A vaporizing assembly for an aerosol-generating system may comprise a delivery device and a heater assembly. The heater assembly may comprise a heat resistive substrate and a heating element. The delivery device is configured to deliver an aerosol-forming substrate to at least a surface of the heat resistive substrate, wherein the heating element is isolated or separated from the aerosol-forming substrate by the heat resistive substrate. The present disclosure is also directed to a method for generating an aerosol.

A novel aromatherapy vaporization device is disclosed having a first and second housing with a heating chamber for receiving of phyto material. The heating chamber has an ambient air input port that receives ambient air that does not flow past hot electrical components when entering the heating chamber. An inhalation tube is coupled with the heating chamber for receiving of phyto material vapor therein in a second mode of operation and in a first mode of operation the inhalation tube is uncoupled from the heating chamber to allow for loading of phyto material therein.

An atomizing assembly includes a tubing section having an inlet end and an outlet end. The inlet end of the tubing section is connectable to a liquid storage portion, and the outlet end of the tubing section is in fluid communication with an atomizing nozzle. The tubing section is configured to deliver a flow of liquid aerosol-forming substrate through the atomizing nozzle. The atomizing nozzle includes an air channel configured to establish an air flow through the nozzle. The air flow is mixed with the flow of liquid aerosol-forming substrate.

The invention relates to a nebulization device (1) for medical mixture. It comprises a containing ampoule (2) for medical mixture, comprising an upper component (2a) and a lower component (2b) connected to each other, at least one emission opening (11) of the nebulized medical mixture from the ampoule (2), and at least one entry window (19) for the intake of air within the ampoule (2). Moreover, the nebulization device (1) comprises at least one atomizer (14) for the intake of pressurized gas, within the lower component (2b) of the ampoule (2), the atomizer (14) being surmounted by the upper component (2a). Advantageously, at least one, preferably two selection side windows (24) are provided on the upper component (2a), the opening of the selection side windows (24) being shielded by shielding means (16), moved by a command shaft (17).

An inhaler device for pulmonary delivery of at least one substance from a drug dose cartridge to an inhaling user, including: a first conduit for conducting a carrier airflow to a proximal opening of a mouthpiece for use by the user; a holder configured to position the dose cartridge within the carrier airflow; and a second conduit for conducting a shunting airflow to the mouthpiece without passing through the dose cartridge position. In some embodiments, a controller connected to a valve controls a rate of carrier airflow, for example by controlling the shunting airflow, based on a sensor indication of airflow rate and a target airflow profile.

Provided herein is a method of pulmonary delivering to a subject at least one pharmacologically active agent being in a plant material, which is effected by pulmonary delivering the agent to the subject using a metered dose inhaler device that is configured to vaporize at least one pre-determined vaporized amount of the agent upon controllably heating the plant material, wherein the pre-determined vaporized amount is selected so as to achieve at least one pre-determined pharmacokinetic effect and/or at least one pre-determined pharmacodynamic effect induced by the agent in the subject.

A dose unit including at least one isolated bioactive agent applied on a carrier material in thermal contact with an electrically heating element configured to vaporize a pre-determined amount of the agent for pulmonary delivery thereof is provided herein, as well as devices for effecting vaporization and pulmonary delivery of the isolated agent, and methods for preparing the dose unit, controllably releasing the agent therefrom, methods for pulmonary delivery thereof and methods of treatment of medical conditions treatable by pulmonary delivery of the isolated bioactive agent.

An aerosol generator for generating an aerosol from a fluid, comprising: a vibratable membrane having a first side for being in contact with the fluid and an opposite second side, the membrane having a plurality of through holes penetrating the membrane in an extension direction from the first side to the second side, whereby the fluid passes the through holes from the first side to the second side when the membrane is vibrated for generating the aerosol at the second side, each through hole having along its extension direction a smallest diameter, a larger diameter that is larger than the smallest diameter and defined by that diameter that is closest to triple, preferably twice said smallest diameter, each through hole having a nozzle portion defined by that continuous portion of the through hole in the extension direction comprising the smallest diameter of the through hole and bordered by the larger diameter of the through hole, wherein the ratio of the total length of each through hole in the extension direction to the length of a respective one of said nozzle portions in the extension direction is at least 4, preferably at least 4.5 and most preferred equal to or larger than 5.

A respiratory therapy management system includes intelligent valved holding chamber devices (IVHCs) corresponding to patients. Each IVHC generates air inflow data during an inhalation therapy session, and determines an inhalation technique score for the session. For each IVHC, a mobile computing device receives and processes inhalation technique scores; generates composite inhalation technique scores and inhalation therapy regimen compliance scores corresponding to multiple inhalation therapy sessions; and presents visual representations of such scores. A remote therapy management server manages patient incentive awards; provides a social media platform and/or games accessible to patients; and communicates with physician computing devices to facilitate physician review of composite inhalation technique scores and inhalation therapy regimen compliance scores, and physician access to the social media platform. For a given patient, provision of incentive awards, aspects of social media interaction, and/or game play depend upon their composite inhalation technique scores and/or inhalation therapy regimen compliance scores.

A nebulizer device includes an air intake port positioned downstream of a nebulizer element, and a mouthpiece positioned upstream of the nebulizer element. A flow sensor is coupled to a controller. The controller is configured to integrate an inhaled air flow signal received from the flow sensor for determining an inhaled air volume. The controller is also configured to turn on the nebulizer element when the inhaled air volume reaches a first predetermined threshold, and turn off the nebulizer element when the inhaled air volume reaches a second predetermined threshold. A method for targeted delivery of aerosolized particles to the lungs is also disclosed.