Effects of resistance exercise with and without creatine supplementation on gene expression and cell signaling in human skeletal muscle.
about
Creatine for treating muscle disordersCreatine for treating muscle disordersThe creatine kinase system and pleiotropic effects of creatineCreatine supplementation with specific view to exercise/sports performance: an updateRegulation of mTORC1 by growth factors, energy status, amino acids and mechanical stimuli at a glanceNutritional and contractile regulation of human skeletal muscle protein synthesis and mTORC1 signalingPhosphocreatine interacts with phospholipids, affects membrane properties and exerts membrane-protective effectsMitochondrial therapy for Parkinson's disease: neuroprotective pharmaconutrition may be disease-modifyingExercise training-induced regulation of mitochondrial qualityL-leucine, beta-hydroxy-beta-methylbutyric acid (HMB) and creatine monohydrate prevent myostatin-induced Akirin-1/Mighty mRNA down-regulation and myotube atrophy.Creatine, L-carnitine, and ω3 polyunsaturated fatty acid supplementation from healthy to diseased skeletal muscle.Skeletal muscle hypertrophy and muscle myostatin reduction after resistive training in stroke survivors.Endurance exercise induces REDD1 expression and transiently decreases mTORC1 signaling in rat skeletal muscle.Interactions of aging, overload, and creatine supplementation in rat plantaris muscleExercise, amino acids, and aging in the control of human muscle protein synthesis.Aerobic exercise + weight loss decreases skeletal muscle myostatin expression and improves insulin sensitivity in older adults.Creatine supplementation enhances muscle force recovery after eccentrically-induced muscle damage in healthy individualsSelective inhibition of ATPase activity during contraction alters the activation of p38 MAP kinase isoforms in skeletal muscle.Muscle expression of genes associated with inflammation, growth, and remodeling is strongly correlated in older adults with resistance training outcomes.Parkinson's disease: mitochondrial molecular pathology, inflammation, statins, and therapeutic neuroprotective nutrition.Effect of nutritional interventions and resistance exercise on aging muscle mass and strength.Characterization and regulation of mechanical loading-induced compensatory muscle hypertrophy.Profiling and quantifying endogenous molecules in single cells using nano-DESI MS.The effect of different acute muscle contraction regimens on the expression of muscle proteolytic signaling proteins and genes.Intramuscular Anabolic Signaling and Endocrine Response Following Resistance Exercise: Implications for Muscle Hypertrophy.Fenugreek increases insulin-stimulated creatine content in L6C11 muscle myotubes.The unfolded protein response is activated in skeletal muscle by high-fat feeding: potential role in the downregulation of protein synthesis.Effects of age and unaccustomed resistance exercise on mitochondrial transcript and protein abundance in skeletal muscle of men.High-power resistance exercise induces MAPK phosphorylation in weightlifting trained men.Changes in resting mitogen-activated protein kinases following resistance exercise overreaching and overtraining.Resistance exercise improves cardiac function and mitochondrial efficiency in diabetic rat hearts.Effect of creatine supplementation during resistance training on lean tissue mass and muscular strength in older adults: a meta-analysis.Effects of dietary creatine supplementation for 8 weeks on neuromuscular coordination and learning in male albino mouse following neonatal hypoxic ischemic insult.Intake of branched-chain or essential amino acids attenuates the elevation in muscle levels of PGC-1α4 mRNA caused by resistance exercise.Histomorphometric analysis of the effects of creatine on rat myometrium.The unfolded protein response is triggered following a single, unaccustomed resistance-exercise bout.Influence of resistance exercise intensity and metabolic stress on anabolic signaling and expression of myogenic genes in skeletal muscle.Impaired exercise-induced mitochondrial biogenesis in the obese Zucker rat, despite PGC-1α induction, is due to compromised mitochondrial translation elongation.Myogenic mRNA markers in young and old human skeletal muscle prior to and following sequential exercise bouts.Efeitos da suplementação de creatina sobre força e hipertrofia muscular: atualizações
P2860
Q24202243-38F416C6-5EE7-4FF1-A5B5-B47AD536A936Q24236598-9F329CF9-A902-414B-9B59-E1604F179759Q24609852-3B4B3EDD-A93F-4B9A-9521-DDC59AD72DE1Q24628688-6B0B9D7C-3779-4301-B5EF-93674E8E5E42Q26764871-2824E44A-D4BA-4A70-A31E-CAE8DCA6C446Q28307009-A09B3582-38A3-41E8-A374-082A2880CC89Q28482353-DA4A4D7B-CF1B-494E-B8EB-60794EF8DB5EQ28732683-A1FCB9B1-7FB9-4ADA-84A2-7205B88B9503Q30418478-481888C6-3534-4624-9074-ED2622B59752Q34052044-0A42B99F-502A-464A-A4BF-530413D6E2B1Q34177044-51FCA81B-1CE5-4538-821D-305841A3D61BQ34520666-02D614C4-D904-4D9E-B236-37F34351AB52Q35094227-72D6CFC6-BC30-468A-84B4-FF031A465740Q35179777-6E5895F3-DADA-44EF-B295-553F88A93384Q35787793-39CA6666-3711-43CD-B20C-50BA0C04E1C5Q37093279-46EDCDE7-8574-4978-9881-E2F246207587Q37229351-53F5D3A2-C00C-4FB3-AE27-119B32A8833FQ37250102-1C6A7442-CE04-4852-9D1A-E9691AFCCA9FQ37265761-8A3E49FC-E7DA-4DA4-82F6-12ADB5320401Q37779428-B3D6AA94-056C-4BE8-B5DB-7FE40E0C01A0Q38017570-ED60E15F-6C71-4076-AB8C-2A03F07B7EADQ38110504-924F5926-6A02-4039-BD14-C4081F2A3326Q38637924-7AD03A00-C613-40B6-ADD7-16CB0E12542EQ38639794-34981360-7FC7-445F-8527-CEBD0533A302Q38669070-974DD7A0-E54D-4DD1-9CE7-04C0CF6CE8DDQ38806389-0079C722-ED60-4E9F-8F11-891292DC389AQ39700372-729D0271-62E1-48AF-9A6E-BA457F0377C9Q41392862-F10CE9E4-F380-4315-B278-5698CC63A4EBQ43554760-45AFB9E4-B4B2-477E-98E3-64910071D96EQ46014188-2DCEF870-C3CE-45F4-8F59-1121A353755AQ46285400-2187F3EF-7036-42D0-9AA0-5CA826497DAAQ47134091-EF023A5D-EA0C-4F62-9587-324F3F96448DQ47696182-3A7A7058-55CF-4378-8E83-855AE13F7D2DQ51728269-D467F1A4-19C8-487E-B2B7-4B1D9888578AQ53669629-256CE161-DD4D-4CAB-B3F0-B28237D39634Q54339096-480BFE11-9E07-43B8-ABF9-F5E81C4AA4FFQ54345624-9FC5014A-ADFF-4EDB-A00B-22F9BA687788Q54386070-B9EB8069-B8A6-4895-A395-0B2C71B6611FQ54387438-99E652C5-F4ED-45EE-A78A-36C23A80F9AFQ57537609-95F4B142-B951-4881-9F5A-58E7E9636F3D
P2860
Effects of resistance exercise with and without creatine supplementation on gene expression and cell signaling in human skeletal muscle.
description
2007 nî lūn-bûn
@nan
2007年の論文
@ja
2007年学术文章
@wuu
2007年学术文章
@zh
2007年学术文章
@zh-cn
2007年学术文章
@zh-hans
2007年学术文章
@zh-my
2007年学术文章
@zh-sg
2007年學術文章
@yue
2007年學術文章
@zh-hant
name
Effects of resistance exercise ...... ling in human skeletal muscle.
@en
Effects of resistance exercise ...... ling in human skeletal muscle.
@nl
type
label
Effects of resistance exercise ...... ling in human skeletal muscle.
@en
Effects of resistance exercise ...... ling in human skeletal muscle.
@nl
prefLabel
Effects of resistance exercise ...... ling in human skeletal muscle.
@en
Effects of resistance exercise ...... ling in human skeletal muscle.
@nl
P2093
P1476
Effects of resistance exercise ...... ling in human skeletal muscle.
@en
P2093
Daniel Theisen
Henri Nielens
Michael J Rennie
Philip Atherton
Rekha Patel
P304
P356
10.1152/JAPPLPHYSIOL.00873.2007
P407
P577
2007-11-29T00:00:00Z