Knee Muscle Activation Characteristics During Closed Kinetic Chain Directional Loading in Healthy Young Males and Females

Flaxman, Teresa

30 March 2011

Neuromuscular control is believed to play an essential role during dynamic knee joint stabilisation. Evaluation of voluntary muscle action can be delineated as support strategies against external loading moments (Lloyd & Buchanan, 2001). The aim of this study was to determine if males and females exhibit differences in knee muscle action and cocontraction during voluntary isometric closed kinetic chain force generation in various directions in the horizontal plane representative of applied loads transverse to the long axis of the shank. Twenty-six healthy young adults (13 male, 13 female) stood with their dominant leg in a boot fixed to a force platform. A force target matching protocol required subjects to position a cursor (projected on a video screen) over a target and maintain the position for one second. To control the cursor, loads were applied against the force platform with their dominant leg to produce various combinations of anterior-posterior, medial-lateral loads while maintaining constant inferior-superior loads. A successful target match required a normalised force magnitude of equal effort for each subject and target location which triggered the recording of electromyography (EMG) for eight muscles crossing the knee joint. EMG was normalised to percent maximum voluntary isometric contraction. A mean magnitude of muscle activation, mean direction of muscle activation and a muscle specificity index was determined using EMG vectors. In addition, cocontraction indices were also computed for antagonist muscle pairs. Based on similar previous research, it was hypothesised that females would have greater quadriceps and hamstrings coactivation, greater muscle activation magnitudes, lower specificity for the quadriceps than males and no difference in hamstring characteristics. In our study, females significantly cocontracted their vastus lateralis and lateral gastrocnemius muscles to a greater degree than males (p=0.001). No significant differences were observed across sexes for the cocontraction of quadriceps and hamstrings or the lateral quadriceps and gastrocnemius muscles. Females displayed significantly lower specificity than males in their semitendinosus (p=0.025) and tensor fascia lata (p=0.012) activity patterns, greater magnitude of muscle activation in their lateral gastrocnemius (p=0.002) and tensor fascia lata (p<0.003) and no statistical difference in the other muscles. Furthermore, the activation patterns in our study grossly differed from previous open kinetic chain force target matching. These findings indicate that healthy young males and females have differences in their knee muscle control strategies and that knee muscle recruitment patterns differ during weight bearing and non-weight bearing tasks.

Knee

Muscle Activity

Joint Stabilisation

Sex Differences

Cocontraction

Closed Kinetic Chain

Isometric

Knee Muscle Activation Characteristics During Closed Kinetic Chain Directional Loading in Healthy Young Males and Females

Flaxman, Teresa

30 March 2011

Neuromuscular control is believed to play an essential role during dynamic knee joint stabilisation. Evaluation of voluntary muscle action can be delineated as support strategies against external loading moments (Lloyd & Buchanan, 2001). The aim of this study was to determine if males and females exhibit differences in knee muscle action and cocontraction during voluntary isometric closed kinetic chain force generation in various directions in the horizontal plane representative of applied loads transverse to the long axis of the shank. Twenty-six healthy young adults (13 male, 13 female) stood with their dominant leg in a boot fixed to a force platform. A force target matching protocol required subjects to position a cursor (projected on a video screen) over a target and maintain the position for one second. To control the cursor, loads were applied against the force platform with their dominant leg to produce various combinations of anterior-posterior, medial-lateral loads while maintaining constant inferior-superior loads. A successful target match required a normalised force magnitude of equal effort for each subject and target location which triggered the recording of electromyography (EMG) for eight muscles crossing the knee joint. EMG was normalised to percent maximum voluntary isometric contraction. A mean magnitude of muscle activation, mean direction of muscle activation and a muscle specificity index was determined using EMG vectors. In addition, cocontraction indices were also computed for antagonist muscle pairs. Based on similar previous research, it was hypothesised that females would have greater quadriceps and hamstrings coactivation, greater muscle activation magnitudes, lower specificity for the quadriceps than males and no difference in hamstring characteristics. In our study, females significantly cocontracted their vastus lateralis and lateral gastrocnemius muscles to a greater degree than males (p=0.001). No significant differences were observed across sexes for the cocontraction of quadriceps and hamstrings or the lateral quadriceps and gastrocnemius muscles. Females displayed significantly lower specificity than males in their semitendinosus (p=0.025) and tensor fascia lata (p=0.012) activity patterns, greater magnitude of muscle activation in their lateral gastrocnemius (p=0.002) and tensor fascia lata (p<0.003) and no statistical difference in the other muscles. Furthermore, the activation patterns in our study grossly differed from previous open kinetic chain force target matching. These findings indicate that healthy young males and females have differences in their knee muscle control strategies and that knee muscle recruitment patterns differ during weight bearing and non-weight bearing tasks.

Knee

Muscle Activity

Joint Stabilisation

Sex Differences

Cocontraction

Closed Kinetic Chain

Isometric

Caractérisation biomécanique et physiologique de la cocontraction spastique dans la parésie spastique

Vinti, Mariaconceta

29 November 2012

La cocontraction spastique, anomalie ubiquitaire de la commande motrice dans la population parétique, est l'une des formes d'hyperactivité musculaire handicapant le plus sévèrement le mouvement volontaire du sujet atteint de parésie spastique, au membre supérieur comme à la marche. Expliquée par une mauvaise distribution de la commande descendante, la cocontraction spastique est une contraction exagérée du muscle antagoniste, déclenchée par la commande sur l'agoniste, qui vient créer un couple d'opposition voire d'inversion du mouvement désiré. Ce phénomène longtemps sous estimé par cliniciens et chercheurs a été peu caractérisé d'un point de vue biomécanique et physiologique. Cette thèse a eu pour objectif de participer à cette caractérisation, au sein d'une population de sujets atteints d'une parésie spastique. Le présent travail a permis : l'étude des réactivités des cocontractions antagonistes face à des changements de la commande centrale (différents niveaux d'efforts) et des changements périphériques (muscle antagoniste relâché ou étiré) en condition statique (isométrique) ; sa quantification en condition dynamique (phase oscillante de la marche) et enfin sa sensibilité à un agent bloqueur de la jonction neuromusculaire (toxine botulique). Les résultats de ces études permettront aux cliniciens de mieux évaluer et intégrer dans leur examen le phénomène de cocontraction spastique, en dirigeant peut-être leur réflexion vers de nouvelles mesures thérapeutiques. Pour le biomécanicien et le neurophysiologiste, plusieurs outils d'évaluation sont présentés avec un canevas d'indices dynamométriques et électromyographiques susceptibles de faciliter la recherche ultérieure sur le phénomène de cocontraction spastique en particulier, et sur la parésie spastique de façon plus générale.

[SPI] Engineering Sciences

[SPI] Sciences de l'ingénieur

parésie spastique

cocontraction spastique

couple

électromyographie

toxine botulique

Knee Muscle Activation Characteristics During Closed Kinetic Chain Directional Loading in Healthy Young Males and Females

Flaxman, Teresa

30 March 2011

Neuromuscular control is believed to play an essential role during dynamic knee joint stabilisation. Evaluation of voluntary muscle action can be delineated as support strategies against external loading moments (Lloyd & Buchanan, 2001). The aim of this study was to determine if males and females exhibit differences in knee muscle action and cocontraction during voluntary isometric closed kinetic chain force generation in various directions in the horizontal plane representative of applied loads transverse to the long axis of the shank. Twenty-six healthy young adults (13 male, 13 female) stood with their dominant leg in a boot fixed to a force platform. A force target matching protocol required subjects to position a cursor (projected on a video screen) over a target and maintain the position for one second. To control the cursor, loads were applied against the force platform with their dominant leg to produce various combinations of anterior-posterior, medial-lateral loads while maintaining constant inferior-superior loads. A successful target match required a normalised force magnitude of equal effort for each subject and target location which triggered the recording of electromyography (EMG) for eight muscles crossing the knee joint. EMG was normalised to percent maximum voluntary isometric contraction. A mean magnitude of muscle activation, mean direction of muscle activation and a muscle specificity index was determined using EMG vectors. In addition, cocontraction indices were also computed for antagonist muscle pairs. Based on similar previous research, it was hypothesised that females would have greater quadriceps and hamstrings coactivation, greater muscle activation magnitudes, lower specificity for the quadriceps than males and no difference in hamstring characteristics. In our study, females significantly cocontracted their vastus lateralis and lateral gastrocnemius muscles to a greater degree than males (p=0.001). No significant differences were observed across sexes for the cocontraction of quadriceps and hamstrings or the lateral quadriceps and gastrocnemius muscles. Females displayed significantly lower specificity than males in their semitendinosus (p=0.025) and tensor fascia lata (p=0.012) activity patterns, greater magnitude of muscle activation in their lateral gastrocnemius (p=0.002) and tensor fascia lata (p<0.003) and no statistical difference in the other muscles. Furthermore, the activation patterns in our study grossly differed from previous open kinetic chain force target matching. These findings indicate that healthy young males and females have differences in their knee muscle control strategies and that knee muscle recruitment patterns differ during weight bearing and non-weight bearing tasks.

Knee

Muscle Activity

Joint Stabilisation

Sex Differences

Cocontraction

Closed Kinetic Chain

Isometric

Knee Muscle Activation Characteristics During Closed Kinetic Chain Directional Loading in Healthy Young Males and Females

Flaxman, Teresa

January 2011

Neuromuscular control is believed to play an essential role during dynamic knee joint stabilisation. Evaluation of voluntary muscle action can be delineated as support strategies against external loading moments (Lloyd & Buchanan, 2001). The aim of this study was to determine if males and females exhibit differences in knee muscle action and cocontraction during voluntary isometric closed kinetic chain force generation in various directions in the horizontal plane representative of applied loads transverse to the long axis of the shank. Twenty-six healthy young adults (13 male, 13 female) stood with their dominant leg in a boot fixed to a force platform. A force target matching protocol required subjects to position a cursor (projected on a video screen) over a target and maintain the position for one second. To control the cursor, loads were applied against the force platform with their dominant leg to produce various combinations of anterior-posterior, medial-lateral loads while maintaining constant inferior-superior loads. A successful target match required a normalised force magnitude of equal effort for each subject and target location which triggered the recording of electromyography (EMG) for eight muscles crossing the knee joint. EMG was normalised to percent maximum voluntary isometric contraction. A mean magnitude of muscle activation, mean direction of muscle activation and a muscle specificity index was determined using EMG vectors. In addition, cocontraction indices were also computed for antagonist muscle pairs. Based on similar previous research, it was hypothesised that females would have greater quadriceps and hamstrings coactivation, greater muscle activation magnitudes, lower specificity for the quadriceps than males and no difference in hamstring characteristics. In our study, females significantly cocontracted their vastus lateralis and lateral gastrocnemius muscles to a greater degree than males (p=0.001). No significant differences were observed across sexes for the cocontraction of quadriceps and hamstrings or the lateral quadriceps and gastrocnemius muscles. Females displayed significantly lower specificity than males in their semitendinosus (p=0.025) and tensor fascia lata (p=0.012) activity patterns, greater magnitude of muscle activation in their lateral gastrocnemius (p=0.002) and tensor fascia lata (p<0.003) and no statistical difference in the other muscles. Furthermore, the activation patterns in our study grossly differed from previous open kinetic chain force target matching. These findings indicate that healthy young males and females have differences in their knee muscle control strategies and that knee muscle recruitment patterns differ during weight bearing and non-weight bearing tasks.

Knee

Muscle Activity

Joint Stabilisation

Sex Differences

Cocontraction

Closed Kinetic Chain

Isometric

Implication du cortex moteur primaire dans la régulation de la coactivation musculaire. Etude de la modulation des oscillations corticales et des interactions cortico-musculaires

Dal Maso, Fabien

20 September 2012

La coactivation est un phénomène musculaire fondamental pour la stabilisation et la protection des articulations lors de contractions volontaires et joue un rôle essentiel dans le contrôle du mouvement. De nombreuses études ont montré que des mécanismes supraspinaux et spinaux contribuent à la régulation de la coactivation musculaire, mais l'implication du cortex moteur primaire (M1) est encore mal connue. Les modulations des oscillations corticales et des interactions cortico-musculaires ont été étudiées lors de contractions isométriques à différents niveaux de forces chez des participants présentant différents niveaux de coactivation musculaire en raison de leur spécialité sportive (entraînement en force (ST) vs. en endurance (ED)). Chez les ST, une moindre coactivation musculaire est associée à une plus grande activation du M1, ce qui pourrait s'expliquer par le contrôle d'un plus grand nombre de muscles, notamment des muscles antagonistes. Grâce à une méthode novatrice pour analyser les interactions cortico-musculaires, nous montrons qu'il existe un couplage entre le M1 est les muscles antagonistes chez l'ensemble des participants et dans toutes les directions de contraction. Cependant, la magnitude des interactions cortico-musculaires avec les muscles antagonistes est plus faible qu'avec les muscles agonistes, ce qui pourrait s'expliquer par une plus grande implication des mécanismes spinaux dans la régulation de la coactivation musculaire. L'estimation des moments musculaires agoniste et antagoniste à l'aide d'un modèle biomécanique EMG-assisté ouvre la perspective d'étudier directement les corrélats cérébraux des moments musculaires. Dans leur ensemble, nos résultats, obtenus à l'aide d'une approche combinant biomécanique et neurosciences, ont mis en évidence l'implication directe du M1 dans la régulation de la coactivation musculaire lors de contractions isométriques volontaires.

adaptations centrales

contractions isométriques

entraînement en force vs. en endurance

cocontraction

électroencéphalographie

électromyographie

muscles antagonistes

Myodynamika oporové fáze při odrazových pohybech člověka / Myodynamics of the support phase during different take-off tasks in human locomotion

Hojka, Vladimír

January 2013

Title: Myodynamics of the support phase during different take-off tasks in human locomotion Objectives: Six types of take-off movement were analyzed in terms of support limb kinematics, take-off dynamics and muscle activation, in order to identify differences in motor control. Methods: 14 male athletes (22.6 ± 4.4 years; 182.4 ± 5.3 cm; 74.7 ± 6.2 kg) took part in laboratory experiment. Each athlete performed six different take-off movements (running, acceleration - first and second step, long jump take-off, high jump take-off and take-off to the hurdle). System Qualisys was used to analyze kinematics of the support limb. Dynamic of the suport phase was measured with Kistler 9281 EA force- plate. ME6000 apparatus was used to measure the muscle activation. Results were processed and statistically evaluated in Matlab (MathWorks, Inc) environment. Pair ANOVA, T-test and Friedmann test were performed to identify differences between take-off movements. regression analysis was introduced to find the relationship between parameters. Results: Significant differences in take-off dynamics are realized with not so significant differences in kinematic and electromyographic parameters. high jump and long jump take-offs acted most specifically in comparison with other types of take-offs. Two typically...

Myodynamika oporové fáze při odrazových pohybech člověka / Myodynamics of the support phase during different take-off tasks in human locomotion

Hojka, Vladimír

January 2013

Title: Myodynamics of the support phase during different take-off tasks in human locomotion Objectives: Six types of take-off movement were analyzed in terms of support limb kinematics, take-off dynamics and muscle activation, in order to identify differences in motor control. Methods: 14 male athletes (22.6 ± 4.4 years; 182.4 ± 5.3 cm; 74.7 ± 6.2 kg) took part in laboratory experiment. Each athlete performed six different take-off movements (running, acceleration - first and second step, long jump take-off, high jump take-off and take-off to the hurdle). System Qualisys was used to analyze kinematics of the support limb. Dynamic of the suport phase was measured with Kistler 9281 EA force- plate. ME6000 apparatus was used to measure the muscle activation. Results were processed and statistically evaluated in Matlab (MathWorks, Inc) environment. Pair ANOVA, T-test and Friedmann test were performed to identify differences between take-off movements. regression analysis was introduced to find the relationship between parameters. Results: Significant differences in take-off dynamics are realized with not so significant differences in kinematic and electromyographic parameters. high jump and long jump take-offs acted most specifically in comparison with other types of take-offs. Two typically...