A brace incorporates an elongated strut having rigid hinge bars interconnected by an adjustable dual-axis ROM hinge. An exchangeable hinge stop is removably positioned within the ROM hinge, and designed to engage the hinge bars at a predetermined flexion/extension limit, thereby restricting pivoting movement of the strut and custom limiting a range of extension or flexion of the body part. A stop retention post cooperates with a flex member to hold the hinge stop in position relative to the first and second hinge bars. Lifting the flex member outwardly away from the hinge plate allows the hinge stop to be removed from the ROM hinge and exchanged.

The invention relates to a hand orthosis (1) for assisting the movements of a user's hand. The hand orthosis comprises a soft glove (2) adapted to receive at least a part of the user's hand with finger sections of the glove receiving each of the user's fingers. It further comprises at least one actuator box (3), and a power transmission (4) for transferring forces from the at least one actuator box to different parts of the glove via exo-tendons (5). The exo-tendons are arranged on a dorsal side, on a palmar side, or on both a dorsal side and a palmar side of the glove. The exo-tendons are arranged so that the glove can assist flexion, extension, or both extension and flexion of the fingers, respectively and so that the exo-tendons act on the fingers to produce motion that mimics the movement of a human hand. The hand orthosis provides different grasp types, self- adaptation of the fingers' motion to the shape of the object, and physiologically appropriate distribution of finger forces.

An orthopedic device and method for using the same are provided for applying a dynamic load on a leg of a user. The orthopedic device has a rigid or semi-rigid frame including lower and upper frames, and a hinge assembly connecting the lower and upper frames. A dynamic loading component is used to urge the load on the user's leg on the basis of flexion of the hinge assembly on the basis of tension in an elongate element connecting the dynamic loading component and at least one of the lower and upper frames. A peak load is generated at a flexion angle between extension and flexion of the hinge assembly.

A hinge for a brace comprises a tensioning element such as an inelastic cord for applying a restorative force to the hinge. A tensioning mechanism, preferably a hydraulic spring, tensions the cord as the hinge is moved from a rest position to a loaded condition. A tensioning member having a peripheral cam surface applies a tensioning force to the cord as the hinge is moved out of the rest position. The tensioning block and the anchoring block may be operatively geared together along an arc of motion so as to provide a generally symmetrical motion of the tensioning and anchoring portions relative to the gusset. When an external force is applied to move the hinge from the rest position the tension on the cord loads the spring, and when the external force is removed the spring applies a restorative force to move the hinge back to the rest position. Optionally the tensioning member may be configured to be disengaged and reengaged by an external actuator.

A releasable gripping glove is provided having one or more flexible artificial tendons extending through a finger section of a glove body. The flexible artificial tendon is configured to maintain a structurally articulated configuration when the finger section is articulated. Each tendon includes locking teeth that engages with a releasable locking tab extending form a locking mechanism configured to engage the locking teeth when the finger section is articulated. A release mechanism is provided to engage and disengage the locking mechanism. A thumb release rod is positioned within a thumb portion and connected to the release mechanism. The articulating of the finger section releasably locks the flexible artificial tendon in the articulated position, which is releasable through relaxing of the thumb portion.

A customizable knee brace for use in the treatment of osteoarthritis is provided. The customizable knee brace includes a lateral upright. The lateral upright includes at least a first semi-rigid support, a second semi-rigid support, and a hinge physically coupling the first semi-rigid support and the second semi-rigid support. The customizable knee brace further includes a thigh cuff constructed of formable material and coupled to the first semi-rigid support. The customizable knee brace further includes a shin cuff constructed of formable material and coupled to the second semi-rigid support. The customizable knee brace further includes an elastomeric web framework coupled to the lateral upright and configured to secure an area of a knee of a patient when wearing the customizable knee brace. The customizable knee brace further includes at least one tensioning element configured to adjust a tension of the elastomeric web framework.

A versatile orthopedic device is arranged to convert between ligament and osteoarthritis treatment, and to accommodate a variety of leg anatomies. The orthopedic device is preferably configured as a double-upright brace indicating struts, frame component sections and associated hinges preferably intended to be along both medial and lateral sides of a wearer's leg. A strap kit with an unloading strap system may be added to the orthopedic device for conversion into an orthopedic device for osteoarthritis relief.

A hinge which can be included on a brace is disclosed. The hinge can include a first arm, a second arm, and a hinge plate. The first and second arms can be connected to the hinge plate for rotation about first and second axes, respectively. The hinge plate can include an internally threaded aperture. The hinge can also include a force application assembly and an adjustment assembly. The adjustment assembly can include an externally threaded lead screw engaged with the internally threaded aperture, and having a medial end connected to the force application assembly and a keyed bore. The adjustment assembly can include a drive key having a keyed shaft slidingly engaged with the keyed bore and a knob connected to the drive key such that rotation of the knob causes displacement of the force application assembly.

A hinge which can be included on a brace is disclosed. The hinge can include a first arm, a second arm, and a hinge plate. The first and second arms can be connected to the hinge plate for rotation about first and second axes, respectively. The hinge plate can include an internally threaded aperture. The hinge can also include a force application assembly and an adjustment assembly. The adjustment assembly can include an externally threaded lead screw engaged with the internally threaded aperture, and having a medial end connected to the force application assembly and a keyed bore. The adjustment assembly can include a drive key having a keyed shaft slidingly engaged with the keyed bore and a knob connected to the drive key such that rotation of the knob causes displacement of the force application assembly.

An angle limitation system for an orthopedic brace employs a hinge assembly rotatably receiving an upper strut and a lower strut and having a hinge plate and a hinge assembly cap. An extension angle limit element is removably insertable in an anterior port between the hinge plate and hinge assembly cap. The extension angle limit element has a body with limiting surfaces adapted to engage mating faces indented in the anterior edges of the upper and lower strut. A flexion angle limit element is removably insertable in a posterior port between the hinge plate and hinge assembly cap. The flexion angle limit element has a body with limiting surfaces adapted to engage mating faces indented in the posterior edges of the upper and lower strut. Engagement mechanisms are adapted to releasably secure the flexion angle limit element in the posterior port and the engagement angle limit element in the anterior port.