A system for reducing airway obstructions of a patient may include a ventilator, a control unit, a gas delivery circuit with a proximal end in fluid communication with the ventilator and a distal end in fluid communication with a nasal interface, and a nasal interface. The nasal interface may include at least one jet nozzle, and at least one spontaneous respiration sensor in communication with the control unit for detecting a respiration effort pattern and a need for supporting airway patency. The system may be open to ambient. The control unit may determine more than one gas output velocities. The more than one gas output velocities may be synchronized with different parts of a spontaneous breath effort cycle, and a gas output velocity may be determined by a need for supporting airway patency.

The systems, devices, and methods described herein relate to providing breathing gas at a high velocity to a patient using a base unit and an auxiliary unit configured to be removably disposed on or at least partially in the base unit. The base unit has several couplings for improved control and sensing of the auxiliary unit and its components, wherein the couplings are configured to be non-contact with the corresponding components of the auxiliary unit and/or otherwise configured to minimize operational defects or improve efficiency. Non-contact couplings include induction heating, capacitive level sensing, a magnetically coupled rotor pump. RFID tag and reader, and Hall effect sensing. The breathing gas can be provided at high velocities by setting breathing gas flowrates based on dimensions of a nasal cannula used to direct the breathing gas into a patient's nares.

The present disclosure relates to determining a corrected exhaled gas measurement during high flow respiratory therapy. Measuring exhaled gas concentration during high flow respiratory therapy is difficult and inaccurate due to a phenomenon known as flushing. The high flows delivered to the patient flush the dead space in the conducting airways, which causes a dilution effect that results in underestimated or overestimated exhaled gas measurement depending on the gas composition delivered by the high flow system. This can lead to incorrect clinical measurements and diagnoses. Various algorithms are disclosed herein to account for the dilution effect caused by flushing, allowing for the method of measuring gas concentrations to still be used accurately for clinical measurements.

A patient interface assembly includes a housing that defines an inlet port and an outlet port. A jet pump receives pressurized gas flow from the inlet port and delivers the gas flow to the outlet port. A nebulizer is fluidly coupled to the outlet port and positioned to introduce medication into the gas flow and deliver medicated gas flow to a patient.

Condensation or rain-out is a problem in breathing circuits and especially neonatal breathing circuits. The subject patent provides an improved breathing tube component for managing rain-out particularly in neonatal applications. In particular the breathing tube has a smooth inner bore, and an outer insulating layer containing stagnant gas and a heater wire.

Objective Pulmonary Function (PF) evaluation for respiratory fatigue is vital to the diagnosis and management of many pediatric respiratory diseases in the intensive care, emergency and outpatient settings. A non-invasive PF instrument utilizes sensors and software to access respiratory breathing patterns, vital parameters, asynchrony and measures the work of breathing. Software algorithms predict respiratory fatigue. The hardware includes a microcircuit board that individually links to rib cage (RC) and abdominal (ABD) inductance bands. The bands wirelessly transmit changes in RC and ABD circumference. Point-of-care, real-time indices of respiratory work, breathing patterns and respiratory fatigue indices are developed on a user-friendly graphical user interface. The diagnostic data can later be securely emailed as an attachment for entry into patients' electronic medical records or sent to a caretaker's computer, or used directly to control a respiratory therapy device. The system can also be used for telemedicine homecare.

A gas monitoring system for artificial ventilation includes: a sensor that is configured to produce a signal corresponding to a concentration of a predetermined gas in a portion which is in a respiratory circuit of an artificial ventilator, and through which both an inspiratory gas and an expiratory gas pass; a displaying apparatus that is communicable with the sensor; a processor; and a memory that is configured to store a command which is readable by the processor. When, during high-frequency oscillatory ventilation performed by the artificial ventilator, the command is executed by the processor, the processor is to configured to calculate a measurement value of the concentration based on the signal, and is configured to display at least one of a waveform corresponding to the signal and the measurement value on the displaying apparatus.

A nCPAP device includes an net configured for receiving a single gas jet flow. The single gas jet flow supplies gas for both nares. The device also includes a flow splitter configured for proportionally splitting said gas jet flow into two channels for the both nares according to one or more of nave anatomy and flow path resistance.

Embodiments of a respiratory support apparatus are disclosed comprising features configured to minimize, reduce or contain aerosols carrying pathogens that can cause diseases such as COVID 19, SARS, MERS, Tuberculosis, or any other infectious diseases. Embodiments of a respiratory support apparatus are also provided configured to at least reduce the amount of oxygen required, during use of the apparatus, from an external oxygen supply such as an oxygen tank or hospital wall supply. Embodiments of such apparatus are provided with means to recirculate expiratory gases, and/or redirect leak flow. Embodiments of such apparatus are provided in which expiratory gases are sucked away from the patient. Embodiments of such apparatus are provided comprising a first flow generator for delivering inspiratory gases, and a second flow generator for removing expiratory gases.

A breathing assistance device with improved pressure characteristics provides a high level of CPAP per unit of supplementary respirable gas consumed while maintaining low CPAP fluctuations throughout the breath cycle utilizing a frustrum-shaped air channel to accelerate air flow. In some embodiments, a manometer is provided for monitoring pressure and/or a pressure relief valve is provided as a safety measure against overpressure delivered to a patient. In some embodiments, the device is disposable for one-time or single patient use.