Blood flow occlusion-related O2 extraction “reserve” is present in different muscles of the quadriceps but greater in deeper regions after ramp-incremental test

Danilo Iannetta; Dai Okushima; Erin Calaine Inglis; Narihiko Kondo; Juan M. Murias; Shunsaku Koga

doi:10.1152/japplphysiol.00154.2018

Blood flow occlusion-related O₂ extraction “reserve” is present in different muscles of the quadriceps but greater in deeper regions after ramp-incremental test

Danilo Iannetta^*, Dai Okushima, Erin Calaine Inglis, Narihiko Kondo, Juan M. Murias, Shunsaku Koga

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

19 Citations (Scopus)

Abstract

Blood

present in different muscles of the quadriceps but greater in deeper regions after ramp-incremental test. J Appl Physiol 125: 313–319, 2018. First published May 3, 2018; doi:10.1152/japplphysiol.00154. 2018.—It was recently demonstrated that an O2 extraction reserve, as assessed by the near-infrared spectroscopy (NIRS)-derived deoxygenation signal ([HHb]), exists in the superficial region of vastus lateralis (VL) muscle during an occlusion performed at the end of a ramp-incremental test. However, it is unknown whether this reserve is present and/or different in magnitude in other portions and depths of the quadriceps muscles. We tested the hypothesis that an O2 extraction reserve would exist in other regions of this muscle but is greater in deep compared with more superficial portions. Superficial (VL-s) and deep VL (VL-d) as well as superficial rectus femoris (RF-s) were monitored by a combination of low- and high-power time-resolved (TRS) NIRS. During the occlusion immediately post-ramp-incremental test there was a significant overshoot in the [HHb] signal (P 0.05). However, the magnitude of this increase was greater in VL-d (93.2 42.9%) compared with VL-s (55.0 19.6%) and RF-s (47.8 14.0%) (P 0.05). The present study demonstrated that an O2 extraction reserve exists in different pools of active muscle fibers of the quadriceps at the end of a ramp exercise to exhaustion. The greater magnitude in the reserve observed in the deeper portion of VL, however, suggests that this portion of muscle may present a greater surplus of oxygenated blood, which is likely due to a greater population of slow-twitch fibers. These findings add to the notion that the plateau in the [HHb] signal toward the end of a ramp-incremental exercise does not indicate the upper limit of O2 extraction. NEW & NOTEWORTHY Different portions of the quadriceps muscles exhibited an untapped O2 extraction reserve during a blood flow occlusion performed at the end of a ramp-incremental exercise. In the deeper portion of the vastus lateralis muscle, this reserve was greater compared with superficial vastus lateralis and rectus femoris. These data suggest that the O2 extraction reserve may be dependent on the vascular and/or oxidative capacities of the muscles.

Original language	English
Pages (from-to)	313-319
Number of pages	7
Journal	Journal of Applied Physiology
Volume	125
Issue number	2
DOIs	https://doi.org/10.1152/japplphysiol.00154.2018
Publication status	Published - Aug 2018
Externally published	Yes

Keywords

Muscle blood flow heterogeneity
Occlusion
Ramp exercise
[HHb] reserve

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10.1152/japplphysiol.00154.2018

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@article{8dc81d0026fd445f997701f468349235,

title = "Blood flow occlusion-related O2 extraction “reserve” is present in different muscles of the quadriceps but greater in deeper regions after ramp-incremental test",

abstract = "Bloodpresent in different muscles of the quadriceps but greater in deeper regions after ramp-incremental test. J Appl Physiol 125: 313–319, 2018. First published May 3, 2018; doi:10.1152/japplphysiol.00154. 2018.—It was recently demonstrated that an O2 extraction reserve, as assessed by the near-infrared spectroscopy (NIRS)-derived deoxygenation signal ([HHb]), exists in the superficial region of vastus lateralis (VL) muscle during an occlusion performed at the end of a ramp-incremental test. However, it is unknown whether this reserve is present and/or different in magnitude in other portions and depths of the quadriceps muscles. We tested the hypothesis that an O2 extraction reserve would exist in other regions of this muscle but is greater in deep compared with more superficial portions. Superficial (VL-s) and deep VL (VL-d) as well as superficial rectus femoris (RF-s) were monitored by a combination of low- and high-power time-resolved (TRS) NIRS. During the occlusion immediately post-ramp-incremental test there was a significant overshoot in the [HHb] signal (P 0.05). However, the magnitude of this increase was greater in VL-d (93.2 42.9\%) compared with VL-s (55.0 19.6\%) and RF-s (47.8 14.0\%) (P 0.05). The present study demonstrated that an O2 extraction reserve exists in different pools of active muscle fibers of the quadriceps at the end of a ramp exercise to exhaustion. The greater magnitude in the reserve observed in the deeper portion of VL, however, suggests that this portion of muscle may present a greater surplus of oxygenated blood, which is likely due to a greater population of slow-twitch fibers. These findings add to the notion that the plateau in the [HHb] signal toward the end of a ramp-incremental exercise does not indicate the upper limit of O2 extraction. NEW \& NOTEWORTHY Different portions of the quadriceps muscles exhibited an untapped O2 extraction reserve during a blood flow occlusion performed at the end of a ramp-incremental exercise. In the deeper portion of the vastus lateralis muscle, this reserve was greater compared with superficial vastus lateralis and rectus femoris. These data suggest that the O2 extraction reserve may be dependent on the vascular and/or oxidative capacities of the muscles.",

keywords = "Muscle blood flow heterogeneity, Occlusion, Ramp exercise, [HHb] reserve",

author = "Danilo Iannetta and Dai Okushima and Inglis, \{Erin Calaine\} and Narihiko Kondo and Murias, \{Juan M.\} and Shunsaku Koga",

note = "Publisher Copyright: Copyright {\textcopyright} 2018 the American Physiological Society.",

year = "2018",

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doi = "10.1152/japplphysiol.00154.2018",

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T1 - Blood flow occlusion-related O2 extraction “reserve” is present in different muscles of the quadriceps but greater in deeper regions after ramp-incremental test

AU - Iannetta, Danilo

AU - Okushima, Dai

AU - Inglis, Erin Calaine

AU - Kondo, Narihiko

AU - Murias, Juan M.

AU - Koga, Shunsaku

PY - 2018/8

Y1 - 2018/8

N2 - Bloodpresent in different muscles of the quadriceps but greater in deeper regions after ramp-incremental test. J Appl Physiol 125: 313–319, 2018. First published May 3, 2018; doi:10.1152/japplphysiol.00154. 2018.—It was recently demonstrated that an O2 extraction reserve, as assessed by the near-infrared spectroscopy (NIRS)-derived deoxygenation signal ([HHb]), exists in the superficial region of vastus lateralis (VL) muscle during an occlusion performed at the end of a ramp-incremental test. However, it is unknown whether this reserve is present and/or different in magnitude in other portions and depths of the quadriceps muscles. We tested the hypothesis that an O2 extraction reserve would exist in other regions of this muscle but is greater in deep compared with more superficial portions. Superficial (VL-s) and deep VL (VL-d) as well as superficial rectus femoris (RF-s) were monitored by a combination of low- and high-power time-resolved (TRS) NIRS. During the occlusion immediately post-ramp-incremental test there was a significant overshoot in the [HHb] signal (P 0.05). However, the magnitude of this increase was greater in VL-d (93.2 42.9%) compared with VL-s (55.0 19.6%) and RF-s (47.8 14.0%) (P 0.05). The present study demonstrated that an O2 extraction reserve exists in different pools of active muscle fibers of the quadriceps at the end of a ramp exercise to exhaustion. The greater magnitude in the reserve observed in the deeper portion of VL, however, suggests that this portion of muscle may present a greater surplus of oxygenated blood, which is likely due to a greater population of slow-twitch fibers. These findings add to the notion that the plateau in the [HHb] signal toward the end of a ramp-incremental exercise does not indicate the upper limit of O2 extraction. NEW & NOTEWORTHY Different portions of the quadriceps muscles exhibited an untapped O2 extraction reserve during a blood flow occlusion performed at the end of a ramp-incremental exercise. In the deeper portion of the vastus lateralis muscle, this reserve was greater compared with superficial vastus lateralis and rectus femoris. These data suggest that the O2 extraction reserve may be dependent on the vascular and/or oxidative capacities of the muscles.

AB - Bloodpresent in different muscles of the quadriceps but greater in deeper regions after ramp-incremental test. J Appl Physiol 125: 313–319, 2018. First published May 3, 2018; doi:10.1152/japplphysiol.00154. 2018.—It was recently demonstrated that an O2 extraction reserve, as assessed by the near-infrared spectroscopy (NIRS)-derived deoxygenation signal ([HHb]), exists in the superficial region of vastus lateralis (VL) muscle during an occlusion performed at the end of a ramp-incremental test. However, it is unknown whether this reserve is present and/or different in magnitude in other portions and depths of the quadriceps muscles. We tested the hypothesis that an O2 extraction reserve would exist in other regions of this muscle but is greater in deep compared with more superficial portions. Superficial (VL-s) and deep VL (VL-d) as well as superficial rectus femoris (RF-s) were monitored by a combination of low- and high-power time-resolved (TRS) NIRS. During the occlusion immediately post-ramp-incremental test there was a significant overshoot in the [HHb] signal (P 0.05). However, the magnitude of this increase was greater in VL-d (93.2 42.9%) compared with VL-s (55.0 19.6%) and RF-s (47.8 14.0%) (P 0.05). The present study demonstrated that an O2 extraction reserve exists in different pools of active muscle fibers of the quadriceps at the end of a ramp exercise to exhaustion. The greater magnitude in the reserve observed in the deeper portion of VL, however, suggests that this portion of muscle may present a greater surplus of oxygenated blood, which is likely due to a greater population of slow-twitch fibers. These findings add to the notion that the plateau in the [HHb] signal toward the end of a ramp-incremental exercise does not indicate the upper limit of O2 extraction. NEW & NOTEWORTHY Different portions of the quadriceps muscles exhibited an untapped O2 extraction reserve during a blood flow occlusion performed at the end of a ramp-incremental exercise. In the deeper portion of the vastus lateralis muscle, this reserve was greater compared with superficial vastus lateralis and rectus femoris. These data suggest that the O2 extraction reserve may be dependent on the vascular and/or oxidative capacities of the muscles.

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KW - Occlusion

KW - Ramp exercise

KW - [HHb] reserve

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ER -

Blood flow occlusion-related O₂ extraction “reserve” is present in different muscles of the quadriceps but greater in deeper regions after ramp-incremental test

Abstract

Keywords

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