A grip strengthening device having a finger portion for enhancing the grip by means of at least one artificial tendon arranged along at least one finger portion, wherein the finger portion comprises material along both sides and a tip, and possible along a dorsal side, the at least one artificial tendon is attached along both sides so that the artificial tendon may move, wherein the artificial tendon runs closer to a ventral side than the dorsal side of the finger portion, at least at positions corresponding to joints of a wearer's finger, the finger portion will transfer a force to provide a movement of the finger when the artificial tendon is retracted, wherein the artificial tendon runs in a detour towards or to a position in the middle between the dorsal and ventral side or closer to the dorsal side at a proximal portion of the finger portion.

The present disclosure relates to a technical field of medical exercise apparatus. A non-surgical reduction exercise therapy apparatus for rupture of anterior cruciate ligament or achilles tendon includes a thigh immobilization device, a calf immobilization device, an adjustable knee joint hinge and a foot immobilization device, a boot heel being provided under a rear of the boot sole. The present disclosure has a reasonable and compact structure and is convenient to use, and also has characteristics of low treatment cost, no surgery, whole process activities, pleasant dance, no influence on work and study during treatment, and fast healing of the anterior cruciate ligament or achilles tendon.

A rear-entry ankle brace includes an elastomeric component defining an inside elbow channel configured to span an ankle joint. A channel opening extends the length of the elastomeric component for direct insertion on top of a leg. One or more leg straps are used to adjustably tension first and second rear edges of the channel opening toward one another and secure the brace to the lower leg. Two foot straps are used to adjustably tension first and second bottom edges of the channel opening toward one another and secure the brace to the mid-foot. The foot straps overlap on the bottom to define a plantar surface of the brace and cross over each other on the topside of the elastomeric component and are secured to a leg strap. A pair of stabilizing stirrups optionally are included on the inside surfaces of the elastomeric component and receive the malleoli.

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.

A shoulder brace device includes: a torso band, an arm band, and a brace mechanism, such that the brace mechanism is configured to connect to the torso band and the arm band; wherein the brace mechanism includes a ball joint assembly, such that the shoulder brace device enables free range of movement; wherein the brace mechanism can be locked in place or tightened for reduced range of movement.

A method for manufacturing a custom wearable and/or implantable medical device, such as an orthosis (e.g., an ankle brace, etc.), a prosthesis or the like, includes use of scanning processes. A digital model of a surface may be applied to a digital device model to define a custom digital device model. The digital model and, thus, the custom digital device model may include one or more standard features. The custom digital device model may be used with an automated manufacturing process to make some or all of the custom wearable and/or implantable medical device. In some embodiments, additive manufacturing processes may be used to form a portion or all of the custom wearable and/or implantable medical device.

A method for manufacturing a custom wearable and/or implantable medical device, such as an orthosis (e.g., an ankle brace, etc.), a prosthesis or the like, includes use of scanning processes. A digital model of a surface may be applied to a digital device model to define a custom digital device model. The digital model and, thus, the custom digital device model may include one or more standard features. The custom digital device model may be used with an automated manufacturing process to make some or all of the custom wearable and/or implantable medical device. In some embodiments, additive manufacturing processes may be used to form a portion or all of the custom wearable and/or implantable medical device.

The invention relates to a device for supporting at least one foot arch of a user, which device is provided with: a forefoot anchor which is configured to be anchored on the foot, at least partly at the location of the distal part of the metatarsal bones (ossis metatarsi I-V); at least one working strap which can be anchored around the heel and the ends of this at least one working strap are attached or attachable to the forefoot anchor, wherein the device can be brought from a fitting position, in which the at least one working strap is not or virtually not tensioned in order to be able to put the device on a foot of the user, to a working position, in which, in the working position, the at least one working strap is tensioned between the heel and the forefoot anchor in such a way that the part or parts of the tensioned at least one working strap situated under the sole support at least one foot arch of a user.

An orthotic device including a frame assembly and a support structure. The frame assembly includes at least one frame having a first frame opening and a second frame opening. The support structure assembly includes at least one support structure supported by the at least one frame. The at least one support structure includes a mounting portion; a slide engagement member supported by the mounting portion configured to engage the first frame opening; and, at least one snap engagement member supported by the mounting portion configured to engage the second frame opening. The slide engagement member and the at least one snap engagement member are integrally formed with the mounting portion. In another embodiment the orthotic device includes a latch mechanism including a lever assembly, a draw bar, a chafe, a catch, and a first snap fit ledge.

An orthotic device including a frame assembly and a support structure. The frame assembly includes at least one frame having a first frame opening and a second frame opening. The support structure assembly includes at least one support structure supported by the at least one frame. The at least one support structure includes a mounting portion; a slide engagement member supported by the mounting portion configured to engage the first frame opening; and, at least one snap engagement member supported by the mounting portion configured to engage the second frame opening. The slide engagement member and the at least one snap engagement member are integrally formed with the mounting portion. In another embodiment the orthotic device includes a latch mechanism including a lever assembly, a draw bar, a chafe, a catch, and a first snap fit ledge.