A temperature control device has a temperature acquisition unit that acquires information indicating a temperature around a user and a control unit that controls a Peltier element worn by the user to cool or warm the user based on the temperature. The control unit causes the Peltier element to warm the user when the temperature is higher than or equal to a first threshold and causes the Peltier element to cool the user when the temperature is lower than a second threshold.

A low-frequency treatment device and a treatment system with enhanced user convenience. An acquisition unit acquires an atmospheric pressure of a position where the low-frequency treatment device is located (step S102), a determination unit determines whether the atmospheric pressure is less than a threshold (step S104), and a treatment portion increases an intensity of low frequency treatment if the atmospheric pressure is less than the threshold (step S108).

A device comprising a housing having a handle end and a treatment end. The treatment end is configured to provide an antimicrobial treatment and a heat treatment. The treatment end comprises an applicator having an applicator surface for providing at least the heat treatment. The device includes a heat generation unit configured to heat the applicator surface in use, a source of antimicrobial agent, and a control unit operatively connected to at least the heat generation unit for controlling the heat generation unit. The device can be a hand-held device and used to apply topical treatment to a treatment area of a subject.

The present invention relates to a system (100) for controlling a temperature, the system (100) comprising: a temperature sensor module (10), which is configured to measure a temperature value; a microcontroller module (20), which is coupled to the temperature sensor module (10) and which is configured to generate AC heating pulse signals by separate sequential code steps based on the measured temperature value; a coupling module (30) which is coupled to the microcontroller module (20) and which is configured to transform the generated AC heating pulse signals into transformed AC heating pulse signals using a transfer function which is substantially zero for DC signal components; and a heating module (40) which is coupled to the coupling module (30) and which is configured to generate heat according to the transformed AC heating pulse signals.

The cooling system (100, 300, 400, 500, 700, 750) includes an applicator (101, 501, 701) configured to hold a predetermined amount of solid coolant and fluid coolant (117) to cool a targeted area of the body (162, 570) to crystalize the lipid-rich cells underneath the targeted area to reduce the fat cells. The applicator may include a thermoelectric cooler (TEC, 136, 704, 706) where the hot side is cooled by coolant held within the applicator. The cold side of the TEC may be thermally coupled to a cooling plate (138, 560) configured to cool a targeted area of the skin at a predetermined temperature range for a predetermined period of time. The cooling system may also be used to relieve localized pain at certain area of the body and/or utilized for cryotherapy.

The present disclosure relates to vision preservation systems for medical devices, such as cryospray devices for use with endoscopes. Exemplary embodiments provide a distal attachment in the form of a shroud or cap that mounts to the end of a flexible endoscope. A purging fluid supply mechanism is provided along the length of the endoscope, providing a channel for purging fluid, such as gas, to communicate between the endoscope tip and an external gas supply. The cap or shroud assembly incorporates a lens clearing flow field adjustment mechanism, such as nozzles, designed to direct warm (room temperature or higher) purging fluid across a lens at the scope tip. Another flow deflection mechanism, such as a guide or nozzle, may be included with the cap to direct purging fluid at an angle away from the lens. Gas, as an example, directed across and toward the lens purges moisture to avoid condensation on the lens and shears debris and bodily fluids away from the field of view. Gas directed or deflected by a guide away from the lens serves the purpose of keeping incoming particles and fluid droplets (e.g. spatter) from impacting on the lens cover. The cap and shroud are designed to avoid entraining moist air from the body cavity or lumen being treated.

A phototherapy treatment apparatus and methods are provided. In particular, the present disclosure provides a phototherapy treatment apparatus configured to diffusely transmit light emitted from a light source to a patient.

An article configured to warm and monitor a patient during a dialysis treatment, the article includes one or more heating elements. The article also includes one or more sensors configured to monitor a condition of the patient during the dialysis treatment. The article also includes a fabric portion configured to receive the one or more heating elements and the one or more sensors and position the one or more heating elements and the one or more sensors on the patient during treatment. The article also includes a transmitter configured to transmit information from the one or more sensors to a dialysis machine and an electrical connector configured to provide power to at least one of the one or more heating elements and the one or more sensors.

The invention relates to an electrical active assembly for generating a physical effect such as heat, cold or humidity, and a textile assembly, such as a clothing assembly, including said electrical active assembly, with an application to a system for regulating the temperature or humidity of a user's body.

The electrical assembly comprises a first textile support, a first active element 1 for generating the physical effect, connected to a power source, and located on or in the first textile support, a first sensor 2 for sensing data relative to a physical information, such as temperature or humidity, connected to a power source, and located on or in the first textile support, and a first controlling unit 3 connected to the first active element and sensor, and located on or in the first textile support, such as to allow the activation/deactivation by the first controlling unit of the first active element depending on data sensed by the first sensor.

The electrical assembly also comprises a second textile support distinct from the first textile support, a second active element 4 for generating said physical effect, connected to a power source, and located on or in the second textile support, a second sensor 5 for sensing data relative to the physical information, connected to a power source, and located on or in the second textile support, and a second controlling unit 6 connected to the second active element and sensor, and located on or in said second textile support, such as to allow the activation/deactivation by the second controlling unit of the second active element depending on data sensed by the second sensor.

The first controlling unit is connected to the second active element and sensor, such as to allow the activation/deactivation by the first controlling unit of the second active element depending on data sensed by the second sensor and/or by the first sensor, and/or the second controlling unit is connected to the first active element and sensor, such as to allow the activation/deactivation by the second controlling unit of the first active element depending on data sensed by the first sensor and/or by the second sensor.