An inhaler (400) for electronically supervised parenteral administration of a dry powder pharmaceutical composition comprising: storage means (410) for the pharmaceutical composition in a form of a dry powder; administration means (411) for ad- ministration of the pharmaceutical composition; memory (404) and processing means (402); communication means (401); controlled blocking means (403) for blocking administration of the pharmaceutical composition, wherein the inhaler (400) is adapted to receive data corresponding to an administration scheme (11), to determine whether a mobile device (300) with an authorisation token assigned thereto is present, and to control the controlled blocking means (403) so as to allow administration of the pharmaceutical composition only with compliance with the administration scheme (11) in the presence of the mobile device (300) with the authorisation token (12) assigned thereto.

An ultrasonic droplet delivery device and related methods for delivering precise and repeatable amounts of a substance to a user for respiratory use is disclosed. The ultrasonic droplet delivery device generally comprises a body housing, a mouthpiece having an ejector mechanism, and a fluid cartridge having at least one fluid reservoir. In certain embodiments, the ejector mechanism may comprise at least one ultrasonic actuator and at least one aperture plate with a plurality of openings formed through its thickness for ejecting droplets. The device may further comprise at least one differential pressure sensor configured to activate the ejector mechanism upon sensing a pre-determined pressure change within the device to thereby generate the ejected stream of droplets.

Aspects and embodiments of the present invention generally include a device for patient self-administration of a prescribed medication. The total quantity of doses to be contained in the device, the quantity of prescribed medication comprising each individual dose, and the dosing schedule, collectively referred to as prescription parameters, are determined and controlled solely by a health care provider. In accordance with a prescribed dosing schedule, the device makes available for administration the precise quantity of prescribed medication constituting an individual dose. Patient access to the medication as well as patient control of the device is limited solely to the aspects of the device necessary to administer the available dose. The device also has a monitored subassembly which detects and transmits relevant device information to a remote management system accessible to the HCP, including detected attempts to alter, access, control or otherwise tamper with the device beyond its prescribed use.

Provided is a system comprising 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.

Systems and methods for automatically delivering medication to a user. An automated drug delivery system may include a sensor and a wearable automated drug delivery device. The wearable automated drug delivery device may be configured to couple to the skin of a user and may include a controller and a pump. The pump may be configured to output the medication. The controller may be within the wearable automated drug delivery device. The sensor may be coupled to the user and may be configured to collect information regarding the user. The controller of the wearable automated drug delivery device may use the collected information to locally determine an amount of medication to be output from the wearable automated drug delivery device and cause delivery of the amount of medication.

Embodiments of secure wound therapy systems and methods for operating the systems are disclosed. In some embodiments, the apparatus includes a pressure source, a user interface, and a locking mechanism. The locking mechanism can be in one of at least two states, the at least two states including a first state in which the locking mechanism physically prevents user adjustment of one or more operational parameters with the user interface and a second state in which the locking mechanism does not physically prevent user adjustment of the one or more operational parameters with the user interface. The locking mechanism can include an authentication key and a receiver configured to receive an authentication input, which may be compared to the authentication key. Providing a sufficiently matching authentication input can transition the locking mechanism from the first state to the second state, permitting adjustments to the one or more operational parameters.

The invention is directed to an inhalation atomizer comprising a counter and a blocking function. Counter rotates each time the atomizer is actuated. The blocking function includes a first protrusion on the counter and a second protrusion on a lower unit of the atomizer. Once the predetermined number of actuations has been achieved, the first protrusion encounters the second protrusion and prevents further rotation of the counter so that the atomizer is blocked from further use.

Provided is an aerosol generation device that suppresses the effect that errors in the production of structural elements have on the accuracy with which shortage of an aerosol source is detected. An aerosol generation device that comprises: a power source; a load that has a temperature-variable electrical resistance value and atomizes an aerosol source by generating heat due to supply of power from the power source; a first circuit that is used for the load to atomize the aerosol source; a second circuit that is connected in parallel to the first circuit, has a higher electrical resistance value than the first circuit, and is used to detect voltage that changes as a result of changes in the temperature of the load; an acquisition part that acquires the value of voltage that is applied to the second circuit and the load; and sensors that output the value of the voltage that changes as a result of changes in the temperature of the load.

A thermal protection system configured for use with a dialysate container or bag in a dialysis system is disclosed. The thermal protection system being configured so that when the dialysate container is subjected to a temperature greater than a predetermined temperature such as, when the dialysate container is heated within a microwave oven, the thermal protection system is configured to (i) prevent the flow of dialysate from the bag, (ii) indicate that the dialysate container has been subjected to a temperature greater than the predetermined temperature, or (iii) a combination thereof. In one embodiment, the thermal protection system is a circular hollow ring positioned within an exit port of the bag, the ring melting upon reaching the predetermined temperature to block the flow of dialysate. Alternatively, and/or in addition, the thermal protection system may be a thermally sensitive dye configured to change color upon being subjected to the predetermined temperature.

The inhalation device for medically active liquids (F) for generation of an aerosol comprises a housing (1), a reservoir (2), a pumping device with a pumping chamber (3), and a nozzle (6), wherein the interior volume of the pumping chamber (3) is changeable by means of linear relative motion of the pumping chamber to the riser pipe (5). Said linear relative motion can be effected by a relative rotation of a rotatable part (1A) which is part of, or connected to, the housing (1) with respect to a second part (1B) of said housing (1), in that said relative rotation can be transferred by means of a gear mechanism into said relative translational motion. A means for the storage of potential energy (7) is provided which is chargeable by means of said relative rotation, and wherein said energy is releasable to said pumping device when released by activation of a release means. A blocking device is provided which is adapted to block activation of the release means and/or release of the means for the storage of potential energy (7) during rotation of the rotatable part (1A) and/or during loading of the means for the storage of potential energy (7). Also, a method for the prevention of undesired emission of medically active liquid or aerosol from an inhalation device is disclosed.