View clinical trials related to Lung Injury.
Filter by:The optimal amount caloric intake were still controversy in critically ill patients in literature. There were no significant outcome difference with different caloric intake in acute lung injury patients. In order to identify the optimal amount caloric intake in acute lung injury patients, we conduct a prospectively observational study to see whether the caloric differences influence hospital mortality.
Hematopoietic stem cell transplant (HSCT) is an effective but toxic therapy and pulmonary morbidity affects as many as 25% of children receiving transplant. Early pulmonary injury includes diffuse alveolar hemorrhage (DAH), thrombotic microangiopathy (TMA) interstitial pneumonitis (IPS) and infection, while later, bronchiolitis obliterans is a complication of chronic GVHD associated with severe morbidity and mortality. Improved diagnosis and treatment of pulmonary complications are urgently needed as survival after HSCT improves, and as HSCT is increasingly used for non-malignant disorders such as sickle cell disease. Currently, there are large and important gaps in the investigator's knowledge regarding incidence, etiology and optimal treatment of pulmonary complications. Moreover, young children unable to perform spirometry are often diagnosed late, and strategies for monitoring therapeutic response are limited. This is a prospective multi-institutional cohort study in pediatric patients undergoing allogeneic (alloHSCT) or autologous hematopoietic stem cell transplantation (autoHSCT). Assembly of a large prospective uniformly screened cohort of children receiving HSCT, together with collection of biological samples, will be an effective strategy to identify mechanisms of lung injury, test novel diagnostic strategies for earlier diagnosis, and novel treatments to reduce morbidity and mortality from lung injury after transplant.
This study will evaluate the use of N-acetyl cysteine in post-reperfusion pulmonary injury in patients with chronic thromboembolic pulmonary hypertension undergoing pulmonary balloon angioplasty and pulmonary endarterectomy. Half of the patients will receive N-acetyl cysteine and the other placebo.
Previous clinical trials in adults with acute respiratory distress syndrome (ARDS) have demonstrated that ventilator management choices can improve Intensive Care Unit (ICU) mortality and shorten time on mechanical ventilation. This study seeks to scale an established Clinical Decision Support (CDS) tool to facilitate dissemination and implementation of evidence-based research in mechanical ventilation of infants and children with pediatric ARDS (PARDS). This will be accomplished by using CDS tools developed and deployed in Children's Hospital Los Angeles (CHLA) which are based on the best available pediatric evidence, and are currently being used in an NHLBI funded single center randomized controlled trial (NCT03266016, PI: Khemani). Without CDS, there is significant variability in ventilator management of PARDS patients both between and within Pediatric ICUs (PICUs), but clinicians are willing to accept CDS recommendations. The CDS tool will be deployed in multiple PICUs, targeting enrollment of up to 180 children with PARDS. Study hypotheses: 1. The CDS tool in will be implementable in nearly all participating sites 2. There will be > 80% compliance with CDS recommendations and 3. The investigators can implement automatic data capture and entry in many of the ICUs Once feasibility of this CDS tool is demonstrated, a multi-center validation study will be designed, which seeks to determine whether the CDS can result in a significant reduction in length of mechanical ventilation (LMV).
Ventilator-induced lung injury is a common complication. The latest and most noticeable theory of its pathogenesis is called 'ergotrauma' by Gattinoni in 2016. The theory uses ventilator-imposed 'energy' or 'power' to encompass several known forms of injury-inducing factors such as pressure,volume, flow, rate, etc. However, to quantify power imposed by ventilator is no easy task in clinical practice. So, Gattinoni proposed a mathematical formula for easy power calculation. However, Gattinoni did not compare the difference between various etiologies of acute lung injury. We will enroll 100 patients (50 with acute respiratory distress syndrome and 50 with normal lung). The ventilator-imposed power at various tidal volume (6, 8, 10 ml/Kg) and positive end-expiratory pressure (5, 10 cmH2O) will be calculated by the formula. The area enclosed by hysteresis of pressure-volume curve, and hence the work it implies, will be measured as a standard. Our study will aim to compare the formula in different patient groups and in Taiwanese people.
In 1967, the term "respirator lung" was coined to describe the diffuse alveolar infiltrates and hyaline membranes that were found on postmortem examination of patients who had undergone mechanical ventilation.This mechanical ventilation can aggravate damaged lungs and damage normal lungs. In recent years, Various ventilation strategies have been used to minimize lung injury, including low tide volume, higher PEEPs, recruitment maneuvers and high-frequency oscillatory ventilation. which have been proved to reduce the occurrence of lung injury. In 2012,Needham et al. proposed a kind of lung protective mechanical ventilation, and their study showed that limited volume and pressure ventilation could significantly improve the 2-year survival rate of patients with acute lung injury.Volume controlled ventilation is the most commonly used method in clinical surgery at present.Volume controlled ventilation(VCV) is a time-cycled, volume targeted ventilation mode, ensures adequate gas exchange. Nevertheless, during VCV, airway pressure is not controlled.Pressure controlled ventilation(PCV) can ensure airway pressure,however minute ventilation is not guaranteed.Pressure controlled ventilation-volume guarantee(PCV-VG) is an innovative mode of ventilation utilizes a decelerating flow and constant pressure. Ventilator parameters are automatically changed with each patient breath to offer the target VT without increasing airway pressures. So PCV-VG has the advantages of both VCV and PCV to preserve the target minute ventilation whilst producing a low incidence of barotrauma pressure-targeted ventilation. Current studies on PCV-VG mainly focus on thoracic surgery, bariatric surgery and urological surgery, and the research indicators mainly focus on changes in airway pressure and intraoperative oxygenation index.The age of patients undergoing laparoscopic colorectal cancer resection is generally higher, the cardiopulmonary reserve function is decreased, and the influence of intraoperative pneumoperitoneum pressure and low head position increases the incidence of intraoperative and postoperative pulmonary complications.Whether PCV-VG can reduce the incidence of intraoperative lung injury and postoperative pulmonary complications in elderly patients undergoing laparoscopic colorectal cancer resection, and thereby improve postoperative recovery of these patients is still unclear.
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.
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.
Whilst deep vein thrombosis (DVT) is common following traumatic brain injury (TBI), optimal timing and safety of pharmacological prophylaxis is uncertain. Paradoxically the harm associated with the occurrence of is also unclear. This study is an observational pilot that aims to define the incidence of proximal DVT in patients with moderate to severe TBI. It seeks prospectively to determine if there is an association between DVT and outcome. It also seeks to explore possible associations between the occurrence of DVT and the incidence of lung injury and/or ventilator associated pneumonia.
Efforts to identify circulating factors that predict severity of acute lung injury/acute respiratory distress syndrome(ALI/ARDS)patients is unrevealing. The primary purpose of this study is to verify circRNAs and microRNAs might be potential novel ALI/ARDS biomarkers and could play roles in pathogenesis of ALI/ARDS.