A mesh nebulizer that nebulizes and ejects a medicinal liquid through a mesh portion, includes a main body including a vibration portion including a vibration surface, and a medicinal liquid pack to be detachably mounted on the main body. The medicinal liquid pack includes a lid in which the mesh portion is provided, and a medicinal liquid container that includes a recessed portion that is open toward the mesh portion and is covered by the lid, the medicinal liquid being contained in the recessed portion. At least a portion of a bottom surface of the recessed portion of the medicinal liquid container that is to oppose the vibration surface is made of a stretchable material. When the medicinal liquid pack is mounted on the main body, the stretchable material of the bottom surface stretches, allowing the vibration surface to approach the mesh portion of the lid.

An example aerosol delivery device includes a mouthpiece having an airflow outlet, and an airflow passage extending between an airflow inlet and the airflow outlet. The example aerosol delivery device further includes a housing configured to receive a cartridge that includes an aerosolizable substance and a vapor element configured to heat the aerosolizable substance, and an internal power source configured to provide electrical power. The example aerosol delivery device further includes a controller coupled to the internal power source to receive a portion of the electrical power and configured to, when the cartridge is installed at the housing, cause the vapor element of the cartridge to heat the aerosolizable substance to release an aerosol into the airflow passage during an inhalation through the airflow outlet, and a connector configured to receive power from an external source to recharge the internal power source.

A device for inhaling powder-type substances includes a plurality of substance containers that can be moved successively into an emptying position, wherein the substance containers—which are not connected to one another—are accommodated in direct contact with one another in a guide unit attached to the device and can be moved by contact pressure propagating among the substance containers. The guide unit has a drive wheel with accommodating forms separated by drive teeth. The substance container in the emptying position is located in an accommodating form of the drive wheel. A substance container for a device for inhaling powder-type substances has two sub-regions, each separately having an amount of the substance, and both sub-regions have an openable, pierceable cover. A method for filling a device for inhaling powder-type substances uses a plurality of substance containers that can be moved successively into an emptying position.

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.

Devices for generating and releasing vapor. In particular, described herein are portable devices for generating a low-temperature inhalable vapor having an elongated tubular body containing a vaporization chamber and a battery-powered heater, a removable mouthpiece covering the vaporization chamber, a display configured to indicate the temperature of the vaporization chamber; a microcontroller configured to regulate the temperature of the vaporization chamber, and a control to select from among a variety of temperature settings.

A discrete inhalation device comprising a cartridge and a modular body disguised as a lip applicator such as lip gloss or lip stick.

Containment units, dry powder inhalers, delivery systems, and methods for the same are disclosed. Exemplary devices are configured to have inlets and outlets which are formed with the containment walls of a containment unit. Air jets formed by the configuration of inlet(s) and outlet(s) inside the containment unit create significant turbulence and deaggregate the powder. Delivery system components downstream of the containment unit may integrate the exiting aerosol plume with a low flow nasal cannula air stream for delivery to a subject.

A device for inhaling powdery substances contained in capsules has a housing, a capsule receiver, a closing cover, a mouth piece, and a closure cap. The closure cap is designed to cover simultaneously the mouthpiece, closing cover and capsule receiver, wherein the closure cap, mouthpiece and closing cover are hinged in a pivoting manner. Two pivot axes, which are different but run in the same direction, are formed, which, in respect of a side view in which geometric axes of the pivot axes are represented in the form of points, are arranged next to each other and on a same side of the capsule receiver. In a usage state of the device, the first pivot axis is arranged closer to the capsule receiver. The closing cover and the mouthpiece can be pivoted about the first pivot axis and only the closure cap can be pivoted about the second pivot axis.

A vibration conveyor is provided for a capsule-based, single-dose dry powder inhaler of the type comprising an inhaler body comprising a capsule chamber for receiving a dry powder formulation capsule, an inhalation channel in fluid communication with the chamber, and means for piercing a capsule in the chamber to allow outside air flow to be mixed with the contents of said capsule for inhalation thereof, means for monitoring vibrations resulting from inhalation, and means for transferring said vibrations from the inhaler body to the monitoring means. The conveyor comprises a plate interposed between the body and the means for monitoring.

An apparatus includes a first member coupled to a second member. The first member defines a chamber containing a dry powder and includes a chamber wall that forms an outer boundary of the chamber. The second member includes a surface covering the chamber and defines an intake channel and an exit channel. The exit channel is fluidically coupled to the chamber via an exit opening. The intake channel is fluidically coupled to the chamber via an intake port. A center line of the intake channel is tangential to a portion of the chamber wall such that a portion of an inlet airflow conveyed into the chamber via the intake channel has a rotational motion. The intake port is defined at least in part by an intake ramp. The intake ramp includes a transition surface that forms an exit angle with respect to the surface of less than 105 degrees.