Systems and methods configured to provide a physician interface that enables a physician to assess asthma of a subject and provide therapeutic feedback are disclosed. Exemplary implementations may: obtain subject information for the subject including environmental conditions at or around a physical location of the subject, and results of remote diagnostic tests and physician-administered diagnostic tests for the subject; determine, based on the subject information, a condition assessment regarding the asthma of the subject; effectuate presentation of physician interface via a client computing platform associated with the physician, physician interface configured to convey the condition assessment and enable the physician to provide the therapeutic feedback based on the condition assessment; receive the therapeutic feedback via physician interface, wherein the therapeutic feedback includes adjustments to the specified therapy regime; and transmit the therapeutic feedback to a client computing platform associated with the subject for presentation to the subject.

An inhalation monitoring system includes an inhaler having a medicament delivery apparatus configured to deliver medicament to a user during an inhalation of the user; inhalation monitoring apparatus, configured to, during the inhalation, gather data for determining a measure of the user's lung function and/or lung health; and a processor configured to receive the data from the inhalation monitoring apparatus and, using the data, determine a measure of the user's lung function and/or lung health.

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 are configured to inexsufflate a subject and provide cough-by-cough feedback during treatment and/or therapy of the subject. Through sensors that are included in the systems, various gas and/or respiratory parameters maybe measured and/or determined in real-time, such as, for example, peak cough flow and/or inspiratory tidal volume.

A portable inhalation device includes a medication storage component, a flow controller, an atomizer, a medication delivery component, and a pressure sensor. The medication storage component is configured to store medication. The flow controller is configured to cause a force to be applied to the medication stored by the medication storage component to transport the medication to the atomizer. The atomizer is configured to generate droplets from the medication. The medication delivery component includes a delivery channel extending from the atomizer to an outlet opening. The medication delivery component is configured to receive the medication in the delivery channel from the atomizer and dispense the medication via the opening. The pressure sensor is configured to detect a pressure corresponding to a flow rate of air in the delivery channel and output an indication of the detected pressure.

A system for ventilation of a being, comprising at least one ventilator and at least one EIT measuring device, the ventilator comprising at least one controllable respiratory gas source and a programmable control unit for controlling the respiratory gas source and the EIT measuring device comprising at least one sensor apparatus for measuring impedance values of at least one lung of the being and at least one calculation and evaluation unit, and the system assigning the impedance values measured by way of the at least one sensor apparatus to pixels n, and the control unit being configured as specified in the claims.

An inhalation monitoring system includes an inhaler having a medicament delivery apparatus configured to deliver medicament to a user during an inhalation of the user; inhalation monitoring apparatus, configured to, during the inhalation, gather data for determining a measure of the user's lung function and/or lung health; and a processor configured to receive the data from the inhalation monitoring apparatus and, using the data, determine a measure of the user's lung function and/or lung health.

A fluid dynamic valve passively allows fluid flow out of a moving stream in one flow direction and not in the reverse. This allows the collection of fluid from a single direction of an AC fluid flow. The siphoned portion of the flow has a flow rate proportional to the mainstream flow. This device can collect exhaled breath or selective entrenchment during inhale. In one orientation, it can meter aerosolized particles into an inhale breath stream for pulmonary delivery, without complicated breath timing or drug loss due to drug adsorption to the back of the throat. Alternatively, a user can breathe through the device and a proportional amount, relative to the volumetric flow rate, of each exhale can flow into an auxiliary chamber for analysis. In addition, the device has a low respiratory burden and is comfortable to use.

Systems, devices, and methods for determining a user's lung capacity may employ a sound-producing breathing device and a recording device such as a microphone included in a user electronic device (e.g., smart phone or tablet computer). A user may inhale or exhale through the sound-producing breathing device, thereby producing a sound that is received by the microphone and communicated to a processor. The processor may analyze the received sound recording to determine one or more sound intensity values over, for example, the duration of the received sound and/or points in time within the sound recording. The sound intensity values may then be used to determine the user's lung capacity.

A device for delivering medication to a user may include a circular or elliptical body that include a mouthpiece, a flexible strip of medication, a lever, and a mouthpiece cover, where the mouthpiece cover is rotatable about the body. The electronics module may include a communication circuit, a sensor system, and a switch. The lever may be configured to actuate the switch when the lever is moved from a closed position to an open position. The lever is configured to advance a dose of medication on the flexible strip when moved from the closed position to the open position. When actuated, the switch may be configured to switch the electronics module from an off state to an active state wen the lever is actuated for a first time by a user. Thereafter, the electronics module is configured to not return to the off state.