The present invention provides an upper limb function assessment device and the use method thereof and an upper limb rehabilitation training system and the use method thereof, wherein the upper limb function assessment device includes a display, a depth camera and a central processor, the depth camera is used to capture a user's motion, the display is used to display motion demonstration and the user's motion, and the central processor is connected to the display and the depth camera, respectively. The present invention captures the user's motion precisely with the depth camera, which makes the obtained data more accurate and objective, and also facilitates recording and storage of the obtained data. The central processor determines whether the completion of the motion meets the requirements in assessment scales, allowing the user to come up with an assessment report on his own without requiring a lot of assistance from a physician.

According to some embodiments, a device configured for self-administered therapy comprises at least two base members, each base member configured to be secured to a surface for mounting the device of said surface, a shaft configured to secure to the at least two base members and extend between the at least two base members, and at least one therapy member configured to be secured relative to the shaft, wherein the at least one therapy member is configured to rotate relative to the shaft during use, wherein the at least one therapy member is configured to be contacted by a user and configured to rotate during use.

An elbow joint rehabilitation system and an elbow joint rehabilitation method are provided. The elbow joint rehabilitation system includes a support member, a motor, a torque sensing unit, a first electromyography sensor, a second electromyography sensor and a motor control device. In the elbow joint rehabilitation method, the support member is configured to support an arm of a patient. Thereafter, the torque sensing unit is configured to sense the torque applied on the support member to obtain a sensed arm torque signal. Then, the first electromyography sensor and the second electromyography sensor are configured to sense the muscle activities of biceps and triceps of the patient to obtain electromyography signals. Thereafter, the motor is controlled to drive the support member to perform rehabilitation in accordance with the sensed arm torque signal, the electromyography signals and a current support member position provided by the motor.

Embodiments provide devices, systems and methods for preventing deep vein (DV) thrombosis (DVT). One embodiment provides a DVT prevention device including a cuff that fits over a patient's knee, an applanator coupled to an inside cuff surface, an expandable member (EM) coupled to the applanator, a pressure source fluidically coupled to the EM and a controller for controlling EM inflation. When the EM is inflated, it applies a force to the applanator which is transmitted to the knee back surface causing a popliteal vein (PV) under the cuff to be compressed so as to increase backpressure behind the compressed PV and subsequently increase the velocity of blood flow in the leg DV's when the EM is deflated. The EM can be inflated in a cycle including pulsed inflation, inflation hold and relaxation. The cycles can be repeated and adjusted to achieve a desired increase of blood flow/velocity in leg DV's.

A control system and method for an exoskeleton is provided. The control system utilizes the admittance control paradigm to provide a system and method for manipulating the exoskeleton using minimal force from the user. A force/torque sensor and servo motors are fitted onto a passive arm support, enabling motorized support for a user with upper extremity weaknesses. The exoskeleton may be used on any extremity. The admittance control paradigm includes an impedance control and an admittance control to allow a user with upper extremity weakness and limited independence to intuitively and with minimal force control the precise trajectory of their arms to achieve a greater degree of independence in activities of daily living. Unlike existing passive arm supports that utilize springs or rubber bands to balance the user's arm against gravity, this system provides more precise gravity compensation and minimizes the amount of force required to control the exoskeleton.

A system and apparatus for promoting perfusion at a tissue site containing a sprain by applying a vacuum to intact skin extending over or surrounding the tissue site. The system and apparatus comprise a manifold formed from a porous material and configured to be disposed proximate the intact skin for distributing vacuum to the intact skin, and a sleeve adapted to cover the manifold and form a chamber containing the manifold to seal the manifold within the chamber between the sleeve and the intact skin. The system and apparatus further comprise a fluid coupling member adapted to deliver vacuum to the manifold for distribution to the intact skin. A method for applying vacuum to the intact skin of a tissue site is also disclosed and described herein.

A medical device providing a combination of thermal and DVT therapies to a patient. The components, arrangement of components, function of the device as a whole, and methods of use of the device are all devised to maximize therapeutic effectiveness. Effectiveness in this context is measured by the ability to provide a controlled application of the recommended thermal treatment including time, temperature, compression, and number of cycles with specified cycle duration.

A nerve stimulator is provided, and in particular a non-invasive nerve stimulator for peripheral nerves, such as the ulnar and/or median nerves. The stimulator may be fitted proximate the left and/or right arm, wrist or hand of a user, to stimulate the median and/or ulnar nerves using electricity, light, sound, magnetic field, vibration or pressure, or any combination of these stimuli. The apparatus takes the form of a standalone band or clasp, or forms part of a fitness tracker band, watch or smartwatch. The nerve stimulator comprises a stimulus generator, to generate any or a combination of the stimuli mentioned above, an applicator to apply the generated stimulus to the arm, wrist or hand of the user, and a controller to control the operation of the stimulus generator and the applicator. In some cases, for stimuli such as light, sound, magnetic field, vibration or pressure, the generator and applicator may be combined into a single component.

One aspect of the present invention is different embodiments of legs and feet massage apparatuses for providing massage effects to the legs and/or feet of a user. Another aspect is different embodiments of hands and arms massage apparatuses for providing massage effects to the arms and/or hands of the user. Additional aspect is an armrest sliding adjustment apparatus. A further aspect is a bicep and tricep panel sliding adjustment apparatus. Additional aspect is a chair that includes at least one of the following devices, apparatuses and systems described in this application: any of the legs and feet massage apparatuses; any of the hands and arms massage apparatuses; an armrest sliding adjustment apparatus; a bicep and tricep panel sliding adjustment apparatus; a neck and shoulder massage system; an integrated smart medical device; at least one health monitoring device or system; a virtual reality device; and a touchscreen-based control system.