Systems, devices and methods for providing active and/or passive compression therapy to a body part can include a compression device worn over a compression stocking. The compression device can have a pulley based drive train that is driven by a motor to tighten and loosen compression elements, such as compression straps, in a precise, rapid, and balanced manner. Sensors can be used in the compression device and/or compression stockings to provide feedback to modulate the compression treatment parameters.

The present disclosure describes an infant brace for treating an infant with a fractured clavicle. The infant brace includes a torso portion for receiving the donning infant's torso, and an arm portion for receiving the donning infant's arm on the side coinciding with the fractured clavicle. The infant brace is formed from an elastic netting material. The infant brace provides effective immobilization of the infant's affected upper arm while minimizing risks of over-heating or causing pressure sores.

An arm vibration damping device, comprising a housing (9), a longitudinal vibration damping module (1) and a transverse vibration damping module (2), the longitudinal vibration damping module (1) comprising a longitudinal motor (11), a support frame (12) and a mounting frame (13), the mounting frame (13) comprising a U-shape element (131) and a mounting element (132); the support frame (12) being located between the U-shape element (131) and two arms, the longitudinal motor (11) being in a transmission connection with the U-shape element (131); a transverse motor (21) of the transverse vibration damping module (2) being in a transmission connection with the support frame (12) via a reverse mechanism (22); the transverse motor (21), the support frame (12), the U-shape element (131) and the mounting element (132) being arranged along an axial direction of the transverse motor (21). Vibration can be cancelled through movements in a longitudinal direction and in a direction of the longitudinal vibration damping module, and the use of two arms of the U-shape element ensures the stability of the whole mounting frame and a components fitted thereon in a longitudinal movement.

An orthopedic device, first and second struts, and a range-of-motion limiting pivot assembly connecting to the first and second struts. The pivoting assembly having an engagement member linked to a tab disposed and arranged for pulling radially outward away from a central axis of the pivoting assembly for adjusting the range of motion of the pivoting assembly.

A Finger Splint for treating boutonniere deformities is provided. The Finger Splint has a dual axis support mechanism that allows full flexure and extension of the finger while pressure is applied to correct the deformity.

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.

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.

A finger brace is configured for disposition about a lengthwise portion of a human finger between a brace proximal and distal ends. When installed for bracing, the proximal end is anchored at least partially about the outer side of the finger at a location behind the PIP joint. The distal end includes a shank configured for coextension along a lengthwise portion of the outer side of the finger between the PIP joint and the finger nail. Situated between and connecting the support proximal and distal ends is a PIP-joint support that at least partially encircles and supports the PIP joint. In various configurations, a finger brace is incorporated into each glove finger of a sports glove to define a larger overall finger support system. The shanks may be articulated to promote finger bending while preventing rearward hyperextension.

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).

Systems and methods are provided for supporting an arm of a user using a harness configured to be worn on a body of a user; and an arm support coupled to the harness configured to support an arm of the user, the arm support configured to accommodate movement of the arm while following the movement without substantially interfering with the movement of the user's arm. One or more compensation elements may be coupled to the arm support to apply an offset force to at least partially offset a gravitational force acting on the arm as the user moves and the arm support follows the movement of the user's arm, the one or more compensation elements providing a force profile that varies the offset force based on an orientation of the arm support.