A foot massage apparatus includes a housing assembly, a driving mechanism, a front rotating member, a middle rotating member, and a rear rotating member. The middle rotating member is provided with a pivot shaft. An upper end of the pivot shaft is connected with a middle massage head. A lower end of the pivot shaft is provided with an elastic member. When different users use the foot massage apparatus, the middle massage head driven by the pivot shaft can be always in contact with the user's arch for massage. Therefore, the foot massage apparatus can meet the use requirements of different users, and make the user comfortable for massage.

A method of using an ankle exoskeleton device is provided herein. The method includes collecting one or more biomechanical data points from an individual. The method also includes developing individualized musculoskeletal simulations based on the one or more biomechanical data points. In addition, the method includes creating predictive simulations by modeling effects of an ankle exoskeleton device on the individualized musculoskeletal simulations. The method also includes utilizing established device-user relationships with real-time measurements to adjust device control. Lastly, the method includes optimizing design parameters of the exoskeleton device based on the predictive simulations and user responses.

A finger glove liner (2) comprising at least one finger portion (1), for arrangement inside an outer finger glove, making up a grip strengthening finger glove (3) is provided. The finger glove liner (2) is made of a stretchable material (4) in order to suit more than one size of hands, wherein at least one patch (5) of material, which has attached thereto at least an artificial tendon (9), is arranged at the outside of the finger glove liner (2).

A percussive massage device that includes a housing, an electrical source, a motor positioned in the housing, a switch for activating the motor, and a push rod assembly operatively connected to the motor and configured to reciprocate in response to activation of the motor. The housing includes first, second and third handle portions that cooperate to define a handle opening, wherein the first handle portion defines a first axis, the second handle portion defines a second axis and the third handle portion defines a third axis, and wherein the first, second and third axes cooperate to form a triangle.

A grasp assist system includes a glove, finger saddles attached to a respective glove finger, one or more tendon actuators, and artificial tendons. The saddles have a rectangular body partially circumscribing a respective glove finger. Each saddle includes end lobes at opposite distal ends of the body. A first end of each tendon is secured to one of the tendon actuators. A second end forms a triple Brummel loop defining a main loop and two anchor loops. The anchor loops are disposed around the lobes. The saddles may form a rounded, double-headed arrow shape that is at least double the thickness of the body. The finger saddles are anisotropic, with different bending strengths depending on the axis, and may be constructed of thermoplastic polyurethane-coated nylon. Flexion and/or contact sensors and a controller, may be used. A method of connecting the tendon actuator to the finger is also disclosed.

A shock wave treatment device to treat skin and adjacent tissue with a combination of mechanical stimulation and acoustic pressure shock waves, such as methods for cosmetic applications, enhancing blood circulation, and wound treatment, includes a pressure shock wave applicator having a reflector and a mechanical stimulator of one or both of a vacuum device and roller device.

Provided are a support rehabilitation training robot and an operation method thereof. The support rehabilitation training robot includes a crawler-type walking machine, a pedestal, a lifting lead screw mechanism, a manipulator and a counterweight mechanism. The manipulator includes a shoulder joint, a revolute joint, an elbow joint and a wrist joint. Each of the joints includes a motor, a harmonic reducer and an output terminal.

A sliding assembly may include a supporting frame having a proximal end and a distal end, a sliding frame partially inserted to the supporting frame, and a supporting member disposed between the supporting frame and the sliding frame to prevent the supporting frame from directly contacting the sliding frame, wherein the sliding frame is configured to move relative to the supporting frame.

A sliding assembly may include a supporting frame having a proximal end and a distal end, a sliding frame partially inserted to the supporting frame, and a supporting member disposed between the supporting frame and the sliding frame to prevent the supporting frame from directly contacting the sliding frame, wherein the sliding frame is configured to move relative to the supporting frame.

A walking assistance apparatus includes a suit to be worn on a knee and waist of a user, a first wire that couples a portion included in the suit and worn above the knee to a portion included in the suit and worn on the waist, a second wire that couples a portion included in the suit and worn above a back of the knee to a portion included in the suit and worn on the waist, and motors coupled to the first and second wires. The motors are controlled to generate tensions so that each of the first and second wires has a stiffness greater than 200 N/m during a first period including a period of 95% or more and 100% or less of a first gait cycle of the user and a period of 0% or more and 50% or less of a second gait cycle subsequent to the first gait cycle.