A self-aligning, self-drawing coupler for coupling body assemblies together improves usability of a wearable robotic device. A self-contained removable actuator cassette improves the ease of manufacture and of replacing parts in the field. A tensioning retention system designed for one handed operation makes donning and doffing a wearable robotic device easier. A two-stage attachment system increases the range of sizes a wearable robotic device will fit. A removable, integrated ankle-foot orthotic system makes donning and doffing a wearable robotic device easier. An infinitely adjustable, integrated ankle-foot orthotic system increases the range of sizes a wearable robotic device will fit. A manually-removable hip-wing attachment system makes field changes easier, and protecting such a system from inadvertent disengagement during operation increases safety.

An artificial arm in which a finger is bent is proposed. The artificial arm includes an insertion portion inserted into a tip of the finger, a tendon wire which is connected to a lower portion of the insertion portion and allows the insertion portion to perform a joint movement, an adjustment unit which is located on a back of a hand and adjusts tension of the tendon wire, and a connection unit which is made of an elastic material and having one end which is connected to the tendon wire so that an end of the tendon wire faces the adjustment unit and having the other end which is connected to the adjustment unit.

A brace including (i) two or more supports configured to contact body parts on opposite sides or ends of one or more joints when the brace is in use and (ii) one or more force application mechanisms that apply a controllable force to the supports in opposite directions to alleviate compression in the one or more joints is disclosed. Methods of manufacturing the brace and of alleviating compression in one or more joints using the brace are also disclosed.

A method for controlling an artificial orthotic or prosthetic knee joint, on which a lower-leg component is arranged and with which a resistance device is associated, the bending resistance (R) of which resistance device is changed in dependence on sensor data that are determined by means of at least one sensor during the use of the orthotic or prosthetic knee joint, wherein a linear acceleration (a.sub.F) of the lower-leg component is determined, the determined linear acceleration (a.sub.F) is compared with at least one threshold value, and, if a threshold value of the linear acceleration (a.sub.F) of the lower-leg component is reached, the bending resistance (R) is changed.

A robotic joint includes a first link, a middle link, a torque generator, a second link, and a locking mechanism. Different ends of the middle link are rotatably coupled to the first link and the second link. The torque generator is coupled to the first link and the middle link and is configured to produce a torque between these links. The locking mechanism is switchable between a locking state and an unlocking state. In the unlocking state, the locking mechanism allows free rotation of the second link relative to the middle link in the first and second rotation directions. In the locking state, the locking mechanism is configured to impede rotation of the second link relative to the middle link in the first rotation direction and to allow rotation of the second link relative to the middle link in the second rotation direction opposite of the first rotation direction.

A method for producing a hand orthosis, including the steps of: Producing an impression of at least one finger of a patient's hand and at least a part of a forearm, producing a finger section from a reproduction based on the impression, incorporating at least one finger segment in the finger section side corresponding to the hand surface, detecting the physiology of the patient's forearm using at least one captured image from the reproduction together with the finger section, thereby producing a digital 3D model, generating a rail based on the produced digital 3D model, securing at least one force-introducer onto or into the rail, securing a proximal end of the at least one finger segment to a distal end of the rail, and coupling the at least one force-introducer to the at least one finger segment. A hand orthosis is also provided.

A system is provided for supporting an arm of a user that includes a harness configured to be worn by the user, and an arm support coupled to the harness and including an arm rest to support an arm of the user. The arm support is configured to accommodate and follow movement of the arm without substantially interfering in such movement. The arm support may 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. For example, the arm support may transfer at least a portion of the weight of the user's arm to the torso or other region of the user's body and/or may apply an opposing force to at least partially offset the gravitational force acting on the arm.

The application relates to an active joint orthosis, particularly an orthosis for the hip joint, with an extended therapeutic function and including a joint splint with articulated arms that can be pivoted relative to one another and a pad that can be actively moved via a coupling joint or cam profile on one articulated arm.

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.

A power assistive device (100) for hand rehabilitation that provides training of a combined movement of finger flexion-extension and forearm supination-pronation to a user. The power assistive device (100) includes a hand brace (102) and a base (104). The hand brace (102) includes finger driving units (206) that adjustably connect to a platform (202, 204), actuators (208) that connect to the finger driving units (206), and force sensors (232) that connect to the finger driving units (206) and the bottom of the hand brace (102) and detect force signals generated by movement of the hand brace (102). The base (104) removably connects to the hand brace (102) and includes a supporting structure (302), a forearm rotator (110) that includes C-shaped tracks (314, 316) formed along an inner circumferential surface, a rotatable platform (306) that moves along the C-shaped tracks (314, 316), a mounting platform (308) that connects to the rotatable platform (306), and an electromyography (EMG) sensor (402A-402B) that attaches to the upper arm or forearm of the user and senses EMG signals generated by the user.