Systems, methods, and devices are described for providing a fluid control for an inflation system. The control directs fluid flow from an inlet to one or more outlets of the control. The outlets are independently connected in fluid communication with the inlet by through the control. The control allows a user to create a fluid path between the inlet and a selected outlet by positioning the control in an orientation corresponding to the desired outlet. Each outlet is independently connected in fluid communication with the inlet in various orientations of the control.

The invention relates to an enveloping body for at least partially enveloping a limb, having an enclosed volume and a connection for supplying and removing fluid to the volume or from the volume, wherein the enveloping body forms an inner circumference and an outer circumference; on the enveloping body reinforcement elements are arranged that are designed to be brought into contact as a result of the removal of fluid from the volume or to increase their contact with one another as a result of the removal of liquid.

The present disclosure describes soft-robotic wearable devices to treat and/or relieve Carpal Tunnel Syndrome, for example during typing assist applications. Soft actuators within the device adjust the angle of the wearer's wrist angle dynamically to achieve a neutral angle, alleviating the pressure on the median nerve and relieving Carpal Tunnel Syndrome strain.

An appendage pressurization device includes an appendage strap and one or more artificial muscles disposed in the appendage strap and communicatively coupled to a controller. Each artificial muscle includes a housing comprising an electrode region and an expandable fluid region, a dielectric fluid housed within the housing, and an electrode pair positioned in the electrode region of the housing, the electrode pair comprising a first electrode fixed to a first surface of the housing and a second electrode fixed to a second surface of the housing, wherein the electrode pair is actuatable between a non-actuated state and an actuated state such that actuation from the non-actuated state to the actuated state directs the dielectric fluid into the expandable fluid region, expanding the expandable fluid region. The appendage pressurization device also includes a pressure sensor communicatively coupled to the controller, wherein the pressure sensor is configured to output a current pressure value to the controller and actuation of the electrode pair is based on the current pressure value.

A dynamic support apparatus having a frame, a dynamic interface, a temperature control mechanism, and a control system. The dynamic interface is capable of changing its geometry and is disposed on the top surface of the frame. The control system is operably connected to the dynamic interface and controls the changing geometry of the dynamic interface. There is also a temperature control mechanism disposed on the top surface of the frame for maintaining a comfortable temperature and moisture environment between the apparatus and the user's body.

Determining whether a compression garment is worn by a wearer of the garment by analyzing a pressure signal waveform indicative of a fluid pressure in an inflatable and deflatable bladder of the compression garment. Variance detected in the pressure signal waveform during the analysis is indicative of a change in condition of the compression garment. In one aspect the change in condition is verified using confirmatory analysis. In another aspect, the variance is one of a pressure rise and a pressure impulse. In yet another aspect, the variance is an oscillating amplitude as a function of time representative of a pulse of the wearer.

A body joint support device capable of abutting against at least one body joint and accommodating in configuration both to the bending and non-bending states of the body joint includes a covering structure, a control device, and at least one electrode pad unit and/or inflatable airbag. The covering structure can be worn to the body joint, the electrode pad unit is provided on the inner surface of the covering structure, and the control device is provided on the outer surface of the covering structure. The control device can transmit current to the electrode pad unit so that the electrode pad unit outputs current to stimulate and/or heat muscles. When a body joint moves, the force produced by the covering structure can press the electrode pad unit tightly against the skin at the body joint, so that the electrode pad unit does not become loose due to frequent body joint movement.

A control unit system. The system includes a control unit which includes a control unit charging interface, at least one magnet located proximate to the control unit charging interface, at least one actuator, a detachable manifold including at least one magnet, fluidly coupled to the at least one actuator, a pump connected to the at least one actuator for causing actuation thereof, and a control system for controlling the pump, wherein the control system controls the pump to actuate the at least one actuator at least in response to a signal received by the control system. The system also includes a recharging device configured to receive the control unit, the recharging device including a reed switch, wherein when the magnet in the control unit is located proximate to the reed switch, the switch is activated.

Disclosed is a wrap which is removably attached with a body part of a user to provide compression, and protection. The wrap includes first sensing unit, second sensing unit, movement unit, adjuster unit, and a power source. The first sensing unit senses the physiological state of the user's body. The second sensing unit measures the dimension of the body part of the user. The body part is selected from at least one of: wrist, ankle, lower back, knee and/or combination thereof. The movement unit receives sensed information from first sensing unit, and second sensing unit to support an inflate mechanism and deflate mechanism to provide desired compression to the body part of the user. The adjuster unit configured with the movement unit to engage or disengage the wrap from the body part of the user. The power source which further includes a rechargeable battery powers the first sensing unit, second sensing unit, movement unit, and the adjuster unit.

Disclosed is a robotic orthosis for a lower extremity for gait rehabilitation training, comprising a knee stretching member which is provided to be installable on the knee so as to enable the knee joint to be stretched in a swing phase and enable a state in which the knee is stretched to be maintained in a stance phase. The knee stretching member comprises: a knee sleeve surrounding the knee joint; and a knee supporting chamber which is mounted so as to be connected to the knee sleeve, and which, when air is introduced therein and is inflated in the swing phase, enables the knee to be stretched by supporting the knee joint, and enables the state in which the knee is stretched to be maintained in the stance phase.