scholarly article | Q13442814 |
P6179 | Dimensions Publication ID | 1029735547 |
P356 | DOI | 10.1186/CC6102 |
P932 | PMC publication ID | 2206482 |
P698 | PubMed publication ID | 17716366 |
P5875 | ResearchGate publication ID | 6124383 |
P50 | author | David N Herndon | Q96619742 |
P2093 | author name string | Marc G Jeschke | |
Celeste C Finnerty | |||
William B Norbury | |||
Gerd G Gauglitz | |||
Gabriela A Kulp | |||
Ronald P Mlcak | |||
P2860 | cites work | Efficacy of a high-carbohydrate diet in catabolic illness | Q74166205 |
Determinants of skeletal muscle catabolism after severe burn | Q74348772 | ||
Urinary output of adrenaline and noradrenaline in severe thermal burns | Q74443795 | ||
Energy expenditure and caloric balance after burn: increased feeding leads to fat rather than lean mass accretion | Q77376785 | ||
Muscle protein catabolism after severe burn: effects of IGF-1/IGFBP-3 treatment | Q77425358 | ||
Cytokine expression profile over time in severely burned pediatric patients | Q79749281 | ||
Macrophage migration inhibitory factor mediates late cardiac dysfunction after burn injury | Q80606898 | ||
Intensive insulin therapy in critically ill patients | Q29618795 | ||
Interleukin-1 beta suppresses growth hormone-induced acid-labile subunit mRNA levels and secretion in primary hepatocytes | Q32871995 | ||
Metabolic management of patients with severe burns | Q33895418 | ||
New methods for calculating metabolic rate with special reference to protein metabolism | Q34351677 | ||
Intensive insulin therapy in the medical ICU. | Q34490623 | ||
Role of changes in insulin and glucagon in glucose homeostasis in exercise | Q34527726 | ||
Ghrelin--not just another stomach hormone | Q34560824 | ||
Support of the metabolic response to burn injury | Q35796326 | ||
IGF-I/IGFBP-3 equilibrates ratios of pro- to anti-inflammatory cytokines, which are predictors for organ function in severely burned pediatric patients | Q36088038 | ||
Post burn muscle wasting and the effects of treatments | Q36234446 | ||
Age-dependent differences in survival after severe burns: a unicentric review of 1,674 patients and 179 autopsies over 15 years | Q36405973 | ||
Muscle protein turnover and the wasting due to injury and disease | Q39826951 | ||
The IGF system in metabolism regulation. | Q40961363 | ||
Metabolic response to injury and sepsis: changes in protein metabolism | Q41588918 | ||
Association of hyperglycemia with increased mortality after severe burn injury | Q43728082 | ||
IGF-I/BP-3 administration preserves hepatic homeostasis after thermal injury which is associated with increases in no and hepatic NF-kappa B. | Q43792651 | ||
Burn-induced impairment of cardiac contractile function is due to gut-derived factors transported in mesenteric lymph | Q44158047 | ||
Hyperglycemia exacerbates muscle protein catabolism in burn-injured patients | Q44222674 | ||
Hormonal regulation of glucose and system A amino acid transport in first trimester placental villous fragments | Q45147966 | ||
Increased whole body protein breakdown predominates over increased whole body protein synthesis in multiple organ failure. | Q51600443 | ||
Catecholamines: mediator of the hypermetabolic response to thermal injury. | Q51675248 | ||
Body composition changes with time in pediatric burn patients. | Q52018157 | ||
Growth hormone attenuates Na(+)-dependent hepatic amino acid transport in endotoxemic rats. | Q54650020 | ||
Effect of a Hypocaloric Diet, Increased Protein Intake and Resistance Training on Lean Mass Gains and Fat Mass Loss in Overweight Police Officers | Q56114209 | ||
[Myocardial contractile and calcium transport function after severe burn injury] | Q57103422 | ||
Growth hormone regulates amino acid transport in human and rat liver | Q67505368 | ||
Hormonal responses and their effect on metabolism | Q67842894 | ||
Response to glucose infusion in humans: role of changes in insulin concentration | Q69878479 | ||
Transmembrane transport and intracellular kinetics of amino acids in human skeletal muscle | Q72491860 | ||
Growth hormone enhances amino acid uptake by the human small intestine | Q72519254 | ||
Increased rates of muscle protein turnover and amino acid transport after resistance exercise in humans | Q72655300 | ||
Sympathetic nerve and adrenal medullary response to thermal burn. Clinical analysis of adrenaline and noradrenaline depletion | Q72851672 | ||
Influence of glucose kinetics on plasma lactate concentration and energy expenditure in severely burned patients | Q73093184 | ||
Anabolic effects of insulin-like growth factor in combination with insulin-like growth factor binding protein-3 in severely burned adults | Q73198506 | ||
Insulin-like growth factor I in combination with insulin-like growth factor binding protein 3 affects the hepatic acute phase response and hepatic morphology in thermally injured rats | Q73542801 | ||
An abundant supply of amino acids enhances the metabolic effect of exercise on muscle protein | Q73575676 | ||
P433 | issue | 4 | |
P921 | main subject | inflammation | Q101991 |
P304 | page(s) | R90 | |
P577 | publication date | 2007-01-01 | |
P1433 | published in | Critical Care | Q5186602 |
P1476 | title | Burn size determines the inflammatory and hypermetabolic response | |
P478 | volume | 11 |
Q35617840 | A quantitative model of thermal injury-induced acute inflammation |
Q37198029 | Abnormal insulin sensitivity persists up to three years in pediatric patients post-burn |
Q42100792 | Acute kidney injury in burns: a story of volume and inflammation |
Q36040903 | Aging and the pathogenic response to burn. |
Q34051592 | Animal models in burn research |
Q37647984 | Bacterial respiratory tract infections are promoted by systemic hyperglycemia after severe burn injury in pediatric patients |
Q24187666 | Beta adrenergic antagonists for hospitalized burned patients |
Q84583532 | Brown fat activity is not apparent in subjects with HIV lipodystrophy and increased resting energy expenditure |
Q35929590 | Burn enhances toll-like receptor induced responses by circulating leukocytes |
Q41893791 | Burn injury-induced IRS-1 degradation in mouse skeletal muscle. |
Q99710958 | Burn resuscitation strategy influences the gut microbiota-liver axis in swine |
Q38001207 | Burn size estimation in children: still a problem. |
Q36906032 | Burned Adults Develop Profound Glucose Intolerance |
Q34920165 | Changes in fat distribution in children following severe burn injury |
Q41858093 | Changes in the levels of interleukins 6, 8, and 10, tumor necrosis factor alpha, and granulocyte-colony stimulating factor in Korean burn patients: relation to burn size and postburn time |
Q99551990 | Changing of serum metabolic hormone and liver size during acute phase of severe adult burn patients |
Q93054612 | Comparative Analysis of the Host Response in a Rat Model of Deep-Partial and Full-Thickness Burn Wounds With Pseudomonas aeruginosa Infection |
Q37158026 | Cytokine expression profile over time in burned mice |
Q36102387 | Development of a vascularized skin construct using adipose-derived stem cells from debrided burned skin |
Q40060254 | Differential regulation of innate immune cytokine production through pharmacological activation of Nuclear Factor-Erythroid-2-Related Factor 2 (NRF2) in burn patient immune cells and monocytes. |
Q42736081 | Early Enteral Nutrition for Burn Injury. |
Q55510371 | Early application of continuous high-volume haemofiltration can reduce sepsis and improve the prognosis of patients with severe burns. |
Q36515425 | Early leukocyte gene expression associated with age, burn size, and inhalation injury in severely burned adults |
Q60304383 | Effect of TNF-α Concentration on Selected Clinical Parameters of Swine After Burns |
Q38064238 | Enteral nutrition support in burn care: a review of current recommendations as instituted in the Ross Tilley Burn Centre |
Q64230442 | Exendin-4 Exacerbates Burn-Induced Morbidity in Mice by Activation of the Sympathetic Nervous System |
Q37297015 | Fenofibrate does not affect burn-induced hepatic endoplasmic reticulum stress |
Q38512684 | Gene expression profiling of long-term changes in rat liver following burn injury |
Q37205263 | Genetic risk factors for hypertrophic scar development. |
Q47656508 | Glucocorticoid receptor expression and binding capacity in patients with burn injury |
Q39646254 | Glucose Control in Severely Burned Patients Using Metformin: An Interim Safety and Efficacy Analysis of a Phase II Randomized Controlled Trial |
Q35751814 | In situ metabolic flux analysis to quantify the liver metabolic response to experimental burn injury |
Q36179118 | Inflammation, organomegaly, and muscle wasting despite hyperphagia in a mouse model of burn cachexia. |
Q37241722 | Insulin resistance postburn: underlying mechanisms and current therapeutic strategies |
Q36200340 | Integrity of airway epithelium in pediatric burn autopsies: Association with age and extent of burn injury |
Q34065625 | Intensive insulin therapy in severely burned pediatric patients: a prospective randomized trial |
Q90007202 | Leptin and fractalkine: Novel subcutaneous cytokines in burn injury |
Q34200054 | Leukocyte infiltration and activation of the NLRP3 inflammasome in white adipose tissue following thermal injury |
Q33971060 | Long-term persistance of the pathophysiologic response to severe burn injury |
Q38672123 | Management and outcomes of children with severe burns in New South Wales: 1995-2013. |
Q51820100 | Measures of Total Energy Expenditure and Its Components Using the Doubly Labeled Water Method in Rehabilitating Burn Children. |
Q52331745 | Metformin adapts its cellular effects to bioenergetic status in a model of metabolic dysfunction. |
Q37178361 | Modulation of the hypermetabolic response to trauma: temperature, nutrition, and drugs |
Q36976763 | Norepinephrine inhibits macrophage migration by decreasing CCR2 expression |
Q37186721 | Nutrition in burns: Galveston contributions |
Q37064208 | Occurrence of multiorgan dysfunction in pediatric burn patients: incidence and clinical outcome |
Q34179131 | Omega-3 polyunsaturated fatty acids augment the muscle protein anabolic response to hyperinsulinaemia-hyperaminoacidaemia in healthy young and middle-aged men and women |
Q37718022 | Outcome of acute kidney injury in severe burns: a systematic review and meta-analysis |
Q37235858 | Oxandrolone in pediatric patients with severe thermal burn injury |
Q37377946 | Oxandrolone treatment in adults with severe thermal injury. |
Q99549050 | Pathological Responses of Cardiac Mitochondria to Burn Trauma |
Q36251408 | Pathophysiologic Response to Burns in the Elderly |
Q33369410 | Pathophysiologic response to severe burn injury |
Q38863378 | Perioperative Temperature Management During Burn Care |
Q26827374 | Physical rehabilitation of pediatric burns |
Q34154148 | Plasma proteome response to severe burn injury revealed by 18O-labeled "universal" reference-based quantitative proteomics |
Q37352809 | Preclinical evaluation of epinephrine nebulization to reduce airway hyperemia and improve oxygenation after smoke inhalation injury |
Q35587597 | Predictive Value of IL-8 for Sepsis and Severe Infections After Burn Injury: A Clinical Study |
Q34173618 | Predictors of insulin resistance in pediatric burn injury survivors 24 to 36 months postburn |
Q97885001 | Profile and factors influencing resting energy expenditure in adult burn patients |
Q38851267 | Progress in burns research: a review of advances in burn pathophysiology |
Q34433355 | Propranolol decreases cardiac work in a dose-dependent manner in severely burned children |
Q37674052 | Randomized controlled trial to determine the efficacy of long-term growth hormone treatment in severely burned children |
Q39197243 | Recovery trajectories after burn injury in young adults: does burn size matter? |
Q36928131 | Relation between proteinuria and acute kidney injury in patients with severe burns |
Q92519262 | Resting Energy Expenditure and Protein Balance in People with Epidermolysis Bullosa |
Q37973966 | Role of the PPAR-α agonist fenofibrate in severe pediatric burn |
Q42430756 | Serum from human burn victims impairs myogenesis and protein synthesis in primary myoblasts |
Q38046995 | Severe burn injury, burn shock, and smoke inhalation injury in small animals. Part 1: burn classification and pathophysiology |
Q38468012 | Shock - A reappraisal: The holistic approach |
Q47366169 | Skeletal Muscle Mitochondrial Function is Determined by Burn Severity, Sex and Sepsis, and is Associated with Glucose Metabolism and Functional Capacity in Burned Children |
Q37790972 | Stem Cells and Burns: Review and Therapeutic Implications |
Q38072592 | Stem cell application in acute burn care and reconstruction |
Q37067305 | Survivors versus nonsurvivors postburn: differences in inflammatory and hypermetabolic trajectories |
Q37310054 | TNF-α/IL-10 Ratio Correlates with Burn Severity and May Serve as a Risk Predictor of Increased Susceptibility to Infections |
Q36714067 | Temporal cytokine profiles in severely burned patients: a comparison of adults and children |
Q57797690 | The Long-Term Impact of Severe Burn Trauma on Musculoskeletal Health |
Q38854100 | The National Institute on Disability, Independent Living, and Rehabilitation Research Burn Model System: Twenty Years of Contributions to Clinical Service and Research. |
Q39957822 | The Use of Blood Products in Adult Patients with Burns. |
Q39144663 | The biochemical alterations underlying post-burn hypermetabolism |
Q34273469 | The effect of ketoconazole on post-burn inflammation, hypermetabolism and clinical outcomes. |
Q35823021 | The effect of obesity on adverse outcomes and metabolism in pediatric burn patients |
Q37260905 | The hepatic response to thermal injury: is the liver important for postburn outcomes? |
Q37181299 | The hypermetabolic response to burn injury and interventions to modify this response |
Q35559639 | Transpulmonary thermodilution for hemodynamic measurements in severely burned children |
Q37338544 | Tumor necrosis factor gene variation and the risk of mortality after burn injury: a cohort study |
Q37427744 | Ultra-Early versus Early Excision and Grafting for Thermal Burns up to 60% Total Body Surface Area; A Historical Cohort Study |
Q90172253 | Understanding acute burn injury as a chronic disease |
Q57814729 | Weight changes and patterns of weight measurements in hospitalized burn patients: a contemporary analysis |
Q37881472 | What, how, and how much should patients with burns be fed? |
Q46265210 | Xanthine oxidase contributes to sustained airway epithelial oxidative stress after scald burn |
Q39009452 | Xenogeneic Mesenchymal Stromal Cells Improve Wound Healing and Modulate the Immune Response in an Extensive Burn Model. |
Q37317235 | Year in review 2007: Critical Care--shock |
Q83695859 | [Antimicrobial treatment in burn injury patients] |
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