Activité, Système Moteur & Coordination
Douleur - Allodynie/Hyperalgésie Thermique
Douleur - Spontanée - Déficit de Posture
Douleur - Allodynie/Hyperalgésie Mécanique
Anxiété & Dépression
Apprentissage/Mémoire - Attention - Addiction
Physiologie & Recherche Respiratoire
Métabolisme & Prise Alimentaire
Douleur
Métabolisme
Système moteur
Neurodégénérescence
Thématiques transversales
Système musculaire
Functions de motricité générale
Troubles de l'humeur
Other disorders
Joints
Système Nerveux Central (SNC) 
Système sensoriel
Authors
J. Bouitbir, F. Daussin, A.-L. Charles, L. Rasseneur, S. Dufour et al.
Lab
CHRU of Strasbourg, Physiology and Functional Explorations Department, Strasbourg, France
Journal
Muscle and Nerve
Abstract
Introduction: Statins are associated with adverse skeletal muscle effects. Our objective was to determine if muscular adaptations following exercise training prevented deleterious effects of atorvastatin in glycolytic skeletal muscle. Methods: 20 rats were divided into 2 groups: a control group (n=10; Cont) and a 10 days of training group (n=10; Training). Using the permeabilized fibers technique, we explored mitochondrial function. Results: Exercise training increased Vmax and H2O2 production without altering the free radical leak, and mRNA expression of SOD2 and Cox1 were higher in trained muscle. In the Cont group, atorvastatin exposure increased H2O2 production and decreased skeletal muscle Vmax. The decreased Vmax effect of atorvastatin was dose dependent. Interestingly, the half-maximal inhibitory concentration (IC50) was higher in the Training group. H2O2 production increased in trained muscle after atorvastatin exposure. Conclusions: These results suggest that improvements in mitochondrial respiratory and antioxidant capacities following endurance training protected them against statin exposure.
BIOSEB Instruments Used:
Treadmill (BX-TM),Passive avoidance (LE870)
