Effects of immobilization on electromyogram power spectrum changes during fatigue
Deutscher übersetzter Titel: | Auswirkungen von Immobilisierung auf die Änderungen im EMG-Spektrum bei Muskelermüdung |
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Autor: | Duchateau, Jacques; Hainaut, Karl |
Erschienen in: | European journal of applied physiology |
Veröffentlicht: | 63 (1991), 6, S. 458-462, Lit. |
Format: | Literatur (SPOLIT) |
Publikationstyp: | Zeitschriftenartikel |
Medienart: | Gedruckte Ressource Elektronische Ressource (online) |
Sprache: | Englisch |
ISSN: | 1439-6319, 0301-5548 |
DOI: | 10.1007/BF00868078 |
Schlagworte: | |
Online Zugang: | |
Erfassungsnummer: | PU199203052877 |
Quelle: | BISp |
Abstract des Autors
The maximal force and median frequency (MF) of the electromyogram (EMG) power density spectrum (PDS) have been compared in disused (6 weeks immobilization) and control (contralateral) human adductor pollicis muscles during fatigue induced by voluntary or electrically-triggered (30 Hz) contractions. The results indicated that after 6 weeks immobilization, MF was not significantly different in disused and control muscles although the force and integrated EMG were drastically reduced during a maximal voluntary contraction (MVC; by 55 and 45, respectively, n=8). During sustained 60s MVC, the force decreased at the same rate in immobilized and control muscles, but the shift of MF towards lower frequency values was smaller in disused muscle as compared to control by (14 vs 28, respectively). In electrically-induced fatigue, the force decrease and the MF shift were larger after inactivity (41 and 43) in one subject, and 50 and 54 in the other subject, respectively) as compared to control (29 and 34 in one subject, and 37 and 38 in the other subject, respectively). These results emphasize the caution that should be exercised when EMG signals are quantified by computing the power density spectrum. The different effects of fatigue during voluntary and electrically-imposed contractions in disused and control muscles indicated that immobilization induced changes in the neural command for the contraction which compensated, at least in part, for its decreased contractile efficiency and resistance to fatigue.