View clinical trials related to Acute Lung Injury.
Filter by:Acute respiratory distress syndrome (ARDS) is a serious disease with high mortality. In patients who survive ARDS, respiratory, neurological and motor sequelae are frequent, negatively impacting on the patient's quality of life, and engendering substantial healthcare costs (rehabilitation, long-term care, delayed return to work). There may also be repercussions on the patient's family and entourage. The severity of ARDS and the burden it represents have underpinned intensive research to identify treatment strategies that could improve mortality. However, it is important to ensure that any improvement in mortality does not come at the price of an excess of sequelae and disability in survivors. The oxygenation strategy used to treat ARDS may have an impact on mortality in these patients. The CLOSE study, in which our group participated, recently demonstrated the feasibility of two oxygenation strategies in intensive care unit (ICU) patients with ARDS. We have also initiated the LOCO-2 study (NCT02713451), whose aim is to show a reduction in mortality in ARDS using a "conservative" oxygenation strategy (PaO2 maintained between 55 and 70 mmHg) as compared to a classical "liberal" oxygenation strategy (PaO2 between 90 and 105 mmHg). The LTO-BLOXY study is a substudy of the on-going LOCO-2 study
Acute respiratory distress syndrome (ARDS) is a devastating inflammatory and destructive disease in critical ill patients. Preclinical studies have shown a promising perspective of mesenchymal stem cells (MSCs) therapies in ARDS. But the safety and efficacy of umbilical cord MSCs (UCMSCs) have not yet been convinced in clinical trails. This study will explore the safety and life-rescue potential of UCMSCs in refracotry ARDS.
In this study, the investigators aim to better characterize the outcomes of pediatric acute respiratory distress syndrome (PARDS) survivors, to examine whether subgroups of children with PARDS can be identified, and to determine whether an earlier diagnosis of PARDS using a computerized decision support system will improve the care of these children.
Previous studies have shown that a positive fluid balance was an independent factor of worse prognosis in ICU patients with acute respiratory distress syndrome (ARDS), and negative fluid balance has been demonstrated to increase oxygenation index, reduce time under mechanical ventilation and ICU length of stay with no noticeable adverse effects. But there is no evidence that faster speed of negative fluid balance would be more beneficial for ARDS patients. So researchers designed the study to prove the effect of negatively fluid balancing speed for ICU patients with ARDS.
Animal experimentals have shown that the more physiology-driven airway pressure release ventilation (APRV) methodologies in ARDS may significantly improve alveolar recruitment and gas exchange, increased homogeneity, and attenuate lung injury, without circulatory depression, as compared with conventional low tial volume lung protective ventilation. our previous single centre,random control study showed that clinical benefit for early use of APRV in ARDS. Nonetheless, clinical data on ARDS are still limited, most of them derived from small clinical trials in which variable outdated APRV settings were used, consequently, the findings of these studies were controversial. Additionally, the previous single-centre,random control study showed that clinical benefit for APRV.Therefore,the investigators are ready to design a multiple centres,random control study to further verify the effect of APRV plus protocol in ARDS.
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.
The aim is to test a device for applying continuous negative abdominal pressure in patients with ARDS
This is a feasibility study of the use of a novel technique called 'Inspiwave' to measure heart and lung function in adult patients in critical care. The preliminary work has already been undertaken in animal models and in healthy volunteers. The ultimate aim of this study is to develop a clinical tool for measuring (and therefore being able to make treatment changes based on) indices of heart and lung function in critical care patients. This study is the first assessment of the technique in this population, and whilst we know it works in patients undergoing general anaesthesia, we now need to assess whether Inspiwave can be used at all in critical care patients who may have much more physiological derangement. The purpose of this phase of the research is to determine whether it is feasible to use Inspiwave in critical care. Inspiwave generates a sinusoidally modulated tracer gas signal in the inspired air. It also measures the resulting signal in the expired air. The unique handling of this signal by the patient can used be to derive key variables related to cardiopulmonary function such as lung volume, pulmonary blood flow, the deadspace (wasted ventilation) and the degree to which ventilation and blood flow are non-uniform. These are 'vital signs' in sick patients, yet are currently technically difficult to measure, particularly non-invasively.
Community acquired pneumonia (CAP) is a major cause of morbidity and mortality worldwide. Despite recent improvement in acute management (specifically for administration of antibiotics) many severe presentations of pneumonia worsen, progressing to Acute Respiratory Distress Syndrome (ARDS), a clinical entity with 40% hospital mortality. Dysregulation of immune response is thought to be largely implicated in severe pneumonia progressing to ARDS. Notably, experimental studies have recently suggested the implication of non-conventional T lymphocytes and innate cells in this immunopathology. However, no data are available in Humans in clinical settings. This study aims to explore the role of non-conventional T cells in pneumonia and ARDS, in participants. For this purpose, 100 participants admitted to Intensive Care Unit (ICU) with a diagnosis of CAP will be included, and 50 "control" participants with no pneumonia nor shock. Presence and functionality of non-conventional T cells and innate cells will be explored using flow-cytometry and ex-vivo stimulation, alongside with cytokines productions. These analyses are conducted in the blood, and, for invasively ventilated participants, in tracheal aspirates or broncho-alveolar fluids if available. For each participants included, the analyses are conducted at different time-points during ICU stay: inclusion, day 3, day 8 and day 15. Moreover, participants with ARDS, for whom a post-ICU follow-up program is normally established after discharge, will have blood analysis from blood samples taken during the follow-up visit up to 8 months after inclusion. Immunophenotypage and functionality of non-conventional T cells and innate cells will be compared to clinical parameters and their evolution, between "CAP" participants and "Control" participants", and for each participants, according to the different time-point of analysis, in order to better understand dynamic of innate immunity during pneumonia and ARDS.
Acute respiratory distress syndrome (ARDS) in neonates has been defined in 2017.The death rate is over 50%. HFOV and CMV are two main invasive ventilation strategies. However, which one is better needing to be further elucidated.