View clinical trials related to Mechanical Ventilation.
Filter by:The purpose of this study is to investigate the efficacy and safety of a low dose ketamine infusion used in combination of standard of care in critically ill patients to test whether ketamine can help to shorten the time of being in breathing tube and ventilator compared to the standard of care alone.
Mortality rates in children with pediatric acute respiratory distress syndrome (PARDS) are higher in Asia compared to other regions. In adults with acute respiratory distress syndrome, the only therapy that improves mortality rates is a lung protective ventilation strategy. The pediatric ventilation recommendations are extrapolated from evidence in adults, including ventilation with low tidal volume, low peak/plateau pressures and high-end expiratory pressure. A recent retrospective study of ventilation practices in Asia showed varying practices with regards to pulmonary and non-pulmonary therapies, including ventilation. This study aims to determine the prevalence and outcomes of PARDS in the Pediatric Acute and Critical Care Medicine Asian Network (PACCMAN). This study will also determine the use of pulmonary (mechanical ventilation, steroids, neuromuscular blockade, surfactant, pulmonary vasodilators, prone positioning) and non-pulmonary (nutrition, sedation, fluid management, transfusion) PARDS therapies. To achieve this aim, a prospective observational study which involves systematic screening of all pediatric intensive care unit (PICU) admissions and collection of pertinent clinical data will be conducted. Recruitment will be consecutive and follow up will continue to intensive care discharge.
Background: Delirium is a common acute confusion state in patients in intensive care units (ICUs). It has been linked to poor clinical prognoses (e.g., prolonged ICU stay) in critical patients. Furthermore, it might connect with long-term cognitive dysfunction. Mostly, pharmacological treatments have been frequently prescribed for preventing ICU delirium; however, their side effects might subsequently increase the risks of ICU delirium. Therefore, developing an effective non-pharmacological intervention of preventing delirium among critically mechanical ventilated patients is of clinical relevance. Purposes: To examine the effects of music intervention on reducing delirium in mechanically ventilated critical patients, to determine its beneficial effects on delirium-related outcomes, including sedation time, the duration of mechanical ventilation, and the length of ICU stay, and to compare the change of heart rate variability between groups.
The study Short description of the protocol intended for the lay public. Include a brief statement of the study hypothesis. (Limit: 5000 characters) Neuromuscular blocking agents (NMBAs) are drug capable of inducing a complete paralysis of the muscle. Their use is frequent in the intensive care unit (ICU). Most of the time it is used as a single infusion to facilitate endotracheal intubation, but in the ICU the use of continuous infusion is common in several pathologies: acute distress respiratory syndrome, post-cardiac arrest survivor under hypothermia to prevent shivering, abdominal compartment syndrome, severe traumatic brain injury with uncontrolled intra-cranial pressure and severe asthma among others. A monitoring of the dose of NMBAs is recommended to guide the depth of paralysis and to guide recovery, but in the ICU, the interest of such a monitoring during continuous infusion is unclear and the level of evidence is low. The investigators propose to conduct a prospective multicentric observational study to describe the current practice in the use of NMBAs in mechanically ventilated patients in the ICU. As a primary objective we will describe the prevalence of NMBAs use in the ICU. As a secondary objective, the investigators will investigate the impact of protocol and/or monitoring devices of NMBAs on the dose administered and clinical outcome endpoints.
Critically ill patients under mechanical ventilation (MV) have pain, anxiety, sleep deprivation and agitation. The use of analgesics and sedatives drugs (sedoanalgesia) is a common practice to produce pain relief and comfort during the VM. Despite its usefulness, it has been documented that the excessive use of sedatives is associated with an increased risk of prolonging the stay under MV and in the Intensive Care Unit (ICU). To avoid this, current evidence suggests the use of protocols guided to clinical goals, such as the sedation-agitation scale (SAS), or daily suspension of infusions to avoid excess sedation. These protocols minimize the prescription of deep sedation, which is still necessary for 20-30% of patients. Monitoring of sedation with electroencephalography in the ICU has been underutilized. In fact, only the use of indices that are generated from algorithms of the electroencephalographic signal processing has been reported. However, it has been shown that the use of these monitoring systems does not benefit the heterogeneous groups of patients in MV. Currently, the clinical monitors used to measure the effect of drugs used in a sedoanalgesia show in the screen the spectrogram of the brain electrical signal and quantify the frequency under which 95% of the electroencephalographic power is located, known as spectral edge frequency 95 (SEF95). This value in a person who is conscious is usually greater than 20 Hz, in a patient undergoing general anesthesia it is between 10 and 15 Hz. In preliminary measurements, in deeply sedated patients in the ICU, SEF95 values are under 5 Hz. This would indicate that patients in the ICU are being overdosed. It is unknown if in cases with an indication of deep sedation, the use of monitoring by spectrogram is superior to the standard management guided at clinical scales, such as SAS. Therefore, the investigators propose the following hypothesis: In patients with an appropriate indication of deep sedation (SAS 1-2), the sedoanalgesia guided by the spectral edge frequency 95 reduces the consumption of propofol compared to the deep sedoanalgesia guided by the sedation scale agitation in MV patients in the ICU maintaining a clinically adequate level of sedation.
Volume expansion is one of the main treatments for shock. A test to predict the effectiveness of volume expansion prior to administration would avoid the need for excess treatment if it proves to be unnecessary.PEEP test would be an easy alternative to the tests used in current practice.
The researchers hypothesized that the aid of the resuscitator by the technique Air Stacking increase lung volume, promoting increased lung compliance and improvement of the ventilatory pattern. In addition, Air Stacking does not depend on patient collaboration. The objective of this study was to compare the effects of breath stacking and air stacking techniques on respiratory mechanics and ventilatory pattern in patients admitted to the ICU
The aim of this study is to compare the effects of a strategy aimed at increasing alveolar recruitment (high PEEP levels adjusted according to driving pressure and recruitment maneuvers) with that of a strategy aimed at minimizing alveolar distension (low PEEP level without recruitment maneuver) on postoperative respiratory failure and mortality in patients receiving low VT ventilation during emergency abdominal surgery.
The aim of this multicenter, investigator-initiated, prospective, randomized, open-label, non-inferiority study is to evaluate a prednisone prescribing strategy, guided by eosinophil blood count compared to the standard (systematic) administration of corticosteroids, in patients with COPD exacerbation requiring ventilatory support. Patients fulfilling inclusion criteria and consenting to participate in the study, will be randomized through a random table generated electronically, to eosinophil-guided group or to control group. In the eosinophil-guided group, prednisone (1mg/kg/day for up to 5 days or during the hospital stay if less than 5 days) is administered only if the eosinophil count is >2%. If blood eosinophil count is ≤2%, no corticosteroids are given. In the control group: a treatment based on prednisone at a daily dose of 1 mg/kg will be routinely administered for a maximum of 5 days, or during the hospital stay, if it is less than 5 days. Corticosteroid treatment is taken in the morning in patients with NIV, and through the gastric tube in intubated patients. The hypothesis tested is a non-inferiority of the "eosinophil-guided strategy" compared to the standard strategy, with less exposure to corticosteroids. The primary endpoint is the proportion of unventilated patients at day 6 which is set to 50% in the control group. A pre-specified difference <10% would be a non-inferiority margin. Secondary endpoints are: Number of ICU days alive without ventilatory support within 28 days after recruitment, length of stay in intensive care Unit, the intubation rate in patients initially under NIV, Mortality in the ICU, Hospital mortality. Safety: New onset of diabetes or worsening of diabetes requiring the start or the increase in insulin therapy, Upper gastrointestinal bleeding (2 g drop of Hb requiring blood transfusion or fibroscopy), Uncontrolled hypertensive crisis requiring the introduction of new antihypertensives, ICU-acquired neuromyopathy, Nosocomial infection, Relapse rate / recurrence defined respectively by the rate of a new hospital consultation and/or admission in the week or the month following index hospitalization. Sample size calculation: In a non-inferiority study, with an incidence of the event (no ventilation at D6) of 50% in the control group ( with 10% of acceptable difference for non-inferiority), a power of 80% and alpha error <0.05, it would take 86 patients per arm by anticipating 2% of lost sight.
The purpose of this single-centered, proof of concept study is to determine whether it is feasible to perform a phrenic nerve block to reduce diaphragm electrical activity and, therefore, inspiratory effort and if such block reduces self-inflicted lung injury on patients under mechanical ventilation on spontaneous breathing. Ten patients will be monitored with electrical impedance tomography, NAVA catheter, and esophageal balloon. Using a nerve stimulator and an ultrasound, we will identify the phrenic nerve on its cervical portion bilaterally and administer perineural low-dose lidocaine. Diaphragm electrical activity, transpulmonary pressure and data on ventilation distribution will be continuously collected. The study will be over once the patient presents the same diaphragm electrical activity and transpulmonary pressure as before the phrenic nerve block.