Unilateral static and dynamic hamstrings stretching increases contralateral hip flexion range of motion

Summary Static (SS) and dynamic stretching (DS) can lead to subsequent performance impairments or enhancement with the stretched limb. Crossover or non‐local muscle fatigue (NLMF) refers to unilateral fatigue‐induced impairments in a contralateral or non‐exercised muscle. Whereas there are conflicti...

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Published inClinical physiology and functional imaging Vol. 37; no. 1; pp. 23 - 29
Main Authors Chaouachi, Anis, Padulo, Johnny, Kasmi, Sofien, Othmen, Aymen Ben, Chatra, Moktar, Behm, David G.
Format Journal Article
LanguageEnglish
Published England Wiley Subscription Services, Inc 01.01.2017
Subjects
Adolescent
Athletes
Biomechanical Phenomena
crossover
Electromyography
flexibility
Hamstring Muscles - physiology
Hip Joint - physiology
Humans
Male
Muscle Contraction
Muscle Strength
Muscle Stretching Exercises - methods
power
Range of Motion, Articular
stretch tolerance
Torque
Tunisia
Young Adult
torque
crossover
flexibility
power
stretch tolerance
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Abstract Summary Static (SS) and dynamic stretching (DS) can lead to subsequent performance impairments or enhancement with the stretched limb. Crossover or non‐local muscle fatigue (NLMF) refers to unilateral fatigue‐induced impairments in a contralateral or non‐exercised muscle. Whereas there are conflicting findings in the NLMF literature, there are few studies examining the effect of an acute bout of SS or DS on contralateral flexibility, torque or power. Fourteen highly trained subjects (means ± standard deviations: 18 ± 2 years; 179·4 ± 4·6 cm; 70·5 ± 6·3 kg; %body fat: 10·7 ± 2·5%) were tested before and following separate sessions of eight repetitions of 30 s of unilateral hip flexion SS or DS. Pre‐ and postintervention testing at 1 and 10 min included hip flexor range of motion (ROM), isokinetic leg flexion torque and power at 60°.s−1 and 300°.s−1 of the stretched and contralateral limbs. The stretched limb had a 6·3% (P = 0·01; ES: 0·91) ROM increase with DS at 10 min. The contralateral non‐stretched hip flexors experienced ROM increases with SS of 5·7% (P = 0·02; ES: 0·68) from pretest to 1 min post‐test, whereas DS showed 7·1% (P<0·0001; ES: 1·09) and 8·4% (P = 0·005; ES: 0·89) increases, respectively. There were no relative differences in ROM changes between conditions or limbs nor any stretch‐induced changes in isokinetic torque or power. In conclusion, unilateral SS and DS augment contralateral limb ROM likely through an increased stretch tolerance.
AbstractList Summary Static ( SS ) and dynamic stretching ( DS ) can lead to subsequent performance impairments or enhancement with the stretched limb. Crossover or non‐local muscle fatigue ( NLMF ) refers to unilateral fatigue‐induced impairments in a contralateral or non‐exercised muscle. Whereas there are conflicting findings in the NLMF literature, there are few studies examining the effect of an acute bout of SS or DS on contralateral flexibility, torque or power. Fourteen highly trained subjects (means ± standard deviations: 18 ± 2 years; 179·4 ± 4·6 cm; 70·5 ± 6·3 kg; %body fat: 10·7 ± 2·5%) were tested before and following separate sessions of eight repetitions of 30 s of unilateral hip flexion SS or DS . Pre‐ and postintervention testing at 1 and 10 min included hip flexor range of motion ( ROM ), isokinetic leg flexion torque and power at 60°.s −1 and 300°.s −1 of the stretched and contralateral limbs. The stretched limb had a 6·3% ( P  = 0·01; ES : 0·91) ROM increase with DS at 10 min. The contralateral non‐stretched hip flexors experienced ROM increases with SS of 5·7% ( P  = 0·02; ES : 0·68) from pretest to 1 min post‐test, whereas DS showed 7·1% ( P< 0·0001; ES : 1·09) and 8·4% ( P  = 0·005; ES : 0·89) increases, respectively. There were no relative differences in ROM changes between conditions or limbs nor any stretch‐induced changes in isokinetic torque or power. In conclusion, unilateral SS and DS augment contralateral limb ROM likely through an increased stretch tolerance.
Summary Static (SS) and dynamic stretching (DS) can lead to subsequent performance impairments or enhancement with the stretched limb. Crossover or non-local muscle fatigue (NLMF) refers to unilateral fatigue-induced impairments in a contralateral or non-exercised muscle. Whereas there are conflicting findings in the NLMF literature, there are few studies examining the effect of an acute bout of SS or DS on contralateral flexibility, torque or power. Fourteen highly trained subjects (means ± standard deviations: 18 ± 2 years; 179·4 ± 4·6 cm; 70·5 ± 6·3 kg; %body fat: 10·7 ± 2·5%) were tested before and following separate sessions of eight repetitions of 30 s of unilateral hip flexion SS or DS. Pre- and postintervention testing at 1 and 10 min included hip flexor range of motion (ROM), isokinetic leg flexion torque and power at 60°.s-1 and 300°.s-1 of the stretched and contralateral limbs. The stretched limb had a 6·3% (P = 0·01; ES: 0·91) ROM increase with DS at 10 min. The contralateral non-stretched hip flexors experienced ROM increases with SS of 5·7% (P = 0·02; ES: 0·68) from pretest to 1 min post-test, whereas DS showed 7·1% (P<0·0001; ES: 1·09) and 8·4% (P = 0·005; ES: 0·89) increases, respectively. There were no relative differences in ROM changes between conditions or limbs nor any stretch-induced changes in isokinetic torque or power. In conclusion, unilateral SS and DS augment contralateral limb ROM likely through an increased stretch tolerance.
Static (SS) and dynamic stretching (DS) can lead to subsequent performance impairments or enhancement with the stretched limb. Crossover or non-local muscle fatigue (NLMF) refers to unilateral fatigue-induced impairments in a contralateral or non-exercised muscle. Whereas there are conflicting findings in the NLMF literature, there are few studies examining the effect of an acute bout of SS or DS on contralateral flexibility, torque or power. Fourteen highly trained subjects (means ± standard deviations: 18 ± 2 years; 179·4 ± 4·6 cm; 70·5 ± 6·3 kg; %body fat: 10·7 ± 2·5%) were tested before and following separate sessions of eight repetitions of 30 s of unilateral hip flexion SS or DS. Pre- and postintervention testing at 1 and 10 min included hip flexor range of motion (ROM), isokinetic leg flexion torque and power at 60°.s and 300°.s of the stretched and contralateral limbs. The stretched limb had a 6·3% (P = 0·01; ES: 0·91) ROM increase with DS at 10 min. The contralateral non-stretched hip flexors experienced ROM increases with SS of 5·7% (P = 0·02; ES: 0·68) from pretest to 1 min post-test, whereas DS showed 7·1% (P<0·0001; ES: 1·09) and 8·4% (P = 0·005; ES: 0·89) increases, respectively. There were no relative differences in ROM changes between conditions or limbs nor any stretch-induced changes in isokinetic torque or power. In conclusion, unilateral SS and DS augment contralateral limb ROM likely through an increased stretch tolerance.
Static (SS) and dynamic stretching (DS) can lead to subsequent performance impairments or enhancement with the stretched limb. Crossover or non-local muscle fatigue (NLMF) refers to unilateral fatigue-induced impairments in a contralateral or non-exercised muscle. Whereas there are conflicting findings in the NLMF literature, there are few studies examining the effect of an acute bout of SS or DS on contralateral flexibility, torque or power. Fourteen highly trained subjects (means ± standard deviations: 18 ± 2 years; 179·4 ± 4·6 cm; 70·5 ± 6·3 kg; %body fat: 10·7 ± 2·5%) were tested before and following separate sessions of eight repetitions of 30 s of unilateral hip flexion SS or DS. Pre- and postintervention testing at 1 and 10 min included hip flexor range of motion (ROM), isokinetic leg flexion torque and power at 60°.s-1 and 300°.s-1 of the stretched and contralateral limbs. The stretched limb had a 6·3% (P = 0·01; ES: 0·91) ROM increase with DS at 10 min. The contralateral non-stretched hip flexors experienced ROM increases with SS of 5·7% (P = 0·02; ES: 0·68) from pretest to 1 min post-test, whereas DS showed 7·1% (P&lt;0·0001; ES: 1·09) and 8·4% (P = 0·005; ES: 0·89) increases, respectively. There were no relative differences in ROM changes between conditions or limbs nor any stretch-induced changes in isokinetic torque or power. In conclusion, unilateral SS and DS augment contralateral limb ROM likely through an increased stretch tolerance.
Summary Static (SS) and dynamic stretching (DS) can lead to subsequent performance impairments or enhancement with the stretched limb. Crossover or non‐local muscle fatigue (NLMF) refers to unilateral fatigue‐induced impairments in a contralateral or non‐exercised muscle. Whereas there are conflicting findings in the NLMF literature, there are few studies examining the effect of an acute bout of SS or DS on contralateral flexibility, torque or power. Fourteen highly trained subjects (means ± standard deviations: 18 ± 2 years; 179·4 ± 4·6 cm; 70·5 ± 6·3 kg; %body fat: 10·7 ± 2·5%) were tested before and following separate sessions of eight repetitions of 30 s of unilateral hip flexion SS or DS. Pre‐ and postintervention testing at 1 and 10 min included hip flexor range of motion (ROM), isokinetic leg flexion torque and power at 60°.s−1 and 300°.s−1 of the stretched and contralateral limbs. The stretched limb had a 6·3% (P = 0·01; ES: 0·91) ROM increase with DS at 10 min. The contralateral non‐stretched hip flexors experienced ROM increases with SS of 5·7% (P = 0·02; ES: 0·68) from pretest to 1 min post‐test, whereas DS showed 7·1% (P<0·0001; ES: 1·09) and 8·4% (P = 0·005; ES: 0·89) increases, respectively. There were no relative differences in ROM changes between conditions or limbs nor any stretch‐induced changes in isokinetic torque or power. In conclusion, unilateral SS and DS augment contralateral limb ROM likely through an increased stretch tolerance.
Author Padulo, Johnny
Kasmi, Sofien
Behm, David G.
Chaouachi, Anis
Othmen, Aymen Ben
Chatra, Moktar
Author_xml – sequence: 1
  givenname: Anis
  surname: Chaouachi
  fullname: Chaouachi, Anis
  organization: National Center of Medicine and Science in Sports (CNMSS)
– sequence: 2
  givenname: Johnny
  surname: Padulo
  fullname: Padulo, Johnny
  organization: National Center of Medicine and Science in Sports (CNMSS)
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  givenname: Sofien
  surname: Kasmi
  fullname: Kasmi, Sofien
  organization: National Center of Medicine and Science in Sports (CNMSS)
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  surname: Othmen
  fullname: Othmen, Aymen Ben
  organization: National Center of Medicine and Science in Sports (CNMSS)
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  surname: Chatra
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  organization: National Center of Medicine and Science in Sports (CNMSS)
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  givenname: David G.
  surname: Behm
  fullname: Behm, David G.
  email: dbehm@mun.ca
  organization: Memorial University of Newfoundland
BackLink https://www.ncbi.nlm.nih.gov/pubmed/26017182$$D View this record in MEDLINE/PubMed
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ContentType Journal Article
Copyright 2015 Scandinavian Society of Clinical Physiology and Nuclear Medicine. Published by John Wiley & Sons Ltd
2015 Scandinavian Society of Clinical Physiology and Nuclear Medicine. Published by John Wiley & Sons Ltd.
Copyright © 2017 Scandinavian Society of Clinical Physiology and Nuclear Medicine
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Issue 1
Keywords torque
crossover
flexibility
power
stretch tolerance
Language English
License 2015 Scandinavian Society of Clinical Physiology and Nuclear Medicine. Published by John Wiley & Sons Ltd.
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Snippet Summary Static (SS) and dynamic stretching (DS) can lead to subsequent performance impairments or enhancement with the stretched limb. Crossover or non‐local...
Static (SS) and dynamic stretching (DS) can lead to subsequent performance impairments or enhancement with the stretched limb. Crossover or non-local muscle...
Summary Static ( SS ) and dynamic stretching ( DS ) can lead to subsequent performance impairments or enhancement with the stretched limb. Crossover or...
Summary Static (SS) and dynamic stretching (DS) can lead to subsequent performance impairments or enhancement with the stretched limb. Crossover or non-local...
SourceID proquest
crossref
pubmed
wiley
SourceType Aggregation Database
Index Database
Publisher
StartPage 23
SubjectTerms Adolescent
Athletes
Biomechanical Phenomena
crossover
Electromyography
flexibility
Hamstring Muscles - physiology
Hip Joint - physiology
Humans
Male
Muscle Contraction
Muscle Strength
Muscle Stretching Exercises - methods
power
Range of Motion, Articular
stretch tolerance
Torque
Tunisia
Young Adult
Title Unilateral static and dynamic hamstrings stretching increases contralateral hip flexion range of motion
URI https://onlinelibrary.wiley.com/doi/abs/10.1111%2Fcpf.12263
https://www.ncbi.nlm.nih.gov/pubmed/26017182
https://www.proquest.com/docview/1848275608
https://search.proquest.com/docview/1826626406
Volume 37
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