Active clinical trials for "Respiratory Insufficiency"

The study aims to assess early (one to three days after intubation) tracheostomy effectiveness in terms of reduction in ventilator associated pneumonia (VAP) incidence.

The aim of the data collection is to create an advanced reliable method to remotely monitor patient on chronic home non-invasive ventilation (NIV), both regarding ventilatory efficacy and patient comfort, both in the hospital and at home by assessing gas exchange, lung mechanics and the interaction between the patient and the ventilator. For this purpose, we will set-up of databank of synchronously acquired datasets of already standard care monitored parameters during NIV (transcutaneous monitoring of gas exchange; ventilator data including data on PVA), and newly non-invasively acquired data on patient effort (EMG, patient ratings) and lung (hyper)inflation (EIT), during the set-up and follow-up of standard care chronic NIV.

Measurements of esophageal pressure (Pes) as surrogate for pleural pressure are routinely performed in selected ICU patients to facilitate lung-protective ventilation and assess breathing effort. Pes is clinically measured via a nasogastric esophageal catheter. Current techniques involve balloon catheters but have some important disadvantages as they could deflate over time and require a very precise positioning and filling volume. A solid-state sensor does not have disadvantages associated with balloon catheters and may therefore be a useful alternative in clinical practice. This method-comparison study in adult mechanically ventilated ICU patients evaluates the accuracy of Pes measured using an esophageal catheter with a solid-state sensor as compared to a balloon catheter as reference standard.

The study will be a multicenter, multinational, prospective single arm blinded non-interventional follow-up study (from DXT-CS-005) to validate RESPINOR DXT's performance to identify patients at increased risk of weaning failure during the spontaneous breathing trial (SBT). Continuous diaphragmatic excursion measurements by RESPINOR DXT will be conducted during the patients' first SBT. The recording shall be initiated 15 minutes prior to the first SBT and will end 15 minutes post SBT. All patients on mechanical ventilation in the ICU meeting the eligibility criteria shall undergo a daily screen for weaning readiness. If any of the components of the daily screen is not met, the patient will not undergo a SBT that day and continued to be screened daily. Patients passing daily screening criteria shall automatically receive an SBT. The SBT shall last for 30-120 minutes and be performed on continuous positive airway pressure up to 5 cm H2O and pressure support up to 7 cm H2O. The SBT shall be terminated, and mechanical ventilation reinstituted at the original settings if the patient meets any of the SBT failure criteria. A trial is considered successful, and physicians will be asked to approve extubation when the patient can breathe spontaneously for the whole trial. As part of the clinical investigation, patients shall be continued to be screened daily until extubation, 21 days after enrollment, the performance of tracheostomy, death, or withdrawal of care. All patients shall be followed until hospital discharge or death.

Diseases of the lungs can be life-threatening. When these organs fail to adequately work, treatments to support their function are offered, often in Intensive Care Units (ICU). Respiratory failure patients may need sedation and placement of a tube in their windpipe so that a mechanical ventilator can take over their breathing until they have recovered enough to breathe again on their own. One problem that occurs in patients under mechanical ventilation is that parts of the lung tissue tend to collapse (atelectasis), reducing the amount of the lung that is able to transfer oxygen and carbon dioxide effectively and even progressing to pneumonia. To address this problem, ICU doctors often perform a procedure named 'recruitment manoeuvre', which involves briefly inflating the patient's lungs with enough pressure to try to open up the collapsed areas of lung. However, fundamental aspects of the change in the functioning of the heart and lungs that occur during and after such manoeuvre are not fully understood. In this study, funded by the University of Oxford, the investigators wish to study patients with respiratory failure who are receiving mechanical ventilation. Participants will be recruited at the ICU of the Royal Berkshire Hospital having their cardiopulmonary data collected over the course of a day. During this period, some patients will be assessed to determine whether they may benefit from a recruitment manoeuvre using a pressure-volume curve. As this assessment is not perfect, the investigators wish to study which features of this curve predict a successful recruitment. The investigators will do this by evaluating the volume of the lung before and after the recruitment manoeuvre is performed using a device named Optical Gas Analyser. A better understanding of the effects of the recruitment manoeuvre will help the investigators to determine how and when such manoeuvres should be performed in critically ill patients.

Coronavirus Disease (COVID-19) is characterized by a hypercoagulable state, sometimes difficult to be managed with heparin. Bivalirudin, a member of the direct thrombin inhibitor drug class, offers potential advantages compared to heparin, including to its ability to exert its effect by directly attaching to and inhibiting freely circulating and fibrin-bound thrombin. Investigators have therefore designed this pilot open-label randomized controlled trial to assess if a off-label infusion of bivalirudin may reduce thrombosis, mortality, Intensive Care Unit (ICU) length of stay and increase ventilator free days of patients admitted in ICU for acute respiratory failure due to COVID-19, as compared to first-line treatment with heparin.

High frequency percussive ventilation (HFPV) is used in patients with underlying pulmonary atelectasis, excessive airway secretions, and respiratory failure. HFPV is a non-continuous form of high-frequency ventilation delivered by a pneumatic device that provides small bursts of sub-physiological tidal breaths at a frequency of 60-600 cycles/minute superimposed on a patient's breathing cycle. The high-frequency breaths create shear forces causing dislodgement of the airway secretions. Furthermore, the HFPV breath cycle has an asymmetrical flow pattern characterized by larger expiratory flow rates, which may propel the airway secretions towards the central airway. In addition, the applied positive pressure recruits the lung units, resulting in a more homogeneous distribution of ventilation and improved gas exchange. In acute care and critical care settings, HFPV intervention is used in a range of patients, from spontaneously breathing patients to those receiving invasive mechanical ventilation where HFPV breaths can be superimposed on a patient's breathing cycle or superimposed on breaths delivered by a mechanical ventilator. The most common indications for HFPV use are reported as removal of excessive bronchial secretions, improving gas exchange, and recruitment of atelectatic lung segments. This study aims to assess the lung physiological response to HFPV in terms of aeration and ventilation distribution in patients with acute respiratory failure due to SARS-CoV-2 infection and requiring high flow oxygen therapy through nasal cannula

Landmark trials in critical care have demonstrated that, among critically ill adults receiving invasive mechanical ventilation, the use of low tidal volumes and low airway pressures prevents lung injury and improves patient outcomes. Limited evidence, however, informs the best method of mechanical ventilation to achieve these targets. To provide mechanical ventilation, clinicians must choose between modes of ventilation that directly control tidal volumes ("volume control"), modes that directly control the inspiratory airway pressure ("pressure control"), and modes that are hybrids ("adaptive pressure control"). Whether the choice of the mode used to target low tidal volumes and low inspiratory plateau pressures affects clinical outcomes for critically ill adults receiving mechanical ventilation is unknown. All three modes of mechanical ventilation are commonly used in clinical practice. A large, multicenter randomized trial comparing available modes of mechanical ventilation is needed to understand the effect of each mode on clinical outcomes. The investigators propose a 9-month cluster-randomized cluster-crossover pilot trial evaluating the feasibility of comparing three modes (volume control, pressure control, and adaptive pressure control) for mechanically ventilated ICU patients with regard to the outcome of days alive and free of invasive mechanical ventilation.

This study targets adult patients treated with high flow nasal cannula (HFNC) at emergency department (ED) of Severance hospital, Yonsei university. Patients with acute hypoxic respiratory failure presenting to the ED receive conventional oxygen therapy as initial treatment unless immediate endotracheal intubation is required. Partial rebreathing oxygen masks are mainly applied at first. If the patient's condition does not improve despite such treatment, the patient receives HFNC or endotracheal intubation. However, possible treatment range have not been studied, especially in ED. Decisions are made based on the personal experience of the medical staff in charge. Applying HFNC to patients who eventually fail can lead to delayed intubation and increased mortality. Failure prediction models such as ROX index and HACOR score have been developed due to such reasons. However, such models are mostly based on intensive care unit studies and after application of HFNC. Therefore, failure prediction model at the time before application of HFNC and efficacy of existing models in ED are necessary. This study is a prospective observational study and follows the standard treatment guidelines applied to the patient and the judgment of the attending physician during the patient's treatment process. Immediately before applying HFNC, the patient's respiratory rate, pulse rate, blood pressure, SpO₂, PaO₂, PaCO₂, GCS score are determined, and FiO₂ is measured above upper lips using oxygen analyzer(MaxO2+AE, Maxtec, USA). From these data, ROX index (SF ratio/respiratory rate), ROX-HR (ROX index/pulse rate), POX index (PF ratio/respiratory rate), POX-HR (POX index/pulse rate), and HACOR score (Heart Rate, Acidosis, Consciousness, Oxygenation, Respiratory rate) are calculated. The settings (flow rate, FiO₂, temperature) at the time of HFNC application are also measured. The same indices and HFNC settings are checked 30 minutes, 1 hour, 2 hours, 4 hours, 6 hours, and 12 hours after applying HFNC. Modified Borg score and comfort scale using 5-point Likert scale are additionally determined at 30 minutes for patient's comfort. Primary outcome is HFNC failure at 28 days, defined by endotracheal intubation. Other outcomes include intubation in ED and mortality at 28 and 90 days collected through phone interview. The receiver operating curve for ROX index, HACOR score, ROX-HR, and POX-HR at baseline, 30 minutes, 1 hour, 2 hours, 4 hours, 6 hours, and 12 hours are drawn for the outcomes. The area under the curve of the above indices are compared and cutoff values are chosen with maximum value of index J by the Youden's Index. A binary variable is created based on the cutoff values and multivariable logistic regression analyses are performed. Cutoff values for maximum specificity are also invested suggesting the lower limit of the indicator to which HFNC can be applied.

The objective of this study is to assess the efficacy and safety of this new Prismalung+ membrane in its intended clinical setting by demonstrating a reduction in ventilatory parameters and pulmonary energy load or the successful maintenance of spontaneous breathing, respectively, the absence of the need to initiate vv-ECMO therapy, and initial survival.