| scholarly article | Q13442814 |
| P50 | author | Blake B. Rasmussen | Q42425454 |
| Elena Volpi | Q53537198 | ||
| Hans C Dreyer | Q92171772 | ||
| P2093 | author name string | Satoshi Fujita | |
| David L Chinkes | |||
| Jerson G Cadenas | |||
| P2860 | cites work | mTOR interacts with raptor to form a nutrient-sensitive complex that signals to the cell growth machinery | Q24302549 |
| The AMP-activated protein kinase--fuel gauge of the mammalian cell? | Q24315074 | ||
| Distinct signaling events downstream of mTOR cooperate to mediate the effects of amino acids and insulin on initiation factor 4E-binding proteins | Q24519078 | ||
| Regulation of elongation factor 2 kinase by p90(RSK1) and p70 S6 kinase. | Q24535599 | ||
| TSC2 mediates cellular energy response to control cell growth and survival | Q27860970 | ||
| AMP-activated protein kinase suppresses protein synthesis in rat skeletal muscle through down-regulated mammalian target of rapamycin (mTOR) signaling | Q28216932 | ||
| Activation of AMP-activated protein kinase leads to the phosphorylation of elongation factor 2 and an inhibition of protein synthesis | Q28218978 | ||
| Stimulation of the AMP-activated protein kinase leads to activation of eukaryotic elongation factor 2 kinase and to its phosphorylation at a novel site, serine 398 | Q28237559 | ||
| The tuberous sclerosis protein TSC2 is not required for the regulation of the mammalian target of rapamycin by amino acids and certain cellular stresses | Q28240102 | ||
| Thr2446 is a novel mammalian target of rapamycin (mTOR) phosphorylation site regulated by nutrient status | Q28245724 | ||
| Rheb binds and regulates the mTOR kinase | Q28247033 | ||
| Redox regulation of the nutrient-sensitive raptor-mTOR pathway and complex | Q28273915 | ||
| AMP-activated protein kinase, a metabolic master switch: possible roles in type 2 diabetes | Q28369312 | ||
| Calmodulin-dependent protein kinase kinase-beta is an alternative upstream kinase for AMP-activated protein kinase | Q28567006 | ||
| Caspase cleavage of initiation factor 4E-binding protein 1 yields a dominant inhibitor of cap-dependent translation and reveals a novel regulatory motif | Q28579562 | ||
| Selective activation of AMPK-PGC-1alpha or PKB-TSC2-mTOR signaling can explain specific adaptive responses to endurance or resistance training-like electrical muscle stimulation | Q28582298 | ||
| Inactivation of acetyl-CoA carboxylase and activation of AMP-activated protein kinase in muscle during exercise | Q28610612 | ||
| Growing roles for the mTOR pathway | Q29616212 | ||
| Branched-chain amino acids increase p70S6k phosphorylation in human skeletal muscle after resistance exercise | Q33976354 | ||
| Analysis of the role of the AMP-activated protein kinase in the response to cellular stress. | Q33979128 | ||
| Ca2+/calmodulin-dependent protein kinase kinase-beta acts upstream of AMP-activated protein kinase in mammalian cells. | Q34438345 | ||
| Regulation of peptide-chain elongation in mammalian cells | Q34992462 | ||
| Contractile and nutritional regulation of human muscle growth | Q35185647 | ||
| Control of muscle protein kinetics by acid-base balance | Q35977143 | ||
| New roles for the LKB1-->AMPK pathway. | Q36076064 | ||
| Effect of exercise on synthesis and degradation of muscle protein | Q41810633 | ||
| Exercise induces isoform-specific increase in 5'AMP-activated protein kinase activity in human skeletal muscle. | Q42490447 | ||
| Response of muscle protein turnover to insulin after acute exercise and training | Q42855078 | ||
| Acute metabolic acidosis decreases muscle protein synthesis but not albumin synthesis in humans | Q43812623 | ||
| Progressive increase in human skeletal muscle AMPKalpha2 activity and ACC phosphorylation during exercise | Q43879217 | ||
| Contribution of insulin to the translational control of protein synthesis in skeletal muscle by leucine | Q43948696 | ||
| Regulation of 5'AMP-activated protein kinase activity and substrate utilization in exercising human skeletal muscle | Q44253307 | ||
| Immediate response of mammalian target of rapamycin (mTOR)-mediated signalling following acute resistance exercise in rat skeletal muscle | Q44560775 | ||
| Effect of exercise intensity on skeletal muscle AMPK signaling in humans | Q44564007 | ||
| Leg glucose and protein metabolism during an acute bout of resistance exercise in humans. | Q44934583 | ||
| Malonyl-CoA and carnitine in regulation of fat oxidation in human skeletal muscle during exercise | Q45071070 | ||
| Akt activates the mammalian target of rapamycin by regulating cellular ATP level and AMPK activity | Q46606786 | ||
| Short-term exercise training in humans reduces AMPK signalling during prolonged exercise independent of muscle glycogen | Q46624502 | ||
| Anabolic signaling and protein synthesis in human skeletal muscle after dynamic shortening or lengthening exercise | Q46786550 | ||
| Increase in S6K1 phosphorylation in human skeletal muscle following resistance exercise occurs mainly in type II muscle fibers | Q46910048 | ||
| Response of protein synthesis to hypercapnia in rats: independent effects of acidosis and hypothermia | Q47771834 | ||
| Acute metabolic acidosis inhibits muscle protein synthesis in rats | Q51020759 | ||
| Effect of exercise intensity on skeletal muscle malonyl-CoA and acetyl-CoA carboxylase | Q51535541 | ||
| Effect of exercise and recovery on muscle protein synthesis in human subjects | Q52471662 | ||
| An oral essential amino acid-carbohydrate supplement enhances muscle protein anabolism after resistance exercise | Q54063913 | ||
| Leg Blood Flow during Exercise in Man | Q54465143 | ||
| The time course for elevated muscle protein synthesis following heavy resistance exercise. | Q55066374 | ||
| Mixed muscle protein synthesis and breakdown after resistance exercise in humans | Q55067147 | ||
| The determination of low d5-phenylalanine enrichment (0.002-0.09 atom percent excess), after conversion to phenylethylamine, in relation to protein turnover studies by gass chromatography/electron ionization mass spectrometry | Q56227948 | ||
| Exercise rapidly increases eukaryotic elongation factor 2 phosphorylation in skeletal muscle of men | Q58172158 | ||
| Early signaling responses to divergent exercise stimuli in skeletal muscle from well-trained humans | Q58449853 | ||
| Metabolic and mitogenic signal transduction in human skeletal muscle after intense cycling exercise | Q58449877 | ||
| Effect of Exercise on Protein Turnover in Man | Q70939134 | ||
| Protein synthesis versus energy state in contracting muscles of perfused rat hindlimb | Q71345508 | ||
| Increased rates of muscle protein turnover and amino acid transport after resistance exercise in humans | Q72655300 | ||
| Postexercise recovery of skeletal muscle malonyl-CoA, acetyl-CoA carboxylase, and AMP-activated protein kinase | Q77520236 | ||
| Phosphorylation of p70(S6k) correlates with increased skeletal muscle mass following resistance exercise | Q77788757 | ||
| P433 | issue | Pt 2 | |
| P407 | language of work or name | English | Q1860 |
| P921 | main subject | phosphorylation | Q242736 |
| P304 | page(s) | 613-624 | |
| P577 | publication date | 2006-07-27 | |
| P1433 | published in | Journal of Physiology | Q7743612 |
| P1476 | title | Resistance exercise increases AMPK activity and reduces 4E-BP1 phosphorylation and protein synthesis in human skeletal muscle | |
| P478 | volume | 576 |
| Q57794858 | A Brief Review on Concurrent Training: From Laboratory to the Field |
| Q28580387 | A Ca(2+)-calmodulin-eEF2K-eEF2 signalling cascade, but not AMPK, contributes to the suppression of skeletal muscle protein synthesis during contractions |
| Q37251400 | A chronic increase in physical activity inhibits fed-state mTOR/S6K1 signaling and reduces IRS-1 serine phosphorylation in rat skeletal muscle. |
| Q33705520 | A comparison of 2H2O and phenylalanine flooding dose to investigate muscle protein synthesis with acute exercise in rats |
| Q37541118 | A metabolic link to skeletal muscle wasting and regeneration |
| Q30514019 | A moderate acute increase in physical activity enhances nutritive flow and the muscle protein anabolic response to mixed nutrient intake in older adults. |
| Q36527961 | AMP kinase activation improves angiogenesis in pulmonary artery endothelial cells with in utero pulmonary hypertension |
| Q46813693 | AMPK activation attenuates S6K1, 4E-BP1, and eEF2 signaling responses to high-frequency electrically stimulated skeletal muscle contractions |
| Q37834161 | AMPK activation, a preventive therapeutic target in the transition from cardiac injury to heart failure |
| Q37386321 | AMPK and the biochemistry of exercise: implications for human health and disease |
| Q47781006 | AMPK in skeletal muscle function and metabolism. |
| Q33976384 | Activation of mTORC1 signaling and protein synthesis in human muscle following blood flow restriction exercise is inhibited by rapamycin. |
| Q42608770 | Acute high-caffeine exposure increases autophagic flux and reduces protein synthesis in C2C12 skeletal myotubes |
| Q35588649 | Acute molecular responses to concurrent resistance and high-intensity interval exercise in untrained skeletal muscle |
| Q47134495 | Acute resistance exercise induces Sestrin2 phosphorylation and p62 dephosphorylation in human skeletal muscle. |
| Q51740157 | Adaptive remodeling of skeletal muscle energy metabolism in high-altitude hypoxia: Lessons from AltitudeOmics |
| Q37017913 | Addition of carbohydrate or alanine to an essential amino acid mixture does not enhance human skeletal muscle protein anabolism |
| Q37339750 | Aerobic exercise overcomes the age-related insulin resistance of muscle protein metabolism by improving endothelial function and Akt/mammalian target of rapamycin signaling |
| Q27024546 | Age effect on myocellular remodeling: response to exercise and nutrition in humans |
| Q55053241 | Age-related differences in lean mass, protein synthesis and skeletal muscle markers of proteolysis after bed rest and exercise rehabilitation. |
| Q42444632 | Age-related differences in the dose-response relationship of muscle protein synthesis to resistance exercise in young and old men. |
| Q36507525 | Aging Reduces the Activation of the mTORC1 Pathway after Resistance Exercise and Protein Intake in Human Skeletal Muscle: Potential Role of REDD1 and Impaired Anabolic Sensitivity |
| Q35033673 | Aging and microRNA expression in human skeletal muscle: a microarray and bioinformatics analysis |
| Q36454435 | Aging differentially affects human skeletal muscle amino acid transporter expression when essential amino acids are ingested after exercise |
| Q37016672 | Aging differentially affects human skeletal muscle microRNA expression at rest and after an anabolic stimulus of resistance exercise and essential amino acids |
| Q35166239 | Aging impairs contraction-induced human skeletal muscle mTORC1 signaling and protein synthesis. |
| Q85030250 | Ambulating With Pulmonary Artery or Femoral Catheters in Place |
| Q33840291 | An increase in essential amino acid availability upregulates amino acid transporter expression in human skeletal muscle |
| Q55107416 | Anabolic Heterogeneity Following Resistance Training: A Role for Circadian Rhythm? |
| Q38693701 | Andrographolide Suppresses MV4-11 Cell Proliferation through the Inhibition of FLT3 Signaling, Fatty Acid Synthesis and Cellular Iron Uptake |
| Q33976336 | Application of the [γ-32P] ATP kinase assay to study anabolic signaling in human skeletal muscle |
| Q35294194 | Association between myosin heavy chain protein isoforms and intramuscular anabolic signaling following resistance exercise in trained men. |
| Q38189267 | Autophagic cellular responses to physical exercise in skeletal muscle. |
| Q27000625 | Autophagy is essential to support skeletal muscle plasticity in response to endurance exercise |
| Q35993635 | Bed rest impairs skeletal muscle amino acid transporter expression, mTORC1 signaling, and protein synthesis in response to essential amino acids in older adults. |
| Q45078495 | Betaine supplementation enhances anabolic endocrine and Akt signaling in response to acute bouts of exercise |
| Q33841125 | Blood flow restriction exercise stimulates mTORC1 signaling and muscle protein synthesis in older men |
| Q35902939 | Both resistance- and endurance-type exercise reduce the prevalence of hyperglycaemia in individuals with impaired glucose tolerance and in insulin-treated and non-insulin-treated type 2 diabetic patients |
| Q36934986 | Cancer cachexia prevention via physical exercise: molecular mechanisms |
| Q39043465 | Carbohydrate intake and resistance-based exercise: are current recommendations reflective of actual need? |
| Q38110504 | Characterization and Regulation of Mechanical Loading‐Induced Compensatory Muscle Hypertrophy |
| Q28565436 | Chronic paraplegia-induced muscle atrophy downregulates the mTOR/S6K1 signaling pathway |
| Q36309131 | Co-ingestion of carbohydrate and whey protein increases fasted rates of muscle protein synthesis immediately after resistance exercise in rats |
| Q47388796 | Combined effects of low-intensity blood flow restriction training and high-intensity resistance training on muscle strength and size |
| Q38421077 | Comparative effects of whey protein versus L-leucine on skeletal muscle protein synthesis and markers of ribosome biogenesis following resistance exercise |
| Q28267408 | Comparison of availability and plasma clearance rates of β-hydroxy-β-methylbutyrate delivery in the free acid and calcium salt forms |
| Q34616237 | Comparison of bolus injection and constant infusion methods for measuring muscle protein fractional synthesis rate in humans |
| Q53130147 | Concurrent exercise incorporating high-intensity interval or continuous training modulates mTORC1 signaling and microRNA expression in human skeletal muscle |
| Q38923257 | Concurrent exercise training: do opposites distract? |
| Q51412357 | Contraction intensity and feeding affect collagen and myofibrillar protein synthesis rates differently in human skeletal muscle |
| Q83189082 | Contraction-induced changes in TNFalpha and Akt-mediated signalling are associated with increased myofibrillar protein in rat skeletal muscle |
| Q39974546 | Decrease in Akt/PKB signalling in human skeletal muscle by resistance exercise |
| Q52605239 | Dietary protein and exercise training in ageing |
| Q61788535 | Differential effects of resistance and endurance exercise in the fed state on signalling molecule phosphorylation and protein synthesis in human muscle |
| Q46246829 | Differential stimulation of myofibrillar and sarcoplasmic protein synthesis with protein ingestion at rest and after resistance exercise |
| Q37137271 | Does AMP-activated protein kinase negatively mediate aged fast-twitch skeletal muscle mass? |
| Q37985564 | Does Exercise-Induced Muscle Damage Play a Role in Skeletal Muscle Hypertrophy? |
| Q55431394 | Effect of 8-week leucine supplementation and resistance exercise training on muscle hypertrophy and satellite cell activation in rats. |
| Q48005675 | Effect of acute treadmill exercise on cisplatin-induced muscle atrophy in the mouse |
| Q93224066 | Effect of eccentric action velocity on expression of genes related to myostatin signaling pathway in human skeletal muscle |
| Q58556360 | Effect of exercise modality on markers of insulin sensitivity and blood glucose control in pregnancies complicated with gestational diabetes mellitus: a systematic review |
| Q30383045 | Effects of Arachidonic Acid Supplementation on Acute Anabolic Signaling and Chronic Functional Performance and Body Composition Adaptations. |
| Q58750306 | Effects of Protein Supplementation on Performance and Recovery in Resistance and Endurance Training |
| Q33638591 | Effects of alfa-hydroxy-isocaproic acid on body composition, DOMS and performance in athletes. |
| Q28109460 | Effects of contraction and insulin on protein synthesis, AMP-activated protein kinase and phosphorylation state of translation factors in rat skeletal muscle |
| Q41999349 | Effects of leucine supplementation and resistance training on myopathy of diabetic rats |
| Q42173246 | Effects of treadmill exercise on skeletal muscle mTOR signaling pathway in high-fat diet-induced obese mice |
| Q47969599 | Electrical pulse stimulation: an in vitro exercise model for the induction of human skeletal muscle cell hypertrophy. A proof-of-concept study |
| Q35094227 | Endurance exercise induces REDD1 expression and transiently decreases mTORC1 signaling in rat skeletal muscle |
| Q95660532 | Enhanced skeletal muscle insulin sensitivity after acute resistance-type exercise is upregulated by rapamycin-sensitive mTOR complex 1 inhibition |
| Q37190170 | Essential amino acid and carbohydrate ingestion before resistance exercise does not enhance postexercise muscle protein synthesis |
| Q33660488 | Essential amino acid ingestion alters expression of genes associated with amino acid sensing, transport, and mTORC1 regulation in human skeletal muscle. |
| Q43419044 | Eukaryotic initiation factor 2B epsilon induces cap-dependent translation and skeletal muscle hypertrophy |
| Q34204391 | Excess leucine intake enhances muscle anabolic signaling but not net protein anabolism in young men and women |
| Q55030690 | Exercise and Nutrition Strategies to Counteract Sarcopenic Obesity. |
| Q92518945 | Exercise and Sirtuins: A Way to Mitochondrial Health in Skeletal Muscle |
| Q38017323 | Exercise intensity and muscle hypertrophy in blood flow–restricted limbs and non‐restricted muscles: a brief review |
| Q35787793 | Exercise, amino acids, and aging in the control of human muscle protein synthesis. |
| Q54385382 | Exercise-induced AMPK activation does not interfere with muscle hypertrophy in response to resistance training in men. |
| Q37233128 | Expression of growth-related genes in young and older human skeletal muscle following an acute stimulation of protein synthesis |
| Q34153509 | Free acid gel form of β-hydroxy-β-methylbutyrate (HMB) improves HMB clearance from plasma in human subjects compared with the calcium HMB salt. |
| Q54491763 | Genetic Strain-Dependent Protein Metabolism and Muscle Hypertrophy Under Chronic Isometric Training in Rat Gastrocnemius Muscle |
| Q34464470 | Heat shock response and autophagy--cooperation and control |
| Q54620933 | Heat stress enhances mTOR signaling after resistance exercise in human skeletal muscle |
| Q54334425 | High force development augments skeletal muscle signalling in resistance exercise modes equalized for time under tension. |
| Q30729568 | How to explain exercise-induced phenotype from molecular data: rethink and reconstruction based on AMPK and mTOR signaling |
| Q27693892 | Human muscle protein turnover—why is it so variable? |
| Q37710664 | Humanin skeletal muscle protein levels increase after resistance training in men with impaired glucose metabolism |
| Q46291569 | Immobilization induces anabolic resistance in human myofibrillar protein synthesis with low and high dose amino acid infusion |
| Q54608690 | Impact of protein coingestion on muscle protein synthesis during continuous endurance type exercise. |
| Q45013210 | Increased net muscle protein balance in response to simultaneous and separate ingestion of carbohydrate and essential amino acids following resistance exercise. |
| Q43148361 | Increased p70s6k phosphorylation during intake of a protein-carbohydrate drink following resistance exercise in the fasted state. |
| Q26748964 | Influence of Acute and Chronic Exercise on Glucose Uptake |
| Q27003307 | Influence of Amino Acids, Dietary Protein, and Physical Activity on Muscle Mass Development in Humans |
| Q47799259 | Influence of past injurious exercise on fiber type-specific acute anabolic response to resistance exercise in skeletal muscle. |
| Q54345624 | Influence of resistance exercise intensity and metabolic stress on anabolic signaling and expression of myogenic genes in skeletal muscle. |
| Q39634846 | 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. |
| Q34032001 | Insulin stimulates human skeletal muscle protein synthesis via an indirect mechanism involving endothelial-dependent vasodilation and mammalian target of rapamycin complex 1 signaling |
| Q42251241 | Intake of a Ketone Ester Drink during Recovery from Exercise Promotes mTORC1 Signaling but Not Glycogen Resynthesis in Human Muscle |
| Q51728269 | Intake of branched-chain or essential amino acids attenuates the elevation in muscle levels of PGC-1α4 mRNA caused by resistance exercise. |
| Q34485229 | Intense resistance exercise induces early and transient increases in ryanodine receptor 1 phosphorylation in human skeletal muscle |
| Q36620195 | Interactions between exercise and nutrition to prevent muscle waste during ageing |
| Q38204299 | Interference between concurrent resistance and endurance exercise: molecular bases and the role of individual training variables |
| Q38669070 | Intramuscular Anabolic Signaling and Endocrine Response Following Resistance Exercise: Implications for Muscle Hypertrophy |
| Q90151151 | Ketogenic Diet and Skeletal Muscle Hypertrophy: A Frenemy Relationship? |
| Q37383513 | LKB1 and AMP-activated protein kinase control of mTOR signalling and growth |
| Q64083817 | Lactate production without hypoxia in skeletal muscle during electrical cycling: Crossover study of femoral venous-arterial differences in healthy volunteers |
| Q36521506 | Leucine partially protects muscle mass and function during bed rest in middle-aged adults |
| Q34330791 | Leucine-enriched amino acid ingestion after resistance exercise prolongs myofibrillar protein synthesis and amino acid transporter expression in older men. |
| Q37251386 | Leucine-enriched essential amino acid and carbohydrate ingestion following resistance exercise enhances mTOR signaling and protein synthesis in human muscle. |
| Q40593691 | Leucine-enriched essential amino acids attenuate muscle soreness and improve muscle protein synthesis after eccentric contractions in rats |
| Q37135107 | Leucine-enriched nutrients and the regulation of mammalian target of rapamycin signalling and human skeletal muscle protein synthesis |
| Q48155681 | Linking Cancer Cachexia-Induced Anabolic Resistance to Skeletal Muscle Oxidative Metabolism. |
| Q38614834 | Low Skeletal Muscle Mass is Associated with the Risk of Low Bone Mineral Density in Urban Dwelling Premenopausal Women. |
| Q33658994 | Low-load high volume resistance exercise stimulates muscle protein synthesis more than high-load low volume resistance exercise in young men. |
| Q36178553 | MAFbx, MuRF1, and the stress-activated protein kinases are upregulated in muscle cells during total knee arthroplasty |
| Q39262984 | MYC and AMPK-Save Energy or Die! |
| Q34802103 | Mammalian target of rapamycin complex 1 activation is required for the stimulation of human skeletal muscle protein synthesis by essential amino acids |
| Q53687296 | May the force be with you: why resistance training is essential for subjects with type 2 diabetes mellitus without complications |
| Q38383123 | Mechanical cues in orofacial tissue engineering and regenerative medicine. |
| Q92628963 | Mechanical loading stimulates hypertrophy in tissue-engineered skeletal muscle: Molecular and phenotypic responses |
| Q36973429 | Mechanical stimuli of skeletal muscle: implications on mTOR/p70s6k and protein synthesis. |
| Q28079049 | Mechanosensitive Molecular Networks Involved in Transducing Resistance Exercise-Signals into Muscle Protein Accretion |
| Q38922063 | Mixed lactate and caffeine compound increases satellite cell activity and anabolic signals for muscle hypertrophy. |
| Q64257830 | Moderate-intensity aerobic exercise improves skeletal muscle quality in older adults |
| Q37486043 | Molecular responses to high-intensity interval exercise |
| Q37485998 | Molecular responses to strength and endurance training: are they incompatible? |
| Q42365569 | Molecular, neuromuscular, and recovery responses to light versus heavy resistance exercise in young men. |
| Q54978305 | Muscle Protein Anabolic Resistance to Essential Amino Acids Does Not Occur in Healthy Older Adults Before or After Resistance Exercise Training. |
| Q34085586 | Muscle protein breakdown has a minor role in the protein anabolic response to essential amino acid and carbohydrate intake following resistance exercise. |
| Q43819395 | Muscle size and arterial stiffness after blood flow‐restricted low‐intensity resistance training in older adults |
| Q46703582 | Muscle time under tension during resistance exercise stimulates differential muscle protein sub-fractional synthetic responses in men. |
| Q34579211 | Nutrient signalling in the regulation of human muscle protein synthesis |
| Q28307009 | Nutritional and contractile regulation of human skeletal muscle protein synthesis and mTORC1 signaling |
| Q36948650 | Nutritional interventions to promote post-exercise muscle protein synthesis. |
| Q50421405 | Paralytic and non-paralytic muscle adaptations to exercise training vs. high protein diet in individuals with long-standing spinal cord injury |
| Q42425417 | Paraplegia increases skeletal muscle autophagy |
| Q84229953 | Phosphatidic acid: a novel mechanical mechanism for how resistance exercise activates mTORC1 signalling |
| Q37486029 | Physiologic and molecular bases of muscle hypertrophy and atrophy: impact of resistance exercise on human skeletal muscle (protein and exercise dose effects). |
| Q48141398 | Post-absorptive muscle protein turnover affects resistance training hypertrophy. |
| Q34485018 | Post-exercise cold water immersion attenuates acute anabolic signalling and long-term adaptations in muscle to strength training |
| Q38479055 | Post-exercise impact of ingested whey protein hydrolysate on gene expression profiles in rat skeletal muscle: activation of extracellular signal-regulated kinase 1/2 and hypoxia-inducible factor-1α. |
| Q33793228 | Post-exercise protein synthesis rates are only marginally higher in type I compared with type II muscle fibres following resistance-type exercise |
| Q79233726 | Predominant alpha2/beta2/gamma3 AMPK activation during exercise in human skeletal muscle |
| Q26749616 | Protein Considerations for Optimising Skeletal Muscle Mass in Healthy Young and Older Adults |
| Q37082292 | Protein blend ingestion following resistance exercise promotes human muscle protein synthesis |
| Q46631241 | Protein coingestion stimulates muscle protein synthesis during resistance-type exercise |
| Q37370849 | Protein turnover, amino acid requirements and recommendations for athletes and active populations |
| Q37175505 | Proteins regulating cap-dependent translation are downregulated during total knee arthroplasty |
| Q47753820 | Randomized, four-arm, dose-response clinical trial to optimize resistance exercise training for older adults with age-related muscle atrophy. |
| Q46135983 | Rapamycin administration in humans blocks the contraction-induced increase in skeletal muscle protein synthesis |
| Q36924317 | Rapamycin does not affect post-absorptive protein metabolism in human skeletal muscle |
| Q54617034 | Rapid induction of REDD1 expression by endurance exercise in rat skeletal muscle |
| Q35994715 | Reactive hyperemia is not responsible for stimulating muscle protein synthesis following blood flow restriction exercise |
| Q92723887 | Recent Data on Cellular Component Turnover: Focus on Adaptations to Physical Exercise |
| Q36781795 | Reduced AMPK-ACC and mTOR signaling in muscle from older men, and effect of resistance exercise. |
| Q35583549 | Regulation of survival gene hsp70 |
| Q37346834 | Regulatory mechanisms of skeletal muscle protein turnover during exercise. |
| Q50879152 | Relationship between exercise volume and muscle protein synthesis in a rat model of resistance exercise |
| Q47129256 | Repeated bouts of resistance exercise with short recovery periods activates mTOR signaling, but not protein synthesis, in mouse skeletal muscle. |
| Q34707947 | Repeated resistance exercise training induces different changes in mRNA expression of MAFbx and MuRF-1 in human skeletal muscle. |
| Q35773058 | Resistance Exercise Training Alters Mitochondrial Function in Human Skeletal Muscle. |
| Q33732617 | Resistance Training for Glycemic Control, Muscular Strength, and Lean Body Mass in Old Type 2 Diabetic Patients: A Meta-Analysis |
| Q37638217 | Resistance exercise and nutrition to counteract muscle wasting |
| Q46537256 | Resistance exercise biology: manipulation of resistance exercise programme variables determines the responses of cellular and molecular signalling pathways |
| Q54568265 | Resistance exercise enhances the molecular signaling of mitochondrial biogenesis induced by endurance exercise in human skeletal muscle |
| Q37033519 | Resistance exercise increases human skeletal muscle AS160/TBC1D4 phosphorylation in association with enhanced leg glucose uptake during postexercise recovery. |
| Q33895553 | Resistance exercise increases leg muscle protein synthesis and mTOR signalling independent of sex |
| Q43788186 | Resistance exercise induced mTORC1 signaling is not impaired by subsequent endurance exercise in human skeletal muscle |
| Q38685326 | Resistance exercise initiates mechanistic target of rapamycin (mTOR) translocation and protein complex co-localisation in human skeletal muscle |
| Q51905788 | Resistance exercise-induced increase in muscle mass correlates with p70S6 kinase phosphorylation in human subjects. |
| Q41851925 | Resistance training for diabetes prevention and therapy: experimental findings and molecular mechanisms |
| Q36498001 | Role of Ingested Amino Acids and Protein in the Promotion of Resistance Exercise-Induced Muscle Protein Anabolism. |
| Q38128640 | Role of stearoyl-CoA desaturase-1 in skeletal muscle function and metabolism |
| Q46034890 | Rosiglitazone-induced heart remodelling is associated with enhanced turnover of myofibrillar protein and mTOR activation. |
| Q36952785 | Safety and Efficacy of Mobility Interventions in Patients with Femoral Catheters in the ICU: A Prospective Observational Study |
| Q36633369 | Sake Protein Supplementation Affects Exercise Performance and Biochemical Profiles in Power-Exercise-Trained Mice |
| Q36956001 | Sequential muscle biopsies during a 6-h tracer infusion do not affect human mixed muscle protein synthesis and muscle phenylalanine kinetics. |
| Q46066667 | Sirolimus and mTORC1: centre stage in the story of what makes muscles bigger? |
| Q50228186 | Skeletal Muscle Hypertrophy with Concurrent Exercise Training: Contrary Evidence for an Interference Effect |
| Q37395559 | Skeletal Muscle Protein Balance and Metabolism in the Elderly |
| Q34036589 | Skeletal muscle Ras-related GTP binding B mRNA and protein expression is increased after essential amino acid ingestion in healthy humans |
| Q35108785 | Skeletal muscle amino acid transporter expression is increased in young and older adults following resistance exercise. |
| Q36758018 | Skeletal muscle autophagy and protein breakdown following resistance exercise are similar in younger and older adults |
| Q43827533 | Skeletal muscle eEF2 and 4EBP1 phosphorylation during endurance exercise is dependent on intensity and muscle fiber type |
| Q47450273 | Skeletal muscle performance and ageing |
| Q37273785 | Skeletal muscle protein anabolic response to resistance exercise and essential amino acids is delayed with aging |
| Q35447810 | Skeletal muscle protein metabolism in the elderly: Interventions to counteract the 'anabolic resistance' of ageing |
| Q33816833 | Skeletal muscle signaling associated with impaired glucose tolerance in spinal cord-injured men and the effects of contractile activity |
| Q39231283 | Soy-Dairy Protein Blend or Whey Protein Isolate Ingestion Induces Similar Postexercise Muscle Mechanistic Target of Rapamycin Complex 1 Signaling and Protein Synthesis Responses in Older Men. |
| Q33708188 | Soy-dairy protein blend and whey protein ingestion after resistance exercise increases amino acid transport and transporter expression in human skeletal muscle. |
| Q37863056 | Stretching skeletal muscle in vitro: does it replicate in vivo physiology? |
| Q33745051 | Supraphysiological hyperinsulinaemia is necessary to stimulate skeletal muscle protein anabolism in older adults: evidence of a true age-related insulin resistance of muscle protein metabolism. |
| Q36246665 | Targeting anabolic impairment in response to resistance exercise in older adults with mobility impairments: potential mechanisms and rehabilitation approaches. |
| Q36119634 | The Differential Hormonal Milieu of Morning versus Evening May Have an Impact on Muscle Hypertrophic Potential |
| Q92087685 | The Psychiatric Risk Gene NT5C2 Regulates Adenosine Monophosphate-Activated Protein Kinase Signaling and Protein Translation in Human Neural Progenitor Cells |
| Q42838952 | The acute effects of strength, endurance and concurrent exercises on the Akt/mTOR/p70(S6K1) and AMPK signaling pathway responses in rat skeletal muscle |
| Q35759869 | The anabolic response to resistance exercise and a protein-rich meal is not diminished by age |
| Q42975275 | The degree of p70 S6k and S6 phosphorylation in human skeletal muscle in response to resistance exercise depends on the training volume |
| Q47250783 | The development of skeletal muscle hypertrophy through resistance training: the role of muscle damage and muscle protein synthesis. |
| Q38639794 | The effect of different acute muscle contraction regimens on the expression of muscle proteolytic signaling proteins and genes. |
| Q45938844 | The effect of electrical muscle stimulation on the prevention of disuse muscle atrophy in patients with consciousness disturbance in the intensive care unit |
| Q35913175 | The effect of exercise on expression of myokine and angiogenesis mRNA in skeletal muscle of high fat diet induced obese rat. |
| Q33844350 | The effects of age and muscle contraction on AMPK activity and heterotrimer composition |
| Q64114699 | The effects of resistance training on bone mineral density and bone quality in type 2 diabetic rats |
| Q38569753 | The metabolic and temporal basis of muscle hypertrophy in response to resistance exercise |
| Q36920587 | The molecular bases of training adaptation |
| Q51481701 | The muscle‐hypertrophic effect of clenbuterol is additive to the hypertrophic effect of myostatin suppression |
| Q52638050 | The putative leucine sensor Sestrin2 is hyperphosphorylated by acute resistance exercise but not protein ingestion in human skeletal muscle. |
| Q39501565 | The response of muscle protein synthesis following whole-body resistance exercise is greater following 40 g than 20 g of ingested whey protein |
| Q37160004 | The role of mTOR signalling in the regulation of skeletal muscle mass in a rodent model of resistance exercise. |
| Q38179978 | The role of mTORC1 in regulating protein synthesis and skeletal muscle mass in response to various mechanical stimuli. |
| Q34108429 | The role of milk- and soy-based protein in support of muscle protein synthesis and muscle protein accretion in young and elderly persons |
| Q45995855 | The role of phosphoinositide 3-kinase and phosphatidic acid in the regulation of mammalian target of rapamycin following eccentric contractions. |
| Q37043350 | The serine protease, dipeptidyl peptidase IV as a myokine: dietary protein and exercise mimetics as a stimulus for transcription and release |
| Q57577236 | Timing and distribution of protein ingestion during prolonged recovery from resistance exercise alters myofibrillar protein synthesis |
| Q51385155 | Training in the fasted state facilitates re-activation of eEF2 activity during recovery from endurance exercise. |
| Q37422140 | Translational signaling responses preceding resistance training-mediated myofiber hypertrophy in young and old humans |
| Q44820634 | Vitamin C administration attenuates overload‐induced skeletal muscle hypertrophy in rats |
| Q28384458 | Vitamin C and E supplementation alters protein signalling after a strength training session, but not muscle growth during 10 weeks of training |
| Q40377091 | Whey protein ingestion activates mTOR-dependent signalling after resistance exercise in young men: a double-blinded randomized controlled trial |
| Q87025443 | Whey protein intake after resistance exercise activates mTOR signaling in a dose-dependent manner in human skeletal muscle |
| Q90136344 | Whey protein sweetened with Stevia rebaudiana Bertoni (Bert.) increases mitochondrial biogenesis markers in the skeletal muscle of resistance-trained rats |
| Q37638216 | mTOR function in skeletal muscle: a focal point for overnutrition and exercise |
| Q38003176 | mTORC1 and the regulation of skeletal muscle anabolism and mass |
Search more.