Active clinical trials for "Lung Injury"

The investigators propose to perform a one-year prospective audit of all Acute lung injury (ALI)and cute respiratory distress syndrome (ARDS) pediatric patients managed in several ICUs in Spain. The investigators intend to collect data from all children (from 1 month to 18 years of age) admitted with or developing ALI/ARDS with the aim to understand the epidemiology and natural history of acute lung injury in the pediatric setting. These ICUs are scattered through the Spain and are representative of the demographic differences across the country.

Identify pediatric oncologic patients with ALI/ARDS at GRAACC/IOP's Pediatric Intensive Care Unit and evaluate the mechanical ventilation practice in these subjects for a 48mo period.

To survey the prevalence and the mortality of the Acute Lung Injury/ Acute Respiratory Distress Syndrome (ALI/ARDS) in 12 university hospital ICUs in Shanghai.

Patients admitted to Intensive Care Unit often are affected by acute respiratory failure at admission or during hospital stay, with a mortality of 30%. Treatment remains largely supportive with mechanical ventilation as the mainstay of management by improving the hypoxemia and reducing the work of breathing; however, the mechanical forces generated during ventilation can further enhance pulmonary inflammation and edema, a process that has been termed ventilator induced lung injury (VILI). Consequently, in clinical practice the lung protective ventilation is mainly based on the reduction of the tidal volume, the airway and the transpulmonary plateau pressure. A good clinical practice is based on the assessment of changes in respiratory mechanics. Aim of the study is to determine the accuracy of the OPTIVENT system in measuring transpulmonary pressure, comparing it with the systems currently in use in our Operative Unit.

As an important life sustaining support , mechanical ventilation has greatly promoted the development of modern intensive care units. However, mechanical ventilation can lead to ventilator-induced lung injury, including barotrauma, volutrauma, atelectrauma and biotrauma. All patients undergoing mechanical ventilation are at risk of barotrauma. A multicenter prospective cohort study of 5183 patients with mechanical ventilation showed that the incidence of pulmonary barotrauma was 3%. The incidence of pulmonary barotrauma varied according to the causes of mechanical ventilation: chronic obstructive pulmonary disease (3%), asthma (6%), chronic interstitial lung disease (10%), acute respiratory distress syndrome (7%) and pneumonia (4%). At present, it is considered that one of the main causes of barotrauma is the increasing of transpulmonary pressure. Transpulmonary pressure is the difference between alveolar pressure and intrapleural pressure. The commonly adopted lung protective ventilation methods include: limiting plateau pressure less than or equal to 30 cmH2O, using small tidal volume ventilation (6-8 mL/kg ideal body weight) . All the above methods are to reduce trans-pulmonary pressure by reducing alveolar pressure. In addition to reducing alveolar pressure, increasing pleural pressure is another important way to reduce transpulmonary pressure and the incidence of barotrauma. At present, the main method is the use of neuromuscular blockade. However, there are many shortcomings in of neuromuscular blockade: 1. Time limit, generally not more than 48 hours; 2. Long-term use of neuromuscular blockade causes adverse reactions such as myopathy; 3. Neuromuscular blockade are only suitable for invasive mechanical ventilation patients, but not for non-invasive mechanical ventilation or high flow oxygen inhalation patients. Therefore, it is urgent to find other methods to reduce trans-pulmonary pressure and lung injury. The investigators drew inspiration from the early mechanism of "iron lung" ventilator and the clinical practice of reducing trans-pulmonary pressure and lung injury in obese patients. In the early stage, the investigators carried out the clinical practice of extrapulmonary lung protection strategy, that is, to give thoracic band restraint to patients undergoing non-invasive mechanical ventilation so as to reduce chest wall compliance, which can be significantly reduced under the same inspiratory pressure and occurrence of barotrauma. However, the respiratory mechanics mechanism of this method still needs to be further studied to determine whether it can reduce the incidence of barotrauma by reducing transpulmonary pressure. It is accessible and inexpensive. The aim of this study was to determine the changes of transpulmonary pressure in patients with invasive mechanical ventilation before and after thoracic band fixation by esophageal manometry without spontaneous breathing.

The investigators decided to conduct a longitudinal study that compares the pulmonary tomographic patterns found in patients with viral pneumonia (i.e. influenza H1N1 and SARS-CoV-2) at a regional hospital. The primary aim of this study is to evaluate the association between the radiological CT pattern and the need for invasive mechanical ventilation. A secondary aim is to assess the mortality within the first 28 days of intensive care unit admission.

With the perception that lung protective ventilation with regard to low tidal volume ventilation and limiting airway pressures improves outcome in ARDS (acute respiratory distress syndrome) and that the development of new technical devices of extracorporeal lung assist systems with lower complication rates support establishment of lung protective ventilation strategies these systems are more and more frequently used. All critically ill patients with and without ECLA (extracorporeal lung assist)/ECMO (extracorporeal membrane oxygenation) treatment are on high risk for muscle wasting, leading to more comorbidity and higher mortality risk. Besides inflammation malnutrition is known as one of the main risk factors. Over and underfeeding should be prevented. However nutritional aspects of patients on extracorporeal lung assist are hardly investigated. Up to now changes in metabolic rates induced by ECLA/ECMO are poorly described. Factors like work of breathing, changes in cardiac output and septic state are influencing energy metabolism but until now there is no tool for measuring energy expenditure in clinical routine for patients on ECLA/ECMO. Indirect calorimetry is a simple device only for patients without ECLA/ECMO system. Oxygenation and CO2 (carbon dioxide) elimination by the lung assist system can be calculated but is not implemented to clinical routine. The combination of indirect calorimetry and calculation of lung assist function at the same time would give us the chance to adapt nutrition rates to energy expenditure. This may prevent muscle wasting and weakness. This pilot study will include 40 participating patients during 8 month investigating nutritional therapy adapted to energy expenditure calculated by O2 and CO2 turnover rates in patients on ECLA or ECMO systems. The investigators aim is to describe a calculation to set nutrition targets in ECMO patients. Second the investigators will describe level of nutritional needs under consideration of different mechanical ventilation states. Third O2 consumption and CO2 elimination will be used to estimate cardiac output.

In this study the investigators aim to compare two common methods to estimate the lung recruitment in ALI/ARDS patients.

To investigate the possible mechanisms of pulmonary and systemic permeability change including cytokine, extravascular lung water index (EVLWI), and oxygenation parameters in patients with sepsis related acute lung injury (ALI)/acute respiratory distress syndrome (ARDS).

Classically lung elastance and transpulmonary pressure are measured from the difference in tidal variations of airway pressure subtracted by tidal variations i esophagus pressure divided by the tidal volume. This requires the presence of a esophageal balloon catheter which is cumbersome and costly. In this study values obtained as described above are compared to values obtained with a new method in which a stepwise increase in positive endexpiratory pressure (PEEP) is performed with a size of the lung volume increase which corresponds to the tidal volume which the patient is ventilated with. The measurements are performed in sedated and mechanically ventilated patients in the intensive care unit.