View clinical trials related to Respiratory Insufficiency.
Filter by:Acute respiratory distress syndrome (ARDS) is a life-threatening condition that causes high mortality (41% to 58%). Previous studies have reported that biomarkers can facilitate phenotypic diagnosis of ARDS, enabling precision treatment of ARDS. Although there were many studies that found some potential therapeutic targets for ARDS, no pharmacotherapies have been validated to treat ARDS. The development of biomarkers to predict the prognosis and monitor the response to treatment would be of interest for selecting patients for specific therapeutic trials. Many recent studies have shown that immune metabolic changes are involved in the pathogenesis of ARDS and may become a new therapeutic target for them. We aimed to identify a panel of immunometabolic and lipidomic biomarkers derived from blood and bronchoalveolar lavage fluid (BALF) which may help differentiate the ARDS endotypes.
There is a direct relationship between the sedative agent and the duration of ventilation.
PRACTICAL: PRACTICAL is a randomized multifactorial adaptive platform trial for acute hypoxemic respiratory failure (AHRF). This platform trial will evaluate novel interventions for patients with AHRF across a range of severity states (i.e., not intubated, intubated with lower or higher respiratory system elastance, requiring extracorporeal life support) and across a range of investigational phases (i.e., preliminary mechanistic trials, full-scale clinical trials). ULTIMATE domain (currently enrolling): The ULTIMATE pilot trial is a multi-center, randomized, open-label trial, embedded as a domain within the PRACTICAL platform trial. This domain will evaluate the effect of ultra-low intensity ventilation facilitated by CO2 removal through VV-ECMO versus best current conventional ventilation on all-cause hospital mortality among patients with early moderate-severe AHRF with high respiratory system elastance receiving potentially injurious mechanical ventilation. Invasive Mechanical Ventilation (IMV) Strategies domain: The IMV Strategies domain will evaluate multiple novel invasive ventilation strategies in comparison to conventional lung-protective ventilation in patients with acute hypoxemic respiratory failure (AHRF). Multiple approaches to mechanical ventilation are used, and the optimal approach is unknown. An efficient strategy to identify the best strategy is to compare multiple potential approaches simultaneously to determine more rapidly (a) which interventions are least effective (and should be dropped), and (b) which interventions result in the best outcomes for patients. In the current domain design, we will compare the current recommended ventilation strategy to two new approaches: a strategy that targets lung-inflating (driving) pressure instead of lung-inflating (tidal) volume, and a strategy that aims to maintain an optimal level of breathing effort to prevent diaphragm atrophy and injury while maintaining safe lung-inflating pressures. CORT-E2: The Corticosteroid Early and Extended (CORT-E2) Trial is a phase III, multicentre Bayesian randomized controlled trial (RCT), which includes two cohorts within the domain; one examining the role of early corticosteroids as compared to not extending in persisting AHRF due to COVID or non-COVID (Extended Cohort).
Patients with respiratory failure have high morbidity and mortality. Long-term mechanical ventilation causes a high medical burden and cannot cure respiratory failure. Therefore, in-depth research on early weaning and oxygen therapy nursing mode is needed. Currently, studies on artificial airway high-flow oxygen therapy are limited. Studies have reported that oxygen inhalation devices that increase expiratory resistance produce flow-dependent positive airway pressure and lung volume effects that improve oxygenation and ventilation. It means that the innovation of oxygen therapy device may be a change The key to improving lung function and reducing mechanical ventilation in patients with respiratory failure. The project team is committed to the innovation of high-flow oxygen therapy devices and the research on oxygen therapy care. In the early stage, the "New Artificial Airway High Flow Oxygen Therapy Device" was designed (NTHF), in 2018, the new technology and new projects were declared and approved to solve the problem of the flow rate of oxygen therapy devices. In the pre-test, 78 tracheotomy patients were observed using NTHF and respiratory humidification therapy device (AIRVOTM2 ) with high-flow oxygen therapy. As a result, NTHF was superior to AIRVOTM2 in improving airway humidification, oxygenation effect and cost, and published an article, which was approved in 2019 "Non-inferiority of humidification performance of a novel high-flow oxygen therapy device in oxygen therapy for tracheostomy-off-weaned patients. In 2021, it will be approved for the promotion of appropriate technologies for health and health in Guangdong Province. Relying on the high-level clinical key specialties of Guangdong Province, support with scientific research technology and financial support conditions. Research hypothesis: NTHF has the physiological effects of increasing the positive expiratory pressure of artificial airway, alveolar ventilation, and humidification, and can improve the lung function of patients with respiratory failure after tracheotomy.
This study aims to compare care provided by physiotherapists, combining respiratory care and early rehabilitation in intensive care unit, with standard care on the rate of acute respiratory failure within 7 days after extubation, in patients with high risk of extubation failure.
Introduction: Patients on mechanical ventilation suffer alterations in the viscoelastic characteristics of the mucus due to changes in the humidity and temperature of the inhaled air and in the respiratory volumes and flows. The literature has pointed out the use of mechanical ventilators as a tool for mobilizing secretions and closed-system aspiration associated with expiratory pause has been shown to be effective in mobilizing secretions. Objectives: To assess whether there is a difference in the mass of aspirated secretion with the application of the expiratory pause during aspiration. Methods: A crossover, randomized study. Applied to children aged 0 to 5 years and 11 months who are intubated for 24 hours with orotracheal tubes or tracheostomy. There will be an exclusion of patients who present with undrained pneumothorax, cranial hypertension or any other clinical situation that has a clinical contraindication to aspiration and patients whose parents do not agree to participate in the study. The technique will be during aspiration in the tube with where to apply or not the expiratory pause on the mechanical ventilator. This secretion will be weighed so that there is fidelity in the results.
Retrospective observational study performed in a internal medicine ward of a French university hospital. Included patients were hospitalized for acute shortness of breath who have benefited from a eFOCUS which was defined as a focused cardiac Ultrasound with utilization of Doppler measurements. The objectives were the therapeutic and diagnosis changes induced by eFoCUS. The primary endpoint was defined by the pooled introduction or discontinuation of diuretics, antibiotics or anticoagulants associated with eFoCUS results.
Multicenter, cluster randomized, controlled, open-label trial to assess if AnapnoGuard System can minimize tracheal microaspiration and the risk of ventilator-associated pneumonia when compared to standard treatment
In patients with acute hypoxemic respiratory failure (AHRF), High Flow Nasal Therapy (HFNT) improves oxygenation, tolerance, and decreases work of breathing as compared to standard oxygen therapy by facemask. The hypothesis is that this flow challenge (ROX index variation from 30 to 60L/min) could be used as a test for assessing changes in lung aeration, analyzed by the variation in end expiratory lung volume (ΔEELV), in patients treated with HFNC. It may allow to personalize the flow settings during HFNC. In this sense, an increase in EELV will be observed with higher flows in responders and, therefore, these participants may benefit from increasing the flow. In contrast, to increase the flow in non-responders (no significant increase in EELV with higher flows) increase the risk of patient self-inflicted lung injury (P-SILI).
Investigation Device: EZVent Ventilator System is designed for respiratory support in hospitalized mechanical ventilated patients. The Ventilator is designed to be used for adults patients. It is designed to be a stationary product suitable for service in hospitals, critical care situations to provide continuous positive pressure respiratory support to the patient. The ventilator met EDA, ISO 80601-2-12 requirements on essential performance of critical care ventilator and other applicable international standards. Study Title: Open-labeled, non-randomized, self-controlled study to evaluate the safety and performance of EZVent in hospitalized mechanically ventilated patients. Investigational Device EZVent Ventilator System. Purpose: Evaluation of the safety and performance of EZVent in hospitalized mechanically ventilated patients. Objectives: Evaluation of the safety and performance of EZVent through monitoring the vital signs and arterial blood gases (ABG) in comparison to a commercial ventilator.