An example of a nitric oxide (NO) generating system includes an NO generating formulation, having: a stable NO donor/adduct; a hydrophilic binder; and an additive. The additive is to control a rate of release of NO from the stable NO donor/adduct after the formulation is exposed to an effective amount of water, water vapor, or blue or ultraviolet (UV) light. This example NO generating system further includes an inhalation device in operative contact with the NO generating formulation.

An example of a nitric oxide (NO) generating system includes an NO generating formulation, having: a stable NO donor/adduct; a hydrophilic binder; and an additive. The additive is to control a rate of release of NO from the stable NO donor/adduct after the formulation is exposed to an effective amount of water, water vapor, or blue or ultraviolet (UV) light. This example NO generating system further includes an inhalation device in operative contact with the NO generating formulation.

A sensing arrangement for a medical device includes a housing having a rigid portion and a flexible portion, a collar of the flexible portion attached to an exterior of the rigid portion such that a stem of the rigid portion extends into an interior of the flexible portion. A sensing element is positioned at least partially within a passageway of the rigid portion, with at least one wire extending from the sensing element through the passageway and into the interior of the flexible portion. Front and rear flanges protrude from the flexible portion and are adapted to allow the sensing arrangement to be attached into an aperture in a wall of the medical device. The stem of the rigid portion may be positioned between the collar and front flanges of the flexible portion, such that the stem does not extend through the aperture of the wall of the medical device. There are also provided a seal, a removable component, a medical device and a system.

Therapy gas delivery systems that provide run-time-to-empty information to a user of the system and methods for administering therapeutic gas to a patient. The therapeutic gas delivery system may include a gas pressure sensor attachable to a therapeutic gas source that communicates therapeutic gas pressure data to a therapeutic gas delivery system controller, a gas temperature sensor positioned to measure gas temperature in the therapeutic gas source that communicates therapeutic gas temperature data to the therapeutic gas delivery system controller, at least one flow controller that communicates therapeutic gas flow rate data to the therapeutic gas delivery system controller, at least one flow sensor that communicates flow rate data to the therapeutic gas delivery system controller, and at least one display that communicates run-time-to-empty to a user of the therapeutic gas delivery system. The therapeutic gas delivery system controller of the system includes a processor that executes an algorithm to calculate the run-time-to-empty from the data received from the gas pressure sensor, temperature sensor, flow controller and flow sensor, and directs the result to the display.

A system for controlled sympathectomy procedures is disclosed. A system for controlled micro ablation procedures is disclosed. Methods for performing a controlled surgical procedure are disclosed. A system for performing controlled surgical procedures in a minimally invasive manner is disclosed. An implantable device for monitoring and/or performing a neuromodulation procedure is disclosed.

Described are methods and devices for therapeutic or medical gas delivery that utilize at least one proportional control valve and at least one binary control valve. The proportional control valve may be in series with the binary control valve to provide a valve combination capable of pulsing therapeutic gas at different flow rates, depending on the setting of the proportional control valve. Alternatively, the proportional control valve and binary control valve may be in parallel flow paths.

Systems and methods for generating nitric oxide are disclosed. A nitic oxide (NO) generation system includes at least one pair of electrodes configured to generate a product gas containing NO from a flow of a reactant gas; and a controller configured to regulate the amount of nitric oxide in the product gas produced by the at least one pair of electrodes by utilizing duty cycle values of plasma pulses selected from a plurality of discrete duty cycles to produce a target rate of NO production based on an average of discrete production rates associated with each of the plurality of discrete duty cycles.

Systems and methods for generating nitric oxide are disclosed. A nitic oxide (NO) generation system includes at least one pair of electrodes configured to generate a product gas containing NO from a flow of a reactant gas; and a controller configured to regulate the amount of nitric oxide in the product gas produced by the at least one pair of electrodes by utilizing duty cycle values of plasma pulses selected from a plurality of discrete duty cycles to produce a target rate of NO production based on an average of discrete production rates associated with each of the plurality of discrete duty cycles.

Module for housing electronic and electromechanical medical equipment including a portable digital camera and processing circuitry with machine vision and machine learning software for automatically documenting healthcare events and healthcare equipment operations in the electronic health record.

A therapeutic gas delivery system with at least one gas supply subsystem is disclosed. The at least one gas supply subsystem may include a gas source coupling configured to receive a therapeutic gas source and form a fluid flow connection with the therapeutic gas source, a therapeutic gas delivery system controller, and one or more display(s) configured to be in communication over a communication path with the therapeutic gas delivery system controller. The display may be configured to display a graphical, illustrative, or numerical indicator of one or more flow or system parameters.