View clinical trials related to Mechanical Ventilation.
Filter by:In patients who are mechanically ventilated for more than 72 hours weaning failure is a common issue. The Spontaneous breathing trial (SBT) is often done to assess if the patient can be extubated with a high chance of success. However, re-intubation rates are between 15 - 20 % after a successful SBT. The rapid shallow breathing index (RSBI) is an important parameter used in an SBT. Because the high incidence of extubation failure (re-intubation within 48 hours) a search for a better parameter than the RSBI is warranted. Using the measured end-tidal oxygen (etO2) of mechanically ventilated patients it is possible to calculate the VO2, which is a measure of patient effort. The VO2 is a parameter with the potential to predict weaning success or failure, together with other parameters of patient effort like the work of breathing (WOB), pressure time product (PTP) and esophageal pressure swings, reflecting muscle strength of the diaphragm. Therefore, the investigators want to investigate if these parameters are associated with an SBT success or failure.
Sedatives and analgesics are usually given for analgesic, anxiolytic, or sedating purposes for patients with critical illness, while they inevitably inhibit respiratory and circulatory function. Sometimes, patients receive deep sedation to induce hypoventilation or suppress spontaneous respiratory effort. The sedation level in clinical practice is usually assessed with subjective sedation scoring systems, such as the Richmond Agitation Sedation Scale (RASS). However, studies have found that sedation depth based on RASS is not a reliable marker of respiratory drive during critical illness. In recent years, researchers have proposed to monitor the effects of sedatives and analgesics on respiratory indicators and to implement lung-protective sedation, such as P0.1, Pocc, Pmus, WOB, and PTP. However, different pharmacological characteristics, different depths of sedation, and different sedation regimens among different sedatives and analgesics make a great difference in their effects on respiration. Ciprofol is an analog of propofol, with increased stereoselective effects adding to its anesthetic properties, is increasingly used in the intensive care unit, but its effects on respiration are not well understood. Therefore, this study aims to investigate the effects of ciprofol on respiratory patterns, respiratory drive, and inspiratory effort in mechanically ventilated patients.
this study is to assess the hemodynamic profile of ketamine compared with propofol in critically ill, mechanically ventilated adult Patients study will be carried out on 100 mechanically ventilated patients who received one sedative agent propofol or ketamine The patients will be randomized into two equal groups to receive either ketamine or propofol Group 1 (Ketamine group): ketamine is initiated at 0.5 mg/kg/h and titrated by 0.25 mg/kg/h every 15 minutes to a maximum dosage of 4 mg/kg/h to achieve appropriate sedation. Group 2 (Propofol group): Propofol is initiated at 0.3 to 0.6 mg /kg/hr. and titrated by 0.3 to 0.6 mg/kg/h every 5 to 10 minutes up to a maximum dosage of 4.5 to 4.8 mg/kg/hr. to achieve appropriate sedation.
The goal of this randomized clinical cross-over trial is to compare power dissipation (Pd) during flow-controlled ventilation with either standard of low tidal volume ventilation or compliance guided individualization of ventilator settings. This study is performed in patients scheduled for open abdominal surgery and the primary and secondary outcome parameters are: - power dissipation [J/min] during ventilation calculated by integrating the hysteresis of the tracheal pressure-volume loop - applied mechanical power during ventilation calculated by published formulas [1] - oxygenation of the blood assessed by PaO2/FiO2 ratio - decarboxylation assessed by required respiratory minute volume to maintain normocapnia - comparison of respiratory variables in low tidal volume versus individualized ventilation Participants will randomly receive either low tidal volume (LTV) or individualized flow-controlled ventilation [2]. In the LTV group, the positive end-expiratory pressure will be set to 5 cmH2O and the peak pressure set to achieve a tidal volume of 7 ml/kg predicted body weight. In the individualized group positive end-expiratory and peak pressure will be titrated to achieve the highest compliance [2]. In both groups the flow will be set to achieve normocapnia (PaCO2 35-45 mmHg). After obtaining three consecutive measurements the ventilation strategy will be switched to the alternative regime in a cross-over design and again, three measurements recorded. The investigators hypothesize, that individualized ventilator settings are able to improve ventilation efficiency in terms of a lower required minute volume to maintain normocapnia and thus is able to reduce power dissipation during ventilation. Secondary endpoint will be a comparison of Pd to calculated mechanical power, as a currently accepted surrogate parameter for ventilation invasiveness [2] and also outcome predictor. Additionally, gas exchange parameters such as oxygenation and decarboxylation will be compared between low tidal volume and individualized ventilation.
This is a single-center, prospective, physiological study. The study will enroll the traumatic lung injury patient who has at least 2 rib fractures requiring mechanical ventilation being on partially assisted breathing mode and on activity as tolerated (AAT) order with or without C-collar. Once being confirmed to meet the inclusion criteria, the research team will apply the EIT on the patient and start recording as well as perform lung ultrasound in the specific areas of interest in the selected time points of the study. The MV ventilator setting and some vital sign data will be also collected at selected time points of study. The EIT will continuously record from 5 minutes when patient is on supine position, then the investigators will turn patient using positioning wedge pillow to the sides with 30-minute EIT recording each side, lastly, the investigators will turn patient back to supine and continuously record for 30 minutes. The study will use the same protocol to perform in 3 different settings of mechanical ventilation (weaning process) i.) during partially assisted breathing, ii.) during high setting of spontaneous breathing and iii.) during low setting of spontaneous breathing.
This study will investigate the distribution of gas during mechanical ventilation in patients undergoing robot assisted laparoscopic prostatectomy. The gas distribution of ventilation are monitored and data extracted using electric impedance tomography in different respiratory rates.
The goal of this clinical trial is to compare weaning from mechanical ventilation in critically ill children. The main questions it aims to answer are: - Will weaning with neurally adjusted ventilatory assist (NAVA) mode ventilation result in shorter ventilator day than synchronised intermittent mandatory ventilation (SIMV) mode? - Will weaning with NAVA mode ventilation result in shorter paediatric intensive care unit (PICU) length of stay than SIMV mode? Participants will be randomised to NAVA or SIMV group for weaning from mechanical ventilation, then PICU outcomes from both groups will be collected, analysed and compared.
The goal of this prospective observational study is to describe the incidence of reverse trigger (RT) in mechanically ventilated patients with diagnosis of acute respiratory distress syndrome (ARDS). The main questions it aims to answer are: - Real incidence of RT based on continuous monitoring - The response to mechanical ventilatiory adjustments Participants will be included as soon as neuromuscular blockers (NMB)/sedation is stopped or in case of spontaneous respiratory efforts detection, whatever happens first. Continuous monitoring will be performed by esophageal manometry until switch to a pressure support (spontaneous) mode, restart of deep sedation/neuromuscular blockers by medical indication, or death. In order to allow detection of possible RT in patients with ongoing sedation/NMB, mechanical ventilator waveforms will be screened every 1-2 hours by investigators and critical care physicians with at least 1 year of specific training in detection of dyssynchronies.
The aim of this study is to compare the efficacy of dexmedetomidine and propofol on decreasing stress in mechanically ventilated patients by using salivary alpha-amylase as a stress marker.
Carbon dioxide (CO2) pneumoperitoneum and clasp-knife positioning are commonly used to improve surgical access during robot-assisted laparoscopic urological surgery. However, these methods are sometimes associated with several unwanted cardiopulmonary effects such as increased mean arterial pressure, decreased pulmonary compliance and functional residual capacity, increased peak inspiratory pressure, and respiratory acidosis in association with hypercarbia. Volume-controlled ventilation (VCV) is the most commonly used method of ventilation during general anesthesia. It provides fixed minute ventilation and pulmonary resistance, which affect airway pressure. In pressure-controlled ventilation (PCV), constant inspiratory airway pressure can be achieved by decelerating the flow. However, minute ventilation is not fixed . CO2 pneumoperitoneum in the clasp-knife positioning can influence hemodynamic variables, including blood pressure, heart rate, and cardiac output. This is because changes in airway pressure affect intrathoracic pressure and the function of the heart itself. In this randomized study, we investigated the effects of VCV and PCV on peak inspiratory pressure during robot-assisted laparoscopic urological surgery involving CO2 pneumoperitoneum in the clasp-knife position.