The invention relates to a thermal skin treatment device comprising a skin contact component with a skin contact surface; a thermal energy component in thermal contact with the skin contact component; a temperature control circuit electrically connected to the thermal energy component and comprising a user interface; and an energy source electrically connected to said thermal energy component for energy supply. Said temperature control circuit is adapted to control an amount of energy supplied from said energy source to said thermal energy component such that a first predetermined temperature is maintained at the skin contact surface for a first duration, or a second predetermined temperature is maintained at the skin contact surface for a second duration, wherein said first predetermined temperature is in a range of 40° C.+/−2° C., and wherein said second predetermined temperature is in a range of 19° C.+/−2° C. The temperature control circuit is adapted to maintain for a predetermined duration, during operation, only said first predetermined temperature or said second predetermined temperature at the skin contact surface. The invention further relates to a method for non-therapeutic treatment of a human eye region by means of a thermal skin treatment device according to the invention.

A therapeutic device includes a substrate, a seal to couple the substrate to a surface, and at least one port defined in the substrate through which a therapeutic fluid is introduced between the surface and the substrate such that the therapeutic fluid directly contacts the surface.

A cold and/or hot compress system, comprising a water bag (101), an air bag (102), a water circulation assembly (2) in fluid communication with the water bag (101) and a pneumatic assembly (3) in fluid communication with the air bag (102). In the cold and/or hot compress system, the water circulation assembly (2) is independent from the pneumatic assembly (3). Therefore, during the delivery of a cooling or heating therapy, the independent pneumatic assembly (3) can be driven by an air pressure waveform defined by parameters pre-stored in a control panel (402) to cause the water bag (102) to apply cold/hot compress to a region of interest of a patient's body. Independent water and air circulation paths in the system avoid interference between water and air flows therein, allowing the system to applied more stable compress with minimized pressure errors. Moreover, a more constant water flow rate and a more uniform temperature distribution across the surface of the water bag are achievable.

A cold and/or hot compress system, comprising a water bag (101), an air bag (102), a water circulation assembly (2) in fluid communication with the water bag (101) and a pneumatic assembly (3) in fluid communication with the air bag (102). In the cold and/or hot compress system, the water circulation assembly (2) is independent from the pneumatic assembly (3). Therefore, during the delivery of a cooling or heating therapy, the independent pneumatic assembly (3) can be driven by an air pressure waveform defined by parameters pre-stored in a control panel (402) to cause the water bag (102) to apply cold/hot compress to a region of interest of a patient's body. Independent water and air circulation paths in the system avoid interference between water and air flows therein, allowing the system to applied more stable compress with minimized pressure errors. Moreover, a more constant water flow rate and a more uniform temperature distribution across the surface of the water bag are achievable.

This application provides an intelligent control apparatus, including: a control circuit and a detection and heating circuit. The detection and heating circuit includes a detection and heating material. When the detection heating material works in a detection mode, the detection and heating circuit obtains a bioelectric signal of a user by using the detection and heating material. The control circuit instructs, according to the bioelectric signal, the detection heating circuit to switch a working mode of the detection and heating material to a heating mode; and instructs the detection and heating circuit to determine heating duration and/or a heating temperature of the detecting and heating material. The apparatus may be used in the field of artificial intelligence. Through control of the control circuit, the detection heating material can have both detection and heating functions. Intelligent perception of a state of the user is implemented by detecting of the bioelectric signal.

This application provides an intelligent control apparatus, including: a control circuit and a detection and heating circuit. The detection and heating circuit includes a detection and heating material. When the detection heating material works in a detection mode, the detection and heating circuit obtains a bioelectric signal of a user by using the detection and heating material. The control circuit instructs, according to the bioelectric signal, the detection heating circuit to switch a working mode of the detection and heating material to a heating mode; and instructs the detection and heating circuit to determine heating duration and/or a heating temperature of the detecting and heating material. The apparatus may be used in the field of artificial intelligence. Through control of the control circuit, the detection heating material can have both detection and heating functions. Intelligent perception of a state of the user is implemented by detecting of the bioelectric signal.

A temperature modulation assembly and a multi-layer retention mechanism for such a temperature therapy device are disclosed. According to one embodiment, a temperature modulation assembly for a temperature therapy device has a heat spreader and a mounting plate coupled to a bottom portion of a spacer, wherein the heat spreader is disposed between the mounting plate and the spacer. The temperature modulation assembly has a heatsink and a fan coupled to a top portion of the spacer, wherein the heatsink is disposed between the top portion of the spacer and the fan. The temperature modulation assembly further includes a heating and/or cooling device disposed within a central opening of the spacer, wherein the heating and/or cooling device is located between the heatsink and the heat spreader.

An improved medical pad for contact thermal exchange with a patient includes a fluid circulation layer for containing a thermal exchange fluid circulatable therethrough, a first port and a second port for circulating the thermal exchange fluid in to and out of the fluid circulation layer, and a hydrogel layer interconnected to and extending across one side of the fluid circulation layer to define an adhesive surface for adherence to a patient's skin. The hydrogel layer can include an ultraviolet light-cured composition with a cross-linking copolymer, water, and glycerol. The hydrogel layer is provided to have a thermal conductivity of at least about 1.9 ca//hr-cm-° C.

A therapeutic cooling and/or compression system, configured to cool a body portion, comprises a conformal covering for covering the body portion configured to extract heat energy from the body portion, a sensor device within the conformal covering for sensing a parameter of the body portion, an actuator configured for changing an amount of heat energy extracted from the body portion, and a control unit configured for regulating the actuator responsive to control input from the sensor device. The system may be portable, enabling a patient to walk while undergoing treatment.

A therapeutic cooling and/or compression system, configured to cool a body portion, comprises a conformal covering for covering the body portion configured to extract heat energy from the body portion, a sensor device within the conformal covering for sensing a parameter of the body portion, an actuator configured for changing an amount of heat energy extracted from the body portion, and a control unit configured for regulating the actuator responsive to control input from the sensor device. The system may be portable, enabling a patient to walk while undergoing treatment.