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.

A lower support type rehabilitation device for fingers includes a cover plate having a hand covering portion and a plurality of through holes. A plurality of finger supports are disposed on the hand covering portion, each having a first finger base, a second finger base pivotally connected to the first finger base, two side arms and a beam disposed on the first finger base. A traction device is disposed on the hand covering portion and has a first processing module, a plurality of driving modules electrically connected to the first processing module, a plurality of pulling ropes connected to the plurality of driving modules and a plurality of pressure sensors electrically connected to the first processing module. Each of the plurality of pulling ropes passes through one of the plurality of through holes for fixing to the beam of the first finger base.

Device (100) for applying haptic stimuli to a body part (200) of a user, comprising a stiff support (30) configured to contact the body part 200; a containing element configured to keep the body part (200) in contact with the stiff support (30); an actuating element configured to push the stiff support (30) into the containing element and apply a pressure to the body part 200. The containing element comprises a stiff frame (10) defining a recess (20) to house the body part 200. The frame (10) comprises two lateral stiff guides (51) defining the recess (20) and the stiff support (30) is configured to move in a guided manner in the stiff guides (51). At least one servomotor (40, 40′) is provided connected integrally to the stiff frame (10) on the opposite side to the stiff support (30) with respect to the recess (20) and arranged to cause a relative movement, inside the recess (20) and with respect to the lateral stiff rails (51), of the stiff support (30) with respect to the body part (200). At least one belt (50, 50′) sliding parallel to the lateral stiff rails (51) and connected respectively with the servomotor (40) and the stiff support (30) is provided. The servomotor (40) is configured to operate the or each belt (50, 50′) to cause guided movement in the stiff guides (51) of the stiff support (30).

An exoskeleton robot for hand and wrist kinetic rehabilitation provides passive, active-assisted, and active resistance rehabilitation for fingers and wrist joints independently. It relieves pain during exercises and stimulates the mechanoreceptors for all hand and wrist joints. The device provides levels of differentiation for finger rehabilitation through independent motion control mechanisms for all ten phalanges of the fingers and the wrist with a full range of motion, which helps in focusing the work on each joint selectively. It is portable, operates using an electric power source only, easy to wear, fits different hand sizes, and most of its parts made of lightweight plastic.

A hand rehabilitation device, a rehabilitation training device, and a method for controlling the same are disclosed, and the hand rehabilitation device includes a hand rehabilitation component including: a glove; a hand pneumatic muscle group including at least one finger pneumatic muscle component, wherein a back of each finger sleeve in the glove is installed with at least one of the at least one finger pneumatic muscle component; and a stopper which is connected with each finger sleeve and a side of each of the at least one finger pneumatic muscle component facing a corresponding finger sleeve.

An improved dual glove exoskeleton system and method for rehabilitation of stroke victims is provided to increase recovery through optic, neural, and muscular stimulation. The proposed approach employs an algorithm that is configured to determine a degree of dysfunction, of certain extremities, and in particular, an upper extremity. During rehabilitation and recovery, the proposed system is designed to monitor a position of a healthy limb and allow a patient to attempt a mirrored position in a damaged limb. The system and method then completes the movement in an assisted-control manner. The system detects how each finger responds individually to the treatment and chooses an exercise program that is appropriate under the circumstances to further assist with rehabilitation.

The present disclosure relates to a device including electrostatic brakes providing haptic kinaesthetic feedback to a user in e.g. assistive, rehabilitation or virtual reality scenarios, as well as tele-manipulation.

Systems and methods for robotic and exoskeleton hands are provided. An exoskeleton hand can include a flexible actuator having a cavity and a reinforcement band. The cavity can be filled with a fluid from a pressure source, forcing the actuator to deform, bend or extend. The fluid that fills the cavity as a driving force can be a gas or liquid, which can be recyclable or disposable.

A finger exoskeleton robot includes a support plate, at least one finger mechanism, and a temperature control system. Each of the finger mechanisms includes a plurality of finger sleeves and joint drivers. The sleeves of the finger mechanism are sequentially arranged at a distance and configured to be correspondingly worn on a plurality of knuckles of the user's fingers. Every two finger sleeves adjacent to each other of the finger mechanism are connected by one joint driver. The support plate and one of the finger sleeves closest to the support plate are connected by one joint driver. The joint driver is switched between a flat state and a curved state when the temperature of the joint drivers is higher than or lower than a phase change temperature value. A temperature control system is electrically connected to the respective joint drives and respectively controls the temperature of the joint drivers.

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.