reconstructed even in the presence of random and systematic noise generated to reflect the effects of sampling errors, and incomplete muscle activation.
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U2 - 10.1123/jab.24.3.197
DO - 10.1123/jab.24.3.197
M3 - Article
C2 - 18843149
AN - SCOPUS:53549129214
SN - 1065-8483
VL - 24
SP - 197
EP - 206
JO - Journal of applied biomechanics
JF - Journal of applied biomechanics
IS - 3
ER -