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Difference between revisions of "Boushel 2011 Mitochondrion"

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|journal=Mitochondrion
|journal=Mitochondrion
|abstract=Across a wide range of species and body mass a close matching exists between maximal conductive oxygen delivery and mitochondrial respiratory rate. In this study we investigated in humans how closely ''in vivo'' maximal oxygen consumption (''V''O(2)max) is matched to muscle tissue-specific OXPHOS capacity ([[State 3]]) respiration. High-resolution respirometry was used to quantify mitochondrial respiration from the biopsies of arm and leg muscles while ''in vivo'' arm and leg ''V''O(2) were determined by the Fick method during leg cycling and arm cranking. We hypothesized that muscle mitochondrial respiratory rate exceeds that of systemic oxygen delivery. OXPHOS capacity of the deltoid muscle (4.3±0.4 mmol O(2)kg(-1)min(-1)) was similar to the ''in vivo'' ''V''O(2) during maximal arm cranking (4.7±0.5 mmol O(2)kg(-1)min(-1)) with 6 kg muscle. In contrast, the mitochondrial OXPHOS capacity of the quadriceps was 6.9±0.5 mmol O(2)kg(-1)min(-1), exceeding the ''in vivo'' leg ''V''O(2)max (5.0±0.2mmolO(2)kg(-1)min(-1)) during leg cycling with 20 kg muscle (''P''<0.05). Thus, when half or more of the body muscle mass is engaged during exercise, muscle mitochondrial respiratory capacity surpasses ''in vivo'' ''V''O(2)max. The findings reveal an excess capacity of muscle mitochondrial respiratory rate over O(2) delivery by the circulation in the cascade defining maximal oxidative rate in humans.
|abstract=Across a wide range of species and body mass a close matching exists between maximal conductive oxygen delivery and mitochondrial respiratory rate. In this study we investigated in humans how closely ''in vivo'' maximal oxygen consumption (''V''O(2)max) is matched to muscle tissue-specific OXPHOS capacity ([[State 3]]) respiration. High-resolution respirometry was used to quantify mitochondrial respiration from the biopsies of arm and leg muscles while ''in vivo'' arm and leg ''V''O(2) were determined by the Fick method during leg cycling and arm cranking. We hypothesized that muscle mitochondrial respiratory rate exceeds that of systemic oxygen delivery. OXPHOS capacity of the deltoid muscle (4.3±0.4 mmol O(2)kg(-1)min(-1)) was similar to the ''in vivo'' ''V''O(2) during maximal arm cranking (4.7±0.5 mmol O(2)kg(-1)min(-1)) with 6 kg muscle. In contrast, the mitochondrial OXPHOS capacity of the quadriceps was 6.9±0.5 mmol O(2)kg(-1)min(-1), exceeding the ''in vivo'' leg ''V''O(2)max (5.0±0.2mmolO(2)kg(-1)min(-1)) during leg cycling with 20 kg muscle (''P''<0.05). Thus, when half or more of the body muscle mass is engaged during exercise, muscle mitochondrial respiratory capacity surpasses ''in vivo'' ''V''O(2)max. The findings reveal an excess capacity of muscle mitochondrial respiratory rate over O(2) delivery by the circulation in the cascade defining maximal oxidative rate in humans.
|mipnetlab=SE Stockholm Boushel RC, AT Innsbruck Gnaiger E, AT Innsbruck OROBOROS, AT Innsbruck MitoCom
|mipnetlab=SE Stockholm Boushel RC, AT Innsbruck Gnaiger E, AT Innsbruck OROBOROS, AT Innsbruck MitoCom, CA Vancouver Boushel RC
|discipline=Mitochondrial Physiology
|discipline=Mitochondrial Physiology
}}
}}

Revision as of 09:48, 27 July 2015

Publications in the MiPMap
Boushel RC, Gnaiger E, Calbet JA, Gonzalez-Alonso J, Wright-Paradis C, Sondergaard H, Ara I, Helge JW, Saltin B (2011) Muscle mitochondrial capacity exceeds maximal oxygen delivery in humans. Mitochondrion 11:303-7.

» PMID: 21147270

Boushel RC, Gnaiger E, Calbet JA, Gonzalez-Alonso J, Wright-Paradis C, Sondergaard H, Ara I, Helge JW, Saltin B (2011) Mitochondrion

Abstract: Across a wide range of species and body mass a close matching exists between maximal conductive oxygen delivery and mitochondrial respiratory rate. In this study we investigated in humans how closely in vivo maximal oxygen consumption (VO(2)max) is matched to muscle tissue-specific OXPHOS capacity (State 3) respiration. High-resolution respirometry was used to quantify mitochondrial respiration from the biopsies of arm and leg muscles while in vivo arm and leg VO(2) were determined by the Fick method during leg cycling and arm cranking. We hypothesized that muscle mitochondrial respiratory rate exceeds that of systemic oxygen delivery. OXPHOS capacity of the deltoid muscle (4.3±0.4 mmol O(2)kg(-1)min(-1)) was similar to the in vivo VO(2) during maximal arm cranking (4.7±0.5 mmol O(2)kg(-1)min(-1)) with 6 kg muscle. In contrast, the mitochondrial OXPHOS capacity of the quadriceps was 6.9±0.5 mmol O(2)kg(-1)min(-1), exceeding the in vivo leg VO(2)max (5.0±0.2mmolO(2)kg(-1)min(-1)) during leg cycling with 20 kg muscle (P<0.05). Thus, when half or more of the body muscle mass is engaged during exercise, muscle mitochondrial respiratory capacity surpasses in vivo VO(2)max. The findings reveal an excess capacity of muscle mitochondrial respiratory rate over O(2) delivery by the circulation in the cascade defining maximal oxidative rate in humans.


O2k-Network Lab: SE Stockholm Boushel RC, AT Innsbruck Gnaiger E, AT Innsbruck OROBOROS, AT Innsbruck MitoCom, CA Vancouver Boushel RC


Labels: MiParea: Respiration, mt-Biogenesis;mt-density, Exercise physiology;nutrition;life style 

Stress:Ischemia-reperfusion  Organism: Human  Tissue;cell: Skeletal muscle  Preparation: Intact organism, Permeabilized tissue 


Coupling state: OXPHOS 

HRR: Oxygraph-2k 


O2k-Publications