Annemie M W J Schols1, Harry R Gosker. 1. Department of Respiratory Medicine, NUTRIM School for Nutrition, Toxicology & Metabolism, Maastricht University Medical Centre +, P.O. Box 5800, 6202 AZ, Maastricht, The Netherlands. A.Schols@PUL.unimaas.nl
Abstract
PURPOSE OF REVIEW: The focus of this review is on translation of putative mechanisms of altered energy metabolism and muscle maintenance in cachexia to clinical comparative and intervention studies on chronic obstructive pulmonary disease (COPD). RECENT FINDINGS: Pulmonary cachexia is a well recognized feature of COPD, but its cause is poorly understood. Recent studies have shed new light on the molecular mechanisms that underlie cachexia in this disorder. In addition to muscle wasting, COPD patients also suffer from so-called loss of peripheral 'muscle oxidative phenotype', rendering these muscles less energy efficient and more prone to oxidative stress, which may in turn augment loss of muscle mass. SUMMARY: Recent translational approaches have clearly advanced our understanding of the pathophysiology of cachexia in COPD. Although this complex clinical syndrome may clearly benefit from multidimensional interventions, for a tailored therapeutic approach based on distinct wasting and pulmonary phenotypes, more mechanistic knowledge on abnormal regulation of energy balance and muscle maintenance in COPD cachexia is needed.
PURPOSE OF REVIEW: The focus of this review is on translation of putative mechanisms of altered energy metabolism and muscle maintenance in cachexia to clinical comparative and intervention studies on chronic obstructive pulmonary disease (COPD). RECENT FINDINGS:Pulmonary cachexia is a well recognized feature of COPD, but its cause is poorly understood. Recent studies have shed new light on the molecular mechanisms that underlie cachexia in this disorder. In addition to muscle wasting, COPDpatients also suffer from so-called loss of peripheral 'muscle oxidative phenotype', rendering these muscles less energy efficient and more prone to oxidative stress, which may in turn augment loss of muscle mass. SUMMARY: Recent translational approaches have clearly advanced our understanding of the pathophysiology of cachexia in COPD. Although this complex clinical syndrome may clearly benefit from multidimensional interventions, for a tailored therapeutic approach based on distinct wasting and pulmonary phenotypes, more mechanistic knowledge on abnormal regulation of energy balance and muscle maintenance in COPD cachexia is needed.
Authors: Ava C Wilson; Preeti L Kumar; Sool Lee; Margaret M Parker; Itika Arora; Jarrett D Morrow; Emiel F M Wouters; Richard Casaburi; Stephen I Rennard; David A Lomas; Alvar Agusti; Ruth Tal-Singer; Mark T Dransfield; J Michael Wells; Surya P Bhatt; George Washko; Victor J Thannickal; Hemant K Tiwari; Craig P Hersh; Peter J Castaldi; Edwin K Silverman; Merry-Lynn N McDonald Journal: Respir Res Date: 2020-05-01
Authors: David Pj van Dijk; Marcel Cg van de Poll; Alastair Gw Moses; Thomas Preston; Steven Wm Olde Damink; Sander S Rensen; Nicolaas Ep Deutz; Peter B Soeters; James A Ross; Kenneth Ch Fearon; Cornelis Hc Dejong Journal: J Cachexia Sarcopenia Muscle Date: 2015-04-20 Impact factor: 12.910