View clinical trials related to Oxidative Injury.
Filter by:The goal of this observational study is to define a personalized risk model in the super healthy and homogeneous population of Italian Air Force high-performance pilots. This peculiar cohort conducts dynamic activities in an extreme environment, compared to a population of military people not involved in flight activity. The study integrates the analyses of biological samples (urine, blood, and saliva), clinical records, and occupational data collected at different time points and analyzed by omic-based approaches supported by Artificial Intelligence. Data resulting from the study will clarify many etiopathological mechanisms of diseases, allowing the creation of a model of analyses that can be extended to the civilian population and patient cohorts for the potentiation of precision and preventive medicine.
In this study, the researchers propose to investigate the efficacy of inhaled nitric oxide to prevent ischemia-reperfusion (I/R) hepatocyte injury in patients who receive extended donor criteria(EDC)liver grafts based on changes in proteomic and metabolomic markers following revascularization of the donor graft. In reviewing the literature, no uniform extended criteria donor classification exists. The characteristics most associated with liver graft failure appear to be cold ischemia time greater than 10 hours, warm ischemia time greater than 40 minutes, donor age > 55 years of age, donor hospitalization > 5 days, a donation after cardiac death (DCD) graft, and a split graft. The researchers will exclude warm ischemia time as this is impossible to predict prior to the transplantation. Any donor meeting at least one of the other criteria will be classified as an EDC donor. Hypothesis 1: Inhaled nitric oxide will improve overall outcome of liver recipients after EDC liver transplantation - Suppression of oxidative injury will improve graft function postoperatively as measured by International Normalized Ratio (INR) bilirubin, transaminases, and duration of hospital stay. Hypothesis 2: The mechanisms of therapeutic efficacy of inhaled nitric oxide is based on reduction in post-reperfusion oxidative injury as readily measured by the detectable changes in the protein and metabolic profiles in plasma of patients treated with inhaled-NO - Nuclear Magnetic Resonance (NMR)-based metabolic markers (xanthine end-products, lactate, and hepatic osmolytes) that are consistent with acute liver injury will be decreased in NO-treated recipients. - Protein markers of reperfusion injury (argininosuccinate synthase (ASS) and estrogen sulfotransferase (EST-1) will be greater in the plasma of patients who are not treated with inhaled-NO - Reduced oxidative injury will be reflected by a decrease in the number of mitochondrial peroxiredoxins isoforms and the number that are oxidized in NO-treated liver recipients.
Preterm infants are born with immature lungs and often require help with breathing shortly after birth. This currently involves administering 100% oxygen. Unfortunately, delivery of high oxygen concentrations leads to the production of free radicals that can injure many organ systems. Term and near-term newborns deprived of oxygen during or prior to birth respond as well or better to resuscitation with room air (21% oxygen) compared to 100% oxygen. However, a static concentration of 21% oxygen may be inappropriate for preterm infants with lung disease. Our study will investigate how adjusting the amount of oxygen given to sick preterm newborns will affect the ability to maintain a safe oxygen level in their blood. Each infant will be assigned to receive one of three treatments at birth. Resuscitation will either start with 21% oxygen and be increased if needed, 100% oxygen and be decreased if needed or 100% oxygen with no changes made (current standard of treatment). The first two groups will have adjustments in oxygen concentration as needed to reach a safe target range of blood oxygen saturation. We anticipate that preterm newborn infants resuscitated with higher oxygen concentrations will have higher than "normal" levels of oxygen in their blood while those resuscitated initially with lower concentrations of oxygen will be more likely to have "normal" oxygen levels in their blood. All premature infants will have a surface probe placed on the right hand to measure the saturation of blood with oxygen. Following the resuscitation, treatment will proceed as per standard of care until hospital discharge. All infants will be admitted to the neonatal intensive care unit given their prematurity. The purpose of this study is to investigate how safely restricting the amount of oxygen delivered to newborns during resuscitation will affect the amount of oxygen in their blood. Hypothesis: In this randomized control trial, infants resuscitated with a "low oxygen delivery (LOD)" strategy (initiation of resuscitation with 21% O2) will remain normoxemic for the greatest proportion of time during resuscitation and infants resuscitated with a "high oxygen delivery (HOD)" strategy (100% O2 used for the entire resuscitation) will be normoxemic for the smallest proportion of time during resuscitation.