The present invention relates to a kit comprising: a) a bag having an outlet, the outlet being closable and openable; b) a solid and/or liquid active agent precursor; and c) means for releasing a gaseous active agent or a gaseous active agent mixture from the active agent precursor; a method for producing a gaseous active agent or a gaseous active agent mixture comprising the steps: a) providing the kit; b) providing the solid and/or liquid active ingredient precursor in the bag; and c) releasing the gaseous active ingredient or the gaseous active ingredient mixture from the solid and/or liquid active ingredient precursor with the aid of the means for releasing a gaseous active ingredient or a gaseous active ingredient mixture, and a gaseous composition obtainable by the process.

The present invention relates to a kit comprising: a) a bag having an outlet, the outlet being closable and openable; b) a solid and/or liquid active agent precursor; and c) means for releasing a gaseous active agent or a gaseous active agent mixture from the active agent precursor; a method for producing a gaseous active agent or a gaseous active agent mixture comprising the steps: a) providing the kit; b) providing the solid and/or liquid active ingredient precursor in the bag; and c) releasing the gaseous active ingredient or the gaseous active ingredient mixture from the solid and/or liquid active ingredient precursor with the aid of the means for releasing a gaseous active ingredient or a gaseous active ingredient mixture, and a gaseous composition obtainable by the process.

The invention relates to a capsule for use in a vaporizer, having at least one first cavity formed at least in part by a lid, side walls and bottom of the capsule, and a vaporizable active substance accommodated in the first cavity of the capsule, wherein the side walls and/or the bottom are at least in sections double-walled with an inner wall facing the first cavity of the capsule and an outer wall facing the outside of the capsule, so that at least one second cavity is formed between the inner wall and the outer wall of the capsule, inner wall facing the first cavity of the capsule and an outer wall facing the outside of the capsule, so that at least one second cavity is formed between the inner wall and the outer wall, wherein an auxiliary substance, preferably a further active substance, a chemical reactant and/or a flavoring agent is accommodated in the second cavity. A corresponding vaporizer as well as a corresponding vaporizer system are further described.

The invention relates to a capsule for use in a vaporizer, having at least one first cavity formed at least in part by a lid, side walls and bottom of the capsule, and a vaporizable active substance accommodated in the first cavity of the capsule, wherein the side walls and/or the bottom are at least in sections double-walled with an inner wall facing the first cavity of the capsule and an outer wall facing the outside of the capsule, so that at least one second cavity is formed between the inner wall and the outer wall of the capsule, inner wall facing the first cavity of the capsule and an outer wall facing the outside of the capsule, so that at least one second cavity is formed between the inner wall and the outer wall, wherein an auxiliary substance, preferably a further active substance, a chemical reactant and/or a flavoring agent is accommodated in the second cavity. A corresponding vaporizer as well as a corresponding vaporizer system are further described.

The invention relates to a unit for the micronization of a solid active agent, such as a salt, preferably table salt (NaCI), for inhalation, comprising a micronizer driven by a motor. The unit according to the invention is characterised in that micronization is performed by a unit constituted by a closed rotary drum (2) receiving a solid active agent having the same grain size, preferably 0.1-4 mm, as table salt (NaCI), where the wall surfaces of the micronizer unit are made at least in part of a material having a filtering capacity of 0.1-1000 m, the material preferably being a mesh-like or microperforated material. A further unit according to the invention is characterised in that the micronizer consists of a rotary block (23) made of the active agent, a friction block (24) adapted to be in frictioning relation with the rotary block, and a clamping mechanism (25) adapted for holding the friction block (24) in position and for clamping the friction block (24) to the rotary block (23), the micronizer being disposed in a closed housing (11), and the wall surfaces of the housing (11) being at least in part made of a material having a filtering capacity of 0.1-1000 m.

A system and method of use for an operational halotherapy device and red light device in an enclosed space. The halotherapy and red light system generally comprise a machine disposed in the enclosed space that disperses salt particles into the air, and includes a red light device that emits red light waves. The combination of both devices produces a refractory phenomenon when the red light waves make contact with the salt particles dispersed in the air to cause a plethora of multi-dimensional dispersions of light waves. Moreover, every time a salt particle makes contact with a red light wave, a portion of the wave light is absorbed by the particle and its temperature increases, lessening the moisture in the particle. The lessening of moisture in the particle dries the particle further, which enhances the therapeutic properties of the inhalable salt particle.

Vaporizers are provided. A representative vaporizer includes a power source; a heating element that is electrically coupled to the power source; multiple chambers that are coupled to the heating element and are configured to vaporize a substance that is placed within the multiple chambers; an inner tube that is coupled to the multiple chambers and is configured to allow the vaporized substance to exit therefrom; and a housing that houses the power source, heating element, inner tube, and multiple chambers.

The device (1) for supplying micronized medical salt comprises a container (2) for medical salt, having a vertical longitudinal development and a lower end portion (3) provided with a mouth of release (4) of the medical salt, a screw (20) inserted into the container and having an upper end (21) and a lower end (22) which is free, rotation members (30) of the screw mechanically connected thereto for rotating it with respect to the container, where the screw advances the medical salt downward so that the medical salt is released in a controlled manner from the mouth of release (4), the device further comprising a dispenser (50) which comprises a supply duct (51) and a ventilation member (60) which generates an air flow within the supply duct, where the mouth of release is in communication with the supply duct so as to release the medical salt directly in the air flow.

A system and method of use for an operational halotherapy device and red light device in an enclosed space. The halotherapy and red light system generally enclosed space, a red light device, and a salt aerosol discharge system that disperses salt particles into the air of the enclosure. The combination of both devices produces a refractory phenomenon when the red light waves make contact with the salt particles dispersed in the air to cause a plethora of multi-dimensional dispersions of light waves. Moreover, every time a salt particle makes contact with a red light wave, a portion of the wave light is absorbed by the particle, and its temperature increases, lessening the moisture in the particle. The lessening of moisture in the particle dries the particle further, which enhances the therapeutic properties of the inhalable salt particle.

A system for increasing organic cell regeneration in a cellular medium includes an electromagnetic (EN) field generating device adapted to produce a constant EM field of less then 1 mT at a radiation frequency of substantially 7.69 Hz, which comprises at least one coil and is adapted to generate the EM field so that the cellular medium is substantially within the generated EM field. A resonance medium is also provided for locating substantially at or adjacent the cellular medium, wherein the resonance medium comprises a composition which is adapted to resonate at the frequency of The EM field generated by the device, wherein the composition is a biologically active composition containing at least a composition comprising crystalline structure minerals.