Is the balance between skeletal muscular metabolic capacity and oxygen supply capacity the same in endurance trained and untrained subjects?

Rud, Bjarne; Hallén, Jostein

doi:10.1007/s00421-008-0947-8

Cited by 4 publications

(4 citation statements)

References 22 publications

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“…This increase in blood flow is a consequence of an increase in local vascular conductance, albeit muscle blood flow is balanced by sympathetic vasoconstrictor activity during whole-body exercise (Secher et al 1977, Volianitis & Secher 2002, Mortensen et al 2005, Rud & Hallen 2009. Both muscle oxidative capacity and one-legged VO 2 max were increased by one-legged endurance training in endurance-trained subjects, without affecting their VO 2 max for cycling.…”

Section: Discussionmentioning

confidence: 99%

“…Hence, training-induced increase in muscular oxidative capacity affects both oxygen delivery and extraction and During exercise, muscle perfusion increases with intensity to suffice the oxygen demand. This increase in blood flow is a consequence of an increase in local vascular conductance, albeit muscle blood flow is balanced by sympathetic vasoconstrictor activity during whole-body exercise (Secher et al 1977, Volianitis & Secher 2002, Mortensen et al 2005, Rud & Hallen 2009. Accordingly, at high exercise intensities, when a maximal cardiac output is approached, the increase in blood flow to the exercising muscles is restricted and the increase in oxygen uptake per unit of developed power attenuated.…”

Section: Discussionmentioning

confidence: 99%

“…During whole-body exercise, however, limited venous return to the heart and hence cardiac output provoke peripheral vasoconstriction that implicates muscle blood flow and oxygen uptake (Secher et al 1977, Volianitis & Secher 2002, Mortensen et al 2005. For example, in both endurance-trained and untrained subjects, leg oxygen uptake during cycling is lower than 50% of the capacity of the leg as revealed during one-legged knee extension exercise (Rud & Hallen 2009). That is the case because the arterial baroreceptors secure arterial blood pressure at the expense of flow to working skeletal muscles (Collins et al 2001, Ogoh et al 2003.…”

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confidence: 99%

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One‐legged endurance training: leg blood flow and oxygen extraction during cycling exercise

et al. 2012

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That enhanced VO(2) max for the trained leg had no implication for cycling VO(2) max supports that there is a central limitation to VO(2) max during whole-body exercise. However, the metabolic balance between the legs was changed during high-intensity exercise as oxygen delivery and oxygen extraction were higher in the trained leg, suggesting that endurance training ameliorates blunting of leg blood flow and oxygen uptake during whole-body exercise.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

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confidence: 99%

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One‐legged endurance training: leg blood flow and oxygen extraction during cycling exercise

et al. 2012

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“…Moreover, studies indicate that the oxygen consumption of the working muscles (i.e., quadriceps femoris) at maximal exercise for the single-leg knee-extensor ergometer are approximately two to three times higher than the oxygen consumption for the same muscles during cycle ergometry [ 33 , 34 , 35 ]. For example, Ru and Hallén [ 36 ] reported that mass-specific oxygen uptake (i.e., dividing the net oxygen uptake by the active muscle mass during exercise) was significantly higher for single-leg knee-extensor ergometer versus cycle ergometry (~0.400 vs. ~0.015 L of oxygen per kg of muscle mass per min). In addition, studies have compared the EMG amplitude for the quadriceps femoris muscles, using incremental testing, between the two exercise modalities (single-leg cycle ergometry and single-leg knee-extensor ergometer) and found that the EMG amplitude is ~40% higher at maximal exercise for single-leg knee-extensor ergometer versus single-leg cycle ergometry [ 37 ].…”

Section: Discussionmentioning

confidence: 99%

The Influence of Cold Therapy on the Physical Working Capacity at the Electromyographic Threshold for Consecutive Exercise Sessions

Maasri,

Jarvie,

Karski

et al. 2024

Bioengineering

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Background: The purpose of this study was to determine whether cold therapy after the first exercise test influences the physical working capacity at the fatigue threshold (PWCFT) during the second exercise test. We hypothesized that cold therapy would delay the onset of PWCFT for the second exercise test relative to the control visit (i.e., no cold therapy). Methods: Eight healthy college-aged men volunteered for the present study. For each of the two visits, subjects performed incremental, single-leg, knee-extensor ergometer, followed by either resting for 30 min (control visit) or having a cold pack applied for 15 min and then resting for 15 min (experimental visit). Then, the same exercise test was performed. The order of visits (control vs. experimental) was randomized for each subject. The exercise indices and PWCFT were determined for each of the two visits and statistically analyzed using two-way repeated measures analysis of variance. Results: The results indicate no significant (p > 0.05) mean differences for maximal power output, heart rate at end-exercise, and PWCFT between the control and cold therapy visits. Moreover, there were no significant (p > 0.05) mean differences between the first and second exercise workbout within each visit. Conclusions: The findings of this study suggest that cold therapy did not influence neuromuscular fatigue.

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Single- Versus Double-Leg Cycling: Small Muscle Mass Exercise Improves Exercise Capacity to a Greater Extent in Older Compared With Younger Population

Haddad,

Spence,

Peiffer

et al. 2024

Journal of Aging and Physical Activity

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Manipulating the amount of muscle mass engaged during exercise can noninvasively inform the contribution of central cardiovascular and peripheral vascular-oxidative functions to endurance performance. To better understand the factors contributing to exercise limitation in older and younger individuals, exercise performance was assessed during single-leg and double-leg cycling. 16 older (67 ± 5 years) and 14 younger (35 ± 5 years) individuals performed a maximal exercise using single-leg and double-leg cycling. The ratio of single-leg to double-leg cycling power (RatioPower SL/DL) was compared between age groups. The association between fitness (peak oxygen consumption, peak power output, and physical activity levels) and RatioPower SL/DL was explored. The RatioPower SL/DL was greater in older compared with younger individuals (1.14 ± 0.11 vs. 1.06 ± 0.08, p = .041). The RatioPower SL/DL was correlated with peak oxygen consumption (r = .886, p < .001), peak power output relative to body mass (r = .854, p < .001), and levels of physical activity (r = .728, p = .003) in the younger but not older subgroup. Reducing the amount of muscle mass engaged during exercise improved exercise capacity to a greater extent in older versus younger population and may reflect a greater reduction in central cardiovascular function compared with peripheral vascular-oxidative function with aging.

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Is the balance between skeletal muscular metabolic capacity and oxygen supply capacity the same in endurance trained and untrained subjects?

Cited by 4 publications

References 22 publications

One‐legged endurance training: leg blood flow and oxygen extraction during cycling exercise

One‐legged endurance training: leg blood flow and oxygen extraction during cycling exercise

The Influence of Cold Therapy on the Physical Working Capacity at the Electromyographic Threshold for Consecutive Exercise Sessions

Single- Versus Double-Leg Cycling: Small Muscle Mass Exercise Improves Exercise Capacity to a Greater Extent in Older Compared With Younger Population

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