View clinical trials related to Mechanical Ventilation.
Filter by: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.
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)
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.
Goal of this study is to determine optimal PEEP levels for patients undergoing surgery in lateral decubitus position. Patients will be randomized into 3 groups - PEEP 0, 5 and 10 mbar. Endotracheal anesthesia will be conducted with propofol, fentanyl, rocuronium and sevoflurane/O2/air gas mixture. Patients with preexisting lung disease, organ transplants and disseminated malignant disease will be excluded. Demographic data - age, weight, height, ASA status, smoking history will be recorded. EIT measured parameters - tidal variation ratio of nondependent and dependent lung, regional end-tidal and end-expiratory lung impedances as well as horizontal and vertical centers of ventilation will be recorded and calculated at 3 time points - before anesthesia induction, 5 minutes after lateral positioning of the patient and 90 minutes after lateral positioning. ABGs will be sampled to calculate aA gradient and Horovitz quotient at those time points as well as measured hemodynamic parameters (HR, BP, CI, SVI). Primary endpoints for the study are nondependent/dependent tidal variation ratios measured at predefined time points and changes in ABGs. Secondary endpoints are number of postoperative pulmonary complications (defined as new onset of pneumonia during 28 days of followup), length of hospital stay and changes in hemodynamic parameters.
In intensive care unit (ICU), mechanical ventilation (MV) is part of routine care. Weaning phase is a daily preoccupation for the caregivers. Prolonged MV can lead to many complications. Failing the weaning phase expose the patient to the need for reintubation, that improves the mortality. The caregiver faces a major problem, in one hand the need to wean properly and quickly and on the other the risk of reintubation. In order to help the clinician making the good choice, the spontaneous breathing trial (SBT) is a key tool. The international literature provides the investigators many ways to perform the SBT. The most common is the T-piece; the patient is disconnected from the ventilator and connected to a T-piece that can provide supplemental oxygen. Another one is the Support pressure trial, the patient is still connected to the ventilator, but the setups are changed to recreate the T-piece conditions. In many French ICU's, the SBT is performed by using a heat humidifier filter that is directly connected to the endotracheal tube, this filter allows the clinician to provide supplemental oxygen in accordance with the patient need. In high risk for reintubation patients, the SBT can create physical stress, that lead to prolonged MV. In our ICU, for those patients, the investigators perform the SBT by connecting the patient to a device that provides high flow oxygen trough endotracheal connector for tracheotomy. The investigators hypothesis that high flow oxygen SBT, will allow the high risk for reintubation patients to succeed the SBT.
The investigators hypothesis is that the adjustment of the inspiratory time may optimize the distribution of ventilation and increase tidal volume, producing potential therapeutic effects on the displacement of secretions and respiratory mechanics. The objective of this study was To evaluate the effects of hyperinflation with the ventilator associated with increased inspiratory time on respiratory mechanics.
Ultrasonography is a commonly used diagnostic and procedural adjunctive modality in intensive care. Weaning of neurosurgical patients off ventilatory support is a critical procedure, fraught with risks of hypoxia and hypercapnia. Weaning involves sequential reduction of ventilatory support and regular assessments for extubation followed by spontaneous breathing trials. In this study, we evaluate parameters of ultrasonographic evaluation of lung aeration and cardiac function in neurosurgical patients undergoing weaning and their ability to predict successful weaning and extubation.
Among critically ill patients requiring mechanical ventilation and catecholamines for shock, nearly 40% to 50% die, and functional recovery is often delayed in survivors. International guidelines include early nutritional support (≤48 h after admission), 20-25 kcal/kg/d at the acute phase, and 1.2-2 g/kg/d protein. These targets are rarely achieved in patients with severe critically illnesses. Recent data challenge the wisdom of providing standard amounts of calories and protein during the acute phase of critical illness. Studies designed to improve enteral nutrition delivery showed no outcome benefits with higher intakes. Instead, adding parenteral nutrition to increase intakes was associated with longer ICU stays and more infectious complications. Studies suggest that higher protein intakes during the acute phase may be associated with greater muscle wasting and ICU-acquired weakness. The optimal calorie and protein supply at the acute phase of severe critical illness remains unknown. NUTRIREA-3 will be the first trial to compare standard calorie and protein feeding complying with guidelines to low-calorie low-protein feeding potentially associated with improved muscle preservation, translating into shorter mechanical ventilation and ICU-stay durations, lower ICU-acquired infection rates, lower mortality, and better long-term clinical outcomes. This multicentre, randomized, controlled, open trial will compare, in patients receiving mechanical ventilation and treated with vasoactive agent for shock two strategies for initiating nutritional support at the acute phase of ICU management (D0-D7): early calorie/protein restriction (6 kcal/kg/d/0.2-0.4 g/kg/d, Low group) or standard calorie/protein targets (25 kcal/kg/d/1.0-1.3 g/kg/d, Standard group). Patients in both groups will receive enteral or parenteral nutrition appropriate for their critical illness. Two alternative primary end-points will be evaluated: all-cause mortality by day 90 and time to discharge alive from the ICU. Second end-points will be calories and proteins delivered, nosocomial infections, gastro-intestinal complications, glucose control, liver dysfunctions, muscle function at the time of readiness for ICU discharge and quality of life at 3 months and 1 year after study inclusion.
The Rapid Shallow Breathing Index (RSBI) is the ratio between respiratory rate (RR) and tidal volume (VT). It is routinely used to predict mechanical ventilation weaning outcome in ICU patients. However RSBI doesn't reflect the muscular contribution of diaphragm or accessory muscles in generating tidal volume. Actually, diaphragmatic dysfunction can even delay weaning process, because accessory muscles are more fatigable than the diaphragm. Hence, the investigators hypothesized that diaphragmatic displacement (DD) could be associated with RSBI in a new index named Rapid Shallow Diaphragmatic Index (RSDI) such as: RSDI = RSBI/DD. The aim of this study is to compare the ability of the RSDI versus the traditional RSBI to predict weaning success in ready-to-wean patients.