Midazolam Whole Body Physiologically Based Pharmacokinetic Model
Respiratory FailureComaThis study investigates what independent variables may influence Midazolam Pharmacokinetics in critically ill patients.
Microcirculation in Venoarterial Extracorporeal Membrane Oxygenation Life Support
Heart FailureRespiratory FailureExtra-corporeal membrane oxygenation (ECMO) life support system can provide both cardiac and respiratory support to patients with heart and respiratory failure. It can save time for these organs to recovery or for these patients to receive further management. However, many patients will die in spite of ECMO support. One of the key factor is whether the blood flow provided by the ECMO can meet the requirement of organ perfusion. The adequacy of macrocirculation may be determined by arterial pressure and minute blood flow of ECMO. However, the adequacy of microcirculation remains as a major unresolved clinical problem. This is a prospective observational clinical trial. The sublingual microcirculation will be examined with the incident dark field video microscope within 6 hours after venoarterial ECMO placement, and then at 24 h, 48 h, 72 h, and 96 h. The severity of multiple organ injury and clinical data will be recorded as well. The major parameters of microcirculation include total small vessel density, perfused small vessel density, and microvascular flow index. The sublingual microcirculation will also be examined before weaning off ECMO, within 6 hours after ECMO removal, and then at 24 h, 48 h, and 72 h. Serum level of endothelial cell specific molecule-1 at specific time points will be examined. The data of 14-day mortality, 28-day mortality, duration of ECMO support, and intensive care unit stay will be recorded. This study aims primarily to investigate the relationship between microcirculation and prognosis of these patients. This study will also investigate the relationship among serum level of endothelial cell specific molecule-1, microcirculation, and prognosis of these patients. Wish the results of this study can be applied in further research to help to improve the quality of ECMO care.
Change of Regional Ventilation During Spontaneous Breathing After Lung Surgery
Pulmonary InfectionRespiratory Insufficiency3 morePerioperative changes in regional ventilation by pulmonary electrical impedance tomography and spirometry will be investigated in patients at risk for postoperative pulmonary complications. Those patients undergo lung and flail chest surgery.
Non-invasive Measurements of Elastance and Resistance
Respiratory InsufficiencyThe study aims to assess the agreement between respiratory mechanics parameters measured noninvasively by means of brief airways occlusions at the beginning of inspiration and the reference parameters obtained with standard techniques of esophageal and gastric pressure under static and dynamic conditions in a mixed population of ICU patients mechanically ventilated in pressure support ventilation mode.
Evaluation of Different Interfaces for Noninvasive Positive Pressure Ventilation (NPPV)
Respiratory FailureHealthyIn this study the investigators aimed to study the ventilatory performance of different interfaces during NPPV delivering.
Prediction of Outcome of Weaning From Mechanical Ventilation Using the Electrical Activity of the...
Respiratory InsufficiencySeveral types of spontaneous breathing trials (SBTs) have been proposed to evaluate when a patient is ready to be weaned from the ventilator based on breathing pattern measurements. The T-piece technique allows clinicians to calculate breathing patterns accurately but many prefer to use minimal levels of assistance, which unfortunately modifies breathing pattern. The interest of Neurally Adjusted Ventilatory Assist (NAVA) is that tidal volume (Vt) supposedly represents what the patient really wants: without disconnecting the patient from the ventilator, it may be possible to determine what is the real need and whether the patient is able to maintain Vt without support. The aims of the study are as follows: to test whether the changes in Vt after the removal of a standardized level of NAVA assistance (ΔVt) can predict weaning outcome; to compare the proposed titration of effort in NAVA (occlusion) with Patient-Ventilator Breath Contribution (PVBC) and titration using the Pmusc/Eadi index (PEI) relating the pressure generated by the respiratory muscles (muscular pressure; Pmusc) to the electrical activity of the diaphragm (EAdi); to assess the effect of PEEP on the change in Vt; and to evaluate EAdi after extubation. Patients ventilated for at least 24 hours who are ready to undergo an SBT will be included. Patients younger than 18 years of age and/or who have a contraindication to NAVA catheter insertion and/or surgical patients expected to be extubated within 12 hours will be excluded. After a baseline inclusion period with the pre-enrollment mode of ventilation, the standardized NAVA level will be applied for 20 minutes, during which both Patient-Ventilator Breath Contribution (PVBC) and PEI will be calculated. After the NAVA trial, a period of Continuous Positive Airway Pressure (CPAP) 5 (2-3 minutes) followed by a period of CPAP 0 (2-3 minutes) (both with NAVA gain 0) will be performed in order to record the difference with Vt during standardized NAVA (ΔVt). At the end of this period, the patient will be switched back to the baseline settings for 30 minutes-3 hours. After this period, the patient will perform an SBT with CPAP 0 or CPAP 5 for 1 hour. At the end of the SBT, the attending physician will decide whether or not to extubate the patient according to standard criteria and blinded to the ΔVt results. Ultimately, patients will be classified as "success" or "failure" and the ΔVt will be compared between these two groups.
Fourth International Study of Mechanical Ventilation From VENTILA GROUP
Acute Respiratory FailureMechanical Ventilation2 moreA prospective, international and multicenter, non interventional single-cohort study, which will enroll consecutive adult patients who have received mechanical ventilation (invasive and noninvasive ventilation) for at least 12 hours during a 1-month period, and will follow each patient for the duration of mechanical ventilation, up to 28 days. The main objectives will be to analyze the mortality and clinical outcomes in ventilated patients and secondly, to evaluate the practices of liberation from mechanical ventilation, the failure of non invasive ventilation in the ICU, and to analyze the clinical outcomes in specific populations of critically ill patients with the need of mechanical ventilation.
Clinical Evaluation of FreeO2 (Version 4) in All Patients Receiving Oxygen
Respiratory DiseaseRespiratory Failure3 moreEvaluation of automatic titration of oxygen with a new version of FreeO2 (V4)
Intra-operative Inspiratory Oxygen Fraction and Postoperative Respiratory Complications
Respiratory FailureAcute Respiratory Failure Requiring Intubation4 moreRespiratory complications represent the second most frequent type of postoperative complications with an incidence estimated to range from 2.0% to 7.9% It has been shown that intra-operative protective ventilation is associated with a reduced risk of respiratory complications. The effects of intra-operative inspiratory oxygen fraction (FiO2) remain to be investigated. In this study, the investigators aim to investigate the association between intra-operative FiO2 and respiratory complication as well as surgical site infection and ICU admission in patients undergoing non-cardiothoracic surgery. The investigators primary hypothesis is that high intra-operative FiO2 increases the risk of postoperative respiratory complications independent of predefined risk factors.
Noninvasive NAVA Versus Flow-triggered Noninvasive Pressure Support in Pediatric Respiratory Failure...
Acute Respiratory FailureAcute Hypoxemic Respiratory Failure (AHRF) is a leading cause of admission in Pediatric Intensive Care Unit (PICU). Traditional treatment includes endotracheal intubation and mechanical ventilation, that are invasive and not free from risks. Recent experiences from pediatric studies showed that Non-Invasive Pressure Support Ventilation (NIV-PS) has been associated with lower intubation rate, adverse events and mortality compared to mechanical ventilation delivered by an endotracheal tube. Nonetheless, in pediatric ARF, the application of a well-synchronized NIV-PS is technically challenging due to the presence of leaks and the age-specific characteristics of pediatric respiratory pattern (high respiratory rate, short inspiratory/expiratory time and weak inspiratory effort). Consequently, NIV-PS often results in difficult patient-ventilator interaction, with a failure rate up to 43% . Neurally Adjusted Ventilatory Assist (NAVA) is a new form of ventilatory assistance wherein the ventilator applies positive pressure throughout inspiration synchronously and proportionally to the Electrical Diaphragm activity (Edi). Thus, NAVA is not influenced by large leaks around uncuffed endotracheal tubes or noninvasive interfaces. Studies in intubated children found that NAVA improved interaction by reducing asynchronies and optimizing ventilator cycling.Two recent studies showed that the application of Non-Invasive NAVA (NIV-NAVA) in children with ARF is feasible and may reduce asynchronies as compared to NIV-PS. More recently, in a recent RCT of our group, we demonstrated that NIV NAVA in children was associated with lower asynchronies, longer synchronization time between patient and ventilator at lower peak and mean airway pressure. However no data are published to address the question if the better synchronization between patients and ventilator obtained with NIV NAVA could lead to a reduction in intubation rate and PICU outcomes. To address this question, we designed an observational retrospective study aiming to define if early delivered NIV NAVA could reduce intubation rate if compared with traditionally flow-cycled NIV PS in hypoxemic children admitted to PICU.