Supramaximal Exercise

Ferretti, Guido

doi:10.1007/978-3-319-05636-4_6

Cited by 3 publications

(6 citation statements)

References 68 publications

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“…In CP ex , other factors may have contributed to the increase in , , and MP in addition to the mechanisms discussed here above. Indeed, the growth of the cardiorespiratory and metabolic response could also be an effect of the slow component of , which is known to occur above the CP and which is mainly related to the recruitment of fast-twitch fibers and to a progressive shift toward fatty acid utilization during a long-lasting exercise (Jones et al 2011 ; Ferretti 2015 ; Burnley and Jones 2018 ). The higher [La − ] observed in our study in CP ex seems to support this statement.…”

Section: Discussionmentioning

confidence: 99%

“…4 ), even though T was the same. Since, in absence of [La − ] accumulation during an exercise transient, the time constant of the kinetics is invariant, power independent, and equal to that of phosphocreatine breakdown (di Prampero and Margaria 1968 ; Binzoni et al 1997 ), and since the mechanical AMP was the same in CP ex as in CP-50 ex , the postulated higher oxygen deficit in the former than in the latter case can only be attributed to its anaerobic lactic component (facultative component of the oxygen deficit due to early lactate accumulation) (di Prampero 1981 ; Ferretti 2015 ).…”

Section: Discussionmentioning

confidence: 99%

“…The history of the energetics of muscular exercise concerns mostly the study of the cardiorespiratory and metabolic responses to square-wave, constant-power submaximal work (di Prampero 1981 ; Whipp and Ward 1982 ; Poole and Jones 2012 ; Ferretti 2015 ; Ferretti et al 2022 ). In a square-wave transition from rest to light or moderate exercise, during which no lactate accumulation occurs, the time constant of the primary component of the bi-exponential pulmonary oxygen uptake ( ) kinetics (Poole and Jones 2012 ; Ferretti 2015 ) corresponds to that of phosphocreatine breakdown (Binzoni et al 1992 ; Rossiter et al 2002 ). In this type of exercise, the rest-to-exercise transition (on-phase) and exercise-to-rest transition upon exercise cessation (off-phase) show a symmetrical response (Özyener et al 2001 ).…”

Section: Introductionmentioning

confidence: 99%

“…Due to anaerobic metabolism contribution to energy supply in this transient, asymmetries between the two phases appear, with a longer time constant in the on- than in the off-phase (Paterson and Whipp 1991 ; Özyener et al 2001 ). In this scenario, the appearance of the so-called slow component, accompanied by a continuous increase in blood lactate accumulation, carries along a furtherly accentuated asymmetric pattern between the on- and off-phases of the kinetics (Poole et al 1994 ; Jones et al 2011 ; Ferretti 2015 ).…”

Section: Introductionmentioning

confidence: 99%

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Energetics of sinusoidal exercise below and across critical power and the effects of fatigue

Borrelli,

Shokohyar,

Rampichini

et al. 2024

Eur J Appl Physiol

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Purpose Previous studies investigating sinusoidal exercise were not devoted to an analysis of its energetics and of the effects of fatigue. We aimed to determine the contribution of aerobic and anaerobic lactic metabolism to the energy balance and investigate the fatigue effects on the cardiorespiratory and metabolic responses to sinusoidal protocols, across and below critical power (CP). Methods Eight males (26.6 ± 6.2 years; 75.6 ± 8.7 kg; maximum oxygen uptake 52.8 ± 7.9 ml·min−1·kg−1; CP 218 ± 13 W) underwent exhausting sinusoidal cycloergometric exercises, with sinusoid midpoint (MP) at CP (CPex) and 50 W below CP (CP-50ex). Sinusoid amplitude (AMP) and period were 50 W and 4 min, respectively. MP, AMP, and time-delay (tD) between mechanical and metabolic signals of expiratory ventilation ($${\dot{V}}_{E}$$ V ˙ E ), oxygen uptake ($${\dot{V}}_{{{\text{O}}}_{2}}$$ V ˙ O 2 ), and heart rate ($${f}_{H}$$ f H ) were assessed sinusoid-by-sinusoid. Blood lactate ([La−]) and rate of perceived exertion (RPE) were determined at each sinusoid. Results $${\dot{V}}_{{{\text{O}}}_{2}}$$ V ˙ O 2 AMP was 304 ± 11 and 488 ± 36 ml·min−1 in CPex and CP-50ex, respectively. Asymmetries between rising and declining sinusoid phases occurred in CPex (36.1 ± 7.7 vs. 41.4 ± 9.7 s for $${\dot{V}}_{{{\text{O}}}_{2}}$$ V ˙ O 2 tD up and tD down, respectively; P < 0.01), with unchanged tDs. $${\dot{V}}_{{{\text{O}}}_{2}}$$ V ˙ O 2 MP and RPE increased progressively during CPex. [La−] increased by 2.1 mM in CPex but remained stable during CP-50ex. Anaerobic contribution was larger in CPex than CP-50ex. Conclusion The lower aerobic component during CPex than CP-50ex associated with lactate accumulation explained lower $${\dot{V}}_{{{\text{O}}}_{2}}$$ V ˙ O 2 AMP in CPex. The asymmetries in CPex suggest progressive decline of muscle phosphocreatine concentration, leading to fatigue, as witnessed by RPE.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Energetics of sinusoidal exercise below and across critical power and the effects of fatigue

Borrelli,

Shokohyar,

Rampichini

et al. 2024

Eur J Appl Physiol

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show abstract

“…Second, because we relied on the assumption of a pure aerobic metabolism to calculate Ė , we could not investigate f p greater than 70 rpm in the water. This, together with the provision of longer recovery intervals in case of elevated postexercise [La], was also crucial to minimize fatigue and the slow component of the V˙O 2 kinetics (23,24) throughout the protocol. However, we still cannot rule out a minimal effect of fatigue, especially in those subjects who completed the study on a single day, although the randomization and balancing of the exercise bouts intrinsically mitigates this possible bias.…”

Section: Discussionmentioning

confidence: 99%

Effects of Water Immersion on the Internal Power of Cycling

Vinetti

Ferretti

Hostler

2021

Medicine &Amp; Science in Sports &Amp; Exercise

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Purpose Water immersion adds additional drag and metabolic demand for limb movement with respect to air, but its effect on the internal metabolic power ( Ė int ) of cycling is unknown. We aimed at quantifying the increase in Ė int during underwater cycling with respect to dry conditions at different pedaling rates. Methods Twelve healthy subjects (four women) pedaled on a waterproof cycle ergometer in an experimental pool that was either empty (DRY) or filled with tap water at 30.8°C ± 0.6°C (WET). Four different pedal cadences ( f p ) were studied (40, 50, 60, and 70 rpm) at 25, 50, 75, and 100 W. The metabolic power at steady state was measured via open circuit respirometry, and Ė int was calculated as the metabolic power extrapolated for 0 W. Results The Ė int was significantly higher in WET than in DRY at 50, 60, and 70 rpm (81 ± 31 vs 32 ± 30 W, 167 ± 35 vs 50 ± 29 W, 311 ± 51 vs 81 ± 30 W, respectively, all P < 0.0001), but not at 40 rpm (16 ± 5 vs 11 ± 17 W, P > 0.99). Ė int increased with the third power of f p both in WET and DRY ( R 2 = 0.49 and 0.91, respectively). Conclusions Water drag increased Ė int , although limbs unloading via the Archimedes’ principle and limbs shape could be potential confounding factors. A simple formula was developed to predict the increase in mechanical power in dry conditions needed to match the rate of energy expenditure during underwater cycling: 44 f p 3 – 7 W, where f p is expressed in Hertz.

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Artificial Intelligent Agent for Autonomous Prediction and Dynamic Feedback for High Performance Athletes

Lewis

Bihn

2017

2017 International Conference on Computational Science and Computational Intelligence (CSCI)

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Supramaximal Exercise

Cited by 3 publications

References 68 publications

Energetics of sinusoidal exercise below and across critical power and the effects of fatigue

Energetics of sinusoidal exercise below and across critical power and the effects of fatigue

Effects of Water Immersion on the Internal Power of Cycling

Artificial Intelligent Agent for Autonomous Prediction and Dynamic Feedback for High Performance Athletes

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