Effects of arm cranking exercise on muscle oxygenation between active and inactive muscles in people with spinal cord injury

Objective: We investigated the effects of the incremental arm-cranking exercise (ACE) on tissue oxygen saturation (StO 2 ) between active and inactive muscles, and the relationship between peak oxygen uptake (VO 2peak ) and changes in the StO 2 in inactive muscles. Design: Observational study. Setti...

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Published inThe journal of spinal cord medicine Vol. 44; no. 6; pp. 931 - 939
Main Author Horiuchi, Masahiro
Format Journal Article
LanguageEnglish
Published England Taylor & Francis 02.11.2021
Subjects
Arm
Autonomic Dysfunction
Blood Flow
Exercise Therapy - methods
Extraction
Heart Rate
Humans
Muscle, Skeletal
Oxygen Consumption - physiology
Spinal Cord Injuries
Sympathetic Vasoconstriction
Heart Rate
O2 Extraction
Sympathetic Vasoconstriction
Blood Flow
Autonomic Dysfunction
Online AccessGet full text
ISSN1079-0268
2045-7723
2045-7723
DOI10.1080/10790268.2020.1754649

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Abstract Objective: We investigated the effects of the incremental arm-cranking exercise (ACE) on tissue oxygen saturation (StO 2 ) between active and inactive muscles, and the relationship between peak oxygen uptake (VO 2peak ) and changes in the StO 2 in inactive muscles. Design: Observational study. Setting: Community-based supervised intervention. Participants: The participants were individuals with motor and sensory complete spinal cord injury (complete SCI; n = 8) and motor complete but sensory incomplete SCI (incomplete SCI; n = 8), and able-bodied (AB) individuals (n = 8) matched for age, height, and body mass index. Intervention: The ACE was performed at a rate increasing by 10 watts min −1 until exhaustion. Outcome Measures: VO 2peak , heart rate (HR), and StO 2 . Results: While VO 2peak was similar among the groups, peak HR was significantly higher in both SCI groups than in the AB (P < 0.05). In active muscles (biceps brachii), no differences in the StO 2 were observed among the groups (P > 0.05). In inactive muscles (vastus lateralis), the StO 2 in the AB and the incomplete SCI began to decrease at approximately 40% of the peak work rate; however, they remained unchanged in the complete SCI. The reductions in StO 2 in the AB were significantly greater than in the incomplete SCI. Conclusions: These results suggest that sympathetic vasoconstriction occurred in the incomplete SCI and AB, although it did not occur in the complete SCI, probably due to a reduction in sympathetic nerve activity. Sympathetic vasoconstriction in inactive muscles may not contribute to an individual's VO 2peak regardless of their group.
AbstractList Objective: We investigated the effects of the incremental arm-cranking exercise (ACE) on tissue oxygen saturation (StO 2 ) between active and inactive muscles, and the relationship between peak oxygen uptake (VO 2peak ) and changes in the StO 2 in inactive muscles. Design: Observational study. Setting: Community-based supervised intervention. Participants: The participants were individuals with motor and sensory complete spinal cord injury (complete SCI; n = 8) and motor complete but sensory incomplete SCI (incomplete SCI; n = 8), and able-bodied (AB) individuals (n = 8) matched for age, height, and body mass index. Intervention: The ACE was performed at a rate increasing by 10 watts min −1 until exhaustion. Outcome Measures: VO 2peak , heart rate (HR), and StO 2 . Results: While VO 2peak was similar among the groups, peak HR was significantly higher in both SCI groups than in the AB (P < 0.05). In active muscles (biceps brachii), no differences in the StO 2 were observed among the groups (P > 0.05). In inactive muscles (vastus lateralis), the StO 2 in the AB and the incomplete SCI began to decrease at approximately 40% of the peak work rate; however, they remained unchanged in the complete SCI. The reductions in StO 2 in the AB were significantly greater than in the incomplete SCI. Conclusions: These results suggest that sympathetic vasoconstriction occurred in the incomplete SCI and AB, although it did not occur in the complete SCI, probably due to a reduction in sympathetic nerve activity. Sympathetic vasoconstriction in inactive muscles may not contribute to an individual’s VO 2peak regardless of their group.
We investigated the effects of the incremental arm-cranking exercise (ACE) on tissue oxygen saturation (StO ) between active and inactive muscles, and the relationship between peak oxygen uptake (VO ) and changes in the StO in inactive muscles. Observational study. Community-based supervised intervention. The participants were individuals with motor and sensory complete spinal cord injury (complete SCI; n = 8) and motor complete but sensory incomplete SCI (incomplete SCI; n = 8), and able-bodied (AB) individuals (n = 8) matched for age, height, and body mass index. The ACE was performed at a rate increasing by 10 watts min until exhaustion. VO , heart rate (HR), and StO . While VO was similar among the groups, peak HR was significantly higher in both SCI groups than in the AB (P < 0.05). In active muscles (biceps brachii), no differences in the StO were observed among the groups (P > 0.05). In inactive muscles (vastus lateralis), the StO in the AB and the incomplete SCI began to decrease at approximately 40% of the peak work rate; however, they remained unchanged in the complete SCI. The reductions in StO in the AB were significantly greater than in the incomplete SCI. These results suggest that sympathetic vasoconstriction occurred in the incomplete SCI and AB, although it did not occur in the complete SCI, probably due to a reduction in sympathetic nerve activity. Sympathetic vasoconstriction in inactive muscles may not contribute to an individual's VO regardless of their group.
Objective: We investigated the effects of the incremental arm-cranking exercise (ACE) on tissue oxygen saturation (StO 2 ) between active and inactive muscles, and the relationship between peak oxygen uptake (VO 2peak ) and changes in the StO 2 in inactive muscles. Design: Observational study. Setting: Community-based supervised intervention. Participants: The participants were individuals with motor and sensory complete spinal cord injury (complete SCI; n = 8) and motor complete but sensory incomplete SCI (incomplete SCI; n = 8), and able-bodied (AB) individuals (n = 8) matched for age, height, and body mass index. Intervention: The ACE was performed at a rate increasing by 10 watts min −1 until exhaustion. Outcome Measures: VO 2peak , heart rate (HR), and StO 2 . Results: While VO 2peak was similar among the groups, peak HR was significantly higher in both SCI groups than in the AB (P < 0.05). In active muscles (biceps brachii), no differences in the StO 2 were observed among the groups (P > 0.05). In inactive muscles (vastus lateralis), the StO 2 in the AB and the incomplete SCI began to decrease at approximately 40% of the peak work rate; however, they remained unchanged in the complete SCI. The reductions in StO 2 in the AB were significantly greater than in the incomplete SCI. Conclusions: These results suggest that sympathetic vasoconstriction occurred in the incomplete SCI and AB, although it did not occur in the complete SCI, probably due to a reduction in sympathetic nerve activity. Sympathetic vasoconstriction in inactive muscles may not contribute to an individual's VO 2peak regardless of their group.
Objective: We investigated the effects of the incremental arm-cranking exercise (ACE) on tissue oxygen saturation (StO2) between active and inactive muscles, and the relationship between peak oxygen uptake (VO2peak) and changes in the StO2 in inactive muscles.Design: Observational study.Setting: Community-based supervised intervention.Participants: The participants were individuals with motor and sensory complete spinal cord injury (complete SCI; n = 8) and motor complete but sensory incomplete SCI (incomplete SCI; n = 8), and able-bodied (AB) individuals (n = 8) matched for age, height, and body mass index.Intervention: The ACE was performed at a rate increasing by 10 watts min-1 until exhaustion.Outcome Measures: VO2peak, heart rate (HR), and StO2.Results: While VO2peak was similar among the groups, peak HR was significantly higher in both SCI groups than in the AB (P < 0.05). In active muscles (biceps brachii), no differences in the StO2 were observed among the groups (P > 0.05). In inactive muscles (vastus lateralis), the StO2 in the AB and the incomplete SCI began to decrease at approximately 40% of the peak work rate; however, they remained unchanged in the complete SCI. The reductions in StO2 in the AB were significantly greater than in the incomplete SCI.Conclusions: These results suggest that sympathetic vasoconstriction occurred in the incomplete SCI and AB, although it did not occur in the complete SCI, probably due to a reduction in sympathetic nerve activity. Sympathetic vasoconstriction in inactive muscles may not contribute to an individual's VO2peak regardless of their group.Objective: We investigated the effects of the incremental arm-cranking exercise (ACE) on tissue oxygen saturation (StO2) between active and inactive muscles, and the relationship between peak oxygen uptake (VO2peak) and changes in the StO2 in inactive muscles.Design: Observational study.Setting: Community-based supervised intervention.Participants: The participants were individuals with motor and sensory complete spinal cord injury (complete SCI; n = 8) and motor complete but sensory incomplete SCI (incomplete SCI; n = 8), and able-bodied (AB) individuals (n = 8) matched for age, height, and body mass index.Intervention: The ACE was performed at a rate increasing by 10 watts min-1 until exhaustion.Outcome Measures: VO2peak, heart rate (HR), and StO2.Results: While VO2peak was similar among the groups, peak HR was significantly higher in both SCI groups than in the AB (P < 0.05). In active muscles (biceps brachii), no differences in the StO2 were observed among the groups (P > 0.05). In inactive muscles (vastus lateralis), the StO2 in the AB and the incomplete SCI began to decrease at approximately 40% of the peak work rate; however, they remained unchanged in the complete SCI. The reductions in StO2 in the AB were significantly greater than in the incomplete SCI.Conclusions: These results suggest that sympathetic vasoconstriction occurred in the incomplete SCI and AB, although it did not occur in the complete SCI, probably due to a reduction in sympathetic nerve activity. Sympathetic vasoconstriction in inactive muscles may not contribute to an individual's VO2peak regardless of their group.
Author Horiuchi, Masahiro
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  email: mhoriuchi@mfri.pref.yamanashi.jp
  organization: Division of Human Environmental Science, Mount Fuji Research Institute
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Snippet Objective: We investigated the effects of the incremental arm-cranking exercise (ACE) on tissue oxygen saturation (StO 2 ) between active and inactive muscles,...
We investigated the effects of the incremental arm-cranking exercise (ACE) on tissue oxygen saturation (StO ) between active and inactive muscles, and the...
Objective: We investigated the effects of the incremental arm-cranking exercise (ACE) on tissue oxygen saturation (StO2) between active and inactive muscles,...
Objective: We investigated the effects of the incremental arm-cranking exercise (ACE) on tissue oxygen saturation (StO 2 ) between active and inactive muscles,...
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SubjectTerms Arm
Autonomic Dysfunction
Blood Flow
Exercise Therapy - methods
Extraction
Heart Rate
Humans
Muscle, Skeletal
Oxygen Consumption - physiology
Spinal Cord Injuries
Sympathetic Vasoconstriction
Title Effects of arm cranking exercise on muscle oxygenation between active and inactive muscles in people with spinal cord injury
URI https://www.tandfonline.com/doi/abs/10.1080/10790268.2020.1754649
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