BACKGROUND: Oxidative stress is implicated in pathogenesis of cardiac reperfusion injury, characterized by cellular Ca overload and hypercontracture. Volatile anesthetics protect the heart against reperfusion injury primarily by attenuating Ca overload. This study investigated electrophysiological mechanisms underlying cardioprotective effects of sevoflurane against oxidative stress-induced cellular injury. METHODS: The cytosolic Ca levels and cell morphology were assessed in mouse ventricular myocytes, using confocal fluo-3 fluorescence imaging, whereas membrane potentials and L-type Ca current (ICa,L) were recorded using whole-cell patch-clamp techniques. Phosphorylation of Ca/calmodulin-dependent protein kinase II was examined by Western blotting. RESULTS: Exposure to H2O2 (100 μM) for 15 min evoked cytosolic Ca elevation and hypercontracture in 56.8% of ventricular myocytes in 11 experiments, which was partly but significantly reduced by nifedipine, tetracaine, or SEA0400. Sevoflurane prevented H2O2-induced cellular Ca overload in a concentration-dependent way (IC50 = 1.35%). Isoflurane (2%) and desflurane (10%) also protected ventricular myocytes by a degree similar to sevoflurane (3%). Sevoflurane suppressed H2O2-induced electrophysiological disturbances, including early afterdepolarizations, voltage fluctuations in resting potential, and abnormal automaticities. H2O2 significantly enhanced ICa,L by activating Ca/calmodulin-dependent protein kinase II, and subsequent addition of sevoflurane, isoflurane, or desflurane similarly reduced ICa,L to below baseline levels. Phosphorylated Ca/calmodulin-dependent protein kinase II increased after 10-min incubation with H2O2, which was significantly prevented by concomitant administration of sevoflurane. CONCLUSIONS: Sevoflurane protected ventricular myocytes against H2O2-induced Ca overload and hypercontracture, presumably by affecting multiple Ca transport pathways, including ICa,L, Na/Ca exchanger and ryanodine receptor. These actions appear to mediate cardioprotection against reperfusion injury associated with oxidative stress.
BACKGROUND: Oxidative stress is implicated in pathogenesis of cardiac reperfusion injury, characterized by cellular Ca overload and hypercontracture. Volatile anesthetics protect the heart against reperfusion injury primarily by attenuating Ca overload. This study investigated electrophysiological mechanisms underlying cardioprotective effects of sevoflurane against oxidative stress-induced cellular injury. METHODS: The cytosolic Ca levels and cell morphology were assessed in mouse ventricular myocytes, using confocal fluo-3 fluorescence imaging, whereas membrane potentials and L-type Ca current (ICa,L) were recorded using whole-cell patch-clamp techniques. Phosphorylation of Ca/calmodulin-dependent protein kinase II was examined by Western blotting. RESULTS: Exposure to H2O2 (100 μM) for 15 min evoked cytosolic Ca elevation and hypercontracture in 56.8% of ventricular myocytes in 11 experiments, which was partly but significantly reduced by nifedipine, tetracaine, or SEA0400. Sevoflurane prevented H2O2-induced cellular Ca overload in a concentration-dependent way (IC50 = 1.35%). Isoflurane (2%) and desflurane (10%) also protected ventricular myocytes by a degree similar to sevoflurane (3%). Sevoflurane suppressed H2O2-induced electrophysiological disturbances, including early afterdepolarizations, voltage fluctuations in resting potential, and abnormal automaticities. H2O2 significantly enhanced ICa,L by activating Ca/calmodulin-dependent protein kinase II, and subsequent addition of sevoflurane, isoflurane, or desflurane similarly reduced ICa,L to below baseline levels. Phosphorylated Ca/calmodulin-dependent protein kinase II increased after 10-min incubation with H2O2, which was significantly prevented by concomitant administration of sevoflurane. CONCLUSIONS:Sevoflurane protected ventricular myocytes against H2O2-induced Ca overload and hypercontracture, presumably by affecting multiple Ca transport pathways, including ICa,L, Na/Ca exchanger and ryanodine receptor. These actions appear to mediate cardioprotection against reperfusion injury associated with oxidative stress.
Authors: Jennifer Danielsson; Jose Perez-Zoghbi; Kyra Bernstein; Matthew B Barajas; Yi Zhang; Satish Kumar; Pawan K Sharma; George Gallos; Charles W Emala Journal: Anesthesiology Date: 2015-09 Impact factor: 7.892