A steam therapy assembly includes a housing that has an intake and an exhaust to pass air through the intake and the exhaust. A water tank is removably attachable to the housing and the water tank has a fluid port to pass water therethrough for filling the water tank with water. An oil cartridge contains oil and the oil cartridge is removably insertable into the housing. A vaporizing unit is integrated into the housing and the vaporizing unit is in fluid communication between the intake and the exhaust to urge air into the intake and outwardly through the exhaust when the vaporizing unit is turned on. The vaporizing unit vaporizes the water in the water tank into a steam. Additionally, the vaporizing unit vaporizes the oil in the oil cartridge thereby mixing the vaporized oil with the vaporized water.

Device (100) for assisting with mobilizing a joint (3) comprising a first and a second guiding element, the first flexible guiding element (102) being positioned on one of the segments (4), having a first pair of cable passages arranged on the side of the rear face (52) and on the side of the front face (54), the second flexible guiding element (104) being positioned on the other of the segments (5), having a first pair of cable passages, arranged on the side of the rear face (52) and on the side of the front face (54), the second guiding element further comprising a pair of anchoring points arranged on the side of the front face (52) and on the side of the rear face (54), a flexible support part on which a pair of actuators (M11, M12) associated with a pair of winders are arranged, to cause the associated winder to turn in the winding direction and the unwinding direction, and a pair of cables (C11, C12) extending from the winders, up to the anchoring points of the second guiding element, passing through the cable passages of the first pair of cable passages of the first and second guiding elements.

A capsule apparatus comprising: an enclosure and a capsule core arranged in the enclosure. The capsule core comprises: a power supply, an acceleration sensor connected to the power supply, a switching element having an input terminal connected to the power supply and a control terminal connected to the acceleration sensor; a control unit connected to a first output terminal of the switching element; and a working system connected to a second output terminal of the switching element. The capsule core also comprises a microcontroller unit, the control unit is integrated in the microcontroller unit, and the output terminal of the switching element is connected to the microcontroller unit. The acceleration sensor can control the power on and off of the control unit and the working system according to different states.

A penis massager includes a housing and an sleeve. The housing is provided with an accommodating space, and a power source and a circuit board electrically connected to the power source are received in the accommodating space. The sleeve is removably mounted in the accommodating space, one end of the sleeve is concaved to form a interior volume for containing the penis. A vibrating apparatus is arranged in the sleeve and electrically connected to the circuit board for generating a mechanical vibration.

A therapeutic vibration machine with a vibrational assembly adjustably affixed to a post extending from a platform wherein the vibrational assembly is adjustable by an adjustment lever, a rest plate, a pressure plate, and pressure springs, the vibrational assembly includes a vibrational motor, an isolation mounting, and a surface plate wherein the isolation mounting is operative to transferring a vibration supplied from the vibrational motor to the surface plate for utilization by a user.

A system for testing and/or training the vision of a user is disclosed herein. The system includes at least one camera, a visual display device having an output screen, and a data processing device operatively coupled to the at least one camera and the visual display device. In one embodiment, the data processing device is programmed to determine a head position, head velocity, and/or head speed of a user during a vision test or vision training routine from a plurality of images of the head of the user captured by the at least one camera. In another embodiment, the data processing device is programmed to determine, based upon an input signal received from a user input device, a contrast display setting for a screen background relative to at least one visual target, the contrast display setting enabling the user to gradually adapt to increasing levels of visual stimulation.

A focused extracorporeal shock wave therapy (f-ESWT) device includes a handheld housing, a battery, and a transducer assembly. The battery is located in the handheld housing. The transducer assembly is located in the handheld housing and is operably connected to the battery. The transducer assembly is configured to generate a focused shock wave using electrical energy from the battery.

A focused extracorporeal shock wave therapy (f-ESWT) system includes an f-ESWT device and a plurality of interchangeable standoff structures. The f-ESWT device includes a housing. The f-ESWT device is configured to generate a focused shock wave as a combination of a plurality of individual shock waves. Each standoff structure is configured for removable connection to the housing to receive and to transmit the plurality of individual shock waves. Each standoff structure of the plurality of interchangeable standoff structures includes a rigid exterior shell defining a shell space, and an elastomeric interior at least partially located in the shell space. The plurality of individual shock waves is transmitted through the rigid exterior shell and the elastomeric interior of a selected standoff structure of the plurality of interchangeable standoff structures that is removably connected to the housing.

A method of generating a focused shock wave with a handheld focused extracorporeal shock wave therapy (f-ESWT) device includes driving a plurality of piezoelectric elements to generate a focused shock wave based on a first plurality of time delays when a first standoff structure is removably connected to a handheld housing of the f-ESWT device, and driving the plurality of piezoelectric elements to generate the focused shock wave based on a second plurality of time delays when a second standoff structure is removably connected to the handheld housing of the f-ESWT device, the second plurality of time delays different from the first plurality of time delays, and the second standoff structure different from the first standoff structure.

Systems and methods for providing assistance with human motion, including hip and ankle motion, are disclosed. Sensor feedback is used to determine an appropriate profile for actuating a wearable robotic system to deliver desired joint motion assistance. Variations in user kinetics and kinematics, as well as construction, materials, and fit of the wearable robotic system, are considered in order to provide assistance tailored to the user and current activity.