scholarly article | Q13442814 |
P819 | ADS bibcode | 2005PNAS..102.5368P |
P356 | DOI | 10.1073/PNAS.0501211102 |
P932 | PMC publication ID | 556259 |
P698 | PubMed publication ID | 15809440 |
P5875 | ResearchGate publication ID | 7927718 |
P2093 | author name string | Ronald G Tompkins | |
George Dai | |||
Laurence G Rahme | |||
Michael N Mindrinos | |||
A Aria Tzika | |||
Suresh Gopalan | |||
Loukas G Astrakas | |||
Qunhao Zhang | |||
Katie E Padfield | |||
P2860 | cites work | Gene ontology: tool for the unification of biology | Q23781406 |
Structure, Expression, and Chromosomal Assignment of the Human Gene Encoding Nuclear Respiratory Factor 1 | Q24321307 | ||
KEGG: kyoto encyclopedia of genes and genomes | Q24515297 | ||
A case of severe hypermetabolism of nonthyroid origin with a defect in the maintenance of mitochondrial respiratory control: a correlated clinical, biochemical, and morphological study | Q24601956 | ||
A cold-inducible coactivator of nuclear receptors linked to adaptive thermogenesis | Q27860471 | ||
Mechanisms controlling mitochondrial biogenesis and respiration through the thermogenic coactivator PGC-1 | Q28131760 | ||
Assessment of mitochondrial energy coupling in vivo by 13C/31P NMR | Q28344306 | ||
Integrated analysis of protein composition, tissue diversity, and gene regulation in mouse mitochondria | Q28593536 | ||
Database resources of the National Center for Biotechnology | Q29618892 | ||
The metabolic basis of the increase of the increase in energy expenditure in severely burned patients | Q33641425 | ||
Mapping of metabolites in whole animals by 31P NMR using surface coils | Q34057344 | ||
Coordinated patterns of gene expression for substrate and energy metabolism in skeletal muscle of diabetic mice | Q34075210 | ||
Transcriptional activators and coactivators in the nuclear control of mitochondrial function in mammalian cells | Q34122975 | ||
Nuclear activators and coactivators in mammalian mitochondrial biogenesis | Q34657768 | ||
The metabolic effects of thermal injury | Q35193841 | ||
Regulation by insulin of muscle protein metabolism during sepsis and other catabolic conditions | Q35660023 | ||
Transcriptional regulatory circuits controlling mitochondrial biogenesis and function | Q35683727 | ||
NMR spectroscopy as an investigative technique in physiology | Q36446364 | ||
Peroxisome proliferator-activated receptor gamma coactivator-1 promotes cardiac mitochondrial biogenesis | Q37526796 | ||
Patterns of gene expression in atrophying skeletal muscles: response to food deprivation. | Q38361438 | ||
Expression profiling analysis of the metabolic and inflammatory changes following burn injury in rats | Q38521986 | ||
NMR studies of enzymatic ratesin vitroandin vivoby magnetization transfer | Q40078012 | ||
Bioenergetic analysis of peroxisome proliferator-activated receptor gamma coactivators 1alpha and 1beta (PGC-1alpha and PGC-1beta) in muscle cells | Q40649634 | ||
Mechanisms of muscle wasting. The role of the ubiquitin-proteasome pathway | Q41249327 | ||
Burn injury to rat increases nicotinic acetylcholine receptors in the diaphragm | Q41434325 | ||
Insulin resistance in burns and trauma. | Q41711525 | ||
Adaptations of skeletal muscle to exercise: rapid increase in the transcriptional coactivator PGC-1. | Q44240302 | ||
Activity of phosphorylase in total global ischaemia in the rat heart A phosphorus-31 nuclear-magnetic-resonance study | Q46590642 | ||
Neuromuscular dysfunction in burns and its relationship to burn size, hypermetabolism, and immunosuppression | Q47177303 | ||
The 1999 Moyer award. Burn injury induces skeletal muscle apoptosis and the activation of caspase pathways in rats. | Q48375286 | ||
Analysis of thermal injury-induced insulin resistance in rodents. Implication of postreceptor mechanisms. | Q51573603 | ||
Catecholamines: mediator of the hypermetabolic response to thermal injury. | Q51675248 | ||
Intracellular metabolites in rat muscle following trauma: a 31P and 1H nuclear magnetic resonance study. | Q51787008 | ||
Effect of insulin and leucine on protein turnover in rat soleus muscle after burn injury. | Q54524369 | ||
31P NMR measurement of mitochondrial uncoupling in isolated rat hearts | Q68408681 | ||
ATP synthesis kinetics and mitochondrial function in the postischemic myocardium as studied by 31P NMR | Q68436972 | ||
31P NMR magnetization-transfer measurements of ATP turnover during steady-state isometric muscle contraction in the rat hind limb in vivo | Q69692789 | ||
Systemic effects of single hindlimb burn injury on skeletal muscle function and cyclic nucleotide levels in the murine model | Q69838238 | ||
Local effect of burn on skeletal muscle insulin responsiveness | Q70183563 | ||
Analysis of postburn insulin unresponsiveness in skeletal muscle | Q70191182 | ||
Effect of disuse and thermal injury on protein turnover in skeletal muscle | Q70458370 | ||
The effects of thermal injury on mitochondrial oxygen consumption and the glycerol phosphate shuttle | Q72054196 | ||
P433 | issue | 15 | |
P407 | language of work or name | English | Q1860 |
P304 | page(s) | 5368-5373 | |
P577 | publication date | 2005-04-04 | |
P1433 | published in | Proceedings of the National Academy of Sciences of the United States of America | Q1146531 |
P1476 | title | Burn injury causes mitochondrial dysfunction in skeletal muscle | |
P478 | volume | 102 |
Q92619586 | 1H-NMR metabolomics identifies significant changes in hypermetabolism after glutamine administration in burned rats |
Q29617040 | A network-based analysis of systemic inflammation in humans |
Q35009877 | A small volatile bacterial molecule triggers mitochondrial dysfunction in murine skeletal muscle |
Q38380755 | Acute rhabdomyolysis and inflammation |
Q28754648 | Aerobic metabolism underlies complexity and capacity |
Q33579870 | Analysis of factorial time-course microarrays with application to a clinical study of burn injury |
Q36684324 | Bacterial-excreted small volatile molecule 2-aminoacetophenone induces oxidative stress and apoptosis in murine skeletal muscle |
Q34707383 | Bone marrow cell transcripts from Fanconi anaemia patients reveal in vivo alterations in mitochondrial, redox and DNA repair pathways. |
Q38970052 | Burn Serum Stimulates Myoblast Cell Death Associated with IL-6-Induced Mitochondrial Fragmentation. |
Q34415748 | Burn trauma in skeletal muscle results in oxidative stress as assessed by in vivo electron paramagnetic resonance. |
Q24618730 | Burns: an update on current pharmacotherapy |
Q35185112 | Cellular metabolic regulators: novel indicators of low-grade inflammation in humans |
Q33732725 | Combined off-resonance imaging and T2 relaxation in the rotating frame for positive contrast MR imaging of infection in a murine burn model |
Q36495119 | Differential acute and chronic effects of burn trauma on murine skeletal muscle bioenergetics |
Q42700727 | Differential expression of microRNA let-7b-5p regulates burn-induced hyperglycemia |
Q35790242 | Down-regulation of glutatione S-transferase α 4 (hGSTA4) in the muscle of thermally injured patients is indicative of susceptibility to bacterial infection |
Q44922640 | Drosophila melanogaster as a model host for studying Pseudomonas aeruginosa infection |
Q28828916 | Effect of Human Burn Wound Exudate on Pseudomonas aeruginosa Virulence |
Q38441706 | Exercise Altered the Skeletal Muscle MicroRNAs and Gene Expression Profiles in Burn Rats With Hindlimb Unloading |
Q28383451 | First-in-class cardiolipin-protective compound as a therapeutic agent to restore mitochondrial bioenergetics |
Q36344871 | Human mitochondrial oxidative capacity is acutely impaired after burn trauma |
Q43083626 | In vivo high-resolution magic angle spinning magnetic and electron paramagnetic resonance spectroscopic analysis of mitochondria-targeted peptide in Drosophila melanogaster with trauma-induced thoracic injury |
Q79633206 | Insulin sensitivity and mitochondrial function are improved in children with burn injury during a randomized controlled trial of fenofibrate |
Q37527269 | Insulin sensitivity is related to fat oxidation and protein kinase C activity in children with acute burn injury |
Q37304133 | Intensive insulin therapy improves insulin sensitivity and mitochondrial function in severely burned children |
Q33312375 | Involvement of skeletal muscle gene regulatory network in susceptibility to wound infection following trauma. |
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Q38090981 | Mechanisms underlying the anti-wasting effect of L-carnitine supplementation under pathologic conditions: evidence from experimental and clinical studies |
Q35513839 | Microarray analysis suggests that burn injury results in mitochondrial dysfunction in human skeletal muscle |
Q36860285 | Mitochondria-targeted antioxidant promotes recovery of skeletal muscle mitochondrial function after burn trauma assessed by in vivo 31P nuclear magnetic resonance and electron paramagnetic resonance spectroscopy |
Q37802264 | Mitochondrial biogenesis and fragmentation as regulators of muscle protein degradation |
Q38035636 | Mitochondrial biogenesis and fragmentation as regulators of protein degradation in striated muscles |
Q39713513 | Mitochondrial fission and remodelling contributes to muscle atrophy. |
Q33514649 | Molecular characterization and quantification using state of the art solid-state adiabatic TOBSY NMR in burn trauma |
Q53286260 | Morphological changes in distant muscle fibers following thermal injury in Wistar rats. |
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Q37016738 | Nuclear magnetic resonance in conjunction with functional genomics suggests mitochondrial dysfunction in a murine model of cancer cachexia |
Q42791366 | PPAR-alpha agonism improves whole body and muscle mitochondrial fat oxidation, but does not alter intracellular fat concentrations in burn trauma children in a randomized controlled trial. |
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Q46774268 | Skeletal muscle mitochondria exhibit decreased pyruvate oxidation capacity and increased ROS emission during surgery-induced acute insulin resistance |
Q57183649 | Skeletal muscle mitochondrial uncoupling in a murine cancer cachexia model |
Q38565307 | Statins, fibrates, thiazolidinediones and resveratrol as adjunctive therapies in sepsis: could mitochondria be a common target? |
Q34483183 | The Sick and the Weak: Neuropathies/Myopathies in the Critically Ill. |
Q27026797 | The impact of severe burns on skeletal muscle mitochondrial function |
Q37510565 | The role of hyperglycemia in burned patients: evidence-based studies |
Q34130829 | Uncoupled skeletal muscle mitochondria contribute to hypermetabolism in severely burned adults. |
Q34452029 | Use of 1H-nuclear magnetic resonance to screen a set of biomarkers for monitoring metabolic disturbances in severe burn patients |
Q36109316 | What do magnetic resonance-based measurements of Pi→ATP flux tell us about skeletal muscle metabolism? |
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