Περίληψη:
Purpose of Review: Heart failure (HF) is a structural or functional cardiac abnormality which leads to failure of the heart to deliver oxygen commensurately with the requirements of the tissues and it may progress to a generalized wasting of skeletal muscle, fat tissue, and bone tissue (cardiac cachexia). Clinically, dyspnea, fatigue, and exercise intolerance are some typical signs and symptoms that characterize HF patients. This review focused on the phenotypic characteristics of HF-induced skeletal myopathy as well as the mechanisms of muscle wasting due to HF and highlighted possible therapeutic strategies for skeletal muscle wasting in HF. Recent Findings: The impaired exercise capacity of those patients is not attributed to the reduced blood flow in the exercising muscles, but rather to abnormal metabolic responses, myocyte apoptosis and atrophy of skeletal muscle. Specifically, the development of skeletal muscle wasting in chronic HF is characterized by structural, metabolic, and functional abnormalities in skeletal muscle and may be a result not only of reduced physical activity, but also of metabolic or hormonal derangements that favour catabolism over anabolism. In particular, abnormal energy metabolism, mitochondrial dysfunction, transition of myofibers from type I to type II, muscle atrophy, and reduction in muscular strength are included in skeletal muscle abnormalities which play a central role in the decreased exercise capacity of HF patients. Summary: Skeletal muscle alterations and exercise intolerance observed in HF are reversible by exercise training, since it is the only demonstrated intervention able to improve skeletal muscle metabolism, growth factor activity, and functional capacity and to reverse peripheral abnormalities. © 2020, Springer Science+Business Media, LLC, part of Springer Nature.
Συγγραφείς:
Philippou, A.
Xanthis, D.
Chryssanthopοulos, C.
Maridaki, M.
Koutsilieris, M.
Λέξεις-κλειδιά:
biosynthesis; cachexia; catabolism; energy metabolism; exercise; fatigue; heart failure; human; muscle atrophy; muscle metabolism; muscle strength; nuclear magnetic resonance imaging; nutrition; resistance training; Review; skeletal muscle; complication; energy metabolism; heart failure; metabolism; muscle atrophy; pathophysiology; physiology; skeletal muscle, Energy Metabolism; Exercise; Heart Failure; Humans; Muscle, Skeletal; Muscular Atrophy