The present invention relates to a shoulder brace for the rehabilitation of patients that suffer from shoulder instability. The shoulder brace uses a novel elevation and compression cabling system to stabilize and approximate the humerus to glenoid fossa. More specifically, the present invention allows an individual that suffers from shoulder instability to easily put on and, while wearing the device, adjust all forces that approximate their shoulder without the assistance of another individual. The design will also allow the individual the ability to have functional movement. This will give someone who has become dependent on others to regain a greater degree of independence.

An apparatus may include a wearable component having an interior surface and an exterior surface, with a slip-resistant material adhered to the interior surface, the wearable component separably attached to a connecting portion having a receiving element, and the receiving element separably attached to an attachment element removably affixed to an external support structure. A method of stabilization may include obtaining the apparatus, applying the wearable component to a portion of a body, attaching the attachment element to the external support structure, and separably attaching the connecting portion to the attachment element.

An orthopedic device includes a brace support having at least one strap for providing corrective orientation of a joint and unloading of the joint, and an electrical stimulation system for providing an electrical signal to a user's musculature at or proximate to the joint. The electrical stimulation system provides at least one electrical pulse to the musculature in supplement to the corrective orientation of the joint to induce contraction of the musculature. The electrical stimulation system may include at least one electrode for generating the electrical pulse, and a sensor module for determining movement and orientation of a user's limb for selectively activating the at least one electrode according to predefined criteria and feedback from the sensor module.

The present disclosure relates to a fastening system for fastening a first component on a second component, wherein the first component has a first bearing surface and a first direction of extent, and the second component has a second bearing surface and a second direction of extent, and an included angle between the first direction of extent and the second direction of extent is adjustable steplessly within an angle range. The fastening system has a clamp element with which the first component can be fastened on the second component when the first bearing surface lies on the second bearing surface, and, in the fastened state of the two components, at least one force-transmitting element is clamped between the two bearing surfaces.

An ankle brace has a stirrup with a flat bottom portion and a first and second upright leg. Each of the first and second upright legs has an upper end and a lower end, the upper end having a circular opening therethrough and the lower end attached to the flat bottom portion. First and second pivot legs, each having a circular opening therethrough, are releasably and rotatably connected to the first and second upright legs respectively. When connected, the circular openings in the pivot legs overlap the respective circular openings in the upright legs, and each pivot leg is rotatable about an axis through and perpendicular to the pivot leg circular opening. The circular openings in the first and second upright legs are positioned and sufficiently large to allow at least a portion of the malleolus bone of an ankle to protrude therethrough.

The invention relates to a dynamic correction splint (1) with two splint parts (5, 6) connected to each other via a joint (2). Spring bases (25, 26) of a spring device (27) are each coupled to a splint part (5, 6) in such a way that pivoting the splint parts (5, 6) leads to an altered biasing of the spring device (27). The spring device (27) exerts a correction moment onto the splint parts (5, 6) acting in the direction of a correction position of the splint parts (5, 6). The spring device (27) is configured and coupled to the splint parts (5, 6) in such a way that the absolute value of the correction moment increases as the correction position of the splint parts (5, 6) is approached. It is possible that a switching mechanism (40) is present. The switching mechanism (40) is actuated in a motion-controlled way by the pivoting of the splint parts (5, 6) and at its actuation changes the coupling of the splint parts (5, 6) with the spring device (27).

A lower exoskeleton for a user including a pelvic element (1) with a mechanism for securing to an upper part of the user's body; two lower supports (2) with a mechanism for securing to the user's lower limbs and which rest on the ground during stance phases, each of the supports having a thigh segment and a tibia segment connected by a knee link to allow flexion and extension; and hip links for connecting the two lower supports to the pelvic element. The pelvic element has a an inner segment (30) extending symmetrically in relation to a central sagittal plane; and two outer segments (33) extending symmetrically and connected to respective distal ends of the inner segment by linking members (31, 32, 34; 31′), allowing flexion between the inner segment and each outer segment along two orthogonal axes.

An orthopedic device includes a textile panel having interior and exterior surfaces, and a first stabilizer assembly including a first tubular welt sewn or knitted within and extending from an exterior surface of the textile panel. A first cable is slidably extending through the tubular welt and a strap is connected to a first end of the cable extending from a first opening of the welt, and the strap is adjustably securable over the textile panel. The orthopedic device may include various portions of stretchability and features for receiving components for the orthopedic device.

An orthopedic device includes a base shell having ankle and foot receiving portions. The base shell forms an opening over a dorsal aspect of the base shell. A dorsal shell is contoured to generally correspond to the opening in the base shell. The dorsal shell includes a proximal member connected to distal member via a flexible or resilient connecting portion arranged to accommodate a portion of a user's lower leg or ankle. A first flexible edge portion is attached to a distal terminal end of the distal member. The first flexible edge portion is arranged to bend or flex relative to the distal member so as to reduce the likelihood of pressure points on the user's toes from the distal member.

An ankle stabilizing apparatus for minimizing inversion and eversion of the foot includes a body member having at least one cuff member positioned against a cuff portion of the body member, wherein the cuff member defines at least one opening for receiving at least one stabilizing strap such that the cuff member and stabilizing strap dynamically apply a variable force against the body member and ankle. The apparatus promotes variable compression against the ankle upon application and during wear. The apparatus also resists distal migration during wear.