A device for supporting at least one arm of a user includes one or more arm support elements each of which has an arm shell for placing the at least one arm of the user on the arm shell. Force is applied to the arm support elements by at least one passive actuator. A counter bearing for the applied force includes a force transmission element and a counter bearing element. A force application lever is engaged by the one passive actuator and is connected to the arm support or the force transmission element. The force application lever is torque proof and confines an angle which is adjustable.

The invention provides devices and methods for performing transradial catheterization.

A brace configured for attachment to a joint of a subject is provided. The brace includes a first arm having a first end and a second end. The brace includes a second arm having a first end and a second end. The brace includes a hinge assembly coupling the first end of the first arm with the first end of the second arm such that the first arm and the second arm are movable to different relative angular orientations. The brace includes a potentiometer coupled to the hinge assembly. A method of monitoring a relative angular orientation of a first arm of a brace relative to a second arm of the brace is also provided. The method includes monitoring an output of a potentiometer coupled to one of the first arm and the second arm.

The invention relates to deflector (100) to deflect rope (130) in orthopedic or medical accessories, or athletic accessories, whereby the deflector comprises at least first subcomponent (110) and second subcomponent (120), whereby first subcomponent (110) and second subcomponent (120) are adjustable, respectively, with only one degree of freedom against one another, and whereby first subcomponent (110) and second subcomponent (120) exhibit, respectively, at least one rope guidance element (111, 112, 121, 122) to deflect rope (130).

In one embodiment, the orthotic device can include a powered hand portion, a switching element, and a controller. The wearer can interact with the switching element to generate input signals for adjusting an operation of the powered hand portion. The controller can receive the input signals and generate control signals to accordingly adjust the operation of the powered hand portion. In some embodiments, a powered hand portion can be comprised of a plurality of linkages and at least one powered actuator to assist with an opening and closing of the hand portion. The plurality of linkages can be operated by at least one electric motor with quick-connect elements to link onto fingers of a user. In some embodiments, an electrically-actuated clutch mechanism can be affixed to an upper arm section and a lower arm section of an orthotic device. The clutch mechanism can be configured into different positions.

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 disclosure provides apparatus and methods of use pertaining to a biomechanical finger brace assembly. In one embodiment, the assembly includes a coupling tip, a proximal ring configured to concentrically receive a user's finger, a distal ring configured to concentrically receive the finger, and a rocker formed in an H-shape. The distal ring and the rocker are pivotally suspended between a proximal coordinated pivot point anchored on the proximal ring and a distal coordinated pivot point anchored on the coupling tip, such that movements of the finger within the proximal ring articulate the distal ring together with the rocker to articulate the coupling tip. The coupling tip may include an open end or an enclosed recess to accept a minimally-amputated or non-amputated finger. Other embodiments are also disclosed.

A thumb orthosis, particular for correcting malpositions of the thumb in the carpometacarpal joint, includes a) a substantially dimensionally stable molded body bent in a U-shape, which is fitted on the hand between the thumb and index finger in the applied state and supports the thumb and fixes it at a distance from the index finger, wherein the molded body bent in a U-shape has a first end portion and a second end portion, and b) a strap which is fastened by one strap end to the first end portion of the molded body, wherein the second end portion of the molded body has a guiding element for guiding the strap, for example has a turning element for turning the strap back.

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 field splint and system and method for use of the same are disclosed. In one embodiment of the orthopedic field splint, a body has flexion and extension movement parallel to a longitudinal axis between a horizontal axial plane and a rolled sleeve. A coupling member is hingedly connected to the body in overlapping releasable engagement in a closed retracted position and extending beyond the body in an open extended position. A receiving pocket is connected to the body. The receiving pocket and the coupling member having mutually completing mating forms. Multiple sleeves extend longitudinally through the body and each of the sleeves is parallel to the longitudinal axis and configured to accept a rigid slat.