View clinical trials related to Respiratory Insufficiency.
Filter by:Patients suffering from pathology of posterior eye chamber such as diabetic retinopathy, retinal detachment, traumatic eye injury, retained lens fragments, macular hole, pucker, dislocated intraocular lens after cataract surgery or vitreomacular traction are often subjected to pars plana vitrectomy (PPV). PPV is minimally invasive endo-microscopic operation usually performed in topical anesthesia combined with sub-Tenon or retrobulbar block done by surgeon, supplemented by intravenous analgo-sedation given by anesthesiologist. Continuous infusion and dose adjustment of intravenous anesthetics applied should procure moderate sedation and preservation of patients' spontaneous ventilation. However, despite carefully applied anesthetics and standard low-flow nasal oxygenation (LFNO) (5 L/min O2 via nasal catheter), inadequate spontaneous breathing can occur leading to low blood oxygen level (hypoxia). Obese patients are susceptible to hypoxia and hypercapnia (high CO2 blood level) during analgo-sedation. Respiratory instability of obese patients is often associated to their subsequent circulatory instability (heart rate and blood pressure disorders). On the other hand, high-flow nasal oxygenation (HFNO) is usually used during anesthesia induction when difficult maintenance of airway patency is expected, in intensive care units during weaning patients from mechanical respirator and in postanesthesia care units during awakening from anesthesia. It can deliver 20 to 70 L/min, up to 100% inspiratory fraction of O2 (FiO2) to patient. High oxygen/air flow produces 3-7 cmH2O of continuous pressure in patients' upper airways therefore providing better oxygenation. Oxygen/air mixture delivered by HFNO is humidified and heated, thus more comfortable to patient than dry and cold LFNO. Aim of this study is to compare effect of HFNO to LFNO during intravenously applied standardized analgo-sedation given for PPV in obese adult patients. Investigators hypothesize that obese patients, whose breathing pattern is preserved, receiving HFNO vs. LFNO during standardized analgo-sedation for PPV will be more respiratory and circulatory stable, preserving normal blood O2 and CO2 level, breathing pattern, heart rate and blood pressure.
Proposed is a demonstration project to characterize the immediate, short-term and long-term pain and other post-operative outcomes of 60, self-selected breast (n=20), caesarian-section (n=20) and abdominal (n=20) surgical patients who receive opioid-sparing, multimodal anesthesia and pain management care as guided by the ComfortSafe Pyramid.
Extracorporeal membrane oxygenation (ECMO) had been used to treat refractory hypoxemia associated with acute respiratory distress syndrome (ARDS). There were reported good outcome associated with ECMO for ARDS caused by influenza infection from several ECMO centers. However, the outcome of ECMO support in lower ECMO experience center had not been evaluated. This study aimed to evaluate the outcome of ECMO, comparing with conventional treatment among severe hypoxemic ARDS patients who were admitted in limited ECMO experience hospital.
Around 20% of the patients requiring hospitalization for Acute Exacerbation of Chronic Obstructive Pulmonary Disease (AECOPD) develop hypercapnia, which is associated with an increased risk of death. Once Non Invasive Ventilation (NIV) has been initiated, a reduction in Respiratory Rate (RR) and improvement in pH within 4 h predicts NIV success. If pH <7.25 and RR >35 breath per minutes persist, NIV failure is likely. Worsening acidosis, after initial improvement with NIV, is also associated with a worse prognosis. In addition, it has been shown that delaying intubation in patients at high risk for NIV failure has a negative impact on patient survival. Hence, assessing the risk of NIV failure is extremely important. NIV has some limitations: a) intolerance, discomfort and claustrophobia requiring frequent interruptions; b) poor patient-ventilator synchrony, especially in presence of air leaks or high ventilatory requirements. Since removing carbon dioxide by means of an artificial lung reduces the minute ventilation required to maintain an acceptable arterial partial pressure of carbon dioxide (PaCO2), the investigators hypothesize that applying Extra-Corporeal CO2 Removal (ECCO2R) in high-risk AECOPD patients may reduce the incidence of NIV failure and improve patient-ventilator interaction. After the beginning of ECCO2R, NIV could be gradually replaced by High Flow Nasal Cannula Oxygen Therapy (HFNCOT), potentially reducing the risk of ventilator induced lung injury, improving patient's comfort and probably allowing the adoption of a more physiologically "noisy" pattern of spontaneous breathing.
The aim of the present investigation will be to evaluate diaphragmatic excursion velocity during non-invasive ventilation and spontaneous breathing at both inspiration and expiration. this analysis will be performed through diaphragmatic tissue Doppler assessment.
The purpose of the study is to randomly and prospectively evaluate the differences in outcomes between the control group (closed full facemask immediate post-extubation with standard oxygenating device used post-operatively in PACU) and the SuperNO2VA™ group (SuperNO2VA™ immediate post-extubation and post-operatively in PACU)
Patients admitted to Intensive Care Unit often are affected by acute respiratory failure at admission or during hospital stay, with a mortality of 30%. Treatment remains largely supportive with mechanical ventilation as the mainstay of management by improving the hypoxemia and reducing the work of breathing; however, the mechanical forces generated during ventilation can further enhance pulmonary inflammation and edema, a process that has been termed ventilator induced lung injury (VILI). Consequently, in clinical practice the lung protective ventilation is mainly based on the reduction of the tidal volume, the airway and the transpulmonary plateau pressure. A good clinical practice is based on the assessment of changes in respiratory mechanics. Aim of the study is to determine the accuracy of the OPTIVENT system in measuring transpulmonary pressure, comparing it with the systems currently in use in our Operative Unit.
The study will be performed as a randomized controlled non-inferiority trial. HFA has been increasingly used in the last years to treat hypoxic respiratory failure (i.e. type I failure), and numerous studies have shown its efficiency in this indication. Despite this good evidence for HFA in hypoxic respiratory failure, it has only reluctantly been used for hypercapnic respiratory failure. HFA has been shown to generate PEEP, despite not being a closed system, and to improve CO2 clearance by flushing anatomical dead space. It might also help to reduce inspiratory resistance and facilitate secretion clearance from humidified gas. A study on COPD patients showed an increase in breathing pressure amplitude and mean pressure, as well as tidal volume, with a trend towards reduction of carbon dioxide partial pressure. Intervention consists of HFA using standard equipment at the department. A gas flow of 60 litres per minute and a FiO2 as clinically feasible will be used. Therapy will be continued until a pCO2-level of 50 mmHg or less is reached, or therapy has to be aborted because of lack of tolerance by the patient or indication for intubation. Control consists of non-invasive continuous positive airway pressure ventilation support using a tight mask and standard respirator equipment of the Department of Emergency Medicine. A positive airway pressure of 3,67 mmHg and a FiO2 as clinically feasible will be used. Therapy will be continued until a pCO2-level of 50 mmHg or less is reached, or therapy has to be aborted because of lack of tolerance by the patient or indication for intubation.
The purpose of this study is to assess the effect of HFNC on esophageal pressure and diaphragmatic function in patients with acute respiratory failure
To assess the correlations among the physical functional performance, muscle strength, respiratory muscle strength and the ventilator weaning rate.