An inhaler article (150) includes a body (151) extending along a longitudinal axis of the inhaler article from a mouthpiece end (154) to a distal end (156), a capsule cavity (155) and a capsule (160) retained within the capsule cavity. The capsule cavity is defined within the body and bounded downstream by a filter element (157) and bounded upstream by a tubular element (153) defining a central passage (152) in fluid communication with the capsule cavity. The central passage forms an air inlet aperture extending along the longitudinal axis of the inhaler article from the distal end of the body towards the capsule cavity, wherein the tubular element has a central passage inner diameter in a range from about 50% to about 90% of an inner diameter of the capsule cavity. The inhaler article is configured to receive a swirling inhalation airflow into the central passage.

An inhaler article (150) includes a body (151) extending along a longitudinal axis of the inhaler article from a mouthpiece end (154) to a distal end (156), a capsule cavity (155) and a capsule (160) retained within the capsule cavity. The capsule cavity is defined within the body and bounded downstream by a filter element (157) and bounded upstream by a tubular element (153) defining a central passage (152) in fluid communication with the capsule cavity. The central passage forms an air inlet aperture extending along the longitudinal axis of the inhaler article from the distal end of the body towards the capsule cavity, wherein the tubular element has a central passage inner diameter in a range from about 50% to about 90% of an inner diameter of the capsule cavity. The inhaler article is configured to receive a swirling inhalation airflow into the central passage.

An inhaler article includes a body extending along a longitudinal axis from a mouthpiece end to a distal end, a capsule cavity defined within the body and a tubular element extending from the distal end towards the capsule cavity. The tubular element defines a central passage extending from the distal end towards the capsule cavity. The tubular element includes at least one air inlet allowing air to enter into the central passage. The at least one air inlet extends in a direction that is tangential to the central passage.

An inhaler article includes a body extending along a longitudinal axis from a mouthpiece end to a distal end, a capsule cavity defined within the body and a tubular element extending from the distal end towards the capsule cavity. The tubular element defines a central passage extending from the distal end towards the capsule cavity. The tubular element includes at least one air inlet allowing air to enter into the central passage. The at least one air inlet extends in a direction that is tangential to the central passage.

The present invention relates to an apparatus for providing respiratory assistance to a user via a user conduit. The apparatus being operable in a humidifying mode and a non-humidifying mode, and includes a humidification chamber for containing an amount of water that can be located in an operating position in the humidifying mode and, optionally separate from the apparatus in the non-humidifying mode. The apparatus may also have an auxiliary flow path that can be activated in the non-humidifying mode and a powered device that heats water in the humidification chamber when the apparatus is in the humidifying mode.

The present invention relates to an apparatus for providing respiratory assistance to a user via a user conduit. The apparatus being operable in a humidifying mode and a non-humidifying mode, and includes a humidification chamber for containing an amount of water that can be located in an operating position in the humidifying mode and, optionally separate from the apparatus in the non-humidifying mode. The apparatus may also have an auxiliary flow path that can be activated in the non-humidifying mode and a powered device that heats water in the humidification chamber when the apparatus is in the humidifying mode.

The present invention provides a particulate delivery device with an automatic activation mechanism that pierces or cuts a composition capsule when a cap is removed. The cap cannot be replaced once the device is activated for use. The device allows for gas flow through the device from a gas inlet to a gas outlet through a composition receptacle and dispersion chamber to deliver particulate to the airway of a subject.

The present invention provides a particulate delivery device with an automatic activation mechanism that pierces or cuts a composition capsule when a cap is removed. The cap cannot be replaced once the device is activated for use. The device allows for gas flow through the device from a gas inlet to a gas outlet through a composition receptacle and dispersion chamber to deliver particulate to the airway of a subject.

A nitric oxide delivery system, which includes a gas bottle having nitrogen dioxide in air, converts nitrogen dioxide to nitric oxide and employs a surface-active material, such as silica gel, coated with an aqueous solution of antioxidant, such as ascorbic acid. A nitric oxide delivery system may be used to generate therapeutic gas including nitric oxide for use in delivering the therapeutic gas to a mammal.

The disclosure teaches the use of antistatic materials in the airway for thermal aerosol generation devices. The present disclosure teaches the use of antistatic materials for drug delivery in any drug that may be susceptible to charging during aerosol generation.