Leg stiffness and joint stiffness while running to and jumping over an obstacle

Abstract During running, muscles of the lower limb act like a linear spring bouncing on the ground. When approaching an obstacle, the overall stiffness of this leg-spring system ( kleg ) is modified during the two steps preceding the jump to enhance the movement of the center of mass of the body whi...

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Bibliographic Details
Published in:Journal of biomechanics 2014-01, Vol.47 (2), p.526-535
Main Authors: Mauroy, G, Schepens, B, Willems, P.A
Format: Article
Language:English
Subjects:
Ankle
Biomechanical Phenomena
Geometry
Humans
Joint stiffness
Joints - physiology
Jump
Leg - physiology
Leg-stiffness
Male
Movement
Muscles - physiology
Obstacle
Physical Medicine and Rehabilitation
Range of Motion, Articular
Running
Running - physiology
Sports
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Summary:Abstract During running, muscles of the lower limb act like a linear spring bouncing on the ground. When approaching an obstacle, the overall stiffness of this leg-spring system ( kleg ) is modified during the two steps preceding the jump to enhance the movement of the center of mass of the body while leaping the obstacle. The aim of the present study is to understand how kleg is modified during the running steps preceding the jump. Since kleg depends on the joint torsional stiffness and on the leg geometry, we analyzed the changes in these two parameters in eight subjects approaching and leaping a 0.65 m-high barrier at 15 km h−1 . Ground reaction force ( F ) was measured during 5–6 steps preceding the obstacle using force platform and the lower limb movements were recorded by camera. From these data, the net muscular moment ( Mj ), the angular displacement ( θj ) and the lever arm of F were evaluated at the hip, knee and ankle. At the level of the hip, the Mj – θj relation shows that muscles are not acting like torsional springs. At the level of the knee and ankle, the Mj – θj relation shows that muscles are acting like torsional springs: as compared to steady-state running, the torsional stiffness kj decreases from ~1/3 two contacts before the obstacle, and increases from ~2/3 during the last contact. These modifications in kj reflect in changes in the magnitude of F but also to changes in the leg geometry, i.e . in the lever arms of F.
ISSN:0021-9290
1873-2380
DOI:10.1016/j.jbiomech.2013.10.039