An exoskeleton finger rehabilitation training apparatus includes a housing. A first motor and a second motor are disposed inside the housing. A direction of an output shaft of the first motor is opposite to a direction of an output shaft of the second motor. The output shaft of the first motor is provided with a first motor gear. A right side of the first motor gear is engaged with a first transmission gear. An edge of the first transmission gear is sequentially connected to an index finger sleeve and a middle finger sleeve that are axially arranged. The output shaft of the second motor is provided with a second motor gear. A right side of the second motor gear is engaged with a second transmission gear. An edge of the second transmission gear is sequentially connected to a pinky sleeve and a ring finger sleeve that are axially arranged.

A palm-supported finger rehabilitation training device comprises a mounting base, a finger rehabilitation training mechanism mounted on the mounting base, and a driving mechanism for driving the finger rehabilitation training mechanism; wherein the finger rehabilitation training mechanism comprises four independent and structurally identical combined transmission devices for finger training corresponding to a forefinger, a middle finger, a ring finger and a little finger of a human hand, respectively, and the mounting base is provided with a supporting surface capable of supporting a human palm; wherein each combined transmission device for finger training comprises an MP movable chute, a PIP fingerstall, a DIP fingerstall and a connecting rod transmission mechanism; a force sensor is provided to acquire force feedback information to determine and control force stability, and a space sensor is provided to acquire space angle information to control space positions of fingers in real time.

The present invention provides a compact, wearable and portable self driven rehabilitation device which is cost effective, light weight, portable, easy to use and customizable to fit as needed. It provides real-time mirroring effect for better visual feedback.

An orthotic device includes an upper arm section for receiving an upper portion of an arm of a subject, a forearm section for receiving a forearm section of the arm, and at least one elbow joint rotatably coupling the upper arm section and the forearm section. In the orthotic device, the forearm section includes a release control operatively coupled to the at least one elbow joint, where the release control is configured to transition the at least one elbow joint from a restricted motion state to a free motion state when the release control is activated.

Examples of a device for guiding and detecting a motion of a target joints and a motion assistance system such motion guiding devices are described. The motion guiding and detecting device comprises a motion generator and a motion transfer and target interfacing unit to transfer the motion generated by the motion generator to the target joint. The system further includes a motion detection and feedback unit that interfaces with the target, and a controller that interfaces with both the feedback unit and the motion generator to control and coordinate the motion of the motion generator and the target joint.

A method for exercising a joint and a limb including the following: preventing movement of an exercise device actuation member in a first direction unless pressure exerted by the limb against the actuation member is equal to or greater than a predetermined first target pressure; permitting movement of the actuation member in the first direction at a first predetermined speed when pressure exerted by the limb against the actuation member is equal to or greater than the predetermined first target pressure; preventing movement of the actuation member in a second direction unless pressure exerted by the limb against the actuation member is equal to or greater than a predetermined second target pressure; and permitting movement of the actuation member in the second direction at a second predetermined speed when pressure exerted by the limb against the actuation member is equal to or greater than the predetermined second target pressure.

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 device for muscle strength support includes a flexible support structure configured to be worn on a body of a user during use of the device and an actuator unit configured to exert a tensile force on a first tension member of the flexible support structure to support the muscle strength during a movement of a first body part. The first tension member extends along a first path through a guide strap of the flexible support structure to the actuator unit, the guide strap limiting a section of the first path in a direction perpendicular to a path longitudinal direction. The first tension member is further configured to be attached to the first body part during use of the device by a first fastening member.

A finger motion rail is provided for a therapy device for carrying out passive and/or actively-assisted motion of the fingers and thumb of the hand. The therapy device has an upper shell, to which a kinematic motion mechanism of the finger motion rail for each selected finger is connected, each mechanism has a motion drive that is in control engagement with a control system. The kinematic motion mechanism of the finger motion rail, which mechanism has a carriage that moves in a rail provided around the metacarpophalangeal joint and a pivoting lever, is located at the side of each finger for the passive and/or actively-assisted motion of the selected fingers. This allows an individual finger motion rail with the kinematic motion mechanism to be provided for each selected finger, the rail being located at the side of each finger, thus permitting each selected finger to bend and/or stretch without constraint.

A method for producing a hand orthosis, including the steps of: Producing an impression of at least one finger of a patient's hand and at least a part of a forearm, producing a finger section from a reproduction based on the impression, incorporating at least one finger segment in the finger section side corresponding to the hand surface, detecting the physiology of the patient's forearm using at least one captured image from the reproduction together with the finger section, thereby producing a digital 3D model, generating a rail based on the produced digital 3D model, securing at least one force-introducer onto or into the rail, securing a proximal end of the at least one finger segment to a distal end of the rail, and coupling the at least one force-introducer to the at least one finger segment. A hand orthosis is also provided.