Cycling with blood flow restriction improves performance and muscle K<sup>+</sup> regulation and alters the effect of anti‐oxidant infusion in humans

Christiansen, Danny; Eibye, Kasper; Rasmussen, Villads; Voldbye, Hans M.; Thomassen, Martin; Nyberg, Michael; Gunnarsson, Thomas P.; Skovgaard, Casper; Lindskrog, Mads; Bishop, David J.; Hostrup, Morten; Bangsbo, Jens

doi:10.1113/jp277657

Cited by 54 publications

(120 citation statements)

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“…The present study demonstrates that training with a substantial reduction (ß50%) in blood flow to exercising muscles (Christiansen et al 2019b) increases leg convective O 2 transport during both low-(23%) and high-intensity (13%), submaximal exercise in recreationally trained men (V O 2 max = 50 mL kg −1 min −1 ) ( Fig. 1).…”

Section: Bfr-interval Training Increases Leg Convective O 2 Transportsupporting

confidence: 54%

Training with blood flow restriction increases femoral artery diameter and thigh oxygen delivery during knee‐extensor exercise in recreationally trained men

Christiansen

Eibye

Hostrup

et al. 2020

The Journal of Physiology

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Key points Endurance‐type training with blood flow restriction (BFR) increases maximum oxygen uptake (V̇O2max) and exercise endurance of humans. However, the physiological mechanisms behind this phenomenon remain uncertain. In the present study, we show that BFR‐interval training reduces the peripheral resistance to oxygen transport during dynamic, submaximal exercise in recreationally‐trained men, mainly by increasing convective oxygen delivery to contracting muscles. Accordingly, BFR‐training increased oxygen uptake by, and concomitantly reduced net lactate release from, the contracting muscles during relative‐intensity‐matched exercise, at the same time as invoking a similar increase in diffusional oxygen conductance compared to the training control. Only BFR‐training increased resting femoral artery diameter, whereas increases in oxygen transport and uptake were dissociated from changes in the skeletal muscle content of mitochondrial electron‐transport proteins. Thus, physically trained men benefit from BFR‐interval training by increasing leg convective oxygen transport and reducing lactate release, thereby improving the potential for increasing the percentage of V̇O2max that can be sustained throughout exercise. Abstract In the present study, we investigated the effect of training with blood flow restriction (BFR) on thigh oxygen transport and uptake, and lactate release, during exercise. Ten recreationally‐trained men (50 ± 5 mL kg−1 min−1) completed 6 weeks of interval cycling with one leg under BFR (BFR‐leg; pressure: ∼180 mmHg) and the other leg without BFR (CON‐leg). Before and after the training intervention (INT), thigh oxygen delivery, extraction, uptake, diffusion capacity and lactate release were determined during knee‐extensor exercise at 25% incremental peak power output (iPPO) (Ex1), followed by exercise to exhaustion at 90% pre‐training iPPO (Ex2), by measurement of femoral‐artery blood flow and femoral‐arterial and ‐venous blood sampling. A muscle biopsy was obtained from legs before and after INT to determine mitochondrial electron‐transport protein content. Femoral‐artery diameter was also measured. In the BFR‐leg, after INT, oxygen delivery and uptake were higher, and net lactate release was lower, during Ex1 (vs. CON‐leg; P < 0.05), with an 11% larger increase in workload (vs. CON‐leg; P < 0.05). During Ex2, after INT, oxygen delivery was higher, and oxygen extraction was lower, in the BFR‐leg compared to the CON‐leg (P < 0.05), resulting in an unaltered oxygen uptake (vs. CON‐leg; P > 0.05). In the CON‐leg, at both intensities, oxygen delivery, extraction, uptake and lactate release remained unchanged (P > 0.05). Resting femoral artery diameter increased with INT only in the BFR‐leg (∼4%; P < 0.05). Oxygen diffusion capacity was similarly raised in legs (P < 0.05). Mitochondrial protein content remained unchanged in legs (P > 0.05). Thus, BFR‐interval training enhances oxygen utilization by, and lowers lactate release from, submaximally‐exercising muscles of recreationally‐trained men m...

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Section: Bfr-interval Training Increases Leg Convective O 2 Transportsupporting

confidence: 54%

Training with blood flow restriction increases femoral artery diameter and thigh oxygen delivery during knee‐extensor exercise in recreationally trained men

Christiansen

Eibye

Hostrup

et al. 2020

The Journal of Physiology

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“…Prior training studies performing repeated sprints in hypoxia have eluded to increased variation in perfusion during both leg cycling 4 and double poling. 10 Similar research has shown this response during acute leg cycling RST with different levels of BFR, 2 as well as after 6 weeks of single-leg cycling with BFR performing 3 sets of 3 × 2 min interval training, 24 and additionally with 4 weeks of single-leg knee extension with BFR. 25 The present arm cycling result was therefore expected.…”

Section: Discussionmentioning

confidence: 70%

Vascular and oxygenation responses of local ischemia and systemic hypoxia during arm cycling repeated sprints

Willis

Peyrard

Rupp

et al. 2019

Journal of Science and Medicine in Sport

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Objectives: The purpose of this study was to investigate the acute vascular and oxygenation responses to repeated sprint exercise during arm cycling with either blood flow restriction (BFR) or systemic hypoxia alone or in combination. Design: The study design was a single-blinded repeated-measures assessment of four conditions with two levels of normobaric hypoxia (400 m and 3800 m) and two levels of BFR (0% and 45% of total occlusion). Methods: Sixteen active participants (eleven men and five women; mean ± SD; 26.4 ± 4.0 years old; 73.8 ± 9.8 kg; 1.79 ± 0.07 m) completed 5 sessions (1 familiarization, 4 conditions). During each test visit, participants performed a repeated sprint arm cycling test to exhaustion (10 s maximal sprints with 20 s recovery until exhaustion) to measure power output, metabolic equivalents, blood flow, as well as oxygenation (near-infrared spectroscopy) of the biceps brachii muscle tissue. Results: Repeated sprint performance was decreased with both BFR and systemic hypoxia conditions. Greater changes between minimum-maximum of sprints in total hemoglobin concentration ([tHb]) were demonstrated with BFR (400 m, 45% and 3800 m, 45%) than without (400 m, 0% and 3800 m, 0%) (p < 0.001 for both). Additionally, delta tissue saturation index (TSI) decreased more with both BFR conditions than without (p < 0.001 for both). The absolute maximum TSI was progressively reduced with both BFR and systemic hypoxia (p < 0.001). Conclusions: By combining high-intensity, repeated sprint exercise with BFR and/or systemic hypoxia, there is a robust stimulus detected by increased changes in blood perfusion placed on specific vascular mechanisms, which were more prominent in BFR conditions.

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“…Furthermore, several studies demonstrate that reduced blood flow to the exercising limbs produces beneficial adaptive responses that are likely to be responsible for speeded

{\dot{V}}_{O_{2} normalp}

kinetics, such as increased muscle oxidative enzyme activity, capillary density in quadriceps (Conceição et al., ; Esbjörnsson et al., ) and enhanced microvascular filtration capacity in humans (as an index of capillarity; Evans et al., ). Together, these factors might be responsible for speeding

{\dot{V}}_{{normalO}_{2}}

kinetics (Rossiter, ) and increasing

{\dot{V}}_{O_{2} peak}

and exercise tolerance (Abe et al., ; Kancin & Strazar, 2011; Christiansen et al., ; de Oliveira et al., ).…”

Section: Discussionmentioning

confidence: 99%

“…Low‐intensity resistance or endurance exercise training, combined with blood‐flow restriction (BFR), is used as an alternative training method to accrue beneficial muscular training adaptations, among other benefits, especially in those for whom high‐mechanical loads are contraindicated. In particular, endurance BFR training increases several indices of aerobic function, including

{\dot{V}}_{O_{2} \max}

(Abe et al., ; de Oliveira, Caputo, Corvino, & Denadai, ; Park et al., ), exercise tolerance (Abe et al., ; Kancin & Strazar, ; de Oliveira et al., ) and intramuscular adaptations supporting endurance exercise (Christiansen, Eibye, Hostrup, & Bangsbo, ; Christiansen et al., ; Christiansen, Murphy, Bangsbo, Stathis, & Bishop, ). The potential mechanisms responsible for increased

{\dot{V}}_{O_{2} \max}

and exercise tolerance are debated, but include the following: increased stroke volume and cardiac output (Park et al., ); increased muscle capillarity and diffusive oxygen transport (Esbjörnsson et al., ; Evans, Vance, & Brown, ; Kacin & Strazar, ); and increased muscle oxidative enzyme activity (Esbjörnsson et al., ; Kaijser et al., ).…”

Section: Introductionmentioning

confidence: 99%

Speeding of oxygen uptake kinetics is not different following low‐intensity blood‐flow‐restricted and high‐intensity interval training

Corvino

Oliveira

Denadai

et al. 2019

Experimental Physiology

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New Findings What is the central question of this study? Can interval blood‐flow‐restricted (BFR) cycling training, undertaken at a low intensity, promote a similar adaptation to oxygen uptake (V̇normalO2) kinetics to high‐intensity interval training? What is the main finding and its importance? Speeding of pulmonary V̇normalO2 on‐kinetics in healthy young subjects was not different between low‐intensity interval BFR training and traditional high‐intensity interval training. Given that very low workloads are well tolerated during BFR cycle training and speed V̇normalO2 on‐kinetics, this training method could be used when high mechanical loads are contraindicated. Abstract Low‐intensity blood‐flow‐restricted (BFR) endurance training is effective to increase aerobic capacity. Whether it speeds pulmonary oxygen uptake (V̇O2normalp), CO2 output (V̇normalCO2normalp) and ventilatory (V̇ Ep ) kinetics has not been examined. We hypothesized that low‐intensity BFR training would reduce the phase 2 time constant (τp) of V̇O2normalp, V̇normalCO2normalp and V̇ Ep by a similar magnitude to traditional high‐intensity interval training (HIT). Low‐intensity interval training with BFR served as a control. Twenty‐four participants (25 ± 6 years old; maximal V̇normalO2 46 ± 6 ml kg−1 min−1) were assigned to one of the following: low‐intensity BFR interval training (BFR; n = 8); low‐intensity interval training without BFR (LOW; n = 7); or high‐intensity interval training without BFR (HIT; n = 9). Training was 12 sessions of two sets of five to eight × 2 min cycling and 1 min resting intervals. LOW and BFR were conducted at 30% of peak incremental power (Ppeak), and HIT was at ∼103% Ppeak. For BFR, cuffs were inflated on both thighs (140–200 mmHg) during exercise and deflated during rest intervals. Six moderate‐intensity step transitions (30% Ppeak) were averaged for analysis of pulmonary on‐kinetics. Both BFR (pre‐ versus post‐training τp = 18.3 ± 3.2 versus 14.5 ± 3.4 s; effect size = 1.14) and HIT (τp = 20.3 ± 4.0 versus 13.1 ± 2.9 s; effect size = 1.75) reduced the V̇O2normalp τp (P < 0.05). As expected, there was no change in LOW (V̇O2normalp τp = 17.9 ± 6.2 versus 17.7 ± 4.3 s; P = 0.9). The kinetics of V̇normalCO2normalp and V̇ Ep were speeded only after HIT (38.5 ± 10.6%, P < 0.001 and 31.2 ± 24.7%, P = 0.004, respectively). Both HIT and low‐intensity BFR training were effective in speeding moderate‐intensity V̇O2normalp kinetics. These data support the findings of others that low‐intensity cycling training with BFR increases muscle oxidative capacity.

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Cycling with blood flow restriction improves performance and muscle K⁺ regulation and alters the effect of anti‐oxidant infusion in humans

Cited by 54 publications

References 51 publications

Training with blood flow restriction increases femoral artery diameter and thigh oxygen delivery during knee‐extensor exercise in recreationally trained men

Training with blood flow restriction increases femoral artery diameter and thigh oxygen delivery during knee‐extensor exercise in recreationally trained men

Vascular and oxygenation responses of local ischemia and systemic hypoxia during arm cycling repeated sprints

Speeding of oxygen uptake kinetics is not different following low‐intensity blood‐flow‐restricted and high‐intensity interval training

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Cycling with blood flow restriction improves performance and muscle K+ regulation and alters the effect of anti‐oxidant infusion in humans

Cited by 54 publications

References 51 publications

Training with blood flow restriction increases femoral artery diameter and thigh oxygen delivery during knee‐extensor exercise in recreationally trained men

Training with blood flow restriction increases femoral artery diameter and thigh oxygen delivery during knee‐extensor exercise in recreationally trained men

Vascular and oxygenation responses of local ischemia and systemic hypoxia during arm cycling repeated sprints

Speeding of oxygen uptake kinetics is not different following low‐intensity blood‐flow‐restricted and high‐intensity interval training

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Cycling with blood flow restriction improves performance and muscle K⁺ regulation and alters the effect of anti‐oxidant infusion in humans