The present invention is directed to a system and method of use for an operational halotherapy enclosure system sufficiently sized to retain therein an exercise machine for a person to do physical exercise and includes a red light panel and a thermal heating light panel. The halotherapy enclosure system also includes a salt aerosol dispersing device configured to disperse salt particles inside of the enclosed space, and a controller configured to control the emission of red light waves from the red light panel, thermal energy from the thermal heating light panel, and air salination emissions from the aerosol dispersing device within the enclosed space. The combination of aerosolized salt, red light waves, and thermal energy produces an enhanced beneficial result when a person inside of the halotherapy enclosure is exercising and inhaling the aerosolized salt under the red light and thermal energy conditions.

A fine water discharge device of a human body which discharges fine water to the human body includes: fine water generating units being brought into a moisture absorption state and a moisture release state in which moisture is absorbed in, and is released from, a conductive polymer film due to a decrease and an increase in temperature, respectively and disposed in parallel; a blowing unit blowing air so that air flows through the fine water generating units; an electrifying portion individually electrifying the fine water generating units so that a temperature of each fine water generating unit is changed depending on electrification; and a control portion controlling the electrifying portion and the blowing unit so that the fine water generating units are individually switched between the moisture absorption state and the moisture release state to discharge the fine water by blowing air.

A fine water discharge device of a human body which discharges fine water to the human body includes: fine water generating units being brought into a moisture absorption state and a moisture release state in which moisture is absorbed in, and is released from, a conductive polymer film due to a decrease and an increase in temperature, respectively and disposed in parallel; a blowing unit blowing air so that air flows through the fine water generating units; an electrifying portion individually electrifying the fine water generating units so that a temperature of each fine water generating unit is changed depending on electrification; and a control portion controlling the electrifying portion and the blowing unit so that the fine water generating units are individually switched between the moisture absorption state and the moisture release state to discharge the fine water by blowing air.

Devices and methods can be used to apply an adhesion promoter, for example, ozone, over the surface of the biological tissues, before and/or concurrently with the application of the cosmetics to improve the durability and/or appearance of the cosmetics on the biological tissues. The devices can include a recirculation system and/or a filter system to reduce the likelihood of the chemical being released into the atmosphere and/or to increase oxidation of the chemical generated by the device after use of the device.

The purpose of the present invention is to solve conventional problems involving immunoisolation devices using a porous membrane as an immunoisolation membrane, such problems including fibrotic formation on the device surface, shortage of oxygen supplied to cells, and non-uniform distribution of cells. An immunoisolation device for transplantation is characterized by comprising: an immunoisolation membrane; and an oxygen supply mechanism and a three-dimensional cell support which are tightly enclosed inside the immunoisolation membrane by physical sealing, a biocompatible adhesive, or a combination thereof, wherein the immunoisolation membrane is a porous membrane provided with a hydrophilic layer on the outer surface, and the oxygen supply mechanism can supply oxygen to cells supported by the three-dimensional cell support through an oxygen permeable membrane.

Embodiments of the present invention are directed to devices, systems and methods adapted for implementing intermittent displacement of blood to mitigate peripheral nerve neuropathy such as that induced by chemotherapeutic agents (i.e., chemotherapy-induced neuropathy (CIN)) that are administered to a patient. Such devices, systems and methods advantageously provide for precise, uniform and controlled blood flow occluding (and optionally blood displacing) compression along irregular surfaces of an appendage of a patient. Such precise, uniform and controlled blood occluding compression is imparted upon the epidermal and dermis skin layers within the aforementioned areas of a patient's extremities to decrease the time that free nerve endings located in the epidermal and encapsulated nerve endings located in the dermis skin layers are exposed to nerve damaging chemotherapy chemicals, thereby substantially decreasing CIN caused by prolonged exposure to such chemicals.

The present invention relates to a medical bathing equipment for the manufacture and use of a bathing solution containing an active substance and in particular a bathing solution containing NO. The invention also relates to a bathing equipment based on a multi-stage method for generating NO and the bathing equipment in its use for the treatment of diseases, in particular of diabetically caused circulatory disorders and wounds of the lower extremities.

The present invention relates to a medical bathing equipment for the manufacture and use of a bathing solution containing an active substance and in particular a bathing solution containing NO. The invention also relates to a bathing equipment based on a multi-stage method for generating NO and the bathing equipment in its use for the treatment of diseases, in particular of diabetically caused circulatory disorders and wounds of the lower extremities.

An NO-accumulation apparatus, method and use, comprising: a container (120) defining a cavity for accommodating a liquid (105), an inlet (150) for feeding the liquid into the container (120) and an outlet (151) for delivering the liquid from the container (120) to a bath unit; an NO-gas dissolving unit (140) for dissolving gaseous NO in the liquid (105) to produce an NO-containing liquid, wherein the NO-gas dissolving unit (140) is arranged in the container (120) and/or forms a part of the container (120); and an NO-gas port (110) in fluid communication with the NO-gas dissolving unit (140), wherein the NO-gas port (110) is adapted for coupling, particularly for releasably coupling, with an NO-gas supply, whereby the apparatus further comprises means for decoupling the inflow of NO to the liquid (105) within the container from the removal of the NO-containing liquid (NO-decoupling means), so that the removal of the NO-containing liquid is inhibited, when the NO is flowing into the liquid, and also the NO inflow is inhibited when the NO-containing liquid is removed from the container (105).

An NO-accumulation apparatus, method and use, comprising: a container (120) defining a cavity for accommodating a liquid (105), an inlet (150) for feeding the liquid into the container (120) and an outlet (151) for delivering the liquid from the container (120) to a bath unit; an NO-gas dissolving unit (140) for dissolving gaseous NO in the liquid (105) to produce an NO-containing liquid, wherein the NO-gas dissolving unit (140) is arranged in the container (120) and/or forms a part of the container (120); and an NO-gas port (110) in fluid communication with the NO-gas dissolving unit (140), wherein the NO-gas port (110) is adapted for coupling, particularly for releasably coupling, with an NO-gas supply, whereby the apparatus further comprises means for decoupling the inflow of NO to the liquid (105) within the container from the removal of the NO-containing liquid (NO-decoupling means), so that the removal of the NO-containing liquid is inhibited, when the NO is flowing into the liquid, and also the NO inflow is inhibited when the NO-containing liquid is removed from the container (105).