about
Mitochondrial Regulation of the Muscle Microenvironment in Critical Limb IschemiaRegulation of satellite cell function in sarcopeniaUsage of a localised microflow device to show that mitochondrial networks are not extensive in skeletal muscle fibresSkeletal muscle mitochondrial health and spinal cord injuryRedox Mechanism of Reactive Oxygen Species in ExerciseThe role of oxidative stress in skeletal muscle injury and regeneration: focus on antioxidant enzymesRole of Redox Signaling and Inflammation in Skeletal Muscle Adaptations to TrainingUremic myopathy: is oxidative stress implicated in muscle dysfunction in uremia?Green tea extract attenuates muscle loss and improves muscle function during disuse, but fails to improve muscle recovery following unloading in aged ratsExercise performance and physiological responses: the potential role of redox imbalanceMuscle strength mediates the relationship between mitochondrial energetics and walking performanceHyperglycemia-induced diaphragm weakness is mediated by oxidative stress.Effects of acute physical exercise on oxidative stress and inflammatory status in young, sedentary obese subjects.A Transcriptomic Analysis of Physiological Significance of Hypoxia-inducible Factor-1α in Myogenesis and Carbohydrate Metabolism of Genioglossus in MiceCrossroads between peripheral atherosclerosis, western-type diet and skeletal muscle pathophysiology: emphasis on apolipoprotein E deficiency and peripheral arterial disease.Altered cross-bridge properties in skeletal muscle dystrophiesExercise Tolerance Can Be Enhanced through a Change in Work Rate within the Severe Intensity Domain: Work above Critical Power Is Not Constant.Effect of antioxidants on histamine receptor activation and sustained postexercise vasodilatation in humans.The Role of Reactive Oxygen Species in β-Adrenergic Signaling in Cardiomyocytes from Mice with the Metabolic Syndrome.Reactive oxygen species generated from skeletal muscles are required for gecko tail regeneration.Pharmacological targeting of mitochondrial reactive oxygen species counteracts diaphragm weakness in chronic heart failure.Black ginger extract increases physical fitness performance and muscular endurance by improving inflammation and energy metabolism.Modulation of Muscle Fiber Compositions in Response to Hypoxia via Pyruvate Dehydrogenase Kinase-1.Comparative changes in antioxidant enzymes and oxidative stress in cardiac, fast twitch and slow twitch skeletal muscles following endurance exercise training.Diaphragm Abnormalities in Patients with End-Stage Heart Failure: NADPH Oxidase Upregulation and Protein Oxidation.Exercise Training Attenuates the Dysregulated Expression of Adipokines and Oxidative Stress in White Adipose Tissue.The "Goldilocks Zone" from a redox perspective-Adaptive vs. deleterious responses to oxidative stress in striated muscle.Impact of extreme exercise at high altitude on oxidative stress in humans.Redox homeostasis and age-related deficits in neuromuscular integrity and function.Redox control of skeletal muscle atrophy.Control of DNA integrity in skeletal muscle under physiological and pathological conditions.Regulation of NADPH oxidases in skeletal muscle.Age-induced oxidative stress: how does it influence skeletal muscle quantity and quality?Melatonin protects against uric acid-induced mitochondrial dysfunction, oxidative stress, and triglyceride accumulation in C2C12 myotubes.Effects of naringin on physical fatigue and serum MMP-9 concentration in female rats.Comparative adaptations in oxidative and glycolytic muscle fibers in a low voluntary wheel running rat model performing three levels of physical activity.In vivo Ca2+ dynamics induced by Ca2+ injection in individual rat skeletal muscle fibers.Muscle ion transporters and antioxidative proteins have different adaptive potential in arm than in leg skeletal muscle with exercise trainingEstrogens Protect Calsequestrin-1 Knockout Mice from Lethal Hyperthermic Episodes by Reducing Oxidative Stress in Muscle.S-nitrosylation and S-glutathionylation of Cys134 on troponin I have opposing competitive actions on Ca2+ sensitivity in rat fast-twitch muscle fibers.
P2860
Q26774784-326F0160-4055-4D18-897A-A37C8DDC7269Q26826890-B7975F21-2A1F-4D4B-840C-F38A8E5E740BQ27343056-D7A8D75B-3FB9-400E-9C30-E8DCE10DF96AQ28074178-7F78A600-2FDD-4BF3-81CB-668E4EEFFC76Q28075860-3BD9DFC3-B080-4EDD-8A2C-AC9A81E1678BQ28076877-A051F0AD-465F-4573-9230-C688ADE685CFQ28080184-854F3D2B-FAB7-4A0B-AFB6-D562E9BCD0A5Q28084066-1275EE3F-DAFC-491F-8F2F-0870F219085EQ28387094-DB809EF2-1E0A-4DCD-BB8B-83B754526B2DQ33567497-D21E9A0C-09A4-4541-8D76-87C2EF3C4049Q33638920-F68B9F30-4D55-425F-BFD0-EAC9F1B46B03Q33751226-90599B18-6DD3-4119-A2C9-F8EED0A775BCQ33764741-D7D3BB67-C145-4814-BC75-61CF77E2A895Q33864729-85B95E48-2270-4829-A1A9-1015E3B656AAQ33885504-654AA2FC-4DC7-4B51-A40C-1E381443D34EQ34335939-CC9FC87F-A032-4870-831C-4EE9B3194985Q35788588-6A5EC324-1490-4783-9C72-CE3C6E502CA0Q35945529-A05F8121-3B97-44CC-B42E-0186A68376CBQ36209817-F76508FC-486F-4B5E-8CB2-2FCE24243F8EQ36555661-B3BDB0E6-7CF6-4E0E-850C-85A63223C328Q36775314-392C9701-6EE3-4FFC-BC1C-176B51B68AF6Q37097171-D0D58DE7-CEB8-4B59-99DE-34577D4199C0Q37503864-35FBE3D8-68FD-4234-BDF5-D94C95CDD3FBQ37553616-814ED846-0EE9-4FFC-97C7-1D31A0EA64A9Q37570581-8A79652D-151B-456F-93C0-352C44807605Q37607484-746E3218-72D7-4895-A7B4-2A259409719DQ38256368-6F889C68-B045-4D93-AFAB-9FC68E6C5B0BQ38603556-83061FD6-DD83-46A8-9045-5795A954DFE9Q38660882-57A98FC8-F837-4920-AB3D-EC706C9F510DQ38748962-A897F563-0FF7-453B-B324-4580A836C37BQ38819181-5E481D03-23D2-4450-B0FF-8E2167D8DC28Q38835704-798EA95B-F988-415B-9902-7FFF3C8858F0Q38838750-9EA98DD8-5C42-4C83-9BF9-28B913ADEA61Q39070225-9945DB6B-931D-4F2B-A371-143F8F63175AQ39114146-CD60947E-119D-4689-A506-B7A495E347A9Q40279037-F3528BE4-4E09-4EEC-AFBC-360B31B01726Q42316489-DB1C479E-6715-4F65-A89D-15AB80907BD8Q42378116-B22B06CA-DB30-449B-B5F9-B4A58501FF91Q43118514-3C33FAEF-93FB-4A1F-BE6B-F38A6FB5DCA6Q46446019-9C81213D-DE64-48E1-925C-A1223EA40612
P2860
description
article científic
@ca
article scientifique
@fr
articolo scientifico
@it
artigo científico
@pt
bilimsel makale
@tr
scientific article published on April 2011
@en
vedecký článok
@sk
vetenskaplig artikel
@sv
videnskabelig artikel
@da
vědecký článek
@cs
name
Reactive oxygen species: impact on skeletal muscle.
@en
Reactive oxygen species: impact on skeletal muscle.
@nl
type
label
Reactive oxygen species: impact on skeletal muscle.
@en
Reactive oxygen species: impact on skeletal muscle.
@nl
prefLabel
Reactive oxygen species: impact on skeletal muscle.
@en
Reactive oxygen species: impact on skeletal muscle.
@nl
P2093
P2860
P356
P1476
Reactive oxygen species: impact on skeletal muscle.
@en
P2093
Andreas N Kavazis
Scott K Powers
P2860
P304
P356
10.1002/CPHY.C100054
P577
2011-04-01T00:00:00Z