A passively balanced load-adaptive upper limb exoskeleton. An upper arm (A), an elbow (B), a forearm (C), and a hand (D) are arranged sequentially from left to right. An upper arm upper rod (A1) and an upper arm lower rod (A2) each are hinge-connected to an upper arm elbow housing via a bearing. A forearm upper rod (C1) and a forearm lower rod (C2) each are hinge-connected to a forearm elbow housing via a bearing. An upper arm support rod (E) is disposed between an upper arm driving mechanism (A4) and an upper arm elbow assembly (B1). One end of the upper arm support rod is fixedly connected to two upper arm support rod slide blocks (9) in the upper arm driving mechanism, and the other end thereof is hinge-connected to protruding shafts on two sides of an upper arm lead screw nut connection member via bearings. A forearm-upper arm support rod is disposed between a forearm driving mechanism (C4) and a forearm elbow assembly (B2). One end of the forearm-upper arm support rod (K) is fixedly connected to two upper arm support rod slide blocks in the forearm driving mechanism, and the other end thereof is hinge-connected to protruding shafts on two sides of a forearm lead screw nut connection member via bearings. The hand is hinge-connected to a wrist. The upper limb exoskeleton of the invention is used to facilitate handling of heavy goods or carrying of certain items.

In various embodiments a method of synergistically using a neuromodulation stimulator and a robotic exoskeleton for the restoration of voluntary movement and greater muscle activation in chronically paralyzed subjects is provided. The noninvasive neuromodulation system delivers signals to facilitate the restoration and/or enhancement of neurological function where at least one effect is strengthened stepping capacity that can be further substantiated when coupled with robotic exoskeleton assistance.

A device for articular rehabilitation comprising a first element provided with bars for fastening to the proximal portion of a limb and a second element provided with bars for fastening to the distal portion of a limb, said first element comprising a first and a second spherical shell portion opposite to each other, and said second element comprising a first and a second spherical shell portion opposite to each other, said spherical shell portions being configured to fasten said first and second element by means of spherical hinge coupling and being configured so that the space comprised inside said spherical shell portions, when coupled, is such that the joint object of the rehabilitation is allowed to be received therein.

The present invention comprises a novel stretching device for the stretching the wrist and elbow as part of the treatment for lateral epicondylitis (tennis elbow) and medial epicondylitis (golfer's elbow). Consisting of a vertically (normally wall) mounted device with different embodiments being designed for lateral and medial epicondylitis ailments. For tennis elbow the device includes an angular support projecting from a padded vertical section where the back of the hand is placed. This angular support gradually pushes the back of the fingers guiding the hand into a fist, the optimal stretch for tennis elbow. The golfer's elbow version is designed to accept a palm out fingers up hand. It has a finger and compressible palm support section of different depths, the differences support a gentle stretch of the fingers, when the palm is pushed forward and away from the body.

The present disclosure relates to an upper limb assist system including a back bracket, an arm bracket, a motor, and driving belts, wherein the arm bracket includes an upper arm, a forearm, and a hand portion, two ends of the forearm are configured to be rotatably coupled to the upper arm and the hand portion respectively, the upper arm is configured to be rotatably coupled to the back bracket, the upper limb assist system further includes driving members and corresponding rotating wheels disposed on the upper arm, the forearm and the hand portion respectively, wherein the driving member is configured to have a first state and a second state.

A system and method for transmission of a signal for a powered assistive device has a sensor node with a wireless transmitter adapted for digitally transmitting a transmitted signal, the sensor node adapted for receiving and monitoring a sensor signal from a sensor attached to a user, and a master node with a controller and a wireless receiver for receiving the transmitted signal from the wireless transmitter. The master node processes the transmitted signal and communicates a control signal to the powered assistive device. The wireless transmitter transmits the transmitted signal at a first rate when the wireless transmitter adapted to transmit the transmitted signal at a first rate when the sensor signal is indicative of the rest state and to transmit the transmitted signal at a second rate when the sensor signal is indicative of the active state, the second rate being greater than the first rate.

Systems and methods for analysis of symmetry between sides of a body. A wearable device includes a body mounting portion structured and arranged to, in use, be mounted to one or more parts of a body of a patient on one side of the body. The wearable device includes at least one sensor configured to output a signal indicative of at least one physiological parameter from a side of the body to which the wearable device is mounted. At least one processor is configured to receive at least one physiological parameter from the wearable device while mounted to a first side of the body, and at least one physiological parameter from the wearable device while mounted to a second side of the body. An indicator of symmetry between the first side and the second side of the body is determined based at least in part on the at least one physiological parameter from the first side of the body and the at least one physiological parameter from the second side of the body.

A system and apparatus that performs a capture of human motion and location in order to relay the mechanics of joint and body movement to virtual- and augmented-reality based environments. Collected data and measurements using sensors that can be analyzed and sorted. The sensors can be used to passively collect data or can be used to provide data into a feedback loop to drive other systems.

A human-computer interface system having an exoskeleton including a plurality of structural members coupled to one another by at least one articulation configured to apply a force to a body segment of a user, the exoskeleton comprising a body-borne portion and a point-of-use portion; the body-borne portion configured to be operatively coupled to the point-of-use portion; and at least one locomotor module including at least one actuator configured to actuate the at least one articulation, the at least one actuator being in operative communication with the exoskeleton.

A robotic exoskeleton comprising a back portion providing at least two degrees of freedom, two shoulder portions, each shoulder portion providing at least five degrees of freedom, two elbow portions, each elbow portion providing at least one degree of freedom, and two forearm portions, each forearm portion providing at least one degree of freedom. Associated robotic forearm joints and robotic shoulder joints are also addressed.