A lower-leg exoskeleton that includes an inflatable actuator configured to be worn over a front portion of a leg of a user and configured to be disposed directly adjacent to and surrounding a joint of the leg of the user. The inflatable actuator is configured, when worn by the user, to receive and transmit an actuator load generated by the inflatable actuator around the joint of the user to a load contact point. Inflation of the inflatable actuator generates a moment about the joint of the user to cause flexion of the leg of the user.

A device comprising at least two ferrules, which may have a first ferrule (3) and a second ferrule (4), joined by elements by programmable elastic means (5) in the manner of elastic rods or straps with shape memory, wherein each ferrule (3) (4) has a housing (3.1) (4.1) for housing vibration-generating means (6) and (7) fed by means of cables (6.1) and (7.1), respectively, by a control unit which is in charge of controlling and adjusting vibration intensity, phase and speed, wherein the programmable elastic means is preferably a nickel-titanium alloy, and may be compressed air. A device is obtained that is simple to implement and apply in the treatment of arthritis and arthrosis disorders.

A passenger seat for commercial vehicles and rail systems, having at least: a massage pad for increasing the ergonomics in the waist section of the passenger and applying massage; a compressor for inflating the massage pad; cooling pads for cooling the passenger; a heating pad for heating the upper portion of the seat and the backrest contacting the passenger; a presence sensor for determining whether there is a passenger on the passenger seat; a belt sensor for determining whether the passenger fastens the safety belt; a wireless charging unit for the passenger to charge a mobile device without using a connection cable; a manual control panel for the heating pad, cooling pad and the massage pad; a wireless connection module for the heating pad, cooling pad and the massage pad; and a control unit where the data collected from the presence sensor and belt sensor are transmitted.

A system and method for thought-based control of sexual stimulation devices using electroencephalography. In an embodiment, a training phase comprises placing electrodes on the head of a person, measuring electrical signals produced by the person's brain via the electrodes while the user engages in one or more thought-based training tasks, associating patterns of electrical activity in the person's brain while performing the tasks with controls of the sexual stimulation device. In an embodiment, an operation phase comprises generating control signals for the sexual stimulation device based on the associations when the patterns of electrical activity are detected by the electrodes. In some embodiments, machine learning algorithms are used to detect the patterns of electrical activity and make the associations. In some embodiments, data from other biometric sensors is included in the associations.

Stimulation devices and methods of use are described herein. An example stimulation device configured to stimulate a portion of a body of a user comprises a housing that includes a casing and a covering. The casing includes a nozzle, a motor disposed within the casing configured to generate stimulation patterns, a drive shaft connected to the motor, a sensor configured to detect changes in the rotation of the draft shaft, a controller, and a battery. The covering covers a portion of the casing.

Systems and methods described herein include a pressure delivery component that has a pressure applicator configured to selectively apply therapeutic pressure to a treatment portion of a user body, and also includes a thermal delivery component that has a thermal applicator that is a configured to apply thermal treatment to the treatment portion. The thermal applicator may be removably disposable in operative relationship with the pressure delivery component in a use configuration of the treatment delivery component such that the thermal applicator is disposable between the treatment portion and the pressure applicator when the treatment delivery component is disposed on the treatment portion in the use configuration. Moreover, the pressure applicator is operable to apply pressure to the thermal applicator to enhance apposition of the thermal applicator to the treatment portion.

A compression device wearable by a user can apply compression, heat and cold on a left lower limb and a right lower limb of the user. The compression device includes a left massager sleeve, a right massager sleeve, a computing device, a left air pressure hose, and a right air pressure hose. The left massager sleeve and the right massager sleeve surround and secure the left lower limb, and the right lower limb respectively. The computing device generates air pressure. The computing device includes a control panel to control the flow of the air pressure in the left massager sleeve and the right massager sleeve. The left air pressure hose is connected to the left massager sleeve to apply the air pressure to the left lower limb. The right air pressure hose is connected to the right massager sleeve to apply the air pressure to the right lower limb.

A pneumatic module has an air passage formed therein, including an air inlet to receive a source of pressurized air, a first subsystem with an air splitter in fluid communication with the air inlet, a second subsystem, and a third subsystem. The air splitter is configured to create two unequal air pressure fields to deflect an airflow from the air inlet to the second subsystem. The second subsystem is configured to create two unequal air pressure fields to deflect the airflow toward a first air bladder to inflate the first air bladder, and when the first air bladder reaches a first threshold air pressure, a first backpressure from the first air bladder causes the second subsystem to switch and deflect the air flow to a second air bladder. A second backpressure causes the air splitter to switch and deflect the airflow from the second subsystem to the third subsystem.

A valve assembly for select distributed discharge of received fluid in a predetermined manner is generally provided. The assembly includes a manifold and a rotatable valve body. The manifold has an internal chamber, a fluid ingress passage for receipt of fluid, and a plurality of fluid discharge conduits. The fluid ingress passage and fluid discharge conduits are in fluid communication with the internal chamber. A first internal chamber section is characterized by the fluid ingress passage with a second internal chamber section characterized by ingress portions of the fluid discharge conduits. The valve body is adapted to be sealingly seated within the internal chamber so as to fluidly isolate the internal chamber sections, and includes a bore axially extending inwardly from a first end thereof for receipt of fluid from the fluid ingress port of the manifold, and a fluid egress passage in fluid communication with the bore for passage of received fluid to a select fluid discharge conduit of the fluid discharge conduits.

A pneumatic module has an air passage formed therein, including an air inlet to receive a source of pressurized air, a first subsystem with an air splitter in fluid communication with the air inlet, a second subsystem, and a third subsystem. The air splitter is configured to create two unequal air pressure fields to deflect an airflow from the air inlet to the second subsystem. The second subsystem is configured to create two unequal air pressure fields to deflect the airflow toward a first air bladder to inflate the first air bladder, and when the first air bladder reaches a first threshold air pressure, a first backpressure from the first air bladder causes the second subsystem to switch and deflect the air flow to a second air bladder. A second backpressure causes the air splitter to switch and deflect the airflow from the second subsystem to the third subsystem.