This atomization unit is provided with a reservoir that holds an aerosol source, an atomization part that atomizes the aerosol source, and a cap body that blocks a supply port for supplying the aerosol source to the reservoir, wherein movement of the cap body away from the reservoir causes the atomization part and/or a power supply member, which electrically connects a power source and the atomization part, to break.

A dialysis machine has two hydraulic connectors at the dialysate side to which a respective connection line having a filter coupling is connected for connection to a dialyzer, with the hydraulic connectors being an inflow connector for feeding fresh dialysis liquid to the dialyzer and a backflow connector for draining consumed dialysate from the dialyzer. The dialyzer machine also has two parking positions associated with the respective hydraulic connectors for storing the filter couplings when not in operation, wherein the filter couplings of both hydraulic connectors are equipped with a connection sensor which recognizes a connecting of the filter coupling to a dialyzer and/or that both parking positions are provided with separate covers.

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 present disclosure relates to devices, systems and processes for delivering therapeutic fluids. Embodiments disclosed herein are directed to medical devices for housing a therapeutic fluid, and methods and systems for monitoring in an infusion delivery device, using a pressure sensor of the device, one or more of: (A) fill event detection; (B) fill volume detection; (C) mechanical compliance calibration/air detection of an infusion management system after fill event and priming; (D) occlusion detection after removal of insertion seal assembly; (E) detecting fluid path deployment of an infusion delivery device; (F) monitoring for occlusion detection during pump use; and (G) detecting an empty reservoir.

The present disclosure relates to devices, systems and processes for delivering therapeutic fluids. Embodiments disclosed herein are directed to medical devices for housing a therapeutic fluid, and methods and systems for monitoring in an infusion delivery device, using a pressure sensor of the device, one or more of. (A) fill event detection; (B) fill volume detection; (C) mechanical compliance calibration/air detection of an infusion management system after fill event and priming; (D) occlusion detection after removal of insertion seal assembly; (E) detecting fluid path deployment of an infusion delivery device; (F) monitoring for occlusion detection during pump use; and (G) detecting an empty reservoir.

The present disclosure relates to devices, systems and processes for delivering therapeutic fluids. Embodiments disclosed herein are directed to medical devices for housing a therapeutic fluid, and methods and systems for monitoring in an infusion delivery device, using a pressure sensor of the device, one or more of: (A) fill event detection; (B) fill volume detection; (C) mechanical compliance calibration/air detection of an infusion management system after fill event and priming; (D) occlusion detection after removal of insertion seal assembly; (E) detecting fluid path deployment of an infusion delivery device; (F) monitoring for occlusion detection during pump use; and (G) detecting an empty reservoir.

The present disclosure relates to devices, systems and processes for delivering therapeutic fluids. Embodiments disclosed herein are directed to medical devices for housing a therapeutic fluid, and methods and systems for monitoring in an infusion delivery device, using a pressure sensor of the device, one or more of. (A) fill event detection; (B) fill volume detection; (C) mechanical compliance calibration/air detection of an infusion management system after fill event and priming; (D) occlusion detection after removal of insertion seal assembly; (E) detecting fluid path deployment of an infusion delivery device; (F) monitoring for occlusion detection during pump use; and (G) detecting an empty reservoir.

The present disclosure relates to devices, systems and processes for delivering therapeutic fluids. Embodiments disclosed herein are directed to medical devices for housing a therapeutic fluid, and methods and systems for monitoring in an infusion delivery device, using a pressure sensor of the device, one or more of: (A) fill event detection; (B) fill volume detection; (C) mechanical compliance calibration/air detection of an infusion management system after fill event and priming; (D) occlusion detection after removal of insertion seal assembly; (E) detecting fluid path deployment of an infusion delivery device; (F) monitoring for occlusion detection during pump use; and (G) detecting an empty reservoir.

Systems and methods for compensating long term sensitivity drift of catalytic type electrochemical gas sensors used in systems for delivering therapeutic nitric oxide (NO) gas to a patient by compensating for drift that may be specific to the sensors. In at least some instances, the long term sensitivity drift of catalytic type electrochemical gas sensors can be addressed using calibration schedules, which can factor in the absolute change in set dose of NO being delivered to the patient that can drive one or more baseline calibrations. The calibration schedules can reduce the amount of times the sensor goes offline. Systems and methods may factor in actions occurring at the delivery system and/or aspects of the surrounding environment, prior to performing a baseline calibration, and may postpone the calibration and/or rejected using the sensor's output for the calibration.

An electronic atomizer capable of detecting a counterfeit liquid container is illustrated. The electronic atomizer includes a liquid container, a power supply module and a storage box. The liquid container includes an identification code carrier and an atomizing component. The liquid container accommodates fluid to be atomized, and the power supply module provides power to the atomizing component for atomization of the fluid. The storage box has a receiving space and is provided with an identifying device configured to identify the identification code carrier of the liquid container which is placed in the receiving space. Also illustrated are an anti-counterfeit system and a method thereof.