View clinical trials related to Mechanical Ventilation.
Filter by:Sepsis leads to a deregulated host response that can lead to organ failure. During sepsis, experimental and clinical data suggest the occurrence of mitochondrial dysfunctions, particularly in circulating muscle and monocytes, which may contribute to organ failure and death. Lower respiratory infection is the leading cause of death from infectious causes. Mechanical ventilation (MV) is required in 20% of cases of bacterial pneumopathy with Streptococcus pneumoniae (S.p.) , with mortality reaching 50%. There are then frequently criteria for acute respiratory distress syndrome (ARDS), combining bilateral lung involvement and marked hypoxemia. Cyclic stretching of lung cells induced by MV causes sterile inflammation and tissue damage (i.e. ventilator-induced lung injury [VILI]), which can cause cellular dysfunction that alter the immune response, particularly during ARDS. This is why the application of a so-called protective MV is then required. However, this does not prevent about one-third of patients from showing signs of alveolar overdistension, as evidenced by an increase in motor pressure (MP) (MP≥ 15 cmH2O), associated with an increase in mortality. The deleterious effects of MV could be explained by the occurrence of mitochondrial abnormalities. Indeed, the cyclic stretching of lung cells leads to dysfunction in the respiratory chain and the production of free oxygen radicals (FOS), altering membrane permeability. These phenomena could promote VILI, facilitate the translocation of bacteria from the lung to the systemic compartment and lead to alterations in immune response. In our model of S.p. pneumopathy in rabbits, animals on MV develop more severe lung disorders (lack of pulmonary clearance of bacteria, bacterial translocation in the blood, excess mortality), compared to animals on spontaneous ventilation (SV). Intracellular pulmonary mitochondrial DNA (mtDNA) concentrations, a reflection of the mitochondrial pool, are significantly decreased in ventilated rabbits compared to SV rabbits and in infected rabbits compared to uninfected rabbits. At the same time, the mitochondrial content of circulating cells decreased early (H8) in all infected rabbits, but was only restored in rabbits in SV, those who survived pneumonia (Blot et al, poster ECCMID 2015, submitted article). These data suggest an alteration in the mechanisms that restore mitochondrial homeostasis (mitochondrial biogenesis and mitophagy) during the dual infection/MV agression, which may explain the observed excess mortality. Other work by our team illustrates the importance of these phenomena by showing in a mouse model of polymicrobial infection that inhibition of mitophagia in macrophages promotes survival (Patoli et al, in preparation). Human data on this subject are non-existent. The phenomena of mitochondrial dysfunction nevertheless deserve to be explored in humans during the combined MV/pneumopathy aggression in order to understand its possible impact on the effectiveness of the host's immune response. In a personalized medicine approach, these data would open up prospects for targeted therapies, capable of activating mitochondrial biogenesis and/or modulating mitophagia, to prevent organ dysfunction and mortality during severe CALs treated with antibiotic therapy.
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.
Aim of mechanical ventilation is to improve gas exchange and to unload the respiratory muscles delivering a form of mechanical support to the ventilation. At the same time, it is essential that the support is individually-tailored to avoid the development of muscular atrophy, a process called "ventilatory-induced diaphragm dysfunction" Aim of the present study is that the continuous ultrasonographic assesment of diaphragm function, as obtained by the device under investigation (DiaMon, Respinor AS, Oslo, Norway) is related to the degree of effort of inspiratory muscles, as measured by gold-standard indices such as esophageal and gastric pressure measurement. A secondary aim is that the data assessed by the device are related to a standard ultrasonographic examination performed by expert operators. In particular, we will enroll a population of critically ill patients undergoing mechanical ventilation in assisted mode, and we will perform a decremental pressure support trial, with the following aims: 1. to evaluate the performance of a continuous and automated device for the monitoring of diaphragm contractile activity, as compared to standard mechanical indices of respiratory effort such as the pressure-time product (PTP) 2. to evaluate the performance of a continuous and automated device for the monitoring of diaphragm contractile activity, as compared to the ultrasonographic assesment of muscle function performed by an expert operator.
ASV mode of ventilation is an automatic mode with closed-loop control used for mechanical invasive ventilation in intubated patients. It has been studied in adult patients but not in children. This interventional physiology study will include 40 children on mechanical invasive ventilation.
This clinical trial is aimed to show a spontaneous breathing trial using high flow oxygen therapy may lower weaning failure rate and reintubation rate than using T-piece.
The purpose of this study is to assess the left diastolic function at different levels of in patients affected by the acute respiratory distress syndrome (ARDS)
The purpose of this study is to assess the effect of different levels of PEEP on the cardiocirculatory system in patients affected by the acute respiratory distress syndrome (ARDS)
A multicentre quality control survey of home mechanical ventilation in patients. The prescribed ventilation settings, the settings of the ventilator control panel and the actual performance of the ventilator will be tested.
Although non-invasive mechanical ventilation (NIV) is the gold standard treatment for patients with acute exacerbation of COPD (AECOPD) who develop respiratory acidosis, failure rate are still high ranging from 5% to 40%. Recent studies have shown that the onset of severe diaphragmatic dysfunction (DD) during AECOPD increases risk of NIV failure and mortality in this subset of patients. Although the imbalance between the load and the contractile capacity of inspiratory muscles seems the main cause of AECOPD-induced hypercapnic respiratory failure, data regarding the influence of mechanical derangement on diaphragmatic performance in this acute phase are lacking. With this study we aim at investigating the impact of respiratory mechanics on diaphragm function in AECOPD patients who experienced NIV failure. AECOPD with respiratory acidosis admitted to the ICU of the University Hospital of Modena from 2017-2018 undergoing mechanical ventilation (MV) due to NIV failure were enrolled. The study protocol consisted of two consecutive phases; in the first step measurements of static respiratory mechanics and end expiratory lung volume (EELV) were performed after 30 minutes of MV in volume control mode. In the second step transdiaphragmatic pressure (Pdi) was calculated by means of a sniff maneuver (Maximal Pdi) after 30 minutes of spontaneous breathing trial. Linear regression analysis and Pearson's correlation coefficient was used to asses the association between Maximal Pdi values and static and dynamic mechanical features and the association between Maximal Pdi and Pdi/Maximal Pdi.
Inhomogeneous ventilation was more likely to happen in patients after general anesthesia. Inhomogeneous ventilation may associate with ventilator-induced lung injury. A large number of post-neurosurgical patients was delayed extubation and received mechanical ventilation, so that, inhomogeneous ventilation was more likely to happen in the population. Electrical impedance tomography (EIT) is an noninvasive, radiation-free, high temporal resolution, relatively cheap technique in monitoring ventilation distribution bedside. The investigators aimed to investigate the incidence of inhomogeneous ventilation and factors associated with inhomogeneous ventilation in post-neurosurgical patients under mechanical ventilation.