Active clinical trials for "Lung Injury"

PISA is an ancillary study to the NIH funded clinical RESTORE Trial (U01 HL086622). This study will provide data that may allow for improved dosing recommendations in this critically ill population of children.

Acute lung injury in children is a syndrome of rapid onset of acute respiratory failure and require admission into intensive care units (ICU) for advanced life support. There are almost no information on epidemiology of acute lung injury. Published studies do not have information for an entire year and none of them have evaluated the degree of oxygenation failure under standard ventilator settings. The investigators will perform a 1-year prospective audit of all patients admitted with acute lung injury in a network of pediatric ICUs in Spain.

NFKB1 -94ins/del polymorphism has been reported to be associated with reduced promoter activity of NFKB1 and several clinical diseases, but the clinical results cannot always be replicated. Besides, mutate allele is associated with alleviated inflammation in ulcerative colitis and some tumors, but aggravated inflammation in ARDS. The clinical value of this polymorphism remains controversial. This study was performed to investigate the association of NFKB1 -94ins/delATTG polymorphism with lung and/or kidney injury after cardiac surgery with CPB.

Serum KL-6 protein has been described as a biomarker of epithelial lung injury in Respiratory Syncytial Virus bronchiolitis. The investigators can imagine that epithelial injury intensity has consequences on immediate and later respiratory prognosis. Furthermore, this prognosis seems to be different according to the respiratory causative virus. The investigators propose to study, during an epidemic season, the correlation between KL-6 levels and clinical severity, and the type of viral infection.

Given the possible prognostic relationship between exhaled breath condensate pH and clinical symptoms, it is quite plausible that exhaled breath condensate pH can prove useful in the intensive care unit. For example, if exhaled breath condensate pH falls prior to the onset of clinical symptoms, it is likely that it can be useful as an early marker, heralding the onset of various inflammatory lung diseases. Specifically, exhaled breath condensate pH could be used as a safe, non-invasive screening tool for Ventilator Associated Pneumonia. Similarly, just as changes in exhaled breath condensate pH might predict the onset of disease, exhaled breath condensate pH changes might also mark the progression or resolution of disease (e.g. alerting clinicians to possible readiness for extubation). Although such notions are hypothetical, they are beginning to be supported by anecdotal evidence.

The purpose of the study is to assess whether lung ultrasound is able to detect lung injury after lung resection surgery.

Metabolomics, or metabonomics, is a large-scale approach to monitoring as many as possible of the compounds involved in cellular processes in a single assay to derive metabolic profiles. Metabolomics allows for a global assessment of a cellular state within the context of the immediate environment, taking into account genetic regulation, altered kinetic activity of enzymes, and changes in metabolic reactions. Metabolomics may be useful for understanding metabolic imbalances and for diagnosis of human disease. The investigators plan to collect exhaled breath condensate from patients with acute lung injury. Metabolomic analysis in the patients may help us to explore some novel biomarkers for the disease diagnosis and outcome prediction.

The purpose of this prospective, randomized clinical trial is to understand and measure lung injuries caused by CPB in aortic valve surgery. Study questions: Is there any correlation between the release of pro-inflammatory biomarkers and lung injury degree? Is there any correlation between oxyhaemodynamic parameters and lung injury degree? Is there any correlation between oxyhaemodynamic parameters and the release of pro-inflammatory biomarkers? Are budesonide, erdostein and acetylcystein effective in the prevention of lung injuries?

Spontaneous breathing efforts in patients with respiratory failure connected to mechanical ventilation, has been associated with strong respiratory muscles activity. However, these mechanisms may will be present in patients with acute lung deseases who are breathing with no ventilatory support. We hypothesize that spontaneous breathing during acute respiratory failure could induced lung inflammation and worsen lung damage. Hereby, the connection to a ventilatory support tool, may protect the lungs from spontaneous ventilation-induced lung injury. To test our hypothesis, our aim is to determine the effects of spontaneous breathing in acute respiratory failure patients, on lung injury distribution; and to determine whether early controlled mechanical ventilation can avoid these deleterious effects by improving air distribution.

Profile known and novel biomarkers in blood in COVID19 patients to characterize the host response to SARS-CoV-2 over time and in response to treatment. The investigators aim to: Better understand the disease. The investigators will achieve this by characterizing the biology of COVID-19 infection and the pathophysiology of the host response using clinical data together with cellular and molecular measurements over the course of the disease. This will allow better insights for the discovery and development of novel therapeutics. Understand why different patients have different phenotypes and disease presentations over time. The investigators will achieve this by analyzing for patient subgroups. This will allow targeted patient stratification and better matching of resources. Understand how patients are responding to the different medications being tested in clinical trials. The investigators will achieve that by co-enrolling with therapeutic trials. This will allow an understanding of the biological effects of these interventions. Study Design: Observational adaptive study of a translational nature, combining clinical data and basic science investigations in blood samples in the same patients, longitudinally, with serial interim analyses. Primary outcomes: 90 day ICU mortality. Secondary outcomes: measures of ICU utilization and disease severity, and 90 day in-hospital mortality. The study ends after 3 months from admission to the ICU, hospital discharge or death. Location: St. Michael's Hospital (Unity Health Toronto), an academic center in downtown Toronto affiliated with the University of Toronto. The investigators will collect: A) Detailed clinical data including investigations, mechanical ventilation and cardiovascular parameters. B) Blood samples for state-of-the-art multi-omics biomarker discovery and development: cytokines, anti-COVID19 antibodies, autoimmune serology, metabolomics, transcriptomics, epigenomics, deep immune phenotyping, viral loads. For those patients who die with COVID19 The investigators will perform bedside post-mortem biopsies of lung, heart, kidney and muscle. Sampling times: From admission to the maximal severity phase through convalescence, in order to capture the evolution and dynamics of the disease and the recovery process: days 0,1, 3, 5, 7, 10, 15 and 22, and then every 2 weeks until the end of the study (3 months from admission to the ICU, hospital discharge or death).