Tricarboxylic acid cycle intermediates in human muscle during prolonged exercise.
about
Born to run; the story of the PEPCK-Cmus mouseCitrulline/malate promotes aerobic energy production in human exercising muscleMyoadenylate deaminase deficiency does not affect muscle anaplerosis during exhaustive exercise in humansDeamination of amino acids as a source for ammonia production in human skeletal muscle during prolonged exerciseMetabolic dynamics in skeletal muscle during acute reduction in blood flow and oxygen supply to mitochondria: in-silico studies using a multi-scale, top-down integrated modelOverexpression of the cytosolic form of phosphoenolpyruvate carboxykinase (GTP) in skeletal muscle repatterns energy metabolism in the mouseThe key role of anaplerosis and cataplerosis for citric acid cycle function.Metabolic signatures of exercise in human plasmaExercise-induced immunodepression- plasma glutamine is not the link.Effects of dietary glutamine supplementation on the body composition and protein status of early-weaned mice inoculated with Mycobacterium bovis Bacillus Calmette-GuerinNAD(+)/NADH and skeletal muscle mitochondrial adaptations to exercise.Control of respiration and ATP synthesis in mammalian mitochondria and cellsEffects of Citric Acid and l-Carnitine on Physical Fatigue.Diurnal variation of phenylalanine and tyrosine concentrations in adult patients with phenylketonuria: subcutaneous microdialysis is no adequate tool for the determination of amino acid concentrationsOsteocalcin Signaling in Myofibers Is Necessary and Sufficient for Optimum Adaptation to ExerciseRole of NADH/NAD+ transport activity and glycogen store on skeletal muscle energy metabolism during exercise: in silico studiesWhat is the metabolic role of phosphoenolpyruvate carboxykinase?Sports Ultrasound: Applications Beyond the Musculoskeletal SystemThe Pancreatic β-Cell: A Bioenergetic Perspective.Skeletal muscle energy metabolism during prolonged, fatiguing exercise.Effect of carbohydrate ingestion on glucose kinetics and muscle metabolism during intense endurance exercise.Glycogen availability does not affect the TCA cycle or TAN pools during prolonged, fatiguing exercise.Single sodium pyruvate ingestion modifies blood acid-base status and post-exercise lactate concentration in humans.Comparison of amino acid profiles between rats subjected to forced running and voluntary running exercises.Effects of Supplementation with BCAA and L-glutamine on Blood Fatigue Factors and Cytokines in Juvenile Athletes Submitted to Maximal Intensity Rowing Performance.Reduced glycogen availability is associated with an elevation in HSP72 in contracting human skeletal muscle.Exercise with low muscle glycogen augments TCA cycle anaplerosis but impairs oxidative energy provision in humans.Effects of glucose on contractile function, [Ca2+]i, and glycogen in isolated mouse skeletal muscle.Skeletal muscle metabolism is unaffected by DCA infusion and hyperoxia after onset of intense aerobic exercise.Lactate metabolism in resting and contracting canine skeletal muscle with elevated lactate concentration.Dissociation between muscle tricarboxylic acid cycle pool size and aerobic energy provision during prolonged exercise in humans.Relative rates of anaplerotic flux in rested and contracted rat skeletal muscle measured by 13C NMR spectroscopy.Short-term training attenuates muscle TCA cycle expansion during exercise in women.Pyruvate and citric acid cycle carbon requirements in isolated skeletal muscle mitochondria.Effect of endurance training on muscle TCA cycle metabolism during exercise in humans.Regulation of pyruvate dehydrogenase activity and citric acid cycle intermediates during high cardiac power generation.An acute decrease in TCA cycle intermediates does not affect aerobic energy delivery in contracting rat skeletal muscle.Hyperammonaemia-induced skeletal muscle mitochondrial dysfunction results in cataplerosis and oxidative stress.Glutamate availability is important in intramuscular amino acid metabolism and TCA cycle intermediates but does not affect peak oxidative metabolism.A pilot study comparing the metabolic profiles of elite-level athletes from different sporting disciplines.
P2860
Q24652743-007D1848-2B7D-4752-A39F-105153DF8D14Q24672673-DFCFA7F3-15D1-43B4-B25B-C9847D90D33FQ28366955-F57B57D2-4820-4601-9A35-066D4A768F93Q28378781-93E18DC5-4491-4EC2-B8C5-15EA67ED95D5Q28473577-F855C947-C82A-4736-BDE6-AC5B45002981Q30655980-1DFCE2B4-9CA6-4174-9CB0-A756E279BEF3Q34135762-0B3B3019-C491-4C27-AA6D-2C1E04DF044EQ34441396-191EE9E8-7C78-4B33-A32A-651D9BDEC15AQ34787107-A670DC74-F37D-4074-AC06-265F49B3B2DBQ35671168-0A091D8E-837E-4F59-B66A-680B269BCF23Q36176007-2C5CA756-7C42-4BE8-AD41-D51710C29DA6Q36182305-F11516BE-CB96-48D6-AB9A-973565A36A43Q36460014-25138616-7949-428D-9908-3A3B0D7AEB6FQ36863535-D85D1212-87F3-4A84-B140-2EBBCC8BB479Q37012238-FF0C8ECF-AEA9-4D68-86D2-1E97BC871BBCQ37086464-83CE9E9B-71FB-4F83-B112-74B8755D435FQ37447862-A46B274D-41D6-4335-B2BE-21A68613879FQ38926271-2AEAA358-EB8A-42AC-9215-2AE7428F09B6Q38943061-5833B2C8-0367-4D07-AD4B-4E978393125FQ39119066-E3F14B2D-4A56-4167-8F46-F6767B548DA9Q39120376-A9802B57-E80D-4126-AF0A-035AA96B3A0BQ39125110-C2380E12-B751-4C38-9A5E-E0AB663033BCQ40204764-F96BD951-4B61-4FB7-99B0-7E81779712DDQ41512911-C6D3B8F4-1C29-46D8-95FA-EEC68DD38FADQ42106071-3667BED6-637D-443D-A600-EEDEFB9F27A6Q43875696-72D3A314-D20A-4897-845A-E6EC025C965CQ43977832-301DDDF6-2F0D-46D0-8B69-2BF5EA0475F9Q43984426-3B2D8B8D-C8BF-4835-953B-CA1A1398BAF2Q44030239-8B688ED3-34F8-4540-A4A3-EBBE5A70EB90Q44106186-37CEC2E9-A6FD-4F75-8CB6-5A17B804D89CQ44232815-8913AA9F-0E65-40AF-B421-3DCBAA98B63BQ44336647-DE11E43B-144D-4E52-936E-F4CFF499E1C7Q44453295-F1FE537D-8D98-4420-AAE9-B75AF818C6E9Q44645432-530C147F-7F7D-47B6-A3BF-E633A705C7CDQ44879585-9D4DAE73-4B85-48A9-923D-6B2F4DFE1905Q45154656-A521E60B-2D62-4E73-A18F-A7E847B0E116Q46414659-4E843C95-E630-41DB-986F-8A9234A80BD0Q46473191-88EF354F-47B3-4B92-8463-AA9543E2949EQ46568243-AD0F7FBA-C999-4B3B-9015-535C67F12869Q47197594-D0803904-9BEC-47B3-B3D2-7C3E28211EF3
P2860
Tricarboxylic acid cycle intermediates in human muscle during prolonged exercise.
description
1990 nî lūn-bûn
@nan
1990年の論文
@ja
1990年学术文章
@wuu
1990年学术文章
@zh
1990年学术文章
@zh-cn
1990年学术文章
@zh-hans
1990年学术文章
@zh-my
1990年学术文章
@zh-sg
1990年學術文章
@yue
1990年學術文章
@zh-hant
name
Tricarboxylic acid cycle intermediates in human muscle during prolonged exercise.
@en
Tricarboxylic acid cycle intermediates in human muscle during prolonged exercise.
@nl
type
label
Tricarboxylic acid cycle intermediates in human muscle during prolonged exercise.
@en
Tricarboxylic acid cycle intermediates in human muscle during prolonged exercise.
@nl
prefLabel
Tricarboxylic acid cycle intermediates in human muscle during prolonged exercise.
@en
Tricarboxylic acid cycle intermediates in human muscle during prolonged exercise.
@nl
P2093
P1476
Tricarboxylic acid cycle intermediates in human muscle during prolonged exercise.
@en
P2093
P304
P356
10.1152/AJPCELL.1990.259.5.C834
P407
P433
P577
1990-11-01T00:00:00Z