An apparatus to maintain an environment over an anterior surface of a patient eye can include an enclosure sized and shaped to be seated about the patient eye to form a cavity within the enclosure. The enclosure can be configured to contain a fluid other than ambient air in contact with the patient eye. The apparatus can include a fluid regulator in communication with the enclosure, where the fluid regulator can be configured to regulate the composition of the fluid contained within the enclosure.

Disclosed is a device for supplying therapeutic gas, notably NO/N.sub.2 or O.sub.2/N.sub.2O mixtures, including an internal passage with a valve for conveying and controlling the flow of therapeutic gas in the internal passage, a control unit controlling the valve, a graphic display for displaying choices that can be selected by a user, and a selector, such as touch-sensitive keys displayed on the graphic display for making a selection from among the selectable choices displayed on the graphic display. The control unit is configured to count a total number of patients treated by administration of the therapeutic gas from the selection, by a user, via the selector, of a first given choice corresponding to the start of a treatment by administering the therapeutic gas to a patient concerned.

A gas delivery system and method are provided that include a therapeutic gas delivery device, and a high-frequency ventilator delivering a breathing gas to a respiratory circuit. The therapeutic gas delivery system also includes a flow sensor assembly having a single interior chamber. The flow sensor assembly includes a flow sensor connected with the therapeutic gas delivery device and configured to measure a flow rate of the breathing gas. The flow sensor has a sensor gas inlet and a sensor gas outlet. The flow sensor assembly further includes a one-way flow valve disposed downstream of the sensor gas outlet. The one-way flow valve includes a valve gas inlet and a valve gas outlet. Inner diameters of the valve gas inlet and the valve gas outlet are greater than or equal to an inner diameter of at least one of the sensor gas inlet and the sensor gas outlet.

A gas delivery system and method are provided that include a therapeutic gas delivery device, and a high-frequency ventilator delivering a breathing gas to a respiratory circuit. The therapeutic gas delivery system also includes a flow sensor assembly having a single interior chamber. The flow sensor assembly includes a flow sensor connected with the therapeutic gas delivery device and configured to measure a flow rate of the breathing gas. The flow sensor has a sensor gas inlet and a sensor gas outlet. The flow sensor assembly further includes a one-way flow valve disposed downstream of the sensor gas outlet. The one-way flow valve includes a valve gas inlet and a valve gas outlet. Inner diameters of the valve gas inlet and the valve gas outlet are greater than or equal to an inner diameter of at least one of the sensor gas inlet and the sensor gas outlet.

A wearable-intranasal device for opioid overdose detection via overdose-associated increases of carbon dioxide in exhaled breath, and automatic delivery of naloxone in response. The device comprises a wearable nasal clip with drug reservoir(s) containing naloxone, and a CO.sub.2-sensitive hydrogel occluding or encapsulating the naloxone. The hydrogel transitions from a solid state to a liquid or gas state when exposed to an increase in CO.sub.2, thereby unblocking the drug reservoir(s) and releasing naloxone. The device provides a novel disposable, stimuli-responsive, naloxone delivery system, designed to trigger automatically in response to physical symptoms of an overdose without the need for bystander intervention.

A system for delivery of gas to a tissue, comprises: a first container containing the gas, an applicator having a distal end arranged to deliver the gas to the tissue, a second container containing a purging gas; and a flow control system for controlling flow of gas. The system also comprises a three-port valve having a first port for receiving the gas from the first container, a second port for receiving the purging gas from the second container, and a third port in fluid communication with the applicator. The valve is switchable between a first state at which the first port fluidly connects to the third port, and a second state at which the second port fluidly connects to the third port.

A system for delivery of gas to a tissue, comprises: a first container containing the gas, an applicator having a distal end arranged to deliver the gas to the tissue, a second container containing a purging gas, and; and a flow control system for controlling flow of gas. The system also comprises a three-port valve having a first port for receiving the gas from the first container, a second port for receiving the purging gas from the second container, and a third port in fluid communication with the applicator. The valve is switchable between a first state at which the first port fluidly connects to the third port, and a second state at which the second port fluidly connects to the third port.

A system for delivery of gas to a tissue, comprises: a first container containing the gas, an applicator having a distal end arranged to deliver the gas to the tissue, a second container containing a purging gas, and; and a flow control system for controlling flow of gas. The system also comprises a three-port valve having a first port for receiving the gas from the first container, a second port for receiving the purging gas from the second container, and a third port in fluid communication with the applicator. The valve is switchable between a first state at which the first port fluidly connects to the third port, and a second state at which the second port fluidly connects to the third port.

Systems and methods are provided for portable and compact nitric oxide (NO) generation that can be embedded into other therapeutic devices or used alone. In some embodiments, an ambulatory NO generation system can be comprised of a controller and disposable cartridge. The cartridge can contain filters and scavengers for preparing the gas used for NO generation and for scrubbing output gases prior to patient inhalation. The system can utilize an oxygen concentrator to increase nitric oxide production and compliment oxygen generator activity as an independent device. The system can also include a high voltage electrode assembly that is easily assembled and installed. Various nitric oxide delivery methods are provided, including the use of a nasal cannula.

Systems and methods are provided for portable and compact nitric oxide (NO) generation that can be embedded into other therapeutic devices or used alone. In some embodiments, an ambulatory NO generation system can be comprised of a controller and disposable cartridge. The cartridge can contain filters and scavengers for preparing the gas used for NO generation and for scrubbing output gases prior to patient inhalation. The system can utilize an oxygen concentrator to increase nitric oxide production and compliment oxygen generator activity as an independent device. The system can also include a high voltage electrode assembly that is easily assembled and installed. Various nitric oxide delivery methods are provided, including the use of a nasal cannula.