Various systems, devices, NO.sub.2 absorbents, NO.sub.2 scavengers and NO.sub.2 recuperator for generating nitric oxide are disclosed herein. According to one embodiment, an apparatus for converting nitrogen dioxide to nitric oxide can include a receptacle including an inlet, an outlet, a surface-active material coated with an aqueous solution of ascorbic acid and an absorbent wherein the inlet is configured to receive a gas flow and fluidly communicate the gas flow to the outlet through the surface-active material and the absorbent such that nitrogen dioxide in the gas flow is converted to nitric oxide.

A device and method for forming NO-containing gas flow to treat a biological object is disclosed. The device may include an anode, a cathode, an interelectrode area between the cathode and the anode, an NO-containing gas flow outlet channel leading from the interelectrode area to a nozzle for directing and releasing the NO-containing gas flow from the device and a mechanism to adjust a relative position between the anode and the cathode to produce varying concentrations of NO. In addition, the device may include one or more features for interconnecting the various components to ensure proper and consistent assembly of the device.

Described are systems and methods for administration of nitric oxide (NO) with use of left ventricular assists devices (LVADs), as well as systems and methods for monitoring the NO delivery devices and/or the LVAD.

The disclosure concerns various devices implemented to provide a therapeutic gas rich environment to promote healing, reduce fibrosis and scar formations while maintaining anti-inflammatory, anti-thrombotic, antimicrobial, and vasodilating properties. The device generally includes a gas-donor composition that is embedded within a fibrous holding layer. Coupled to one side of the fibrous holding layer is a water-permeable layer and coupled to an opposite side of the fibrous holding layer is a gas-permeable layer. The water-permeable layer is configured to receive and communicate water to the gas-donor composition, wherein upon contact with the water, the gas-donor composition is configured to deliver a therapeutic gas through the gas-permeable layer to a treatment site of a subject.

A method of treating a human subject which is effected by inhalation of gaseous nitric oxide over a period of 8 day to about 28 days is disclosed. The method can be utilized for treating a human subject suffering from, or prone to suffer from, a disease or disorder that is manifested in the respiratory tract, or from a disease or disorder that can be treated via the respiratory tract. The disclosed method can be effected while monitoring one or more of on-site and off-site parameters such as vital signs, methemoglobin levels, pulmonary function parameters, blood chemistry and hematological parameters, blood coagulation parameters, inflammatory marker levels, liver and kidney function parameters and vascular endothelial activation parameters, such that no substantial deviation from a baseline in seen in one or more of the monitored parameters.

A method of treating a human subject which is effected by inhalation of gaseous nitric oxide over a period of 8 day to about 28 days is disclosed. The method can be utilized for treating a human subject suffering from, or prone to suffer from, a disease or disorder that is manifested in the respiratory tract, or from a disease or disorder that can be treated via the respiratory tract. The disclosed method can be effected while monitoring one or more of on-site and off-site parameters such as vital signs, methemoglobin levels, pulmonary function parameters, blood chemistry and hematological parameters, blood coagulation parameters, inflammatory marker levels, liver and kidney function parameters and vascular endothelial activation parameters, such that no substantial deviation from a baseline in seen in one or more of the monitored parameters.

A method and device can alternately deliver high concentration of nitric oxide and oxygen-enriched air.

A method may include producing, in a solution, microbubbles of nitric oxide having a targeted size; and directing the solution to a right side of a patient's heart, such that the microbubbles are directed to the patient's pulmonary arteries prior to being circulated through the patient's body. The solution may include saline or dextrose. Directing the solution to the right side of the patient's heart may include delivering the solution via a catheter, during a right-heart catheterization procedure. Directing the solution to the right side of the patient's heart may include injecting the solution into a median cubital vein of the patient. Directing the solution to the right side of the patient's heart comprises injecting the solution into an internal jugular vein, an external jugular vein or a femoral vein of the patient. The targeted size may correspond to a diameter of a specific branch of the patient's pulmonary arteries.

Various systems and devices for generating nitric oxide are disclosed herein. According to one embodiment, the device includes a body having an inlet, an outlet, and a porous solid matrix positioned with the body. The porous solid matrix is coated with an aqueous solution of an antioxidant, wherein the inlet is configured to receive a gas flow and fluidly communicate the gas flow to the outlet through the solid matrix to convert nitrogen dioxide in the gas flow into nitric oxide. The porous solid matrix allows the device to be used in any orientation. Additionally, the porous solid matrix provides a rigid structure suitable to withstand vibrations and abuse without compromising device functionality.

Systems and methods for nitric oxide (NO) generation systems are provided. In some embodiments, an NO generation system comprises at least one pair of electrodes configured to generate a product gas containing NO from a flow of a reactant gas. The electrodes have elongated surfaces such that a plasma produced is carried by the flow of the reactant gas and glides along the elongated surfaces from a first end towards a second end of the electrode pair. A controller is configured to regulate the amount of NO in the product gas by the at least one pair of electrodes using one or more parameters as an input to the controller. The one or more parameters include information from a plurality of sensors configured to collect information relating to at least one of the reactant gas, the product gas, and a medical gas into which the product gas flows.