Influence of muscle glycogen availability on ERK1/2 and Akt signaling after resistance exercise in human skeletal muscle.
about
Glycogen availability and skeletal muscle adaptations with endurance and resistance exerciseEfficacy and consequences of very-high-protein diets for athletes and exercisersNutritional and contractile regulation of human skeletal muscle protein synthesis and mTORC1 signalingLow-load high volume resistance exercise stimulates muscle protein synthesis more than high-load low volume resistance exercise in young men.Resistance exercise, skeletal muscle FOXO3A, and 85-year-old womenThe order of exercise during concurrent training for rehabilitation does not alter acute genetic expression, mitochondrial enzyme activity or improvements in muscle functionRepeated resistance exercise training induces different changes in mRNA expression of MAFbx and MuRF-1 in human skeletal muscle.Promoting training adaptations through nutritional interventions.Nutrient timing revisited: is there a post-exercise anabolic window?Nutrition for the sprinter.Nutritional strategies to optimize training and racing in middle-distance athletes.Innovations in athletic preparation: role of substrate availability to modify training adaptation and performance.Molecular responses to strength and endurance training: are they incompatible?Strategies to optimize concurrent training of strength and aerobic fitness for rowing and canoeing.Characterization and regulation of mechanical loading-induced compensatory muscle hypertrophy.Dietary strategies to recover from exercise-induced muscle damage.Carbohydrate intake and resistance-based exercise: are current recommendations reflective of actual need?Ingestion of 10 grams of whey protein prior to a single bout of resistance exercise does not augment Akt/mTOR pathway signaling compared to carbohydrate.Fuel for the work required: a practical approach to amalgamating train-low paradigms for endurance athletes.The effect of concurrent training organisation in youth elite soccer players.COX Inhibitor Influence on Skeletal Muscle Fiber Size and Metabolic Adaptations to Resistance Exercise in Older Adults.Molecular, neuromuscular, and recovery responses to light versus heavy resistance exercise in young men.Role of Akt2 in contraction-stimulated cell signaling and glucose uptake in skeletal muscle.Resistance exercise volume affects myofibrillar protein synthesis and anabolic signalling molecule phosphorylation in young men.Basal and insulin-stimulated pyruvate dehydrogenase complex activation, glycogen synthesis and metabolic gene expression in human skeletal muscle the day after a single bout of exercise.Effects of exercise on muscle glycogen synthesis signalling and enzyme activities in pigs carrying the PRKAG3 mutation.Elevation of myostatin and FOXOs in prolonged muscular impairment induced by eccentric contractions in rat medial gastrocnemius muscle.Hamstring injury prevention in soccer: Before or after training?Impact of local heating and cooling on skeletal muscle transcriptional response related to myogenesis and proteolysis.Metabolic and molecular changes associated with the increased skeletal muscle insulin action 24-48 h after exercise in young and old humans.Is sprint exercise a leptin signaling mimetic in human skeletal muscle?Concurrent exercise incorporating high-intensity interval or continuous training modulates mTORC1 signaling and microRNA expression in human skeletal muscle.A putative low-carbohydrate ketogenic diet elicits mild nutritional ketosis but does not impair the acute or chronic hypertrophic responses to resistance exercise in rodents.Influence of resistance exercise intensity and metabolic stress on anabolic signaling and expression of myogenic genes in skeletal muscle.Exercise-induced AMPK activation does not interfere with muscle hypertrophy in response to resistance training in men.Heat stress enhances mTOR signaling after resistance exercise in human skeletal muscle.Fat adaptation followed by carbohydrate restoration increases AMPK activity in skeletal muscle from trained humans
P2860
Q26772305-3997C040-EF29-4E8E-BF07-F2C1DBA783ACQ28306553-275F2FCB-BD60-40B5-8473-9ACA22090F36Q28307009-DE4403E1-666F-433C-9F5E-0477E336E2C3Q33658994-31EDAC37-1541-4409-A956-BB40B081096AQ33747562-AAAA3AAB-CDB6-4D79-ACF9-201B59C6D014Q34301737-BCC7385E-CF9D-4337-A0D2-C7F141BEFA22Q34707947-7CA79D79-CAB9-43F6-95CD-34409890EAF2Q36502971-E2CF1576-3BB5-46B3-B056-CB35272B7FB2Q36624203-E6F95BE8-4D9B-4E6E-B599-A0170C3337FAQ37020217-E070115D-A8AF-4B45-9C9F-6F536EE58A81Q37020222-7A317C92-B828-4AD5-8B7E-784D0DA066C1Q37020254-E80BA9FC-5055-48C5-A46B-C15A083B999EQ37485998-A0A2EE8E-E503-4AEE-B2E4-28998F762AE0Q37855786-55E08BE8-BBD0-41EC-B9CA-EE9D8BB6B9F6Q38110504-A4E74B06-3FCB-4E45-BDFF-1E9A731A6819Q38158175-20E13205-03AC-45EB-9D38-04399C6BAFFDQ39043465-DB8A0DB1-94CD-499E-B6A6-51548A84CE12Q39634846-DE2D70F7-C6A6-4E36-A785-DE03CBD03598Q39736012-0C7540AF-DE3A-4023-B2A1-9BE3CA6EE052Q40721214-3022BB78-A19F-4717-AA22-7D5C001CF137Q41648155-2B6D9304-8BD3-4117-946C-697BBFB913E5Q42365569-4E35D1D3-6F13-472F-8D64-E1B9EC3A481FQ42497456-20751D5F-BDED-47C3-A649-B269B746575EQ43004353-6A985208-C654-48FE-9E9C-CBE082592BAFQ43103744-BB00AB2F-D1BC-48FB-8892-1F2DB4B8A099Q43211417-186EB28C-30C1-4551-B1C7-AA8E8C985E76Q43230270-AE619486-58C5-4FB4-8E6F-A93AD63C0672Q47855087-D4DEB7BF-9F1B-4C63-8F4F-543528DCBA63Q48108733-CDC0A372-FA26-42DE-A45C-E57D6B3CB076Q50058797-FC44AD35-C63F-4BD6-AF26-CC8F7C464181Q51372261-DECE3105-584F-4D72-8EF7-D35DB897422FQ53130147-B79349F8-D36D-4694-AE79-C3D69E751A22Q53803173-DB6A8F12-958B-407D-853C-B8A43EE75270Q54345624-4AD2CA41-D6B4-46CE-A683-5786CEC0CA39Q54385382-50C01E7B-9920-487E-BFC2-0BCEFFEB1FCEQ54620933-BDC9EBD3-3284-4B95-BBA8-0EBF14C5D0F3Q57577406-3979AD67-F899-4B13-9170-FC28EB5AE8ED
P2860
Influence of muscle glycogen availability on ERK1/2 and Akt signaling after resistance exercise in human skeletal muscle.
description
2005 nî lūn-bûn
@nan
2005年の論文
@ja
2005年学术文章
@wuu
2005年学术文章
@zh
2005年学术文章
@zh-cn
2005年学术文章
@zh-hans
2005年学术文章
@zh-my
2005年学术文章
@zh-sg
2005年學術文章
@yue
2005年學術文章
@zh-hant
name
Influence of muscle glycogen a ...... cise in human skeletal muscle.
@en
Influence of muscle glycogen a ...... cise in human skeletal muscle.
@nl
type
label
Influence of muscle glycogen a ...... cise in human skeletal muscle.
@en
Influence of muscle glycogen a ...... cise in human skeletal muscle.
@nl
prefLabel
Influence of muscle glycogen a ...... cise in human skeletal muscle.
@en
Influence of muscle glycogen a ...... cise in human skeletal muscle.
@nl
P2093
P2860
P1476
Influence of muscle glycogen a ...... cise in human skeletal muscle.
@en
P2093
Andrew Creer
Bozena Jemiolo
Dustin Slivka
Scott Trappe
William Fink
P2860
P304
P356
10.1152/JAPPLPHYSIOL.00110.2005
P407
P577
2005-05-05T00:00:00Z