Background <p>Precise monitoring of training intensity in rowing requires indicators capturing both systemic and local physiological responses. Muscle oxygen saturation (SmO<sub>2</sub>), measured by near-infrared spectroscopy (NIRS), reflects local muscular oxygen utilization and may complement traditional systemic indicators such as heart rate (HR), oxygen uptake (V̇O<sub>2</sub>), and mechanical power output (P). This study aimed to investigate SmO<sub>2</sub> dynamics in upper- (biceps brachii, BB) and lower-limb (vastus lateralis, VL) muscles during incremental exercise, representative training sessions, and a 2000&#xa0;m rowing ergometer race, and to evaluate its practical application for individualized monitoring.</p> Methods <p>Twenty-six trained male rowers (age: 19.96 ± 2.66 years; height: 189.12 ± 6.13&#xa0;cm; body mass: 80.12 ± 9.21&#xa0;kg) performed a graded incremental test, four representative training sessions, and a 2000&#xa0;m race on a rowing ergometer. SmO<sub>2</sub> was measured continuously on biceps brachii and vastus lateralis using portable NIRS devices, along with HR, V̇O<sub>2</sub>, and P. Linear mixed-effects models were used to examine within-subject associations between SmO<sub>2</sub> and systemic indicators, accounting for repeated measures across exercise stages.</p> Results <p>During incremental exercise, SmO<sub>2</sub>-VL decreased from 73.7 ± 6.76% at rest to 7.88 ± 4.12% at maximal power, whereas SmO<sub>2</sub>-BB decreased from 68.18 ± 4.49% to 28.93 ± 6.29%. Within-subject associations between SmO<sub>2</sub>-VL and V̇O<sub>2</sub> (β = −1.255, 95% CI − 1.315 to − 1.194, <i>p</i> &lt; 0.001), HR (β = −0.647, 95% CI − 0.675 to − 0.618, <i>p</i> &lt; 0.001), and P (β = −0.186, 95% CI − 0.194 to − 0.177, <i>p</i> &lt; 0.001) were significantly stronger than corresponding SmO<sub>2</sub>-BB associations. SmO<sub>2</sub>-VL also exhibited robust negative associations with HR (<i>r</i> = − 0.857, <i>p</i> &lt; 0.001) and P (<i>r</i> = − 0.841, <i>p</i> &lt; 0.001) during the 2000&#xa0;m race. Variability in SmO<sub>2</sub> responses across training sessions reflected differences in exercise intensity.</p> Conclusion <p>SmO<sub>2</sub> decreases progressively with increasing exercise intensity, with the vastus lateralis showing greater sensitivity than the biceps brachii. Within-subject SmO<sub>2</sub>-VL measurements provide a reliable indicator of local muscular oxygen extraction and can complement systemic variables for individualized training monitoring in rowing.</p>

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Muscle oxygen saturation reflects individualized responses to exercise intensity during rowing ergometer exercise

  • Jinghao Yan,
  • Zhijun Meng,
  • Binghong Gao

摘要

Background

Precise monitoring of training intensity in rowing requires indicators capturing both systemic and local physiological responses. Muscle oxygen saturation (SmO2), measured by near-infrared spectroscopy (NIRS), reflects local muscular oxygen utilization and may complement traditional systemic indicators such as heart rate (HR), oxygen uptake (V̇O2), and mechanical power output (P). This study aimed to investigate SmO2 dynamics in upper- (biceps brachii, BB) and lower-limb (vastus lateralis, VL) muscles during incremental exercise, representative training sessions, and a 2000 m rowing ergometer race, and to evaluate its practical application for individualized monitoring.

Methods

Twenty-six trained male rowers (age: 19.96 ± 2.66 years; height: 189.12 ± 6.13 cm; body mass: 80.12 ± 9.21 kg) performed a graded incremental test, four representative training sessions, and a 2000 m race on a rowing ergometer. SmO2 was measured continuously on biceps brachii and vastus lateralis using portable NIRS devices, along with HR, V̇O2, and P. Linear mixed-effects models were used to examine within-subject associations between SmO2 and systemic indicators, accounting for repeated measures across exercise stages.

Results

During incremental exercise, SmO2-VL decreased from 73.7 ± 6.76% at rest to 7.88 ± 4.12% at maximal power, whereas SmO2-BB decreased from 68.18 ± 4.49% to 28.93 ± 6.29%. Within-subject associations between SmO2-VL and V̇O2 (β = −1.255, 95% CI − 1.315 to − 1.194, p < 0.001), HR (β = −0.647, 95% CI − 0.675 to − 0.618, p < 0.001), and P (β = −0.186, 95% CI − 0.194 to − 0.177, p < 0.001) were significantly stronger than corresponding SmO2-BB associations. SmO2-VL also exhibited robust negative associations with HR (r = − 0.857, p < 0.001) and P (r = − 0.841, p < 0.001) during the 2000 m race. Variability in SmO2 responses across training sessions reflected differences in exercise intensity.

Conclusion

SmO2 decreases progressively with increasing exercise intensity, with the vastus lateralis showing greater sensitivity than the biceps brachii. Within-subject SmO2-VL measurements provide a reliable indicator of local muscular oxygen extraction and can complement systemic variables for individualized training monitoring in rowing.