A device for physiotherapy includes at least a seating surface and a back rest. The back rest is provided with arm holders positionable under a person's underarms. The back rest is also provided with powered apparatus to move the arm holders in a direction away from the seating surface, thereby to lift a person off the seating surface, and to return the person to the seating surface.

A CPR chest compression system which uses tonometric data as feedback for control of chest compression device.

Sensor devices closely attached to a body of a user, and walking assist devices such sensor devices may be provided. For example, a sensor device including a sensor configured to sense physical information of the user, and a support configured to provide an elastic force to the sensor such that the sensor closely attached to the body regardless pf a movement of the user, and enable the sensor to sense the physical information of the user with relative accuracy may be provided.

Therapeutic cushions having a plurality of inflatable columnar cells, pumping mechanism, and a manifold or valve system for moving a fluid between the pumping mechanism and the inflatable columnar cells. The inflatable columnar cells are constructed such that inflation and deflation of the cells cause vertical expansion/contraction of the cells with limited lateral expansion/contraction. The manifold or the valve system connect the pumping mechanism with the inflatable columnar cells such that a plurality of zones are created. A valve assembly can include a plurality of valves and is adjustable among at least three valve configurations to vary fluid connections to the inflatable columnar cells to produce rearwardly advancing waves. A venting manifold may vent air from the cells between the cushions.

An apparatus (10) for the rehabilitation, assistance and/or augmentation of arm strength in a user (U) comprises a support arrangement (12) for supporting the apparatus (10) on the user (U), a linkage arrangement (14) coupled to the support arrangement (12) and for coupling to an arm (A) of the user (U), and an actuation arrangement (16) for operating the linkage arrangement (14) and thereby manipulating the user's arm (A) in response to a user input signal.

The present invention discloses a soft knee exoskeleton driven by a negative-pressure linear actuator, including: an exoskeleton controller, a left leg knee joint soft actuator, a right leg knee joint soft actuator and the like. The soft knee exoskeleton mainly uses a miniature vacuum negative pressure pump as an air pressure power source. A DSP embedded control system performs real-time processing on the data, such as a muscle force, a knee joint angle and a human-machine interaction force, detected by a sensing system, estimates a human-machine cooperation state, and performs real-time control on the switching of the negative pressure flow and an air channel of the miniature vacuum negative pressure pump.

A gait assistance slab is provided. The gait assistance slab includes a body that includes an outer surface. The gait assistance slab further includes a plurality of sensors disposed inside the body. The gait assistance slab further includes a plurality of actuators disposed inside the body. The gait assistance slab further includes circuitry communicatively coupled to the plurality of sensors and the plurality of actuators. The circuitry detects a presence of a person on the outer surface based on an electric signal acquired from one of the plurality of sensors. The circuitry determines a level of actuation of one of the plurality of actuators based on the detected presence of the person and the acquired electric signal. The circuitry further controls, based on the determined level of actuation, the one of the plurality of actuators to assist gait of the person on the outer surface.

The invention discloses a wearable multifunctional powered exoskeleton for cervical vertebra rehabilitation, and relates to the field of man-machine interaction rehabilitation aids. The wearable multifunctional powered exoskeleton for cervical vertebra rehabilitation comprises an active drive motor module, a fixed supporting module and a movable joint component; the active drive motor module is connected to the fixed supporting module, and comprises a left shoulder push rod motor, a right shoulder push rod motor, a cervico-thoracic vertebra left front side push rod motor, a cervico-thoracic vertebra left rear side push rod motor, a cervico-thoracic vertebra right front side push rod motor, and a cervico-thoracic vertebra right rear side push rod motor; and the active drive motor module and the movable joint component are combined to jointly form a six-connecting rod power-driven structure. Through the implementation of the wearable multifunctional powered exoskeleton for cervical vertebra rehabilitation, the passive traction, antiflexion and retroextension, lateral flexion and horizontal rotation four-degree-of-freedom rehabilitation exercises of a cervical vertebra are realized, the traction training of a neck is performed, and the directional resistance training of neck muscles is realized. The wearable multifunctional powered exoskeleton for cervical vertebra rehabilitation improves the muscle force of the neck, enhances the stability of the cervical vertebra, improves and corrects the biomechanical balance of the cervical vertebra.

An exoskeleton (1) having a plurality of autonomously operable modules (2.sub.RK, 2.sub.LK, 2.sub.RH, 2.sub.LH) each having a dedicated controller (23.sub.RK, 23.sub.LK, 23.sub.RH, 23.sub.LH) connected to an actuated joint. The exoskeleton (1) further having a multimaster electrical communicator (3) between the controllers (23.sub.RK, 23.sub.LK, 23.sub.RH, 23.sub.LH) of the modules (2.sub.RK, 2.sub.LK, 2.sub.RH, 2.sub.LH). The controller (23.sub.RK, 23.sub.LK, 23.sub.RH, 23.sub.LH) of each module (2.sub.RK, 2.sub.LK, 2.sub.RH, 2.sub.LH) is configured for: collecting information from sensors; sharing information with the remaining modules through the multimaster electrical communicator (3); determining which other modules (2.sub.RK, 2.sub.LK, 2.sub.RH, 2.sub.LH) are present; and autonomously calculating and commanding a desired trajectory of the actuated joint of the module (2.sub.RK, 2.sub.LK, 2.sub.RH, 2.sub.LH) for assisting the movement of the corresponding biological joint in coordination with the kinematic condition of other biological joints.

An apparatus and method for applying caresses and massages, comprising an apparatus composed of a fixed lower section, which acts as a base, contains the lifting mechanisms, and houses a movable upper section, with a housing that accommodates the rest of the components of the device; a SCARA-type deployable robotic arm housed in the upper section and composed by a plurality of staggered parallel links and articulated at their ends by a power transmission mechanism comprised by motors with belts placed on pulleys coupled to concentric hollow shafts. The upper section is placed on a sliding and rotary platform that supports and guides it on the vertical axis through a vertical lead screw lifting mechanism, also allowing it to rotate on its own axis. The apparatus performs the movements by implementing a method of preset caress and massage patterns assisted by artificial intelligence and guided by several sensors.