TY - JOUR T1 - Sarcopenia from mechanism to diagnosis and treatment in liver disease. AU - Dasarathy,Srinivasan, AU - Merli,Manuela, Y1 - 2016/08/08/ PY - 2016/01/08/received PY - 2016/07/09/revised PY - 2016/07/25/accepted PY - 2016/8/16/pubmed PY - 2018/4/20/medline PY - 2016/8/13/entrez KW - Clinical outcomes KW - Hyperammonemia KW - Leucine KW - Myostatin KW - Sarcopenia KW - mTORC1 SP - 1232 EP - 1244 JF - Journal of hepatology JO - J Hepatol VL - 65 IS - 6 N2 - Sarcopenia or loss of skeletal muscle mass is the major component of malnutrition and is a frequent complication in cirrhosis that adversely affects clinical outcomes. These include survival, quality of life, development of other complications and post liver transplantation survival. Radiological image analysis is currently utilized to diagnose sarcopenia in cirrhosis. Nutrient supplementation and physical activity are used to counter sarcopenia but have not been consistently effective because the underlying molecular and metabolic abnormalities persist or are not influenced by these treatments. Even though alterations in food intake, hypermetabolism, alterations in amino acid profiles, endotoxemia, accelerated starvation and decreased mobility may all contribute to sarcopenia in cirrhosis, hyperammonemia has recently gained attention as a possible mediator of the liver-muscle axis. Increased muscle ammonia causes: cataplerosis of α-ketoglutarate, increased transport of leucine in exchange for glutamine, impaired signaling by leucine, increased expression of myostatin (a transforming growth factor beta superfamily member) and an increased phosphorylation of eukaryotic initiation factor 2α. In addition, mitochondrial dysfunction, increased reactive oxygen species that decrease protein synthesis and increased autophagy mediated proteolysis, also play a role. These molecular and metabolic alterations may contribute to the anabolic resistance and inadequate response to nutrient supplementation in cirrhosis. Central and skeletal muscle fatigue contributes to impaired exercise capacity and responses. Use of proteins with low ammoniagenic potential, leucine enriched amino acid supplementation, long-term ammonia lowering strategies and a combination of resistance and endurance exercise to increase muscle mass and function may target the molecular abnormalities in the muscle. Strategies targeting endotoxemia and the gut microbiome need further evaluation. SN - 1600-0641 UR - https://www.unboundmedicine.com/medline/citation/27515775/full_citation DB - PRIME DP - Unbound Medicine ER -