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Title:Skeletal muscle oxidative function in vivo and ex vivo in athletes with marked hypertrophy from resistance training
Authors:ID Salvadego, Desy (Author)
ID Domenis, R. (Author)
ID Lazzer, Stefano (Author)
ID Porcelli, Simone (Author)
ID Rittweger, Joern (Author)
ID Rizzo, Giovanna (Author)
ID Mavelli, I. (Author)
ID Šimunič, Boštjan (Author)
ID Pišot, Rado (Author)
ID Grassi, Bruno (Author)
Files:URL http://jap.physiology.org/content/early/2013/03/14/japplphysiol.00883.2012.full.pdf+html
 
Language:English
Work type:Not categorized
Typology:1.01 - Original Scientific Article
Organization:UPR - University of Primorska
Abstract:Oxidative function during exercise was evaluated in 11 young athletes with marked skeletal muscle hypertrophy induced by long-term resistance training (RTA, body mass 102.67.3 kg, meanSD) and 11 controls (CTRL, body mass 77.86.0). Pulmonary O2 uptake (V'O2) and vastus lateralis muscle fractional O2 extraction (by near-infrared spectroscopy) were determined during an incremental cycle ergometer (CE) and one-leg knee-extension (KE) exercise. Mitochondrial respiration was evaluated ex vivo by high-resolution respirometry in permeabilized vastus lateralis fibers obtained by biopsy. Quadriceps femoris muscle cross sectional area, volume (determined by magnetic resonance imaging) and strength were greater in RTA vs. CTRL (by ~40%, ~33% and ~20%, respectively). V'O2peak during CE was higher in RTA vs. CTRL (4.050.64 L min-1 vs. 3.560.30); no difference between groups was observed during KE. The O2 cost of CE exercise was not different between groups. When divided per muscle mass (for CE) or quadriceps muscle mass (for KE) V'O2peak was lower (by 15-20%) in RTA vs. CTRL. Vastus lateralis fractional O2 extraction was lower in RTA vs. CTRL at all work rates, both during CE and KE. RTA had higher ADP-stimulated mitochondrial respiration (56.723.7 pmolO2s-1mg-1 ww) vs. CTRL (35.710.2), and a tighter coupling of oxidative phosphorylation. In RTA the greater muscle mass and maximal force, and the enhanced mitochondrial respiration seem to compensate for the hypertrophy-induced impaired peripheral O2 diffusion. The net results are an enhanced whole body oxidative function at peak exercise, and unchanged efficiency and O2 cost at submaximal exercise, despite a much greater body mass
Keywords:skeletal muscle, hypertrophy, mitochondrial respiration, oxidative metabolism, exercise
Year of publishing:2013
Number of pages:str. 1527-1535
Numbering:Vol. 114, no. 11
PID:20.500.12556/RUP-1751 This link opens in a new window
ISSN:8750-7587
UDC:612:796.01
COBISS.SI-ID:2371027 This link opens in a new window
Publication date in RUP:15.10.2013
Views:4608
Downloads:155
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