An apparatus for a fluidic ejection device and a fluidic ejection device containing the apparatus. The apparatus includes a pivot member having at least a first position and a second position, a shaft attached on a first end thereof to the pivot member and on a second end distal from the first end to a capping structure, wherein pivot of the pivot member pivots the capping structure from a first capped position to a second uncapped position adjacent an ejection head of the fluidic ejection device.

A droplet delivery device and related methods for delivering precise and repeatable dosages to a subject for pulmonary use is disclosed. The droplet delivery device includes a housing, a reservoir, and ejector mechanism, and at least one differential pressure sensor. The droplet delivery device is automatically breath actuated by the user when the differential pressure sensor senses a predetermined pressure change within housing. The droplet delivery device is then actuated to generate a stream of droplets having an average ejected droplet diameter within the respirable size range, e.g, less than about 5 μm, so as to target the pulmonary system of the user.

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.

The present invention includes and provides a method of delivering a medicament to an eye of a subject in need thereof a solution, the method comprising: (a) providing droplets containing the medicament with a specified average size and average initial ejecting velocity; and (b) delivering the medicament to the eye, where the droplets deliver a percentage of the ejected mass of the droplets to the eye.

The disclosure relates to medical databases, remote monitoring, diagnosis and treatment systems and methods. In one particular embodiment, a system for remote monitoring, diagnosis, or treatment of eye conditions, disorders and diseases is provided. This method generally includes administering a stream of droplets to the eye of a subject from an ejector device, and storing data related to the administration in a memory of the ejector device. The data may then be monitored and analyzed.

Provided is a nasal drop device which can simply and easily administer an appropriate amount of a solution to a specific site in the nasal cavity without waste. The nasal drop device 100 includes: an ejection portion 104 that ejects droplets into the nasal cavity; and a control portion that acquires suitability information indicating whether or not a current relative angle between a reference line indicating the posture of the face of a user who puts the nasal drop device 100 in the nose and a reference line indicating the posture of the nasal drop device 100 is suitable for the nasal drop, and controls the ejection operation of the ejection portion 104 according to the suitability information.

A fluid dispensing cartridge includes a housing body having a proximal end wall, a distal end wall, a fluid chamber, and a hollow throat portion. The fluid chamber is in fluid communication with the hollow throat portion. The proximal end wall provides a proximal termination of the fluid chamber and the distal end wall provides a distal termination of the hollow throat portion. A plurality of electrical contacts face proximally from the proximal end wall. The fluid dispensing cartridge includes a fluid jetting chip that has a plurality of fluid jetting nozzles.

There is provided a mesh for use in forming droplets of liquid in a nebuliser, the mesh comprising a first portion (22) made of a first material having a plurality of holes passing therethrough; and a second portion (26) made of a second material that is in contact with the first portion (22), the second portion (26) having a corresponding plurality of holes passing therethrough, the plurality of holes in the second portion forming nozzles (28) for an outlet side of the mesh; wherein the first material has a higher density than the second material.

Provided is a smart inhaler, headset and wearable smart mask configured to operate as an air ionizer and a controlled multi-liquid atomizer. The smart mask, headset and smart inhaler use a mature technology to deliver various types of liquid solutions to different applications from health care, drug delivery, immunization to recreational and gaming uses. In addition, the smart mask and headset contain multiple actuators to provide haptic feedback to the areas around the mask and headset. The headset, smart mask and inhaler have a direct communication path to a smart device or it can be a smart device by itself; its various environmental and gas sensors act as a feedback mechanism. The detection level of the organic and non-organic VOC gas emitted when exhaling can be communicated and stored for analysis purposes. The detected gas can be regenerated on the same smart mask or a different remote smart mask.

Provided is a smart inhaler and wearable smart mask configured to operate as an air ionizer and a controlled multi-liquid atomizer. The smart mask and smart inhaler use a mature technology to deliver various types of liquid solutions to different applications from health care, drug delivery, immunization to recreational and gaming uses. In addition, the smart mask contains multiple actuators to provide haptic feedback to the areas around the mask. The smart mask and inhaler have a direct communication path to a smart device or it can be a smart device by itself; its various environmental and gas sensors act as a feedback mechanism. The detection level of the organic and non-organic VOC gas emitted when exhaling can be communicated and stored for analysis purposes. The detected gas can be regenerated on the same smart mask or a different remote smart mask.