Provided is an aerosol generating system including a holder configured to generate aerosol by heating a cigarette; and a cradle including an inner space into which the holder is inserted. The holder is configured to be tiltable with respect the cradle. The holder is inserted into the inner space of the cradle and then tilted to generate the aerosol.

An inhaler includes a mouthpiece cover, a pressure sensor, a first indicator and a second indicator. The first indicator may be configured to indicate based on a state of the cover, and the second indicator may be configured to indicate based on an output of the pressure sensor. For example, when the mouthpiece cover opens, the first indicator may illuminate and a dose of medication may be transferred from a reservoir to a dosing cup. The second indicator may illuminate if an amount of inhaled medication reaches a predetermined threshold for successful inhalation.

An electronic module for an inhaler includes a printed circuit board and electronic components configured to detect at least a status and/or at least a working parameter of the inhaler when the electronic module is attached to the inhaler. A battery is permanently joined to the printed circuit board. A first terminal and a second terminal are electrically connectable one to the other through a main switch to close a circuit between the battery and the electronic components. In a rest configuration, the first and second terminals are electrically separated by the main switch. In a work configuration, the first terminal and the second terminal are electrically connected one to the other through the main switch.

Methods for the treatment of pulmonary cancers (primary, secondary, metastatic, etc.) using an electronic breath actuated droplet delivery device to deliver a cancer therapeutic directly to the pulmonary system of a subject in need thereof is disclosed. An in-line droplet delivery device and related methods for delivering precise and repeatable dosages to a subject for pulmonary use is disclosed. The in-line droplet delivery device includes a housing, an ejector mechanism, and at least one differential pressure sensor. The in-line droplet delivery device is automatically breath actuated by the user when the differential pressure sensor senses a predetermined pressure change within housing. The in-line droplet delivery device is then actuated to generate a plume of droplets having an average ejected particle diameter within the respirable size range, e.g, less than about 5-6 μm, so as to target the pulmonary system of the user.

An inhaler configured and adapted for inhaling an inhalation medium, enriched with active ingredients and/or flavouring substances, includes a cartridge carrier, a storage tank which contains the inhalation medium, a mouthpiece which is associated with the cartridge carrier, and an actuating mechanism for releasing the inhalation medium out of the storage tank in the direction of the mouthpiece. The inhaler has at least one sensor associated with the mouthpiece. The sensor is configured and adapted to detect characteristics of lips of the person using the inhaler and to provide a data signal formed from the characteristics. The sensor is connected to an electronic control unit associated with the inhaler, to which the actuating mechanism is also connected, in such a manner that the inhalation medium is released on the basis of the data signal. A corresponding arrangement and a corresponding method are disclosed.

A system for providing aromatherapy to a user is described herein. The system comprises a mobile computing device including a mobile application to control the system; a diffuser mounted to the mobile computing device, the diffuser including: a body, one or more cavities in the body, one or more heating elements positioned to provide localized heating to the one or more cavities, a processor, and one or more non-transitory computer storage mediums. The system also includes a plurality of carriers including scented material, the carriers sized and configured to reversibly fill a cavity and position scented material proximate a heating element. The non-transitory computer storage mediums are encoded with one or more computer programs that, when executed by the processor in response to instructions from the mobile computing device, instruct the heating elements to apply heat from the heating elements to activate the scented material and deliver a predetermined aromatherapy experience to the user. Corresponding methods also are disclosed.

Aspects and embodiments of the present invention generally include a device for patient self-administration of a prescribed medication. The device makes available for administration the precise quantity of medication constituting a dose at times designated by a health care provider (HCP). Preferably, the device also detects and transmits information to a remote management system accessible to the HCP, including detected attempts to tamper with the device. Advantageously, HCPs may render oversight and control over the device and its use to mitigate risks associated with patients self-administering medication without in-person supervision. This control may include establishing prerequisites the patient must meet prior to a dose being made available, or remote deactivation of the device. This oversight by the HCP may include patient-specific and aggregate data analysis for optimization of treatment or evaluation of the safety and efficacy of a treatment. Furthermore, this oversight may be conducted via a web-based interface.

Provided is a system including a plurality of inhalers that each include a processor configured to determine a value of a usage parameter relating to use of the respective first inhaler, encrypt data based on the value, and transmit the encrypted data. At least two of the inhalers include different medicament, such as a rescue medicament and a maintenance medicament. The system includes an external device that includes a processor configured to distinguish between the encrypted data of each respective inhaler, determine respective usage information relating to each of the distinct types of medicament based on the respective encrypted data, and control a user interface (e.g., of the external device) to communicate the usage information related to each inhaler and/or each respective type of medicament.

An electrically-powered inhalation device for delivery of an aerosol to the oropharynx of a user comprises respective proximal and distal portions, the proximal portion including an inlet for a liquid, the distal portion including an aerosol outlet defining a mist-exiting location and a piezo assembly including an ultrasonically vibrable mesh membrane, for producing, upon electrical activation, a mist comprising droplets of the liquid, the mesh membrane defining a mist-generating location; and an intermediate portion disposed distally from the proximal portion and proximally from the distal portion, wherein the distal portion is dimensioned to vertically span the user's oral cavity from tongue to hard-palate when the user's lips and/or teeth are transversely engaged with the intermediate portion, so as to place the mist-exiting location in fluid communication with the user's oropharynx.

Systems and methods are provided for aerosolizing and delivering therapeutic substances in an electronic aerosol delivery device with airflow regulation. Calibrated airflow resistance settings enable adjustment and control of flow velocity and or flow volume of air, aerosolized air, and or entrained aerosol particles, through the device, for optimal aerosol delivery among diverse conditions and applications.