Dominic S C Raj1, Yijuan Sun, Antonios H Tzamaloukas. 1. Division of Nephrology, University of New Mexico Health Sciences Center, Albuquerque, New Mexico 87131-5271, USA. draj@salud.unm.edu
Abstract
PURPOSE OF REVIEW: This article will provide a comprehensive review and update on recent advances in the field of protein-energy wasting and protein kinetics in patients with end-stage renal disease. RECENT FINDINGS: Hypercatabolism in dialysis patients is related to intradialytic loss of amino acids as well as cytokine activation. Interleukin-6 pays a central role in regulating whole-body, muscle and hepatic protein turnover during hemodialysis. Amino acids released from the muscle protein catabolism are taken up by the liver for de-novo protein synthesis during hemodialysis. Intradialytic nutrient supplementation increases protein synthesis, but does not attenuate muscle protein catabolism. SUMMARY: Protein-energy wasting observed in end-stage renal disease is a maladaptive metabolic state, which often coexists with inflammation. Cytokine-adipokine signaling plays an important role in protein-energy wasting. Peripheral blood mononuclear cells and skeletal muscle are important sources of interleukin-6 during hemodialysis. In addition to contributing to intradialytic protein catabolism, interleukin-6 impairs effective utilization of amino acids for protein synthesis. Although muscle protein breakdown increases during hemodialysis, whole-body proteolysis is not increased. The dissociation between regional and whole-body protein kinetics in end-stage renal disease is due to somatic-hepatic recycling of amino acids. Net anabolism during hemodialysis may be achieved only by providing nutrients as well as inhibiting overt inflammatory signals.
PURPOSE OF REVIEW: This article will provide a comprehensive review and update on recent advances in the field of protein-energy wasting and protein kinetics in patients with end-stage renal disease. RECENT FINDINGS:Hypercatabolism in dialysis patients is related to intradialytic loss of amino acids as well as cytokine activation. Interleukin-6 pays a central role in regulating whole-body, muscle and hepatic protein turnover during hemodialysis. Amino acids released from the muscle protein catabolism are taken up by the liver for de-novo protein synthesis during hemodialysis. Intradialytic nutrient supplementation increases protein synthesis, but does not attenuate muscle protein catabolism. SUMMARY: Protein-energy wasting observed in end-stage renal disease is a maladaptive metabolic state, which often coexists with inflammation. Cytokine-adipokine signaling plays an important role in protein-energy wasting. Peripheral blood mononuclear cells and skeletal muscle are important sources of interleukin-6 during hemodialysis. In addition to contributing to intradialytic protein catabolism, interleukin-6 impairs effective utilization of amino acids for protein synthesis. Although muscle protein breakdown increases during hemodialysis, whole-body proteolysis is not increased. The dissociation between regional and whole-body protein kinetics in end-stage renal disease is due to somatic-hepatic recycling of amino acids. Net anabolism during hemodialysis may be achieved only by providing nutrients as well as inhibiting overt inflammatory signals.
Authors: Eugene P Rhee; Amanda Souza; Laurie Farrell; Martin R Pollak; Gregory D Lewis; David J R Steele; Ravi Thadhani; Clary B Clish; Anna Greka; Robert E Gerszten Journal: J Am Soc Nephrol Date: 2010-04-08 Impact factor: 10.121