The present disclosure provides a joint protection device, comprising a joint protection body that matches a shape of a joint. The joint protection body is a hollow housing having an opened bottom and comprises a front supporting portion and side supporting portions providing supports for the joint. A notch is provided in a portion of the joint protection body, which is close to a joint movement area. The notch divides the joint protection body into a plurality of joint pieces, adjacent joint pieces are connected by two local junctions respectively provided at appropriate positions on two sides of the joint protection body and can rotate with the local junctions as rotation fulcrums. Meanwhile, the present disclosure further provides other joint protection devices similar to the above, where an upper end of a joint protection body is provided with a clearance structure to ensure forward and backward movement of the joint.

The present invention discloses an exoskeleton which comprises a force balance back-carrying unit composed of a back-carrying assisting unit and a front-carrying assisting unit, a hip unit and a lower limb supporting unit, wherein the force balance back-carrying unit transfer the weight of a back-carrying load and/or a front-carrying load to the lower limb supporting unit through the hip unit to achieve the effort of assisting for the back-carrying load and/or the front-carrying load, wherein the length of the hip unit can be adjusted on the left-right plane and the upper-lower plane to adapt to wearers with different body types. On the other hand, the exoskeleton of the present invention is also provided with a buffer device to reduce the impact of the loads on the exoskeleton. The exoskeleton of the present invention also adopts quick-release joints, so as to modularize each part and standardize a docking interface of each module. The present invention can adapt to wearers with different hip shapes, and can transfer the weight of the back-carrying load and the front-carrying load to the lower limb supporting unit separately and simultaneously, so as to increase the weight-bearing efficiency and reduce the injuries to the back, the hands and the ankle joint.

One embodiment is directed to a brace for limiting motion of a joint of an appendage of that is interposed between a first appendage portion and a second appendage portion of a patient, comprising: an upper member removably coupleable to the first appendage portion, the upper member having proximal and distal ends; and a lower member removably coupleable to the second appendage portion, the lower member having proximal and distal ends; wherein the distal end of the upper member and proximal end of the lower member are coupled to form a movable joint that is substantially alignable with the joint of the patient, such that when the patient attempts to move his appendage and associated joint, motion is resisted at this joint in a nonlinear fashion.

A finger-motion assisting apparatus. The apparatus includes a wearing part, a first cover extending from the wearing part to one side, first and second wires pulling the first cover, a pulley around which the first and second wires are wound, and a motor rotating the pulley. The first and second wires are arranged from a first point to a second point of the first cover along the extension direction of the first cover and arranged along at least part of a periphery of the first cover in opposite directions at the second point of the first cover.

An actuator-damper unit for use in orthotic or prosthetic devices. The actuator-damper unit includes a housing which may be fastened on the orthotic or prosthetic device and in which a cylinder is formed. A first piston is displaceably mounted in the cylinder and is coupled to a piston rod. The piston rod is disposed, via a first end, on the first piston and may be coupled, via a second end, to the orthotic or prosthetic device. The first piston separates two fluid chambers in the cylinder from each other and forms a piston-cylinder unit, wherein at least one further piston is coupled to the first piston in order to form at least one further, variable-volume fluid chamber.

The invention relates to a device for supporting at least one arm of a user, with at least one arm support element with a spacer element and an arm shell for mounting on the upper arm, at least one passive actuator which is configured to apply a force to the arm support element, and at least one counter bearing for the force to be applied that comprises at least one force transmission element and a counter bearing element, wherein the spacer element is arranged on the at least one force transmission element such that it can be swivelled, a headrest with at least one shoulder element and at least one support element that is arranged on the at least one shoulder element, wherein the headrest is designed to support the user's head.

Orthoses, which are recommended for those suffering from spastic cerebral palsy to wear during sleep, may require manual adjustment and can cause discomfort while the wearer is trying to fall asleep. Accordingly, a patient-responsive orthosis is provided that includes a forearm splint, a hand actuator, a motor that extends the hand of the wearer by moving the hand actuator, memory that stores instructions, and a processor that extends the hand of the wearer in response to the instructions by causing the motor to move the hand actuator. The orthosis may include a sleep sensor and may be programmed to extend the hand of the wearer while the wearer is asleep. The patient-responsive orthosis may be programmed (e.g., by a clinician specifying a treatment schedule) using a remote device. The patient-responsive orthosis may also store and output usage data (e.g., for review by a clinician).

A wrist joint actuating structure of a hand rehabilitation device includes a palm orthosis body, a forearm orthosis body and a joint unit. The palm orthosis body includes a plurality of finger support rods and a thumb support rod. The joint unit is a universal joint and is connected between the palm orthosis body and the forearm orthosis body. The palm orthosis body can be turned an angle relative to the forearm orthosis body through actuation of the joint unit according to the bending degree of a user's wrist joint. A tension adjustment unit includes elastic members connected to the finger support rods and the thumb support rod. According to the different stretching tensions required by the fingers or the thumb for rehabilitation, the respective lengths of the other ends of the elastic members to be pressed by a fixing seat are adjustable, so as to adjust different stretching tensions.

The present disclosure describes soft-robotic wearable devices to treat and/or relieve Carpal Tunnel Syndrome, for example during typing assist applications. Soft actuators within the device adjust the angle of the wearer's wrist angle dynamically to achieve a neutral angle, alleviating the pressure on the median nerve and relieving Carpal Tunnel Syndrome strain.

An active orthotic device, e.g. a hand orthosis, is attached to one or more limbs of a human subject and comprises a respective set of actuators (21) for moving a respective limb (1A) among the one or more limbs. A method for controlling the orthotic device comprises obtaining one or more bioelectric signals, [S(t)], from one or more bioelectric sensors (10) attached to or implanted in the human subject; processing the one or more bioelectric signals, [5(t)], for prediction of an intended application force, FA(t), of the respective limb (1A) onto an object; obtaining a force signal, PA(t), from a force sensing device (22) associated with the respective set of actuators (21) and/or the respective limb (1A); and generating, as a function of a momentary difference, e(t), between the intended application force, FA(t), and the force signal, PA(t), a respective set of control signals, it(t), for the respective set of actuators (21).