A method for estimating an inhale dose when a drug is delivered to a person using an inhaler is disclosed. A predicted inhale dose (PID) of the drug is estimated based on at least one first-type parameter and at least one second-type parameter. The first-type parameter is related to a breath pattern of the person, and the second-type parameter is related to the inhaler.

A patient interface may include a plenum chamber pressurisable to a therapeutic pressure, a seal-forming structure constructed and arranged to form a seal with a region of the patient's face surrounding an entrance to the patient's airways, a positioning and stabilising structure to provide a force to hold the seal-forming structure in a therapeutically effective position on the patient's head, and a vent structure to allow a continuous flow of gases exhaled by the patient from an interior of the plenum chamber to ambient, wherein the patient interface is configured to leave the patient's mouth uncovered during therapy, wherein the seal-forming structure comprises two lateral support regions, each located at a lateralmost side of the seal-forming structure, and a medial region positioned between the lateral support regions, the hole passing through the medial region, and wherein the lateral support regions are thicker than the medial region.

A dual pressure respiratory assistance device including a gas source which supplies a flow of gas into an air tube having a bubbler branch and a patient branch. A first tube that is connected to the bubbler branch is at least partially submerged in a fluid. An oscillatory relief valve cycles between first and second configurations. The relief valve includes an oscillating member which captures gas released through at least one hole in the first tube when the oscillating member is in a first position. The gas in the oscillating member causes the oscillating member to rise to a second position, wherein gas is released from the oscillating member and the at least one hole is blocked when the oscillating member reaches the second position.

Provided is a respiratory monitoring device that measures and outputs the substantial use time of an oxygen supply device. A respiratory monitoring device (4) used in combination with an oxygen supply device (1) delivering highly concentrated oxygen gas includes a detection unit (6) that detects a change in breathing-related information representing at least one of a pressure, a flow rate, and a gas temperature, based on exhalation and inhalation, a calculation unit (725) that calculates a respiratory rate, based on the change in breathing-related information, a determination unit (726) that determines whether breathing is present, and whether a user of the oxygen supply device is present, based on the respiratory rate, a measurement unit (727) that measures a duration in which a user of an oxygen supply device has been determined to be present, based on a determination result obtained by the determination unit, and an output unit (728) that outputs a cumulative measurement result for the duration.

This disclosure relates to a system configured to detect the presence of secretions in a subject's airway during respiratory therapy. The system can determine whether the subject requires airway clearance. A pressure generator generates a pressurized flow of breathable gas. Sensors generate output signals relating to one or more gas parameters of the pressurized flow of breathable gas. The system can determine a first parameter that is an indication of the volume of breathable gas within the airway of the subject and a time derivative of the first gas parameter to generate a plot of these parameters. The plot includes a perimeter and an area that can be used to determine whether to effectuate initiation of airway clearance based on a complete breathing cycle that includes at least one inhalation and exhalation.

The application describes a nasal sub-system (21) having: a hollow body (22) with an inner chamber (22a) and an inlet (22b) for receiving a respiratory gas, and a pair of nasal prongs (23, 24), in fluid communication with the inner chamber 22a of the hollow body 22, each nasal prong (23, 24) comprising a pair of inner channels (23b, 23c; 24b, 24c), each inner channels (23b, 23c; 24b, 24c) comprising a first channel (23b; 24b) and a second channel (23c; 24c) arranged in parallel, each first passage (23b; 24b) fluidly connecting the internal chamber (22a) of the hollow body (22) with a nostril (13, 14) of the patient (1), and each second passage (23c, 24c) fluidly connecting a nostril (13, 14) with a vent conduit (25) arranged in the hollow body (22) and in fluid communication with the atmosphere via at least one venting port (25a).

A ventilator (100) ventilates a patient (102) by a high-flow oxygen therapy via a tube system (104). The ventilator has at least one sensor element (110), at least one actuatable inhalation valve or exhalation valve (120) and a control unit (130). The sensor element is arranged and configured to determine and to output a measured variable (112) within the tube system. The measured variable indicates a gas flow within the tube system. The actuatable inhalation valve or exhalation valve is arranged and configured to make possible a flow of a breathing gas from a ventilation circuit (107) of the ventilator. The control unit regulates a ventilation pressure provided by the ventilator via the at least one sensor element and the at least one inhalation valve or exhalation valve such that a predefined maximum pressure is not exceeded in a predefined area (140) of the tube system.

The present disclosure is directed to an electronic vaporizing device for vaporizing water-based compositions and other vaporizable materials. The electronic vaporizing device may comprise a vaporizing component having an ultrasonic vibration element operable to produce ultrasonic vibrations to vaporize at least a portion of the vaporizable material received therein. In one embodiment, the vaporizing component may further comprise a heating element operable to produce heat energy to vaporize at least a portion of the vaporizable material received therein. In one embodiment, the electronic vaporizing device may comprise a processor operable to generate at least one vaporizing control signal for selectively operating at least one of the ultrasonic vibration element and the heating element. The operation of the vaporizing component may be determined by an associated user, by a third party via a remote device, and the like.

A system for measuring the vital parameters of low care patients is described. The system includes a connecting element for a nasal cannula or breathing mask for providing a fluidic connection with the patient and a flow and/or pressure sensor in fluidic connection with the nasal cannula or breathing mask, for sensing, when the nasal cannula or breathing mask is connected to the system, at least a negative pressure signal. The system also includes a processor configured for deriving, directly based on said at least a negative pressure signal, information related to the breathing cycle, and an output means configured for outputting at least one vital parameter of the patient, the outputting comprising outputting information related to the breathing cycle.

The invention comprises a method of operating a breathing apparatus comprising measuring a baseline breath flow parameter being respiratory rate and/or tidal volume or a parameter derived therefrom, varying the flow rate provided by the breathing apparatus, measuring a current breath flow parameter being respiratory rate and/or tidal volume or a parameter derived therefrom, comparing the baseline and current breath flow parameters, and altering operation of the breathing apparatus based on the comparison. The invention also comprises a breathing apparatus that implements the above method.