Active clinical trials for "Respiratory Distress Syndrome"

Compare ventilation parameters in Adaptative Support Ventilation mode to conventional mode, on intubated, ventilated and sedated patients, during their secondary transfer from an hospital to another, by a SMUR team.

The acute respiratory distress syndrome (ARDS) is a clinical syndrome characterized by an inflammatory pulmonary edema, severe hypoxia and endothelial and epithelial diffuse aggression. A European study estimated that this disease represents 7% of admissions to intensive care. Despite progress on the modalities of mechanical ventilation, mortality is always between 25 and 55%. The definition of this syndrome was recently amended by individualizing three sub groups based on the importance of hypoxemia (mild, moderate and severe). Achieving a bronchoalveolar lavage (BAL) by bronchoscopy remains a gold standard in the initial research of pulmonary infectious cause or secondarily face the suspicion of ventilator-associated pneumonia. Cardio pulmonary consequences of this act are not well known in patients with ARDS. The first studies on the consequences of a bronchoscopy on oxygenation of a patient breathing spontaneously have 40 years. More recent work showed a simple bronchoscopy could in the mechanically ventilated patient cause an average decrease of 26% from the base of PaO2, 10% of the mean arterial pressure (MAP) and a significant increase in cardiac output. The existence of ARDS was an independent risk factor associated with hypoxemia. A study by published in Crit Care Med in 1990 can serve as a reference in ventilated patients benefiting from BAL by bronchoscopy: in a subgroup of 26 patients, 23% of patients required an increase in the fraction of inspired oxygen (FiO2) post procedure. A study compared changes in PaO2/FiO2 after BAL with and without endoscopy among patients without (n = 23) or with pneumonia (n = 11): the decrease in PaO2/FiO2 was significant only in the "pneumonia" group. In a study of 30 patients ventilated but not hypoxic , PaO2 was still reduced by 20% 2 hours after the completion of a BAL in 40% of patients. A retrospective series of 99 ventilated patients but not hypoxic, shows that the BAL was well tolerated in accordance with a pre oxygenation procedure 15 min and by gradually decreasing the FiO 2 after the end of the procedure. BAL also appears well tolerated in a study of 12 patients ventilated under sedation and muscle relaxation, in shock and in need of positive expiratory pressure (PEEP) of at least 10 cm H2O but the authors show a decrease in PaO2 that extends well beyond the end of the intervention. Their conclusion is going to offer less invasive diagnostic techniques for patients with PaO2 less than 60 mm. No study has targeted the respiratory and hemodynamic consequences of this technique depending on the intensity of ARDS (mild, moderate or severe).

Acute lung injury (ALI) is caused by a wide variety of conditions, but always characterized by hypoxia and non-cardiogenic pulmonary edema. Current treatment of ALI is supportive and treatment of the underlying cause. New therapies to treat severe ALI have not been shown to improve survival, and are limited by financial and logistical resources. The investigators propose to investigate the role of inhaled sodium nitroprusside (iSNP) in ALI. Sodium nitroprusside (SNP) is a vasodilator. When inhaled, SNP may travel to areas of the lung participating in gas exchange, and cause the blood vessels surrounding these areas to enlarge. This may result in an increase of blood vessels to these areas of the lung, and improve oxygenation. Currently, iSNP has not been studied in the adult population. Therefore, this study is intended to find the safety profile of varying doses of iSNP.

Background: Lung contusion affects 17%-25% of adult blunt trauma patients, and is the leading cause of death from blunt thoracic injury. Statins are lipid-lowering drugs with recently suggested anti-inflammatory and antioxidant properties. Cyclo-oxygenase-2 (COX-2) is a key enzyme in the production of prostaglandins (PG), and evidence suggests that COX-2 plays an important role in the pathogenesis of acute lung injury (ALI). Aims: The current study aims at evaluating the beneficial effects of statins and COX-2 receptor inhibitors on ALI elicited by blunt trauma to the chest. Methods: After approval by the institutional ethics and a scientific committee, and obtaining informed consent , patients admitted to the emergency department (ED) due to blunt trauma with a diagnosis of lung contusion will be enrolled in the study.The effects of statins and COX 2 inhibitors on ALI will be assessed by recording clinical parameters and measuring inflammatory mediators levels in the serum and in the bronchoalveolar space. Expected results: The investigators expect to find that the proposed treatment will be effective in reducing ALI burden. The investigators also suppose that using a combination of those drugs will synergistically potentiate their effect on ALI.

Background: Ventilator induced lung injury (VILI) remains a problem in neonatology. High frequency oscillatory ventilation (HFOV) provides effective gas exchange with minimal pressure fluctuation around a continuous distending pressure and therefore small tidal volume. Animal studies showed that recruitment and maintenance of functional residual capacity (FRC) during HFOV ("open lung concept") could reduce lung injury. "Open lung HFOV" is achieved by delivering a moderate high mean airway pressure (MAP) using oxygenation as a guide of lung recruitment. Some neonatologists suggest combining HFOV with recurrent sigh-breaths (HFOV-sigh) delivered as modified conventional ventilator-breaths at a rate of 3/min. The clinical observation is that HFOV-sigh leads to more stable oxygenation, quicker weaning and shorter ventilation. This may be related to improved lung recruitment. This has however to our knowledge not been tested in a clinical trial using modern ventilators. Purpose, aims: To compare HFOV-sigh with HFOV-only and determine if there is a difference in oxygenation expressed as a/A-ratio and/or stability of oxygenation expressed as percentage time with oxygen saturation outside the reference range. To provide information on feasibility and treatment effect of HFOV-sigh to assist planning larger studies. We hypothesize that oxygenation is better during HFOV-sigh. Methods: Infants at 24-36 weeks corrected gestational age already on HFOV are eligible. Patients will be randomly assigned to HFOV-sigh (3 breaths/min) followed by HFOV-only or vice versa for 4 alternating 1-hours periods (2-treatment, double crossover design, each patient being its own control). During HFOV-sigh set-pressure will be reduced to keep MAP constant, otherwise HFOV will remain at pretrial settings. Outcome will be calculated from normal clinical parameters including pulx-oximetry and transcutaneous monitoring of oxygen and carbon-dioxide partial pressures.

Recruitment manoeuvres, consisting of sustained inflations at high airway pressures, have been advocated as an adjunct to mechanical ventilation in lung protective ventilation strategies to prevent the collapse of the lung. This study aims to determine the safety and efficacy of a recruitment manoeuvre, by considering its impact on gas exchange, hemodynamics and on the release of systemic inflammatory mediators.

Nearly forty years ago Berran and coworkers tested an analog oxygen controller to maintain incubator oxygen levels for infants suffering neonatal respiratory disease in order to prevent hyperoxia. There are at least three clinical issues that this technology addresses: the first is avoidance of episodic hyperoxia; the second is decreasing episodic hypoxia; and the third is lowering cumulative oxygen exposure. Clinical trials which have used target SpO2 ranging probably help improve all of these problems, but so far there have been no direct measurements of continuous arterial oxygen levels, nor clinical studies which establish the degree to which improving control over blood oxygen saturation decreases the cumulative amount of oxygen exposure. This study will address the later and is an important step in the process of incorporating closed-loop oxygen control technology as a routine standard of neonatal respiratory care. OBJECTIVES: PART 1: Test and modify the instruction set for the computerized oxygen controller to achieve a goal of less than six (6) operator required interruptions per hour for oxygen saturation deviations outside of study guidelines. PART 2: Perform a within patient cross-over trial of the computerized oxygen controller versus standard of care (the patient's care team adjusts the patient's oxygen level) and evaluate the area under the time curve for oxygen exposure between the two control methods. PART 3:(After successful completion of PART 2) Continuation of the within patient cross-over study with a randomized cross-over sequence. Studies will last 4 to 12 hours divided in two (2) equal time blocks with one cross-over to either automatic or manual control modes. Provision for up to an additional twenty (20) patients to be studied.

The early initiation of Airway Pressure Release Ventilation in multi-system trauma patients decreases the incidence and severity of acute lung injury and Acute Respiratory Distress Syndrome and allows faster recovery of lung function.

An informational evaluation of COVID-19 patients who receive low-level laser therapy in addition to a normal regimen of treatment for symptoms associate with COVID-19. Results are compared to statistical observations published in literature from patients receiving standard care for COVID-19 symptoms without low-level laser therapy.

Non-invasive Continuous Positive Airway Pressure (nCPAP) is widely recognized as an efficient respiratory support in infants with mild to moderate Acute Hypoxemic Respiratory Failure (AHRF). Its application results in alveolar recruitment, inflation of collapsed alveoli, and reduction of intrapulmonary shunt. nCPAP is traditionally delivered with nasal prongs, nasal/facial mask. CPAP by helmet was introduced more recently in the clinical practice. The helmet circuit was described in details in previously published studies. From a physiological point of view the helmet circuit could be considered the best system to deliver CPAP because of the following: 1) it is characterized by the lowest amount of leaks around the interface and mouth opening 2) airways are free from potentially obstructing devices (cannula) thus the resistance is minimized and 3) theoretically the pressure is more stable minimizing the leaks 4) it is comfortable and usually sedation is not needed. High Flow Nasal Cannula (HFNC) is increasing in use both in adults and pediatric population. HFNC could result in several clinical benefits by reducing inspiratory effort and work of breathing, increasing end-expiratory volume and CO2 wash-out for upper airways and creating a CPAP effects of 2-3 cmH2Oin the upper airways. This CPAP effect combined with an increase in CO2 wash-out and optimal airways humidification could decrease the respiratory work of breathing and improve gas exchange. However little is known about the optimal flow rate setting to improve the respiratory mechanics and gas exchange. Recent studies have reported that HFNC in nonintubated children improves oxygenation, reduces the respiratory drive and prevent reintubation in high patient risk. However all these physiological effects during HFNC therapy are only speculative. To address the question on the more efficient devices to support the child in the early phase of mild to moderate AHRF, the Authors designed a physiological randomized crossover study aimed at measuring the physiological effects of HFNC 2 and 3 l/Kg and helmet CPAP on the work of breathing (estimated by the esophageal Pressure Time Product, PTPes) in pediatric AHRF.