Research Project
9845891
Abstract: Nitric oxide (NO) plays a critical role in a wide range of bodily functions, including vasodilation, neurotransmission, wound healing, suppression of platelet activation, and modulation of ciliary beat frequency. In addition, it is a potent and endogenous antimicrobial/antiviral agent produced by macrophages and normally present at moderate levels (0.20-1.0 ppmv) within the upper airways/sinuses of healthy individuals to help prevent chronic upper airway infections. It has been found that significant suppression of NO levels occurs in patients suffering from chronic rhinosinusitis (CRS), and difficult-to-treat lower respiratory infections associated with chronic obstructive pulmonary disease (COPD) and cystic fibrosis (CF). Consequently, it has been shown that patients with respiratory maladies benefit greatly from inhaled nitric oxide (iNO) therapy. In addition, iNO at higher levels (10-50 ppmv) is routinely used in the hospital setting to treat newborns with pulmonary hypertension, adults with acute respiratory distress syndrome (ARDS), and patients with of other respiratory infections such as pneumonia and tuberculosis. Further, it has been demonstrated that iNO therapy improves reperfusion of brain tissue after a stroke, promotes recovery in liver transplant patients, and prevents systemic inflammatory response syndrome (SIRS) (when added to the oxygenator sweep gas) in patients that undergo cardiopulmonary bypass surgery (CPB). Currently, the high cost ($3,000 per day) of iNO delivery systems, which rely on low NO concentrations in metal gas cylinders, restricts the use of gas phase NO both within and outside of the hospital setting. Given the wide diversity of applications and the need to deliver NO in various health care settings (in-patient/out-patient care) and at a much lower cost, there is a growing need for an inexpensive, portable and simple-to-use system to create gas phase NO on demand. Working in collaboration with researchers in the Department of Chemistry at the Univ. of Michigan, NOTA Laboratories proposes to develop such an iNO delivery system. NOTA?s proposed product will consist of a single use reel-to-reel cartridge containing a roll (5-10 m) of S-nitrosothiol (RSNO), either S-nitroso-N-acetyl- penicillamine (SNAP) or S-nitroso-glutathione (GSNO), immobilized onto a polymer carrier. The roll of RSNO film will be housed within a light-resistant compartment and advanced through an illumination zone that is equipped with several light emitting diodes (LEDs) that produce wavelengths at which NO can be efficiently photo-released from the RSNO species (380-580 nm). The advancement of the film through the translucent light compartment will be achieved using a motor-driven pick-up wheel that is controlled through a feedback loop employing a NO electrochemical gas phase sensor situated in-line within the output air stream. A stream of humidified air will be pumped through the NO generating chamber, with the LEDs intensity being adjusted via the feedback loop to release NO into the air stream to provide target concentrations of NO (0.20-200 ppmv). The NO released will then pass out of the LANOR system into the patient?s nose via cannula nasal tubes or a nasal mask. Phase I research will focus on the building a prototype device that can accommodate the reel-to- reel cartridge with an NO2 suppression filter as well as developing the roll of film containing the immobilized RSNO species. Finally, a demonstration of the prototype device?s ability to deliver pure NO at levels between 1 and 200 ppmv for up to 1 week will be made through control of the film advancement and intensity of the illumination. Long-term storage stability studies will demonstrate that the immobilized RSNO film is stable under ambient heat and humidity conditions when stored in an aluminum foil pouch. It is anticipated that the proposed LANOR system will be able to deliver a broad range of therapeutic iNO levels for at least 1 week, depending upon the desired NO level and rate of air delivery.
