View clinical trials related to Lower Extremity Biomechanics.
Filter by:Non-surgical treatment options, like exercise therapy, show excellent short-term effects regarding pain reduction and improvement of knee function. However, mid- and long-term effects are missing so far. This might indicate that long-lasting changes in motor-skill performance (Motor Learning) have not occurred. Motor learning is associated with permanent changes in the capability for skilled movement behavior avoiding unfavorable joint loads and inappropriate muscle activation patterns, leading to compensatory movement strategies. One-sided and high repetitive loads in the knee joint could be one reason for the progression of knee osteoarthritis. Physiotherapeutic strategies should therefore be able to stimulate motor learning processes. In physiotherapy, motor learning can be optimized by using instructions and feedback, targeting an external focus of attention, when learning specific movement patterns. This study investigates the effects of a 12 week exercise therapy program, using an external focus of attention, on functional and biomechanical parameters in patients with knee osteoarthritis. To measure possible changes, functional measurements are taking place at baseline, after 6, 12 and 24 weeks. The biomechanical measurements (3D gait analysis) are taking place at baseline, after 12 and 24 weeks.
Childhood obesity is one of the most critical and accelerating health challenges throughout the world. It is a major risk factor for developing varus/valgus misalignments of the knee joint. The combination of misalignment at the knee and excess body mass may result in increased joint stress and damage to articular cartilage. A training programme, which aims at developing a more neutral alignment of the trunk and lower limbs during movement tasks may be able to reduce knee loading during locomotion. Despite the large number of guidelines for muscle strength training and neuromuscular exercises that exists, most are not specifically designed to target the obese children and adolescent demographic. The purpose of this study is to evaluate a training programme which combines strength and neuromuscular exercises specifically designed to the needs and limitations of obese children and adolescents and analyse the effects of the training programme from a biomechanical and clinical point of view.
The purpose of this study is to quantify changes in ankle and knee motion and force resulting from five progressive modifications to the anterior-posterior trim lines of thermoformed ankle-foot orthoses (AFO). It is hypothesized that the AFO with the most anterior trim line will prevent the most plantar flexion during loading response (the first 10% of the gait cycle)and prevent the most dorsiflexion at terminal stance (from 30 to 50% of the gait cycle) as compared to the non-device condition. This will be evidenced by the sagittal plane ankle motion and ground reaction force magnitude and location during loading response and terminal stance. Additionally, the angular velocity of knee flexion will increase during these same periods. By contrast, as the trim lines are moved more posterior this will result in lowering the effective stiffness of the device which will result in progressive increases in dorsiflexion and allow increasing amounts of knee flexion during terminal stance.