Active clinical trials for "Lung Injury"

Aortic dissection (AD) is one of the most dangerous cardiovascular emergencies, with rapid onset, rapid progression, high fatality rate, and a variety of life-threatening complications. Acute lung injury (ALI) caused by AD is an important cause of many adverse outcomes. Studies have confirmed that 34.9% to 53.8% of AAD patients have ALI before surgery, and Impaired preoperative lung function may lead to worse oxygenation after AD surgery. The pathophysiological mechanism of AD-induced ALI is complex. A variety of preoperative and intraoperative risk factors can induce or aggravate ALI, such as ischemia-reperfusion injury, deep hypothermic circulatory arrest, and inflammatory reactions. At present, the clinical use of improved surgery, cardiopulmonary bypass perfusion, early anti-inflammatory treatment, and protective lung ventilation can reduce and improve perioperative ALI to a certain extent, but it is still not ideal. In recent years, inhibition of neutrophil activation and aggregation, and reduction of neutrophil elastase activity as targets for the treatment of inflammatory injury have also become an important clinical treatment measure, in order to further reduce the body's inflammatory response to improve and alleviate ALI. Sivelestat sodium, as a neutrophil elastase inhibitor, is the only approved therapeutic drug for ALI/ acute respiratory distress syndrome (ARDS) in the world. It is precisely by reducing the inflammatory infiltration of neutrophils and inhibiting neutrophil elastase activity, thereby exerting a certain protective effect on the lungs. The study takes patients with AD surgery as the research object. On the basis of not terminating and changing the original treatment plans, sivelestat sodium was added in the perioperative period to observe the incidence, and severity of ALI/ARDS in the perioperative period. It aims to explore the efficacy and safety of sivelestat sodium in the treatment of pulmonary insufficiency after AD arch surgery under hypothermic circulatory arrest.

The dearth of Intensive care units in low resource settings portends for poor outcomes amongst patients with acute hypoxemic respiratory failure (AHRF) . To our knowledge, the effect of CPAP and HFNC on major outcomes has not been assessed in adults with AHRF in resource-limited settings. The aim of this prospective, multicenter, randomized, controlled, trial is to determine whether High-flow oxygen through a nasal cannula (HFNC) or Continuous positive airway pressure (CPAP) system can reduce mortality among patients with acute hypoxemic respiratory failure (AHRF) in a limited resource setting as compared with standard low flow oxygen therapy?

This is an observational - data and specimen collection study. There have been increasing reports of vaping-induced lung injury, including severe lung injury and rare cases of death. The mechanism by which vaping contributes to lung injury in susceptible persons is unknown, as is impact on chronic lung disease. The investigators aim to identify individuals with chronic electronic nicotine delivery device (ENDD) exposure and matched controls within our ongoing cohort of HIV+ and HIV-uninfected individuals, collect PFT data, bank respiratory and stool samples and collect clinical data for studies of clinical risk, inflammation, biomarkers, and the microbiome in the identification and modification of risk of progression to lung injury or chronic pulmonary disease.

In patients with acute hypoxemic respiratory failure (AHRF), High Flow Nasal Therapy (HFNT) improves oxygenation, tolerance, and decreases work of breathing as compared to standard oxygen therapy by facemask. The hypothesis is that this flow challenge (ROX index variation from 30 to 60L/min) could be used as a test for assessing changes in lung aeration, analyzed by the variation in end expiratory lung volume (ΔEELV), in patients treated with HFNC. It may allow to personalize the flow settings during HFNC. In this sense, an increase in EELV will be observed with higher flows in responders and, therefore, these participants may benefit from increasing the flow. In contrast, to increase the flow in non-responders (no significant increase in EELV with higher flows) increase the risk of patient self-inflicted lung injury (P-SILI).

Lung protective ventilation (LPV) has been proposed to reduce the incidence of postoperative pulmonary complications (PPCs), and protect against ventilator induced lung injury (VILI).

The purpose of the study is to evaluate the efficacy of voxelotor for increasing oxygen saturation in 20 patients with hypoxemia. Specifically, the SpO2/FiO2 ratio will be compared before and after voxelotor use at rest and during exercise (ambulatory patients only). The primary study objective is to evaluate the efficacy of voxelotor for increasing oxygen saturation in patients with hypoxic hypoxemia as a result of end-stage lung disease or acute lung injury. The secondary objective is to evaluate the efficacy of voxelotor on allowing de-escalation of supplemental oxygen support.

Respiratory failure occurs when the lung fails to perform one or both of its roles in gas exchange; oxygenation and/or ventilation. Presentations of respiratory failure can be mild requiring supplemental oxygen via nasal cannula to more severe requiring invasive mechanical ventilation as see in acute respiratory distress syndrome (ARDS).It is important to provide supportive care through noninvasive respiratory support devices but also to minimize risk associated with those supportive devices such as ventilator induced lung injury (VILI) and/or patient self-inflicted lung injury (P-SILI). Central to risk minimization is decreasing mechanical stress and strain and optimizing transpulmonary pressure or the distending pressure across the lung, minimizing overdistention and collapse. Patient positioning impacts ventilation/perfusion and transpulmonary pressure. Electrical impedance tomography (EIT) is an emerging technology that offers a noninvasive, real-time, radiation free method to assess distribution of ventilation at the bedside. The investigators plan to obtain observational data regarding distribution of ventilation during routine standard of care in the ICU, with special emphasis on postural changes and effects of neuromuscular blockade, to provide insight into ventilation/perfusion matching, lung mechanics in respiratory failure, other pulmonary pathological processes.

Mechanical ventilation can lead to diaphragm and lung injury. During mechanical ventilation, the diaphragm could be completely rested or it could be overworked, either of which may cause diaphragm injury. Mechanical stress and strain applied by mechanical ventilation or by the patient's own respiratory muscles can also cause injury to the lungs. Diaphragm and lung injury are associated with increased morbidity and mortality. Throughflow is a novel system that can reduce dead space without the need to increase the tidal ventilation, reducing the ventilatory demands and respiratory drive.

Compared with the information available in sepsis and trauma-associated ARDS, less is known about the cause and pattern of lung injury after thoracic surgery. Definition of lung injury in this context is difficult. Most now use the joint North American-European consensus conference definitions, but these are based only on gas exchange and radiology criteria. While gas exchange measures are reliable, thoracotomy inevitably causes radiological change and the interpretation of plain chest films becomes subjective. Definitions based on permeability and inflammatory changes would improve diagnosis, but are not routinely available in most units. Pressure-controlled volume (PCV) may be useful to improve gas exchange and alveolar recruitment with associated lower airway pressures and shunt fraction during one-lung ventilation (OLV). However, a recent prospective randomized study of the effects of PCV during OLV did not lead to improved oxygenation during OLV compared with VCV, but PCV did lead to lower peak airway pressures. To date, there are no reports of the effects of PCV versus VCV during OLV on the acute lung injury (ALI) after thoracotomy.

This study plans to learn more about people who are sick in the hospital with a lung infection, or respiratory failure. Respiratory failure, or severe lung failure, is a life-threatening disease. When it happens, the lungs have trouble carrying out their normal function of getting oxygen into the blood, and removing carbon dioxide from the body. Investigators are conducting this study to see what drinking too much alcohol, using tobacco products, or using drugs (both legal and illegal) may do to lung infections and respiratory failure. Subjects are asked to be in this research study because they are thought to have a lung infection and may also have respiratory failure. Alcohol, tobacco, and drug use have been linked to lung infections, respiratory failure, and even death, but the reasons for this aren't known. People who use unhealthy amounts of alcohol, tobacco, and or drugs may be more at risk for lung infections, and for severe complications due to lung infection. Subject participation is important whether or not you use alcohol and or drugs.