The effect of blood-flow-restricted interval training on lactate and H+ dynamics during dynamic exercise in man

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The effect of blood-flow-restricted interval training on lactate and H+ dynamics during dynamic exercise in man. / Christiansen, Danny; Eibye, Kasper; Hostrup, Morten; Bangsbo, Jens.

I: Acta Physiologica (Print), Bind 231, Nr. 3, e13580, 2021.

Publikation: Bidrag til tidsskriftTidsskriftartikelfagfællebedømt

Harvard

Christiansen, D, Eibye, K, Hostrup, M & Bangsbo, J 2021, 'The effect of blood-flow-restricted interval training on lactate and H+ dynamics during dynamic exercise in man', Acta Physiologica (Print), bind 231, nr. 3, e13580. https://doi.org/10.1111/apha.13580

APA

Christiansen, D., Eibye, K., Hostrup, M., & Bangsbo, J. (2021). The effect of blood-flow-restricted interval training on lactate and H+ dynamics during dynamic exercise in man. Acta Physiologica (Print), 231(3), [e13580]. https://doi.org/10.1111/apha.13580

Vancouver

Christiansen D, Eibye K, Hostrup M, Bangsbo J. The effect of blood-flow-restricted interval training on lactate and H+ dynamics during dynamic exercise in man. Acta Physiologica (Print). 2021;231(3). e13580. https://doi.org/10.1111/apha.13580

Author

Christiansen, Danny ; Eibye, Kasper ; Hostrup, Morten ; Bangsbo, Jens. / The effect of blood-flow-restricted interval training on lactate and H+ dynamics during dynamic exercise in man. I: Acta Physiologica (Print). 2021 ; Bind 231, Nr. 3.

Bibtex

@article{552b452bede048d69d4972fa516292d0,
title = "The effect of blood-flow-restricted interval training on lactate and H+ dynamics during dynamic exercise in man",
abstract = "Aim: To assess how blood-flow-restricted (BFR) interval-training affects the capacity of the leg muscles for pH regulation during dynamic exercise in physically-trained men.Methods: Ten men (age: 25 ±4y; {\.V}O2max: 50 ±5mL∙kg-1∙min-1) completed a 6-wk interval-cycling intervention (INT) with one leg under BFR (BFR-leg; ~180 mmHg) and the other without BFR (CON-leg). Before and after INT, thigh net H+-release (lactate-dependent, lactate-independent, and sum) and blood acid/base variables, were measured during knee-extensor-exercise at 25% (Ex25) and 90% (Ex90) of incremental-peak-power-output. A muscle biopsy was collected before and after Ex90 to determine pH, lactate, and density of H+ -transport/buffering systems.Results: After INT, net H+-release (BFR-leg: 15±2; CON-leg: 13±3; mmol·min-1; Mean±95%CI), net lactate-independent H+ -release (BFR-leg: 8±1; CON-leg: 4±1; mmol·min-1), and net lactate-dependent H+-release (BFR-leg: 9±3; CON-leg: 10±3; mmol·min-1) were similar between legs during Ex90 (p>0.05), despite a ~142% lower muscle-intracellular-to-interstitial lactate-gradient in BFR-leg (-3±4 vs. 6±6 mmol·L-1 ; p<0.05). In recovery from Ex90, net lactate-dependent H+-efflux decreased in BFR-leg with INT (p<0.05 vs. CON-leg) due to lowered muscle lactate production (~58% vs. CON-leg, p<0.05). Net H+ -gradient was not different between legs (~19%, p>0.05; BFR-leg: 48±30; CON-leg: 44±23; mmol·L-1). In BFR-leg, NHE1-density was higher than in CON-leg (~45%; p<0.05) and correlated with total-net H+-release (r=0.71; p=0.031) and lactate-independent H+-release (r=0.74; p=0.023) after INT, where arterial [HCO3-] and standard-base-excess in Ex25 were higher in BFR-leg than CON-leg.Conclusion: Compared to a training control, BFR-interval training increases the capacity for pH-regulation during dynamic exercise mainly via enhancement of muscle lactate-dependent H+-transport function and blood H+-buffering capacity.",
keywords = "Faculty of Science, Blood flow restriction, Training, H+ release, pH regulation, Lactate, Performance, Cycling, Exercise",
author = "Danny Christiansen and Kasper Eibye and Morten Hostrup and Jens Bangsbo",
note = "This article is protected by copyright. All rights reserved.",
year = "2021",
doi = "10.1111/apha.13580",
language = "English",
volume = "231",
journal = "Acta Physiologica",
issn = "1748-1708",
publisher = "Wiley-Blackwell",
number = "3",

}

RIS

TY - JOUR

T1 - The effect of blood-flow-restricted interval training on lactate and H+ dynamics during dynamic exercise in man

AU - Christiansen, Danny

AU - Eibye, Kasper

AU - Hostrup, Morten

AU - Bangsbo, Jens

N1 - This article is protected by copyright. All rights reserved.

PY - 2021

Y1 - 2021

N2 - Aim: To assess how blood-flow-restricted (BFR) interval-training affects the capacity of the leg muscles for pH regulation during dynamic exercise in physically-trained men.Methods: Ten men (age: 25 ±4y; V̇O2max: 50 ±5mL∙kg-1∙min-1) completed a 6-wk interval-cycling intervention (INT) with one leg under BFR (BFR-leg; ~180 mmHg) and the other without BFR (CON-leg). Before and after INT, thigh net H+-release (lactate-dependent, lactate-independent, and sum) and blood acid/base variables, were measured during knee-extensor-exercise at 25% (Ex25) and 90% (Ex90) of incremental-peak-power-output. A muscle biopsy was collected before and after Ex90 to determine pH, lactate, and density of H+ -transport/buffering systems.Results: After INT, net H+-release (BFR-leg: 15±2; CON-leg: 13±3; mmol·min-1; Mean±95%CI), net lactate-independent H+ -release (BFR-leg: 8±1; CON-leg: 4±1; mmol·min-1), and net lactate-dependent H+-release (BFR-leg: 9±3; CON-leg: 10±3; mmol·min-1) were similar between legs during Ex90 (p>0.05), despite a ~142% lower muscle-intracellular-to-interstitial lactate-gradient in BFR-leg (-3±4 vs. 6±6 mmol·L-1 ; p<0.05). In recovery from Ex90, net lactate-dependent H+-efflux decreased in BFR-leg with INT (p<0.05 vs. CON-leg) due to lowered muscle lactate production (~58% vs. CON-leg, p<0.05). Net H+ -gradient was not different between legs (~19%, p>0.05; BFR-leg: 48±30; CON-leg: 44±23; mmol·L-1). In BFR-leg, NHE1-density was higher than in CON-leg (~45%; p<0.05) and correlated with total-net H+-release (r=0.71; p=0.031) and lactate-independent H+-release (r=0.74; p=0.023) after INT, where arterial [HCO3-] and standard-base-excess in Ex25 were higher in BFR-leg than CON-leg.Conclusion: Compared to a training control, BFR-interval training increases the capacity for pH-regulation during dynamic exercise mainly via enhancement of muscle lactate-dependent H+-transport function and blood H+-buffering capacity.

AB - Aim: To assess how blood-flow-restricted (BFR) interval-training affects the capacity of the leg muscles for pH regulation during dynamic exercise in physically-trained men.Methods: Ten men (age: 25 ±4y; V̇O2max: 50 ±5mL∙kg-1∙min-1) completed a 6-wk interval-cycling intervention (INT) with one leg under BFR (BFR-leg; ~180 mmHg) and the other without BFR (CON-leg). Before and after INT, thigh net H+-release (lactate-dependent, lactate-independent, and sum) and blood acid/base variables, were measured during knee-extensor-exercise at 25% (Ex25) and 90% (Ex90) of incremental-peak-power-output. A muscle biopsy was collected before and after Ex90 to determine pH, lactate, and density of H+ -transport/buffering systems.Results: After INT, net H+-release (BFR-leg: 15±2; CON-leg: 13±3; mmol·min-1; Mean±95%CI), net lactate-independent H+ -release (BFR-leg: 8±1; CON-leg: 4±1; mmol·min-1), and net lactate-dependent H+-release (BFR-leg: 9±3; CON-leg: 10±3; mmol·min-1) were similar between legs during Ex90 (p>0.05), despite a ~142% lower muscle-intracellular-to-interstitial lactate-gradient in BFR-leg (-3±4 vs. 6±6 mmol·L-1 ; p<0.05). In recovery from Ex90, net lactate-dependent H+-efflux decreased in BFR-leg with INT (p<0.05 vs. CON-leg) due to lowered muscle lactate production (~58% vs. CON-leg, p<0.05). Net H+ -gradient was not different between legs (~19%, p>0.05; BFR-leg: 48±30; CON-leg: 44±23; mmol·L-1). In BFR-leg, NHE1-density was higher than in CON-leg (~45%; p<0.05) and correlated with total-net H+-release (r=0.71; p=0.031) and lactate-independent H+-release (r=0.74; p=0.023) after INT, where arterial [HCO3-] and standard-base-excess in Ex25 were higher in BFR-leg than CON-leg.Conclusion: Compared to a training control, BFR-interval training increases the capacity for pH-regulation during dynamic exercise mainly via enhancement of muscle lactate-dependent H+-transport function and blood H+-buffering capacity.

KW - Faculty of Science

KW - Blood flow restriction

KW - Training

KW - H+ release

KW - pH regulation

KW - Lactate

KW - Performance

KW - Cycling

KW - Exercise

U2 - 10.1111/apha.13580

DO - 10.1111/apha.13580

M3 - Journal article

C2 - 33222371

VL - 231

JO - Acta Physiologica

JF - Acta Physiologica

SN - 1748-1708

IS - 3

M1 - e13580

ER -

ID: 251936655