View clinical trials related to Weaning Failure.
Filter by:Mechanical ventilation may be necessary to save the life of a patient due to an accident, pneumonia or surgery. The ventilator then temporarily takes over the function of the respiratory muscles. During treatment in the Intensive Care, the amount of support provided by the ventilator is usually lowered gradually, until the point that the patient can breathe unassisted once again. However, in a large fraction of patients (up to 40%) it takes days to weeks before the patient is able to breathe unassisted, even after the initial disease has been treated. This is called prolonged weaning. A possible cause of prolonged weaning is weakness of the respiratory muscles. The diaphragm, the largest respiratory muscle, can become weakened if it is used too little, much like all other muscles in the body. Additionally, damage and weakness of the diaphragm can occur when the diaphragm has to work excessively. Therefore, it is important that the diaphragm works enough; not so little that it becomes weakened, but not too much either. Measurements of pressure generated by the diaphragm are needed to determine the current level of diaphragm activity in a patient on mechanical ventilation. However, these measurements are rarely performed, because they are time-consuming and require placement of two additional nasogastric catheters. This is a shame, as adequate loading of the diaphragm might prevent development of weakness, leading to shorter duration of mechanical ventilation. Finding alternative measurements of diaphragm effort might be a solution to this problem. It has been hypothesized that the electrical activity of the diaphragm provides a reliable indication of diaphragm effort. This study aims to determine whether there is a correlation between pressure generation by the diaphragm and electrical activity of the diaphragm over a wide range of respiratory activity, from low effort to extreme effort, in healthy volunteers.
Predicting successful discontinuation from mechanical ventilation has been a focus of interest to all critical care physicians . Various weaning indices have been investigated to optimize the weaning process. Among them, the rapid shallow breathing index (RSBI) has gained wide use but it have different sensitivities and specificities. By substituting tidal volume (VT) with diaphragmatic displacement (DD) in the calculation of RSBI a new index (the diaphragmatic rapid shallow breathing index DRSBI) was proposed and it was independently associated with weaning failure and its accuracy for predicting weaning outcome is expected to be superior to the traditional RSBI.
Daily interruption of sedation is one of the modalities which is known to enhance early weaning and separation from mechanical ventilation . Daily sedation interruption is also known to help decreasing incidence of ventilator associated pneumonia. The new modality is no sedation.
Prolonged mechanical ventilation secondary to weaning failure demands a significant amount of intensive care unit (ICU) resources, thus increasing the economic burden of public healthcare costs. One of the proposed mechanisms accounting for weaning failure is the concept that excessive work of breathing for weak respiratory muscles during the liberation from mechanical ventilation compromises cerebral blood flow, thereby predisposing the brain to dysfunction. Restriction in brain perfusion could have an adverse impact on the function of the respiratory muscles by impairing the output of the respiratory centre thus promoting respiratory muscle fatigue, leading to weaning failure. Inspiratory muscle training (IMT) has been shown to improve the functional capacity of the inspiratory muscles in patients with respiratory muscle weakness whilst has been recently proposed as a possible additional component of weaning strategies. Therefore, this project aims to identify both a mechanism that might be linked to prolong ICU length of stay and that at the same time might be amenable to treatment.
This study is designed to determine whether maximal diaphragm thickening fraction measured by ultrasound during volitional maximal inspiratory efforts is a valid measure of diaphragm function in mechanically ventilated patients.
Noninvasive ventilation (NIV) weaning strategies differ considerably from one another. These strategies have yet not been compared to each other. Therefore, the investigators planned to perform a prospective, randomized, pilot study involving hypercapnic acute respiratory failure patients ready to be weaned off from NIV. The investigators are going to compare the success rate of NIV weaning and the duration of NIV after randomization between 3 NIV weaning methods: gradual decrease in duration of NIV or level of ventilator support, and abrupt discontinuation of NIV.
This study compares two opposite strategies of weaning from Mechanical Ventilation. One of them is Low Pressure Support Ventilation during 30 minutes and the other is T-Tube for 2 hours. The aim of the study is to know witch one has a higher successful extubation rate.
Mechanical ventilation is widely used for ICU patients as a lifesaving procedure. However, it is associated with several complications, such as ventilator-associated pneumonia and the increase of hospital morbidity and mortality. To avoid such complications, we need to wean these patients off the ventilator as soon as possible. This must however be done at the right time to avoid other complications, such as the need for re-intubation. For this reason, it is important to have a specific weaning protocol, which will reduce the time on mechanical ventilation, and avoiding the need for re-intubation and other complications. Recently, an argument has developed as to which weaning protocol would be more appropriated, and whether a computer driven weaning protocol could have better results than the conventional weaning protocols focusing on daily screening and daily interruption of sedation followed by a spontaneous breathing test. Our objective is to compare mechanical ventilation times, weaning success up to 48 hours after extubation, re-intubation rates between a group with computer driven weaning protocol (SmartCare) versus a weaning protocol with daily weaning screens and spontaneous breathing trials in ICU patients ventilated for more than 24 hours.
The purpose of this study is to determine whether, as compared with the Venturi mask, a nasal, high-flow oxygenation device (Optiflow) may reduce the extubation failure rate in patients needing oxygen therapy after extubation.
The main objective of the study is to examine the extent of agreement between patient and health care provider assessments of work of breathing and the association of agreement with demographic- and disease-related factors.