A fixed-sensor finger action detecting glove has a glove body, five covering sheets, five fixing bases, five sensors, and five fixing assemblies. A side of the glove body forms a hand back section and five finger back sections. The covering sheet is mounted on the finger back section and forms a passage. The fixing base is made from a flexible material, is mounted through the passage, and has two limiting walls. The sensor is located in the passage between the two limiting walls, preventing the sensor from deviating. The fixing assembly is mounted between an end of the sensor and an end of the finger back section, detachably connects the sensor and the finger back section, and prevents the sensor from moving back and forth. Thus, the fixed-sensor finger action detecting glove is capable of detecting actions of the fingers precisely.

The Thumb Saver is the only product of its kind that has the capability of reducing the cumulative effects of chronic typing, writing and texiing in a convenient means that can be easily employed while an individual is sitting at home or at work. The Thumb Saver is uniquely designed with a sticky, non-skid surface on the top and bottom sides to avoid the device from sliding from the hand during use and offers versatility as the product can be used for both the left and right thumb by simply flipping the product over.

The inventive concept relates to an upper-limb rehabilitation robot that includes a finger exercise device that is mounted on the back of a patient's hand and that exercises a finger of the patient for rehabilitation, a wrist exercise device that is provided on a wrist of the patient and that exercises the wrist of the patient, and an upper-limb exercise device that is spaced apart from the wrist exercise device and that exercises an upper limb of the patient.

A health care device includes a health care body for positioning a body part of a user, so as to maintain a first specific positional relationship with the body part, wherein the body part has an acupoint; an acupoint work piece for performing a health care work onto the use through the acupoint; and a work piece holder having a first end connected to the health care body and a second end for fixing the acupoint work piece, so that under the first specific positional relationship, the acupoint work piece performs the health care work under the condition that the acupoint work piece has a second specific positional relationship with the acupoint. A health care body, method and system are also provided.

A motion assisting apparatus includes a multijoint structure having links in series rotatably connected in a relative manner, the links being integrally deformed in a bendable manner, a linear member inserted through each of the links, wherein one end is fixed to the link in front and another end is elongated via the link in rear, a sliding/holding part which fixes an elongated portion of the linear member, and slidably guides the rear link in a connecting direction between each of the links, a drive unit which drives the rear link to slide toward the sliding/holding part and causes the multijoint structure, through which the linear member has been inserted, to engage in an extending or flexing motion, and a control unit which drive-controls the drive unit so that a sliding direction, a sliding speed and a sliding position of the rear link will become an intended state.

Systems, devices and methods for providing active and/or passive compression therapy to a body part can include a compression device worn over a compression stocking. The compression device can have a pulley based drive train that is driven by a motor to tighten and loosen compression elements, such as compression straps, in a precise, rapid, and balanced manner. Sensors can be used in the compression device and/or compression stockings to provide feedback to modulate the compression treatment parameters.

A compression-resistant device includes least one pair of first and second opposing jaw members having respective engaging surfaces for movement from an open position receiving an object and a closed position engaging the object. A manual compression surface enables a user to manually apply pressure to urge the engaging surfaces from one of the closed position towards an open position or from the open position towards the closed position. At least one resistance member interfaces with the first and second opposing jaw members to resist pressure manually applied by a user urging the engaging surfaces from the closed position towards the open position or from the open position towards the closed position. The manual compression surface includes projections such that manually applied pressure forms at least one aggravated area on a finger surface of the user to initiate a callus. A corresponding method of operating the device is also disclosed.

Various embodiments provide assemblies for manipulating a user's limb with at least one inflatable member. The assemblies comprise a first pliable planar member and a second pliable planar member overlaid atop at least a portion of the first pliable planar member, such that a two ply configuration is provided. The two ply configuration itself comprises at least a distal and a proximal portion and at least one opening configured to accept at least a portion of the user's limb. The first and second pliable planar members combine to define at least one inflatable member, the inflatable member being at least a portion of at least one of the distal and proximal portions, the inflatable member being configured to be selectively inflatable so as to provide at least one inflation force upon the user's limb, such that the joint in the user's limb is manipulated. Associated methods are also provided.

An aid device for the movement and rehabilitation hand fingers includes a exoskeleton, an articulated glove or a wearable mechanism configured to be positioned on the back of at least one finger and to be mechanically constrained to the finger, and a motorized system exerting a movement or a change in the configuration of the exoskeleton. The exoskeleton includes a rigid elements arranged on a row one behind the other along a longitudinal axis parallel to the longitudinal extension of the finger and articulated with each other to make a modular underactuated structure and obtain maximum shape and kinematic adaptability to the fingers, particularly to follow the extension and flexing movement of the fingers. The motorized system includes pulling and/or pushing elements that act on one or more of the elements of the exoskeleton to produce finger movements and particularly the extension and flexing movements of the fingers.

A power assistive device 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 includes a hand brace and a base. The hand brace includes finger assemblies that adjustably connect to a platform, actuators that connect to the finger assemblies, and strain gauge sensors that connect to the finger assemblies and detect force signals generated by movement of the finger assemblies. The base removably connects to the hand brace and includes a forearm support, a C-shaped ring that includes C-shaped tracks formed along an inner circumferential surface of the C-shaped ring, a rotatable platform that moves along the C-shaped tracks, a mounting platform that connects to the rotatable platform, and an electromyography (EMG) sensor that attaches to the forearm of the user and senses EMG signals generated by movement of the hand of the user.