BACKGROUND: Severe burn trauma is characterized by an elevated rate of whole-body energy expenditure. APPROACH: In this short review, we have attempted to assess the metabolic characteristics of and basis for the persistent increase in energy expenditure during the flow phase of the injury. We consider some aspects of normal energy metabolism, including the contribution of the major adenosine triphosphate (ATP)-consuming reactions to the standard or basal metabolic rate. Rate estimates are compiled from the literature for a number of these reactions in healthy adults and burned patients, and the values are related to the increased rates of whole-body energy expenditure with burn injury. RESULTS: Whole-body protein synthesis, gluconeogenesis, urea production, and substrate cycles (total fatty acid and glycolytic-gluconeogenic) account for approximately 22%, 11%, 3%, 17%, and 4%, respectively, of the burn-induced increase in total energy expenditure. CONCLUSIONS: These ATP-consuming reactions, therefore, seem to explain approximately 57% of the increase in energy expenditure. The remainder of the increase may be due, in large part, to altered Na(+)-K(+)-ATPase activity and increased proton leakage across the mitochondrial membrane.
BACKGROUND: Severe burn trauma is characterized by an elevated rate of whole-body energy expenditure. APPROACH: In this short review, we have attempted to assess the metabolic characteristics of and basis for the persistent increase in energy expenditure during the flow phase of the injury. We consider some aspects of normal energy metabolism, including the contribution of the major adenosine triphosphate (ATP)-consuming reactions to the standard or basal metabolic rate. Rate estimates are compiled from the literature for a number of these reactions in healthy adults and burned patients, and the values are related to the increased rates of whole-body energy expenditure with burn injury. RESULTS: Whole-body protein synthesis, gluconeogenesis, urea production, and substrate cycles (total fatty acid and glycolytic-gluconeogenic) account for approximately 22%, 11%, 3%, 17%, and 4%, respectively, of the burn-induced increase in total energy expenditure. CONCLUSIONS: These ATP-consuming reactions, therefore, seem to explain approximately 57% of the increase in energy expenditure. The remainder of the increase may be due, in large part, to altered Na(+)-K(+)-ATPase activity and increased proton leakage across the mitochondrial membrane.
Authors: Ioannis Malagaris; David N Herndon; Efstathia Polychronopoulou; Victoria G Rontoyanni; Clark R Andersen; Oscar E Suman; Craig Porter; Labros S Sidossis Journal: Clin Nutr Date: 2018-06-04 Impact factor: 7.324
Authors: Valeria Righi; Caterina Constantinou; Dionyssios Mintzopoulos; Nadeem Khan; S P Mupparaju; Laurence G Rahme; Harold M Swartz; Hazel H Szeto; Ronald G Tompkins; A Aria Tzika Journal: FASEB J Date: 2013-03-12 Impact factor: 5.191