PURPOSE OF REVIEW: Muscle wasting and impaired muscle oxidative metabolism are common extrapulmonary features of chronic respiratory failure (CRF) that significantly increase disease burden. This review aims to address the question whether hypoxia, an obvious consequence of this disease, actually plays a causal role in these muscle impairments. RECENT FINDINGS: In experimental models, a causal role for hypoxia in muscle atrophy and metabolic impairments has clearly been shown. Although the hypoxia-inducible factors and nuclear factor kappa B are putative mediators of these hypoxia-induced alterations, their true involvement remains to be proven. Molecular signatures of disrupted regulation of muscle mass and oxidative metabolism observed in these experimental models also have been shown in muscles of patients suffering from CRF, suggestive of but not conclusive for a causal role of hypoxia. Therapies, including but not restricted to those aimed at alleviating hypoxia, have been shown to partially but not completely restore muscle mass and oxidative capacity in CRF patients, which may imply an additive effect of nutritional modulation of substrate metabolism. SUMMARY: Although hypoxia clearly affects skeletal muscle maintenance, it remains to be confirmed whether and by which underlying molecular mechanisms hypoxia is causally involved in CRF-related muscle atrophy and impaired oxidative capacity.
PURPOSE OF REVIEW: Muscle wasting and impaired muscle oxidative metabolism are common extrapulmonary features of chronic respiratory failure (CRF) that significantly increase disease burden. This review aims to address the question whether hypoxia, an obvious consequence of this disease, actually plays a causal role in these muscle impairments. RECENT FINDINGS: In experimental models, a causal role for hypoxia in muscle atrophy and metabolic impairments has clearly been shown. Although the hypoxia-inducible factors and nuclear factor kappa B are putative mediators of these hypoxia-induced alterations, their true involvement remains to be proven. Molecular signatures of disrupted regulation of muscle mass and oxidative metabolism observed in these experimental models also have been shown in muscles of patients suffering from CRF, suggestive of but not conclusive for a causal role of hypoxia. Therapies, including but not restricted to those aimed at alleviating hypoxia, have been shown to partially but not completely restore muscle mass and oxidative capacity in CRF patients, which may imply an additive effect of nutritional modulation of substrate metabolism. SUMMARY: Although hypoxia clearly affects skeletal muscle maintenance, it remains to be confirmed whether and by which underlying molecular mechanisms hypoxia is causally involved in CRF-related muscle atrophy and impaired oxidative capacity.
Authors: François Maltais; Marc Decramer; Richard Casaburi; Esther Barreiro; Yan Burelle; Richard Debigaré; P N Richard Dekhuijzen; Frits Franssen; Ghislaine Gayan-Ramirez; Joaquim Gea; Harry R Gosker; Rik Gosselink; Maurice Hayot; Sabah N A Hussain; Wim Janssens; Micheal I Polkey; Josep Roca; Didier Saey; Annemie M W J Schols; Martijn A Spruit; Michael Steiner; Tanja Taivassalo; Thierry Troosters; Ioannis Vogiatzis; Peter D Wagner Journal: Am J Respir Crit Care Med Date: 2014-05-01 Impact factor: 21.405
Authors: Lydia M Le Page; Oliver J Rider; Andrew J Lewis; Victoria Noden; Matthew Kerr; Lucia Giles; Lucy J A Ambrose; Vicky Ball; Latt Mansor; Lisa C Heather; Damian J Tyler Journal: NMR Biomed Date: 2019-05-15 Impact factor: 4.044
Authors: Liesl Wandrag; Mario Siervo; Heather L Riley; Maryam Khosravi; Bernadette O Fernandez; Carl A Leckstrom; Daniel S Martin; Kay Mitchell; Denny Z H Levett; Hugh E Montgomery; Monty G Mythen; Michael A Stroud; Michael P W Grocott; Martin Feelisch Journal: Redox Biol Date: 2017-05-08 Impact factor: 11.799
Authors: Benjamin D McNair; Nicholas A Marcello; Derek T Smith; Emily E Schmitt; Danielle R Bruns Journal: Medicina (Kaunas) Date: 2020-09-03 Impact factor: 2.430