Control of the extension–flexion cycle of human knees during bicycle riding by a synergy of solitary muscular excitations and contractions

A Hill-type model is proposed for the extension–flexion cycle of human knees during bicycle riding. The extension–flexion cycle is controlled by a synergy of muscular excitations and contractions of the knee musculature. Muscular action potentials are modeled by sine-Gordon kinks, while titin-influe...

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Veröffentlicht in:	Nonlinear dynamics 2016-11, Vol.86 (3), p.2071-2080
Hauptverfasser:	Gojkovic, Zoran, Ivancevic, Tijana
Format:	Artikel
Sprache:	eng
Schlagworte:	Actomyosin Automotive Engineering Bicycles Biomedical materials Classical Mechanics Control Dynamical Systems Engineering Excitation Joint surgery Knee Knees Mechanical Engineering Nonlinear dynamics Original Paper Riding Solitary waves Solitons Surgical implants Vibration
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creator	Gojkovic, Zoran Ivancevic, Tijana
description	A Hill-type model is proposed for the extension–flexion cycle of human knees during bicycle riding. The extension–flexion cycle is controlled by a synergy of muscular excitations and contractions of the knee musculature. Muscular action potentials are modeled by sine-Gordon kinks, while titin-influenced actomyosin contractions are modeled by Korteweg-de Vries solitons. As an application, the total knee arthroplasty is discussed.
doi_str_mv	10.1007/s11071-016-3016-6
format	Article
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subjects	Actomyosin Automotive Engineering Bicycles Biomedical materials Classical Mechanics Control Dynamical Systems Engineering Excitation Joint surgery Knee Knees Mechanical Engineering Nonlinear dynamics Original Paper Riding Solitary waves Solitons Surgical implants Vibration
title	Control of the extension–flexion cycle of human knees during bicycle riding by a synergy of solitary muscular excitations and contractions
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