Normal adaptations to exercise despite protection against oxidative stress - Wikidata - awgldk - TriplyDB

Normal adaptations to exercise despite protection against oxidative stress

Normal adaptations to exercise despite protection against oxidative stress

http://www.wikidata.org/entity/Q35543648

about

Role of ROS and RNS Sources in Physiological and Pathological Conditions Dietary Antioxidants as Modifiers of Physiologic Adaptations to Exercise Modulating exercise-induced hormesis: Does less equal more?Supplementation with α-lipoic acid, CoQ10, and vitamin E augments running performance and mitochondrial function in female mice Fit with good fat? The role of n-3 polyunsaturated fatty acids on exercise performance Does vitamin C and E supplementation impair the favorable adaptations of regular exercise?Do antioxidant supplements interfere with skeletal muscle adaptation to exercise training?Rationale for antioxidant supplementation in sarcopenia Elevated mitochondrial oxidative stress impairs metabolic adaptations to exercise in skeletal muscle Exercise and type 2 diabetes: molecular mechanisms regulating glucose uptake in skeletal muscle.Exercise performance and physiological responses: the potential role of redox imbalance Exercise and Glycemic Control: Focus on Redox Homeostasis and Redox-Sensitive Protein Signaling.Effects of exercise with or without blueberries in the diet on cardio-metabolic risk factors: an exploratory pilot study in healthy subjects.Effects of vitamin C and E supplementation on endogenous antioxidant systems and heat shock proteins in response to endurance training.Altering the redox state of skeletal muscle by glutathione depletion increases the exercise-activation of PGC-1α The effect of green tea extract supplementation on exercise-induced oxidative stress parameters in male sprinters.Redox regulation of muscle adaptations to contractile activity and aging.Mitochondrial antioxidative capacity regulates muscle glucose uptake in the conscious mouse: effect of exercise and diet.Vitamin E and vitamin C do not reduce insulin sensitivity but inhibit mitochondrial protein expression in exercising obese rats.Sustained postexercise increases in AS160 Thr642 and Ser588 phosphorylation in skeletal muscle without sustained increases in kinase phosphorylation Exercise, oxidants, and antioxidants change the shape of the bell-shaped hormesis curve.Skeletal muscle reactive oxygen species: a target of good cop/bad cop for exercise and disease.Effects of allopurinol on exercise-induced muscle damage: new therapeutic approaches?Moderate Exercise Allows for shorter Recovery Time in Critical Limb Ischemia.Nuclear factor erythroid-derived 2-like 2 (NFE2L2, Nrf2) mediates exercise-induced mitochondrial biogenesis and the anti-oxidant response in mice.A synopsis on aging-Theories, mechanisms and future prospects.Mitochondria in the middle: exercise preconditioning protection of striated muscle.Oxidative stress and inflammation: liver responses and adaptations to acute and regular exercise."Nutraceuticals" in relation to human skeletal muscle and exercise.Repetitive cryotherapy attenuates the in vitro and in vivo mononuclear cell activation response.Alternate-Day High-Fat Diet Induces an Increase in Mitochondrial Enzyme Activities and Protein Content in Rat Skeletal Muscle Chronic Eccentric Exercise and Antioxidant Supplementation: Effects on Lipid Profile and Insulin Sensitivity Increased Skeletal Muscle GLUT4 Expression in Obese Mice After Voluntary Wheel Running Exercise Is Posttranscriptional.The Ability of Exercise-Associated Oxidative Stress to Trigger Redox-Sensitive Signalling Responses.Reactive oxygen species-mediated control of mitochondrial biogenesis.Effect of a 2000-m running test on antioxidant and cytokine response in plasma and circulating cells.Redox status and antioxidant response in professional cyclists during training.Skeletal muscle uncoupling-induced longevity in mice is linked to increased substrate metabolism and induction of the endogenous antioxidant defense system.A role for reactive oxygen species in the regulation of skeletal muscle hypertrophy.The effects of beetroot juice supplementation on indices of muscle damage following eccentric exercise.

P2860

Q26740342-032C9BB7-C842-44F3-B0B3-135521AEBA2B Q26825013-F8E1DB39-3372-41C3-AFDB-0571F8A69430 Q26997325-743E6AE0-50D2-45A9-BF21-A0C3A927BF21 Q27329547-8D27A700-96D2-4DCA-8812-16A70E22C10E Q28073362-642D7680-16E8-405B-9D5C-28289B30DA5B Q28387788-973EB733-2D40-4E8D-8886-3E5011E5E44F Q28389360-78AF2472-CB4C-4640-BFB2-F9105377C5B3 Q28395964-3809391D-78E4-4231-97CF-E0957B2F012C Q28536393-865A5DC4-48FF-406D-AD65-6B876DC95B42 Q30397046-65C7B171-C05E-48C4-9B63-AA5E2340DAE6 Q33567497-DF4AC982-E73B-4D7B-962F-969BEFB18D59 Q33639120-7B797E12-2135-447E-A13A-D58867CA4F3F Q34311145-2A636812-75C5-410D-A4A8-45BF21392A95 Q34622863-5A9FD229-AF8D-48E4-9F8D-6A060BBF1714 Q35094154-4E378ED7-2925-4EDC-9129-1E75F5A4C2FF Q35847510-06A6269E-C253-4F09-B39C-DD45542599FE Q35921776-A1DC44A7-3460-4C31-9A5C-43DE03E88DC1 Q36320932-891A66FA-3A2C-4D70-80A2-B3FA53169D18 Q36463561-8BB1C7A9-A6CE-4032-B1AA-EB13F2E9B66D Q36530922-2608336E-50D0-4D5B-998C-EF1E1A8ECDA6 Q37693728-9F90AFED-2644-4E18-8B20-F8D949B5CF62 Q38195314-CF1B1F7C-6E30-47A2-8D3A-370D321FE42E Q38245545-123E13ED-ED8B-4E03-82A8-7495AA6A06F8 Q38633070-9D4A0265-359D-4A8A-8DE3-A527DD39A201 Q38777090-0F23FC63-FFEC-4A2F-A9C4-A06CA596AAFE Q38847549-68675B3D-F16A-455D-BAEA-581C3AF27610 Q38883697-2D49D270-AD00-41E7-8CAB-169BB70B1504 Q38976134-5B3F7DE1-E58D-4348-81CE-DBE059657CDB Q39112416-15711FDD-41C6-45AC-90C8-B7A714F2436C Q39838953-324005EE-78C7-4B82-A687-26C519A7E377 Q40742156-234CBF53-6726-4DB3-8556-5D0C9072310A Q41437011-0F0EAC12-5452-4923-A044-4EE2C1030632 Q41640112-2265BB7D-6CF2-44A8-9678-5019A6E53826 Q41662751-FF74CA20-9613-4CCF-A93B-0EDA323E08D9 Q42186468-888C32C8-F7F9-42D1-8BD0-86B57B37310C Q42512701-4995E022-C2E2-4031-9977-16804E885398 Q43520535-4A871B41-D3E8-4254-BE0A-3958FDF5D39C Q43810687-0116192B-6AC1-4180-B5D6-9A8BB3940AD0 Q43985234-7B3977FA-48A4-4B5F-A16F-5AD254AF9317 Q46415028-5263B910-4035-4453-A721-C3F6E67DD90C

P2860

Normal adaptations to exercise despite protection against oxidative stress

http://www.wikidata.org/entity/Q35543648

description

2011 nî lūn-bûn

@nan

2011 թուականի Յուլիսին հրատարակուած գիտական յօդուած

@hyw

2011 թվականի հուլիսին հրատարակված գիտական հոդված

@hy

2011年の論文

@ja

2011年論文

@yue

2011年論文

@zh-hant

2011年論文

@zh-hk

2011年論文

@zh-mo

2011年論文

@zh-tw

2011年论文

@wuu

name

Normal adaptations to exercise despite protection against oxidative stress

@ast

Normal adaptations to exercise despite protection against oxidative stress

@en

type

label

Normal adaptations to exercise despite protection against oxidative stress

@ast

Normal adaptations to exercise despite protection against oxidative stress

@en

prefLabel

Normal adaptations to exercise despite protection against oxidative stress

@ast

Normal adaptations to exercise despite protection against oxidative stress

@en

P1433

Q35543648-40F1FB6E-518C-42D8-B293-899EB7F5084F

P1476

Q35543648-E2FFC28C-47D0-4667-943B-CB3A31AF23FF

P2093

Q35543648-1974F360-AF7F-4B3E-9510-9A28072B04FC

Q35543648-7B660881-E558-4EC0-B4AB-2CC8B8CC8779

Q35543648-97235BB0-DC81-4362-A086-9E5F1DE2FDF7

Q35543648-D85D5AAD-D820-472A-9CD9-B1D381E34D4F

Q35543648-DCF6F977-818B-412F-8D1C-36AD83BB3B21

P2860

Q35543648-0458271A-42BC-47BA-A99F-90D37405362D

Q35543648-0FD47A87-ECCF-41BD-A211-F8E75E515C45

Q35543648-109AEB57-1885-49A0-BB42-8920D0869C50

Q35543648-167AD046-6A35-4C10-B68A-964C18E0CD37

Q35543648-29DD03C5-C8B9-44BE-95CE-95369F0E29BF

Q35543648-37222E08-E533-422F-81F4-4025F16EA8F9

Q35543648-40D57361-170F-4126-8213-F1D439A4ACC7

Q35543648-4DA18CE2-BFC3-4C7D-B5FB-D859DC28BB09

Q35543648-502A13BF-D3B2-4906-B07B-1DCE4CD5F49A

Q35543648-589F7806-D8AA-48C8-9D8A-1AEB4C01CECD

P304

Q35543648-3BA5DA10-CCE1-4E33-98CE-4038F058D9ED

P31

Q35543648-873BD3C2-BBBF-4525-A6AB-8A31DC905088

P356

Q35543648-6A301BA0-7E73-4B11-95DA-93B3E269C7C0

P433

Q35543648-FAEB7C5E-194E-43C4-87CB-03C7834F71DF

P478

Q35543648-C534B5E8-2A24-42FD-929D-DEBFAF544AF4

P577

Q35543648-F29B58AF-E38E-47DD-B238-4BABA74A4BAD

P698

Q35543648-D30E12C2-5F21-46D0-8B14-CD4E8FC8B9D4

P932

Q35543648-8A3FC967-2DF4-409E-B3DC-DE7FED667D2F

P356

AJPENDO.00655.2010

P1433

American Journal of Physiology - Endocrinology and Metabolism

P1476

Normal adaptations to exercise despite protection against oxidative stress

@en

P2093

Dong-Ho Han

http://www.w3.org/2001/XMLSchema#string

John O Holloszy

http://www.w3.org/2001/XMLSchema#string

Kazuhiko Higashida

http://www.w3.org/2001/XMLSchema#string

Mitsuru Higuchi

http://www.w3.org/2001/XMLSchema#string

Sang Hyun Kim

http://www.w3.org/2001/XMLSchema#string

P2860

Protein measurement with the Folin phenol reagent

Antioxidants prevent health-promoting effects of physical exercise in humans

Exercise induces transient transcriptional activation of the PGC-1alpha gene in human skeletal muscle

Direct coupling of transcription and mRNA processing through the thermogenic coactivator PGC-1

Exercise-induced mitochondrial biogenesis begins before the increase in muscle PGC-1alpha expression

Vitamin E, vitamin C, and exercise.

Exercise and oxidative stress methodology: a critique.

Antioxidants in exercise nutrition.

Oral administration of vitamin C decreases muscle mitochondrial biogenesis and hampers training-induced adaptations in endurance performance.

Exercise-induced increase in muscle insulin sensitivity.

P304

E779-84

http://www.w3.org/2001/XMLSchema#string

P31

scholarly article

P356

10.1152/AJPENDO.00655.2010

http://www.w3.org/2001/XMLSchema#string

P433

5

http://www.w3.org/2001/XMLSchema#string

P478

301

http://www.w3.org/2001/XMLSchema#string

P577

2011-07-12T00:00:00Z

http://www.w3.org/2001/XMLSchema#dateTime

P698

21750271

http://www.w3.org/2001/XMLSchema#string

P932

3214004

http://www.w3.org/2001/XMLSchema#string