A massage glove and a vehicle-mounted massage device are provided. The massage glove includes a glove body, at least one acupuncture point massager and a controller. The acupuncture point massager is arranged on the glove body at a position corresponding to an acupuncture point on a hand. The acupuncture point massager is configured to massage the acupuncture point so as to relieve a physical fatigue of a user. The controller is configured to output a control signal to the acupuncture point massager, so as to enable the acupuncture point massager in accordance with the control signal.

An apparatus for treatment of a patient using vibrotactile multi-channel stimulation includes: (1) multiple vibratory stimulators; (2) multiple fastening mechanisms to secure respective ones of the vibratory stimulators to respective parts of a hand of the patient; and (3) a controller connected to the vibratory stimulators to direct operation of the vibratory stimulators.

A finger exerciser includes: a frame on which a palm of a subject to be put; a movable section; a first fixing element; and a second fixing element. The movable is configured to move a first finger group of a subject. The first fixing element is configured to fix a position of the first finger group to the movable section. The second fixing element is configured to fix a position of a second finger group to the frame and has a band-like member including at least two attachment parts apart from each other in a longitudinal direction of the band-like member. The band-like member is attached to the frame at the attachment parts and includes a holder whose location to the frame is changeable. The band-like member is configured to hold the second finger group in a state where the band-like member is attached to the frame.

A haptic device is disclosed comprising at least one fluidic actuator operatively connectable with pumping means; and a plurality of movable members mechanically connected with said at least one fluidic actuator, wherein said movable members can perform a displacement upon actuation of the fluidic actuator and/or resist the movements of a body part of a user upon actuation of the fluidic actuator, to provide a tactile and/or force haptic sensation to a body part of a user. Methods for providing a haptic sensation to a user and receiving haptic input commands from a user are also disclosed.

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.

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 individual linkage mechanism for a finger of an exoskeleton glove with sections that are interconnected with joints to enable changing their mutual angular orientation, which linkage mechanism includes a first linkage attached to the glove, a second linkage connected to the first linkage through a first joint, a third linkage connected to the second linkage through a second joint, and a fourth linkage connected to the third linkage through a third joint, wherein the fourth linkage is provided with a finger orthosis, and the second linkage, the third linkage and the fourth linkage are capable to assume a mutually parallel placement wherein the finger orthosis is adjacent to the second joint at a farthest end from the glove, and the third joint is closer to the glove than the second joint.

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).

An apparatus comprising a vibrating finger device useful in a medical setting includes a device body configured to fit on a finger of a wearer, a vibrating unit, a touch sensitive sensor, and a control module including a computerized processor. The control module includes programming configured to monitor an activation input to the device, determine the monitored activation input to indicate a threshold desired vibration activation input, and activate a vibration cycle within the vibrating unit based upon the determination.

A device comprising at least two ferrules, which may have a first ferrule (3) and a second ferrule (4), joined by elements by programmable elastic means (5) in the manner of elastic rods or straps with shape memory, wherein each ferrule (3) (4) has a housing (3.1) (4.1) for housing vibration-generating means (6) and (7) fed by means of cables (6.1) and (7.1), respectively, by a control unit which is in charge of controlling and adjusting vibration intensity, phase and speed, wherein the programmable elastic means is preferably a nickel-titanium alloy, and may be compressed air. A device is obtained that is simple to implement and apply in the treatment of arthritis and arthrosis disorders.