An ankle brace is provided, including a main body. The main body has a base portion and an abutting portion for abutting against an ankle, the base portion has at least one first guiding slot, the at least one first guiding slot is arranged next to the abutting portion, the abutting portion has a bottom portion, a circumferential side portion which surrounds and is connected to and between the bottom portion and the base portion and at least one second guiding slot, the bottom portion has a receiving space for receiving a part of the ankle, the circumferential side portion projects above a slot bottom of the first guiding slot, and the at least one second guiding slot is arranged on the bottom portion and penetrates the circumferential side portion and communicated with the at least one of the first guiding slots.

An orthotic support comprises a shoulder section for encapsulating a first shoulder of a wearer, a glove section for conforming to at least a portion of the wearer's hand, and a sleeve section for conforming to the wearer's arm, the sleeve section connecting the shoulder section to the glove section. A resilient reinforcement extends from the glove section to the shoulder section, and at least a portion of the reinforcement extends in a spiral around the sleeve section, so that the reinforcement is configured to apply a rotational force to the wearer's arm, when worn, to urge a portion of the wearer's arm to rotate in a predetermined direction. The orthotic support may be usable to treat or prevent shoulder dislocation or subluxation, arm over-pronation or over-supination, wrist flexion or elbow flexion. An orthotic support may comprise a reinforcement with a first branch extending over an anterior portion of the sleeve section, and a second branch extending over a posterior portion of the sleeve section, so that the reinforcement is configured to urge the wearer's upper arm towards a rest position.

A control device for controlling a rigidity of an orthosis, includes a sensing circuit for sensing a falling motion, a signal generating circuit which generates a sensing signal based on the sensing of the falling motion, and a rigidity control mechanism which controls a rigidity of the orthosis based on the sensing signal.

A guard for protecting a finger without interfering with athletic performance, having a rigid core that protects the finger from hyperextension and impact injuries. The guard has a proximal segment and a distal segment, each having a top surface, and a hinge assembly attached and extending above the top surfaces of the distal segment and proximal segment. The hinge assembly allows the distal segment to vary in position between a minimum position and a maximum position while remaining out of the way of adjacent fingers. The guard securely engages the finger by a distal strap that secures to a distal part of the finger, and a proximal strap that secures to a proximal part of the finger. The proximal part has sides that extend alongside the finger, and the distal segment only extends along the superior surface of the finger toward but not reaching the fingertip.

A connector for a strap includes a buckle assembly having a base part, and a strap mount flexibly depending from the buckle assembly. The strap mount is integrally connected to the base part such that the base part is rigid when the strap mount bends relative thereto.

Support braces and methods of manufacturing the same are disclosed. A support brace includes a flexible fabric substrate and an elastomeric member disposed on the surface of the flexible fabric substrate. The elastomeric member is disposed so as to apply pressure non-uniformly about a limb or joint of the wearer, in a pattern selected to divert pain and/or reduce loads on the joint. The flexible fabric substrate can include regions having different levels of elasticity, to provide different levels of compression to different parts of the joint or limb in addition to the compression provided by the elastomeric member. The elastomeric member can be deposited, screen printed, injection molded, or otherwise applied to the fabric substrate, optionally without adhesive.

An orthopedic device comprising a first shell, a second shell, and a hinge connecting to the first and second shells. A first strap having a first end slidably connects to the first shell and a second end removably anchors to the second shell. An overlay extends over a portion of the first shell and forms a clearance with the first shell into which the first end of the first strap extends. Portions of the overlay secure to the first shell outside of the clearance.

A connector for a strap includes a buckle assembly having a base part, and a strap mount flexibly depending from the buckle assembly. The strap mount is integrally connected to the base part such that the base part is rigid when the strap mount bends relative thereto.

The present disclosure provides an orthopedic brace for a limb. The orthopedic brace can include an upper portion, a lower portion, and a multi-axial joint. The multi-axial joint can connect the upper portion and the lower portion and can further a stacked joint assembly configured to rotate about multiple axes. A method of operating an orthopedic system is also provided.

An anatomical brace for dynamically stabilizing the elbow during elbow articulation, the anatomical brace comprising: a brace body comprising a distal portion for fitting over the forearm of a user and a proximal portion for fitting over the upper arm of a user; a hinge mechanism comprising a distal segment, a proximal segment and a pivot for pivotally connecting the distal segment and the proximal segment, the distal segment of the hinge mechanism being mounted to the distal portion of the brace body and the proximal segment of the hinge mechanism being mounted to the proximal portion of the brace body; a pivot cable guide mounted to the anterior portion of the pivot; an upper arm cable guide mounted to at least one of the proximal segment of the hinge mechanism and the proximal portion of the brace body, the upper arm cable guide being configured to change the direction of a cable extending through the upper arm cable guide; an ulnar collateral ligament (UCL) cable guide mounted to the brace body and configured to direct a cable extending through the ulnar collateral ligament (UCL) cable guide over the ulnar collateral ligament (UCL) and toward the distal portion of the brace body; and a cable having a first end and a second end; the first end of the cable being mounted to the distal segment of the hinge mechanism, the second end of the cable being mounted to the distal portion of the brace body, and the cable being routed proximally along the distal segment of the hinge mechanism, through the pivot cable guide, proximally along the proximal segment of the hinge mechanism, through the upper arm cable guide, and through the ulnar collateral ligament (UCL) cable guide; wherein, when the anatomical brace is mounted to the arm of a user so that the distal portion of the brace body is secured to the forearm of the user, and the proximal portion of the brace body is secured to the upper arm of the user, and when the elbow thereafter moves to full extension, the cable is tensioned, whereby to apply a force to the ulnar collateral ligament (UCL) of the user, and when the elbow thereafter moves to full flexion, the cable is relaxed, so that the force applied to the ulnar collateral ligament (UCL) is released.