Stance-control orthotic knee joints stabilize the knee joint during the weight-bearing portion of gait without restricting swing-phase flexion, thus achieving a more normal gait for individuals with quadriceps muscle weakness. These devices must be designed around well-defined stance-control strategies that enable or hinder joint motion at specific events during the gait cycle. This paper presents a new type of stance-control strategy and a novel stance-controller design. Pilot clinical testing was performed on a prototype, demonstrating feasibility of this approach for providing reliable knee stability while facilitating swing-phase flexion. In particular, 44 deg of swing-phase flexion and 15 deg of stance-phase flexion were achieved during level walking. Further testing is needed in situ to provide additional validation and assess other mobility conditions.

Issue Section:
Design Innovation Paper
Keywords:
Design evaluation, Medical design , Springs, Robotics, Bio design, Mechanisms
Topics:
Knee, Orthotics, Design, Weight (Mass), Locks (Waterways), Engineering prototypes, Bearings, Springs, Gait analysis

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