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.

Apparatus for micronizing an inorganic salt, having a receiving vessel for receiving the salt to be micronized in an interior of the receiving vessel; a grinding unit for comminuting the salt located in the receiving vessel and for forming micronized salt particles; an ascending pipe, which is connected fluidically to the receiving vessel and transports the micronized salt particles, wherein one end of the ascending pipe has an outlet orifice through which the micronized salt particles can flow out of the apparatus; a fan; and a housing with an air outlet and an air duct connecting the fan to the air outlet, wherein the air duct is separated by at least one wall from the interior of the receiving vessel, such that the air stream generated by the fan does not flow through the interior of the receiving vessel.

A portable halotherapy device includes a housing, a grinding chamber with a grinding blade that breaks apart dry granular salt into salt particles small enough for halotherapy, an air duct routing air to the chamber, a fluid conduit, and a high-speed exhaust fan. Ambient air flows through the air ducts into the grinding chamber to produce a first air current. Air is diverted from the first air current upward, in a second air current, through the fluid conduit and the fan. The first air current helps move dry granular salt around and against the grinding chamber, breaking it into small salt particles. The second air current is arranged relative to the first air current such that small salt particles, but not larger pieces, are carried as salt aerosol upward through the fluid conduit and fan for distribution to the environment, thereby facilitating a halotherapy session.

A portable halotherapy device includes a housing, a grinding chamber with a grinding blade that breaks apart dry granular salt into salt particles small enough for halotherapy, an air duct routing air to the chamber, a fluid conduit, and a high-speed exhaust fan. Ambient air flows through the air ducts into the grinding chamber to produce a first air current. Air is diverted from the first air current upward, in a second air current, through the fluid conduit and the fan. The first air current helps move dry granular salt around and against the grinding chamber, breaking it into small salt particles. The second air current is arranged relative to the first air current such that small salt particles, but not larger pieces, are carried as salt aerosol upward through the fluid conduit and fan for distribution to the environment, thereby facilitating a halotherapy session.

A micronization unit for a solid active agent, such as a salt, preferably table salt (NaCl), for inhalation, is described.

The micronization unit includes a closed rotary drum containing a solid active agent having a grain size, preferably 0.1-4 millimeters (mm). Wall surfaces of the micronization unit are made at least in part of a material having a filtering capacity of 0.1-1000 micrometers (m). The material preferably is a mesh-like or microperforated material. The rotary drum dispenses particles of reduced size as it rotates.

A device, a system and a method are provided to accurately apply a medically beneficial substance directly to a laterally or superiorly located paranasal sinus cavity. When the device is assembled with a solution in a reservoir, and inverted such that the reservoir is above an input apparatus and a housing, weight of the solution pushes down on a diaphragm creating a negative pressure on the diaphragm, which prevents air from entering the reservoir and prevents a liquid from flowing out of the reservoir. Applying a positive pressure to a bottom of the diaphragm causes the diaphragm to open and allows air to flow into the reservoir. When a user creates the positive pressure by exhaling air into the device the act of exhaling causes the user's choana to close. Thereby any solution introduced into the user's sino-nasal cavity will remain contained within the user's sino-nasal cavity increasing effectiveness of treatment and decreasing user discomfort including gagging, choking, and inner ear disturbance. When the positive pressure on the bottom of the diaphragm is removed, the flow of the liquid from the reservoir stops.

A pulsating inhaler comprising: (a) a fluid oscillator providing focused fluid columns with a series of alternating high and low pressure zones and (b) at least one outlet orifice adapted for delivering said focused fluid column to the respiratory tract of said patient. The fluid oscillator further comprises a piston which is actuated by a motor with an eccentric mechanism. According to alternative embodiment of the invention, the fluid oscillator comprises a rotating disc having a missing section.

A device, a system and a method are provided to accurately apply a medically beneficial substance directly to a laterally or superiorly located paranasal sinus cavity. When the device is assembled with a solution in a reservoir, and inverted such that the reservoir is above an input apparatus and a housing, weight of the solution pushes down on a diaphragm creating a negative pressure on the diaphragm, which prevents air from entering the reservoir and prevents a liquid from flowing out of the reservoir. Applying a positive pressure to a bottom of the diaphragm causes the diaphragm to open and allows air to flow into the reservoir. When a user creates the positive pressure by exhaling air into the device the act of exhaling causes the user's choana to close. Thereby any solution introduced into the user's sino-nasal cavity will remain contained within the user's sino-nasal cavity increasing effectiveness of treatment and decreasing user discomfort including gagging, choking, and inner ear disturbance. When the positive pressure on the bottom of the diaphragm is removed, the flow of the liquid from the reservoir stops.

A device, a system and a method are provided to accurately apply a medically beneficial substance directly to a laterally or superiorly located paranasal sinus cavity. When the device is assembled with a solution in a reservoir, and inverted such that the reservoir is above an input apparatus and a housing, weight of the solution pushes down on a diaphragm creating a negative pressure on the diaphragm, which prevents air from entering the reservoir and prevents a liquid from flowing out of the reservoir. Applying a positive pressure to a bottom of the diaphragm causes the diaphragm to open and allows air to flow into the reservoir. When a user creates the positive pressure by exhaling air into the device the act of exhaling causes the user's choana to close. Thereby any solution introduced into the user's sino-nasal cavity will remain contained within the user's sino-nasal cavity increasing effectiveness of treatment and decreasing user discomfort including gagging, choking, and inner ear disturbance. When the positive pressure on the bottom of the diaphragm is removed, the flow of the liquid from the reservoir stops.