View clinical trials related to Respiratory Failure.
Filter by:A prospective observational study. Enrolled participants admitted to ICU due to pneumonia and respiratory failure need mechanical ventilator support. Investigators collected the residual specimens, such as sputum from endotrachea aspiration, bronchoalveolar lavage fluid in those participants as the usual care in the ICU. Those residual samples were sent to extract RNA and sequence by using high-throughput sequencing (next-generation sequencing) method. Investigators will compared the microbiome feature between lower respiratory tract and stool specimens in those participants diagnosed as pneumonia with respiratory failure.
In case of respiratory distress, patients are intubated to be connected to an artificial respirator to ensure gas exchanges. Before any ventilatory weaning, a breathing test in spontaneous ventilation under artificial nose is practiced. The patient keeps the endotracheal tube but is no longer assisted by the ventilator. Mortality is markedly increased with the prolongation of the weaning period. Despite the presence of all weaning criteria and the success of a breathing test in spontaneous ventilation under artificial nose, failure of extubation occurs in 20% of patients. Experimental application of an additional inspiratory load in awake healthy subjects causes a compensatory increase in respiratory work to maintain effective ventilation, and the subject does not develop hypoventilation. This respiratory drive to breathe has been demonstrated by quantified electroencephalography in inspiratory load tests in the form of pre-inspiratory negative deflections of low amplitude similar to the potential described during the preparation of the voluntary movement of a limb. These inspiratory pre-motor potentials begin about 2.5 seconds before the start of a movement in the additional motor area. Does the simple and noninvasive analysis of inspiratory cortical control during the spontaneous ventilation breath test under artificial nose predict the outcome of this test as well as weaning at 7 days?
The investigators compared oxygen therapy using the HFNC and diffuser mask (an effective low-flow oxygen delivery system) to treat patients with moderate-to-severe acute bronchiolitis admitted to an intensive care unit (ICU).
Pathophysiological changes influenced by multiple factors in critically ill patients, has a significant impact on pharmacokinetics (PK) and pharmacodynamics (PD) of cisatracurium. In order to understand better and find an appropriate dosing regimen, the purpose of this study is to investigate the PK and PD of a loading dose cisatracurium in critically ill patients. Cisatracurium, nondepolarizing neuromuscular blocking agents (NMBAs), are commonly used in intensive care units because of a lesser effect on hemodynamic parameters and a reduction in mortality rate in ARDS patients. Loading dose recommended in clinical practice guidelines for sustained neuromuscular blockade in the adult critically ill patient is 0.1-0.2 mg/kg. Then, maintenance dose of 1-3 mcg/kg/min is followed regarding indications, such as ARDS. However, this recommended loading dose might not be adequate in critically ill patients, the study in this specific population might be needed.
Ventilator hyperinflation (VHI) has been shown to be effective in improving respiratory mechanics, secretion removal, and gas exchange in mechanically ventilated patients; however, there are no recommendations on the best ventilator settings to perform the technique. Thus, the aim of this study was to compare six modes of VHI, concerning physiological markers of efficacy and safety criteria, in order to support the optimal VHI settings selection for mechanically ventilated patients. In a randomized, controlled and crossover study, 30 mechanically ventilated patients underwent 6 modes of ventilator hyperinflation. The maximum expansion (tidal volume), expiratory flow bias criteria (inspiratory and expiratory flow patterns), overdistension (alveolar pressure), asynchronies and hemodynamic variables (mean arterial pressure and heart rate) were assessed during the interventions.
The investigators propose to conduct a feasibility, multi-centre, randomised controlled trial of targeted oxygen therapy in adult critically ill patients receiving mechanical ventilation via an endotracheal tube as part of their treatment for respiratory failure. Participants will be allocated to either a normal blood oxygen target group or a lower than normal blood oxygen target group. The primary purpose of the study will be to assess the feasibility of recruiting complex patients who lack capacity into a clinical trial in which oxygenation is being assessed, and that the clinicians responsible for these patients are able to deliver the intervention effectively. The safety of using a lower than normal blood oxygen target will also be assessed and blood samples taken for subsequent investigation of the biological mechanisms underlying the observed changes. Participants will be randomised (1:1) into either an intervention or control group. The intervention in this trial is tightly controlled administration of oxygen to patients to achieve a haemoglobin oxygen saturation (SpO2) of 88-92%. The control group will also have tightly controlled oxygen administration, but to achieve an SpO2 of 96% or above. The target for the control group represents a normal SpO2, whilst that in the intervention group is lower than what is considered to be normal. It should be noted that although lower than normal, this SpO2 is close to what the general public experience when travelling by pressurised aircraft as the fractional inspired oxygen concentration in that situation is only 0.15-0.17 (15-17%). The controlled oxygen administration would commence as soon as possible after admission to the critical care unit and end following removal of the participant's artificial breathing tube. The researchers and clinical team cannot be blinded to treatment allocation, due to the nature of the intervention. Those analysing the data will be blinded to the intervention.
Acute respiratory failure (ARF) is a life-threatening emergency which occurs due to impaired gas exchange. In the US, the number of hospitalisations owing to acute respiratory failure was 1,917,910 in the year 2009.(1) The incidence of ARF requiring hospitalization was 137.1 per 100,000 population.(2) In ARF due to chronic obstructive pulmonary disease (COPD) and cardiogenic pulmonary edema, non-invasive ventilation (NIV) has been shown to be beneficial. NIV also has several advantages over invasive mechanical ventilation. These include, avoidance of endotracheal intubation and its attendant complications like airway injury, nosocomial infections, and possibly shorter duration of intensive care unit (ICU) stay.(3, 4) The success of NIV depends on several factors like the etiology of the respiratory failure, careful monitoring by the treating physician, and also adequate cooperation of patient. Better synchrony of the patient's spontaneous breaths with the ventilator-delivered breaths may lead to better patient cooperation and thereby, better clinical outcomes. Patient-ventilator asynchrony (PVA) leads to dyspnea, increased work of breathing, and prolonged duration of mechanical ventilation.(5) Pressure support ventilation (PSV) is one of the commonest mode used during NIV. In a prospective multicenter observational study, severe asynchrony (defined as an asynchrony index of >10 %) was seen in 43% of patients of patients with ARF ventilated by NIV with the conventional PSV mode.(6) Neurally adjusted ventilator assist (NAVA) is new mode of ventilation which utilizes the electrical activity of the diaphragm to deliver the breath.(7) During NAVA, breath is delivered when the patient's diaphragm starts contracting. Further, the amount of pressure support given during the breath is proportional to the strength of the electrical signal from the diaphragm. Finally, NAVA also terminates the breath when the electrical activity of the diaphragm wanes. NAVA has been shown to avoid over-assistance, decrease intrinsic positive end-expiratory pressure (PEEP), and minimize wasted efforts.(8) Hence, NAVA may play a major role in improving patient-ventilator synchrony. In a pooled analysis of studies comparing NAVA with PSV during NIV, it was shown that the use of NAVA significantly improved patient-ventilator synchrony.(9) However, so far, no clinical trial has demonstrated that this improvement in synchrony translates into better clinical outcomes. In this randomized controlled clinical trial, we intend to compare the rates of NIV failure and mortality between NAVA and PSV in subjects with acute respiratory failure managed with NIV.
This study evaluates the prognostic value of arterial blood gas analysis in a cohort of Emergency Department patients presenting with shortness of breath of any cause, comparing obese and non-obese patients.
High flow nasal oxygen therapy has been widely used but guidelines as to the optimal starting flow rate and oxygen percentage are not available. Prolonged exposure to an inappropriately high oxygen concentration should be avoided as there is increasing evidence that the production of oxygen free radicals can lead to lung damage. This pilot dose finding study will determine the optimal flow rate and oxygen concentration using HFNO2 for patients with respiratory failure requiring low, medium or high oxygen concentration from conventional low flow devices. An assessment will also be made of comfort and compliance with HFNO2.
Mortality of intubated acute hypoxemic respiratory failure (AHRF) and acute respiratory distress syndrome (ARDS) patients remains considerably high (around 40%) (Bellani 2016). Early implementation of a specific mechanical ventilation mode that enhances lung protection in patients with mild to moderate AHRF and ARDS on spontaneous breathing may have a tremendous impact on clinical practice. Previous studies showed that the addition of cyclic short recruitment maneuvers (Sigh) to assisted mechanical ventilation: improves oxygenation without increasing ventilation pressures and FiO2; decreases the tidal volumes by decreasing the patient's inspiratory drive; increases the EELV by regional alveolar recruitment; decreases regional heterogeneity of lung parenchyma; decreases patients' inspiratory efforts limiting transpulmonary pressure; improves regional compliances. Thus, physiologic studies generated the hypothesis that addition of Sigh to pressure support ventilation (PSV, the most common assisted mechanical ventilation mode) might decrease ventilation pressures and FiO2, and limit regional lung strain and stress through various synergic mechanisms potentially yielding decreased risk of VILI, faster weaning and improved clinical outcomes. The investigators conceived a pilot RCT to verify clinical feasibility of the addition of Sigh to PSV in comparison to standard PSV. The investigators will enrol 258 intubated spontaneously breathing patients with mild to moderate AHRF and ARDS admitted to the ICU. Patients will be randomized through an online automatic centralized and computerized system to the following study groups (1:1 ratio): - PSV group: will be treated by protective PSV settings until day 28 or death or performance of spontaneous breathing trial (SBT); - PSV+Sigh group: will be treated by protective PSV settings with the addition of Sigh until day 28 or death or performance of spontaneous breathing trial (SBT). Indications on ventilation settings, weaning, spontaneous breathing trial and rescue treatment will be specified.