A skin care device includes a receptacle that includes an outlet port and defines a chamber that extends from the outlet port to a sump, which is defined by an impermeable portion of the receptacle, and is disposed for receiving one end of a tube inserted through the outlet port. Wicking material is received over a permeable portion of the receptacle for location over a particular region of the skin. When a vacuum is applied at the sump, the particular region is cooled by evaporative cooling when the particular region is moist. The device includes at least one vent that is so disposed as to promote air flow and to prevent a vacuum from occurring at a portion of the skin adjacent where the wicking material is located while the vacuum is applied. The device can be used for wound care and to dispose wicking material within a skin fold,

A device for reversibly blocking activities of a target region of a subject includes a microfluidic system configured to route a fluid around the target region to change a local temperature of the target region; and an electronic system coupled with the microfluidic system for providing a real-time feedback.

In one embodiment of the present disclosure, a process for electrochemical hydrogen production is provided. The process includes providing an electrochemical cell with an anode side including an anode, a cathode side including a cathode, and a membrane separating the anode side from the cathode side. The process further includes feeding molecules of at least one gaseous reactant to the anode, oxidizing one or more molecules of the gaseous reactant at the anode to produce a gas product and protons, passing the protons through the membrane to the cathode, and reducing the protons at the cathode to form hydrogen gas.

Systems and methods for a medical device configured to provide cooling to a tissue region are provided. The medical device may be configured to noninvasively or invasively cool the tissue region to a predetermined operating temperature via a two-phase heat transfer process.

Proposed is a hand-held cooling device for supplying a cryogen to a target region for cryotherapy. The device can include a cryogen container configured to contain a first cryogen having a first temperature and a nozzle configured to spray a first modified cryogen to the target region, the first modified cryogen having a second temperature higher than the first temperature. The device can also include a cryogen temperature regulator configured to receive the first cryogen and output the first modified cryogen to the nozzle, the cryogen temperature regulator disposed closer to the nozzle than the cryogen container. The cryogen temperature regulator can include a holder tube, a porous structure disposed inside a holder tube and a heater disposed around the holder tube and heating the holder tube so as to increase the first temperature to the second temperature while the first cryogen passes through the porous structure.

Proposed is a hand-held cooling device for supplying a cryogen to a target region for cryotherapy. The device can include a cryogen container configured to contain a first cryogen having a first temperature and a nozzle configured to spray a first modified cryogen to the target region, the first modified cryogen having a second temperature higher than the first temperature. The device can also include a cryogen temperature regulator configured to receive the first cryogen and output the first modified cryogen to the nozzle, the cryogen temperature regulator disposed closer to the nozzle than the cryogen container. The cryogen temperature regulator can include a holder tube, a porous structure disposed inside a holder tube and a heater disposed around the holder tube and heating the holder tube so as to increase the first temperature to the second temperature while the first cryogen passes through the porous structure.