Alterations of stiffness and resting position of the elbow joint following flexors resistance training

Skeletal muscles adapt their length and stiffness according to the functional demands to which they are regularly submitted. The modification of muscle stiffness and length induced by resistance training can alter joint stiffness and, theoretically, change joint resting position. Thirty subjects, ra...

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Published in	Manual therapy Vol. 13; no. 5; pp. 411 - 418
Main Authors	Ocarino, Juliana M., Fonseca, Sérgio T., Silva, Paula L.P., Mancini, Marisa C., Gonçalves, Gabriela G.P.
Format	Journal Article
Language	English
Published	Scotland Elsevier Ltd 01.10.2008
Subjects	Adaptation, Physiological - physiology Adult Analysis of Variance Anthropometry Arthrometry, Articular Biomechanical Phenomena Elasticity Elbow Joint - anatomy & histology Elbow Joint - physiology Electromyography Equilibrium Point Hypothesis Exercise Therapy - methods Female Humans Isometric Contraction Male Models, Biological Muscle, Skeletal - anatomy & histology Muscle, Skeletal - physiology Muscular hypertrophy Physical Medicine and Rehabilitation Range of Motion, Articular - physiology Resting position Sarcomeres - physiology Stiffness Torque Treatment Outcome Weight Lifting - physiology Resting position Stiffness Muscular hypertrophy Equilibrium Point Hypothesis
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ISSN	1356-689X 1532-2769 1532-2769
DOI	10.1016/j.math.2007.03.009

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Abstract	Skeletal muscles adapt their length and stiffness according to the functional demands to which they are regularly submitted. The modification of muscle stiffness and length induced by resistance training can alter joint stiffness and, theoretically, change joint resting position. Thirty subjects, randomly assigned to two groups, were submitted to a resistance training of the elbow flexor muscles of the non-dominant arm. This training was performed in the inner range in group 1 and throughout the complete range of motion in group 2. The dominant arm of each subject was considered the control. A biomechanical model of a hybrid mass–spring pendulum was used to estimate the elbow joint stiffness and the elbow resting position was assessed using a standard goniometer. There was a significant increase in joint stiffness of the experimental arm after complete range of motion training, which was not observed after the training performed in inner range. The resting position of the experimental arm was modified to a significantly greater flexion angle in both groups. No change was observed after resistance training in the control arm. The results showed that modifications in joint stiffness seem to depend on the volume of work imposed to skeletal muscles. In addition, both models of resistance training changed, through different mechanisms, the elbow joint resting position. These findings suggest that posture and joint stability may be modified by specific strengthening protocols.
AbstractList	Skeletal muscles adapt their length and stiffness according to the functional demands to which they are regularly submitted. The modification of muscle stiffness and length induced by resistance training can alter joint stiffness and, theoretically, change joint resting position. Thirty subjects, randomly assigned to two groups, were submitted to a resistance training of the elbow flexor muscles of the non-dominant arm. This training was performed in the inner range in group 1 and throughout the complete range of motion in group 2. The dominant arm of each subject was considered the control. A biomechanical model of a hybrid mass–spring pendulum was used to estimate the elbow joint stiffness and the elbow resting position was assessed using a standard goniometer. There was a significant increase in joint stiffness of the experimental arm after complete range of motion training, which was not observed after the training performed in inner range. The resting position of the experimental arm was modified to a significantly greater flexion angle in both groups. No change was observed after resistance training in the control arm. The results showed that modifications in joint stiffness seem to depend on the volume of work imposed to skeletal muscles. In addition, both models of resistance training changed, through different mechanisms, the elbow joint resting position. These findings suggest that posture and joint stability may be modified by specific strengthening protocols. Skeletal muscles adapt their length and stiffness according to the functional demands to which they are regularly submitted. The modification of muscle stiffness and length induced by resistance training can alter joint stiffness and, theoretically, change joint resting position. Thirty subjects, randomly assigned to two groups, were submitted to a resistance training of the elbow flexor muscles of the non-dominant arm. This training was performed in the inner range in group 1 and throughout the complete range of motion in group 2. The dominant arm of each subject was considered the control. A biomechanical model of a hybrid mass-spring pendulum was used to estimate the elbow joint stiffness and the elbow resting position was assessed using a standard goniometer. There was a significant increase in joint stiffness of the experimental arm after complete range of motion training, which was not observed after the training performed in inner range. The resting position of the experimental arm was modified to a significantly greater flexion angle in both groups. No change was observed after resistance training in the control arm. The results showed that modifications in joint stiffness seem to depend on the volume of work imposed to skeletal muscles. In addition, both models of resistance training changed, through different mechanisms, the elbow joint resting position. These findings suggest that posture and joint stability may be modified by specific strengthening protocols.Skeletal muscles adapt their length and stiffness according to the functional demands to which they are regularly submitted. The modification of muscle stiffness and length induced by resistance training can alter joint stiffness and, theoretically, change joint resting position. Thirty subjects, randomly assigned to two groups, were submitted to a resistance training of the elbow flexor muscles of the non-dominant arm. This training was performed in the inner range in group 1 and throughout the complete range of motion in group 2. The dominant arm of each subject was considered the control. A biomechanical model of a hybrid mass-spring pendulum was used to estimate the elbow joint stiffness and the elbow resting position was assessed using a standard goniometer. There was a significant increase in joint stiffness of the experimental arm after complete range of motion training, which was not observed after the training performed in inner range. The resting position of the experimental arm was modified to a significantly greater flexion angle in both groups. No change was observed after resistance training in the control arm. The results showed that modifications in joint stiffness seem to depend on the volume of work imposed to skeletal muscles. In addition, both models of resistance training changed, through different mechanisms, the elbow joint resting position. These findings suggest that posture and joint stability may be modified by specific strengthening protocols. Skeletal muscles adapt their length and stiffness according to the functional demands to which they are regularly submitted. The modification of muscle stiffness and length induced by resistance training can alter joint stiffness and, theoretically, change joint resting position. Thirty subjects, randomly assigned to two groups, were submitted to a resistance training of the elbow flexor muscles of the non-dominant arm. This training was performed in the inner range in group 1 and throughout the complete range of motion in group 2. The dominant arm of each subject was considered the control. A biomechanical model of a hybrid mass-spring pendulum was used to estimate the elbow joint stiffness and the elbow resting position was assessed using a standard goniometer. There was a significant increase in joint stiffness of the experimental arm after complete range of motion training, which was not observed after the training performed in inner range. The resting position of the experimental arm was modified to a significantly greater flexion angle in both groups. No change was observed after resistance training in the control arm. The results showed that modifications in joint stiffness seem to depend on the volume of work imposed to skeletal muscles. In addition, both models of resistance training changed, through different mechanisms, the elbow joint resting position. These findings suggest that posture and joint stability may be modified by specific strengthening protocols. Abstract Skeletal muscles adapt their length and stiffness according to the functional demands to which they are regularly submitted. The modification of muscle stiffness and length induced by resistance training can alter joint stiffness and, theoretically, change joint resting position. Thirty subjects, randomly assigned to two groups, were submitted to a resistance training of the elbow flexor muscles of the non-dominant arm. This training was performed in the inner range in group 1 and throughout the complete range of motion in group 2. The dominant arm of each subject was considered the control. A biomechanical model of a hybrid mass–spring pendulum was used to estimate the elbow joint stiffness and the elbow resting position was assessed using a standard goniometer. There was a significant increase in joint stiffness of the experimental arm after complete range of motion training, which was not observed after the training performed in inner range. The resting position of the experimental arm was modified to a significantly greater flexion angle in both groups. No change was observed after resistance training in the control arm. The results showed that modifications in joint stiffness seem to depend on the volume of work imposed to skeletal muscles. In addition, both models of resistance training changed, through different mechanisms, the elbow joint resting position. These findings suggest that posture and joint stability may be modified by specific strengthening protocols.
Author	Silva, Paula L.P. Mancini, Marisa C. Gonçalves, Gabriela G.P. Ocarino, Juliana M. Fonseca, Sérgio T.
Author_xml	– sequence: 1 givenname: Juliana M. surname: Ocarino fullname: Ocarino, Juliana M. email: julianaocarino@terra.com.br organization: Centro Universitário de Belo Horizonte UNIBH, Doctor Student Rehabilitation Science Program, Federal University of Minas Gerais – UFMG, Brazil – sequence: 2 givenname: Sérgio T. surname: Fonseca fullname: Fonseca, Sérgio T. organization: School of Physical Education, Physical Therapy and Occupational Therapy – UFMG, Brazil – sequence: 3 givenname: Paula L.P. surname: Silva fullname: Silva, Paula L.P. organization: Doctor Student Center for the Ecological Studies of Perception and Action, University of Connecticut, USA – sequence: 4 givenname: Marisa C. surname: Mancini fullname: Mancini, Marisa C. organization: School of Physical Education, Physical Therapy and Occupational Therapy – UFMG, Brazil – sequence: 5 givenname: Gabriela G.P. surname: Gonçalves fullname: Gonçalves, Gabriela G.P. organization: Master Student Rehabilitation Science Program – UFMG, Brazil
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Cites_doi	10.1080/00222895.1986.10735369 10.1152/jappl.2001.90.2.741 10.1002/mus.10392 10.1152/jappl.1982.53.2.335 10.1016/0021-9290(84)90103-9 10.1007/BF00204052 10.1017/S0140525X00072538 10.1016/S0004-9514(14)60606-1 10.1152/jappl.1998.85.1.98 10.1016/S0268-0033(97)00027-2 10.1152/japplphysiol.01001.2002 10.1046/j.1469-7580.1998.19310131.x 10.1097/00005768-200202000-00027 10.1016/0167-9457(93)90010-M
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SubjectTerms	Adaptation, Physiological - physiology Adult Analysis of Variance Anthropometry Arthrometry, Articular Biomechanical Phenomena Elasticity Elbow Joint - anatomy & histology Elbow Joint - physiology Electromyography Equilibrium Point Hypothesis Exercise Therapy - methods Female Humans Isometric Contraction Male Models, Biological Muscle, Skeletal - anatomy & histology Muscle, Skeletal - physiology Muscular hypertrophy Physical Medicine and Rehabilitation Range of Motion, Articular - physiology Resting position Sarcomeres - physiology Stiffness Torque Treatment Outcome Weight Lifting - physiology
Title	Alterations of stiffness and resting position of the elbow joint following flexors resistance training
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