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.

An adjustable knee ankle foot orthosis for unloading weight from a knee joint afflicted with osteoarthritis, thus reducing pain and improving mobility, comprising: an upper and lower frame connected by an unloading hinge assembly, optionally comprising a sensor and processor allowing for remote or automatic control of brace tension. In embodiments, the brace includes a user mechanism that is capable of adjusting a tensioning element while the brace is being worn. In other embodiments, electronic motors, sensors, and indicators may be included in the brace to improve brace performance and user interaction.

A system and method for providing massaging within a vehicle that include receiving vehicle dynamic data associated with a real-time dynamic performance of the vehicle as the vehicle is being driven for a predetermined period of time. The system and method also include determining at least one strenuous driving activity associated with a driver of the vehicle based on at least one driving maneuver. The system and method additionally include analyzing positional parameters and movement parameters that are associated with at least one area of a body of the driver that is utilized to conduct the at least one driving maneuver for the predetermined period of time. The system and method further include controlling at least one massaging element disposed within the seat of the vehicle to provide massaging to the at least one area of the body of the driver.

A device for performing individual movement analysis and movement therapy on a patient includes a control and analysis unit configured to control a first intervention device in such a way that a first trajectory of the movement of an extremity of the patient is disrupted by a force exerted by a movement module onto the extremity of the patient. A response to this disruption is measured by changed measured values from at least one force sensor and/or at least one angle sensor, and a new, second trajectory is calculated therefrom. New control parameters for controlling the first intervention device are calculated from a comparison of the second trajectory with the first trajectory and/or a target trajectory or the comparison of the disrupted measured values with the non-disrupted measured values.

Air microfluidics and minifluidics enabled active compression apparel enhances mobility and quality of life for individuals by minimizing risks of injuries, enhancing rehabilitation, and maximizing comfort. Balloon actuators, integrated with a garment, provide active compression and augmenting forces to anatomical portions of the human body. The balloon actuators are actuated by fluidic pressurization hardware. The air microfluidics and minifluidics system miniaturizes fluidic pressurization hardware and makes it wearable, ultra lightweight, and ultra formfitting. The air microfluidics and minifluidics system includes micro and mini channels of various lengths, cross-sectional areas, and functions via principles of equivalent hydraulic resistance allowing for fluidic transportation, passive delay in pressurization of the balloon actuators, and digital soft fluidic actuation where the compression force is based on the number of inflated balloon actuators instead of their pressure.

A mobile robot system and method for determining the stiffness of a human arm while moving with a user during overground interaction as the user holds the robot's handle and exchanges forces with it. A mobile base moves with the user, a robot arm interacts with the user, and a controller determines the stiffness. The robot arm includes servomotors driving a linkage mechanism, an end effector including the handle supported by the linkage mechanism, and a force transducer measuring a force applied by the user to the handle. The controller causes the robot arm to generate a force perturbation at the handle, measure a peak velocity achieved by the human arm, determine the stiffness of the human arm as a function of force and displacement, and control operation of the system based on the determined stiffness. A robot body may allow for adjusting the height of the robot arm.

A system for ankle rehabilitation includes a motorized platform arranged to hold an ankle of a subject to be rehabilitated; a first sensor module arranged to detect signals representing movement intention of the ankle on the motorized platform; a second sensor module arranged to detect signals representing actual movement of the ankle on the motorized platform; and a processor arranged to process the signals detected by the first sensor module and the signals detected by the second sensor module, for control of movement of the motorized platform.

An orthopedic system wherein a patient's brain is operably coupled to an actuation assembly for voluntarily moving a brace/limb of the patient between a number of desirable positions. An orthopedic brace, or one of more components thereof, which can be utilized with the orthopedic system.

An auricular peripheral nerve field stimulator includes at least one therapy electrode configured for percutaneous insertion into an auricle of a human ear near at least one neurovascular bundle, and an electrical stimulation device electrically coupled to the at least one therapy electrode, the electrical stimulation device programmed to generate and deliver electrical stimulation signals, with defined stimulation parameters, to the percutaneously inserted at least one therapy electrode to stimulate at least one auricular peripheral nerve field within the auricle, the defined stimulation parameters including a defined signal amplitude, a defined pulse frequency, a defined pulse width, a defined duty cycle and a defined stimulation signal duration.

An integrated functional electrical stimulation (FES) system includes a component of a mobility assistance device, and an FES system mounted within the component. The FES system includes an FES stimulator that is embedded within the component, and a plurality of FES jacks that are electrically connected to the FES stimulator and are located on the component. The FES jacks are configured to receive a plurality of FES electrodes, and an electrical stimulation output from the FES stimulator is conducted through the FES jacks to the FES electrodes. In a wireless embodiment, the FES stimulator is configured to wirelessly transmit a control signal for applying an electrical stimulation output to the plurality of FES electrodes, and the FES jacks are eliminated. The FES stimulator may be embedded within a back portion of the hip component of an exoskeleton device, and in the wired embodiment the FES jacks are located on wing portions of the hip component.