Active clinical trials for "Respiratory Distress Syndrome"

The global pandemic COVID-19 has overwhelmed the medical capacity to accommodate a large surge of patients with acute respiratory distress syndrome (ARDS). In the United States, the number of cases of COVID-19 ARDS is projected to exceed the number of available ventilators. Reports from China and Italy indicate that 22-64% of critically ill COVID-19 patients with ARDS will die. ARDS currently has no evidence-based treatments other than low tidal ventilation to limit mechanical stress on the lung and prone positioning. A new therapeutic approach capable of rapidly treating and attenuating ARDS secondary to COVID-19 is urgently needed. The dominant pathologic feature of viral-induced ARDS is fibrin accumulation in the microvasculature and airspaces. Substantial preclinical work suggests antifibrinolytic therapy attenuates infection provoked ARDS. In 2001, a phase I trial 7 demonstrated the urokinase and streptokinase were effective in patients with terminal ARDS, markedly improving oxygen delivery and reducing an expected mortality in that specific patient cohort from 100% to 70%. A more contemporary approach to thrombolytic therapy is tissue plasminogen activator (tPA) due to its higher efficacy of clot lysis with comparable bleeding risk 8. We therefore propose a phase IIa clinical trial with two intravenous (IV) tPA treatment arms and a control arm to test the efficacy and safety of IV tPA in improving respiratory function and oxygenation, and consequently, successful extubation, duration of mechanical ventilation and survival.

The coronavirus disease 2019 (COVID-19) has rapidly become a pandemic. COVID-19 poses a mortality risk of 3-7%, rising to 20% in older patients with co-morbidities. Of all infected patients, 15-20% will develop severe respiratory symptoms necessitating hospital admission. Around 5% of patients will require invasive mechanical ventilation, and up to 50% will die. Evidence in severe COVID-19 suggests that these patients experience cytokine storm and progressed rapidly with acute respiratory distress syndrome and eventual multi-organ failure. Early identification and immediate treatment of hyperinflammation is thus recommended to reduce mortality. Granulocyte Macrophage Colony Stimulating Factor (GM-CSF) has been shown to be a myelopoietic growth factor that has pleiotropic effects in promoting the differentiation of immature precursors into polymorphonuclear neutrophils, monocytes/ macrophages and dendritic cells, and also in controlling the function of fully mature myeloid cells. It plays an important role in priming monocytes for production of proinflammatory cytokines under TLR and NLR stimulation. It has a broad impact on the processes driving DC differentiation and affects DC effector function at the mature state. Importantly, GM-CSF plays a critical role in host defense and stimulating antiviral immunity. Detailed studies have also shown that GM-CSF is necessary for the maturation of alveolar macrophages from foetal monocytes and the maintenance of these cells in adulthood. The known toxicology, pharmacologic and safety data also support the use of Leukine® in hypoxic respiratory failure and ARDS due to COVID-19. This study aims to recruit patients with evidence of pneumonia and hypoxia who have increased risk for severe disease and need for mechanical ventilation. The overall hypothesis is that GM-CSF has antiviral immunity, can provide the stimulus to restore immune homeostasis in the lung with acute lung injury from COVID-19, and can promote lung repair mechanisms, which would lead to improvement in lung oxygenation parameters.

Whereas the pandemic due do Covid-19 continues to spread, the severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) causes Severe Acute Respiratory Distress Syndrome in 30% of patients with a 30%-60% mortality rate for those requiring hospitalization in an intensive care unit. The main physio-pathological hallmark is an acute pulmonary inflammation. Currently, there is no treatment. Mesenchymal stem cells (MSC) feature several attractive characteristics: ease of procurement, high proliferation potential, capacity to home to inflammatory sites, anti-inflammatory, anti-fibrotic and immunomodulatory properties. If all MSC share several characteristics regardless of the tissue source, the highest productions of bioactive molecules and the strongest immunomodulatory properties are yielded by those from the Wharton's jelly of the umbilical cord. An additional advantage is that they can be scaled-up to generate banks of cryofrozen and thus readily available products. These cells have already been tested in several clinical trials with an excellent safety record. The objective of this project is to treat intubated-ventilated patients presenting with a SARS-CoV2-related Acute Respiratory Distress Syndrome (ARDS) of less than 96 hours by three intravenous infusions of umbilical cord Wharton's jelly-derived mesenchymal stromal cells (UC-MSC) one every other day (duration of the treatment: one week). The primary endpoint is the PaO2/FiO2 ratio at day 7. The evolution of several inflammatory markers, T regulatory lymphocytes and donor-specific antibodies will also be monitored. The trial will include 40 patients, of whom 20 will be cell-treated while the remaining 20 patients will be injected with a placebo solution in addition to the standard of care. Given the pathophysiology of SARS-CoV2, it is thus sound to hypothesize that the intravenous administration of UC-MSC during the initial phase of ARDS could control inflammation, accelerate its recovery with improved oxygenation, reduced mechanical ventilation and ventilation weaning time and therefore reduced length of stay in intensive care. The feasibility of the project is supported by the expertise of the Meary Cell and Gene Therapy Center, which is approved for the production of Advanced Therapy Medicinal Products and has already successfully prepared the first batches of cells, as well as by the involvement of a cardiac surgery team which will leverage its experience with stem cells for the treatment of heart failure to make it relevant to the Stroma-Cov-2 project.

In this study, 120 patients with Acute Respiratory Distress Syndrome (ARDS) will be included on a two years-period in an intensive care unit (Assistance Publique des Hôpitaux de Marseille, France). Those patients will benefit from a blood test at inclusion in order to measure several coagulation biomarkers, including EV-TF. Subsequently, these patients will be treated according to the usual practices of the department, following recommendations. Patients who received an injected CT scan between Day 5 and Day 28 will be divided into two groups based on the presence or absence of a pulmonary embolism on imaging. The measured values of EV-TF levels and other studied biomarkers will be compared between these two groups in order to detect a possible association between them and the diagnosis of pulmonary embolism. It should be noted that patients receiving an injected CT-scan between Day 5 and Day 7 will be included in the main analysis while those receiving it between Day 8 and Day 28 will be included in the secondary analysis. Others will be excluded from any analysis. At the same time, several collections of clinical data will be carried out: on Day 1, Day 7, Day 28, and on the day of the CT scan if it is performed at another time.

Inhalation of toxic gases and chemical irritants during the fire leads to damage to the respiratory tract or the alveolar tissue, which is known as smoke inhalation injury. Acute Respiratory Distress Syndrome (ARDS) is associated with smoke inhalation injury. These patients usually need physiotherapy in the form of chest mobilization and breathing exercises for up to 4 to 6 weeks after discharge from the burns care centre. The patients during this phase are usually in pain and extremely anxious about these exercises. Virtual reality distraction (VRD) is one such technique that is gaining immense popularity recently, it has more immersive distraction when compared to traditional distraction techniques. This study aims to investigate the effect of a virtual reality distraction (VRD) technique as a pain alleviation tool for reducing pain during physiotherapy in burns patients with acute respiratory distress syndrome (ARDS) in a hospital setting.

Barotrauma (pneumothorax, pneumomediastinum) is a well-described complication of Acute Respiratory Distress Syndrome (ARDS), especially in patients with coronavirus disease 2019 (COVID-19) (16.1% in COVID-19, and about 6% in non-COVID-19 ARDS). Macklin effect was recently discovered by our group as an accurate radiological predictor of barotrauma in COVID-19 ARDS; the Investigators also found that density histograms automatically extracted from chest CT images provide a reliable insight into lung composition . Since lung frailty is a major issue also in non-COVID-19 ARDS, the Investigators want to confirm the predictive role of Macklin effect also in this setting. In addition, the Investigators aim to explore inflammatory profiling to decipher different biological aspects of the same clinical issue. Finally, the Investigators want to develop a specific management algorithm for patients diagnosed, according to our findings, with a specific ARDS sub phenotype characterized by increased lung frailty

Inhalation injury become a more common cause of death in burn patients but alone the smoke injury has low mortality rate. It is reported that a combination of smoke injury with cutaneous burn increases the mortality rate and predispose to Acute Respiratory Distress Syndrome. This experimental study aims to report the benefits of postural drainage on the respiratory system in burn patients. This study will determine the effects of postural drainage on oxygen saturation, airway clearance in burn patients with Acute Respiratory Distress Syndrome by comparing mechanical ventilation with and without the application of postural drainage. A randomized clinical trial will be conducted in the data and will be collected from the ICU of Jinnah Burn & Reconstructive Surgery Centre and Shafique Aziz Free Burn Centre through consecutive sampling through technique on 50 patients which will be allocated through sealed opaque enveloped into Group A and Group B. Pre and post treatment value of oxygenation and other variables for both group will be recorded by using APACHE II. Group A will be treated by postural drainage and mechanical ventilation for two consecutive days. Similarly, Group B will be treated by mechanical ventilation only. Data will be analyzed using SPSS software 25. After assessing the normality of data by the Shapiro-Wilk test, it will be decided either parametric or non-parametric tests will be used within a group or between two groups.

The m-CCRP randomized controlled trial will evaluate the efficacy of a collaborative critical care recovery program from acute respiratory failure (ARF) survivors in accomplishing the Institute of Healthcare Improvement's triple aims of better health, better care, at lower cost. Primary Aim: To assess the efficacy of m-CCRP in improving the QOL of ARF survivors compared to attention control at twelve months post hospital discharge. Secondary Aims: To evaluate the efficacy of m-CCRP in improving cognitive, physical, and psychological function of ARF survivors at twelve months post hospital discharge when compared to attention control. To evaluate the efficacy of m-CCRP in reducing health-care utilization, defined as time from enrollment to emergency department visits and/or hospital re-admission, by ARF survivors as compared to attention control at twelve months post hospital discharge.

Mortality of intubated acute hypoxemic respiratory failure (AHRF) and acute respiratory distress syndrome (ARDS) patients remains considerably high (around 40%) (Bellani 2016). Early implementation of a specific mechanical ventilation mode that enhances lung protection in patients with mild to moderate AHRF and ARDS on spontaneous breathing may have a tremendous impact on clinical practice. Previous studies showed that the addition of cyclic short recruitment maneuvers (Sigh) to assisted mechanical ventilation: improves oxygenation without increasing ventilation pressures and FiO2; decreases the tidal volumes by decreasing the patient's inspiratory drive; increases the EELV by regional alveolar recruitment; decreases regional heterogeneity of lung parenchyma; decreases patients' inspiratory efforts limiting transpulmonary pressure; improves regional compliances. Thus, physiologic studies generated the hypothesis that addition of Sigh to pressure support ventilation (PSV, the most common assisted mechanical ventilation mode) might decrease ventilation pressures and FiO2, and limit regional lung strain and stress through various synergic mechanisms potentially yielding decreased risk of VILI, faster weaning and improved clinical outcomes. The investigators conceived a pilot RCT to verify clinical feasibility of the addition of Sigh to PSV in comparison to standard PSV. The investigators will enrol 258 intubated spontaneously breathing patients with mild to moderate AHRF and ARDS admitted to the ICU. Patients will be randomized through an online automatic centralized and computerized system to the following study groups (1:1 ratio): PSV group: will be treated by protective PSV settings until day 28 or death or performance of spontaneous breathing trial (SBT); PSV+Sigh group: will be treated by protective PSV settings with the addition of Sigh until day 28 or death or performance of spontaneous breathing trial (SBT). Indications on ventilation settings, weaning, spontaneous breathing trial and rescue treatment will be specified.

Mechanical respiratory support of preterm neonates with respiratory distress syndrome (RDS) and/or apnoea of prematurity (AOP) might be associated with adverse effects due to positive pressure (barotrauma), excessive gas delivery (volutrauma) or inadequate volume (atelectrauma). Asynchrony between patient efforts and ventilator support increases patient discomfort, favouring "fighting" the machine, and increases the risk of air trapping and lung overdistension even in patients with non-invasive ventilation (NIV). Recently, a new modality of synchronization has been available for pediatric and neonatal use: the neurally adjusted ventilatory assist (NAVA), which uses the diaphragmatic electrical activity (Edi) as a signal to start the rise in pressure of the ventilator, and to adjust the tidal volume and the inspiratory time (cycling off) to the patient needs, breath by breath. The aims of this study are to know whether NIV-NAVA compared to unsynchronized modalities (nCPAP/nIPPV), in infants born < 32 weeks GA with respiratory distress syndrome or requiring prophylactic NIV (immaturity, apnoea) reduces systemic inflammation, measured by serum cytokines concentration, reduces the need for oxygen and respiratory support, and if it increases the probabilities of survival without bronchopulmonary dysplasia (BPD).