View clinical trials related to Ventilator-Induced Lung Injury.
Filter by:1. We collect lung tissues from patients with different ages and confirm that KLK8 expression is positively correlated with age. 2. We collect peripheral blood from patients with different ages and duration of mechanical ventilation to explore the correlation between the degree of endothelial/epithelial damage, age and duration of mechanical ventilation.
Lung protective ventilation with low tidal volumes and low driving pressure are known to reduce mortality in mechanically ventilated patients with acute respiratory failure. This reduction in mortality is known be due to reduction of ventilator induced lung injury that occurs due to high tidal volumes and high driving pressure. When receiving such mechanical ventilation, some patients develop hypercapnia and associated hypercapnic acidosis. Such patients have an increased risk of mortality. While the exact reasons for such increase in mortality is not known, it is recommended to minimise hypercapnia and hypercapnic acidosis during lung protective ventilation. Minimally invasive extracorporeal carbon dioxide removal (ECCO2R) devices are shown to reduce hypercapnia and hypercapnic acidosis. There are several devices that are currently available in the current clinical practice. However, the effect of these devices on reduction in ventilator induced lung injury is not clearly demonstrated. This study aims to assess the use of an ECCO2R device called Prismalung in reducing ventilator induced lung injury. PrismaLung is currently used in our intensive care unit. This assessment is done by measuring interleukins in bronchoalveolar lavage fluid and blood interleukin levels as well as clinical assessment including the reduction of driving pressure.
A project aimed at expanding the monitoring of mechanical energy (ME) in patients on mechanical ventilation (MV), with the aim of contributing to reducing the influence of the device for mechanical ventilation of patients on the lung parenchyma by setting parameters that will lead to lower ventilation energy. According to the parameters set on the device for mechanical ventilation, the mechanical energy will be calculated, which the physician in the interventional arm of the study will be able to use to change the mechanical ventilation settings. The physician will follow the best clinical practice, and in the non-intervention group, the MV setting will be conventional.
Mechanical ventilation may be associated with ventilator-induced lung injury (VILI). Several respiratory variables have been employed to estimate the risk of VILI, such as tidal volumes, plateau pressure, driving pressure, and mechanical power. This dissipation of energy during ventilation can contribute to VILI through two mechanisms, stress relaxation and pendelluft, which can be estimated at the bedside by applying an end-inspiratory pause and evaluating the slow decrease in airway pressure going from the pressure corresponding to zero flow (called pressure P1) and the final pressure at the end of the pause (called plateau pressure P2). The choice of measuring the end-inspiratory airway pressure (PawEND-INSP) at a fixed, although relatively early, timepoint, i.e., after 0.5 second from the beginning of the pause, as prescribed by the indications of the Acute Respiratory Distress Syndrome (ARDS) Network, while assessing the risk of VILI associated with the elastic pressure of the respiratory system, may not reflect the harmful potential associated with the viscoelastic properties of the respiratory system. It is still unclear whether an PawEND-INSP measured at the exact moment of zero flow (P1) is more reliable in the calculation of those variables, such as ΔP and MP, associated with the outcomes of patients with and without ARDS, as compared to the pressure measured at the end of the end-inspiratory pause (plateau pressure P2). This multicenter prospective observational study aims to evaluate whether the use of P1, as compared to P2, affects the calculation of ΔP and MP. The secondary objectives are: 1) verify whether in patients with a lung parenchyma characterized by greater parenchymal heterogeneity, as assessed by EIT, P1-P2 decay is greater than in patients with greater parenchymal homogeneity; 2) evaluate whether patients with both ΔP values calculated using P1 and P2 <15 cmH2O (or both MP values calculated using P1 and P2 <17 J/min) develop shorter duration of invasive mechanical ventilation, shorter ICU and hospital length of stay and lower ICU and hospital mortality, as compared to patients with only ΔP calculated with P1 ≥ 15 cmH2O (or only MP calculated with P1 ≥ 17 J/min) and patients with both ΔP values calculated using P1 and P2 ≥ 15 cmH2O (or both MP values calculated using P1 and P2 ≥ 17 J/min).
The goal of this study is to compare two different ways of helping patients with a condition called sepsis who need help breathing using a machine called a ventilator. The investigators want to study which way of setting the ventilator is better for the lungs. Here are the main questions the investigators want to answer: 1. How does the amount of air in the lungs and the way it moves differ between the two ways? 2. How does the way air spreads out in different parts of the lungs differ between the two ways? In this study, the investigators will take special pictures of the lungs using a machine called a CT scan. The pictures will show us how much the lungs stretch and how much air is in different parts of the lungs. The investigators will compare two different ways of using the ventilator: one personalized for each patient based on their breathing, and another way that is commonly used. By comparing these two ways, the investigators hope to learn which one is better for helping patients with sepsis who need the ventilator. This information can help doctors make better decisions about how to care for these patients and improve their breathing.
The goal of this physiological cross-over clinical trial is to evaluate the effect of different clinically used weaning trials on regional mechanical ventilation in a population of patients undergoing weaning from mechanical ventilation for acute respiratory failure. The main question[s] it aims to answer are: - to evaluate which weaning trial is associated to a better regional ventilation distribution - to evaluate which weaning trial can be comparable to ventilation distribution after extubation Participants will undergo 3 clinically used weaning trials in a random order (cross-over trial). Researchers will compare the different steps to see if regional ventilation distribution is different among the different trial .
Protective ventilatory strategy should be applied to reduce both ventilator-induced lung injury (VILI) and ventilator-induced diaphragm dysfunction (VIDD) after Lung Transplantation (LTx). Neurally Adjusted Ventilatory Assist (NAVA) is an assisted ventilation mode in which respiratory support is coordinated by the electrical activity of the diaphragm (EAdi). Aim of the study is to assess the physiological relationship between neural respiratory drive as assessed by EAdi and tidal volume, driving pressure and mechanical power, at different levels of ventilatory assist, in the absence of pulmonary vagal afferent feedback.
Some ICU ventilated patients might present with large tidal volume despite very low or inexistant presser support. Patient-Self Inflicted Lung Injury (P-SILI) might appear related with large alveolar stretch an distension. Two clinical presentations are observed: patients with or without respiratory distress signs such as supra-clavicular depression and thoracic-abdominal asynchronies. The aim of this study is to compare the pulmonary physio(-patho)logical parameters of these two types of patients (eupneic or with respiratory distress signs), and presenting important TV in spite of a minimal adjustment of the ventilatory support, except for Acute Respiratory Distress Syndrome (ARDS).
Improving the anesthesiology management for surgical correction of spinal deformations with introducing the diagnostic methods and treatment strategy of acute pain, preventing the evolution of chronic pain. Development and implementation in clinical practice perioperative intensive care protocols for surgical correction of spinal deformities.
The purpose of the study is to assess whether lung ultrasound is able to detect lung injury after lung resection surgery.