Active clinical trials for "Respiratory Insufficiency"

This prospective, blinded observational clinical study was aimed to determine the effect of hyperhydration and muscle loss measured by Bioelectrical impedance vector analysis (BIVA) on mortality. The aim was to compare hydratation parameters measured by BIVA: OHY, Extracellular Water (ECW) / Total Body Wate (TBW) and quadrant, vector length, phase angle (PA) with cumulative fluid balance (CFB) recording (input-output) in their ability in predicting mortality as the abilities of the prognostic markers PA (BIVA), Acute Physiology and Chronic Health Evaluation II (APACHE II - score) and presepsin (serum Cluster of Differentiation (CD) 14-ST). The investigators also compared BIVA nutritional indicators (SMM, fat) with BMI and laboratory parameters (albumin, prealbumin and C-reactive protein (CRP) inflammation parameters) in the prediction of mortality. An important goal was to evaluate the usability of the BIVA method in critically ill patients on extracorporeal circulation, to compare the impedance data of the extracorporeal membrane oxygenation (ECMO) and non-ECMO groups.

Taking the patients with chronic respiratory failure caused by COPD as the research object and the acute exacerbation of COPD as the main outcome index, the investigators hope to establish the syndrome differentiation and treatment scheme of COPD treated by traditional Chinese medicine, reduce the acute exacerbation of AECOPD, improve the clinical symptoms, improve the quality of life, reduce the mortality, preliminarily explore the mechanism of action, and lay the foundation for further research.

COVID-19 pneumonia can cause severe acute hypoxemic respiratory failure. The usefulness of noninvasive respiratory support (NIRS), by means of nasal high-flow oxygen (NHFO), continuous positive airway pressure (CPAP), or noninvasive ventilation (NIV), established outside the intensive care unit, is unknown. The aim of this multicenter, retrospective, longitudinal study is to compare the effectiveness of these treatments to prevent death or endotracheal intubation at day 28, and what factors, related to the disease or to the characteristics of the treatment itself, can condition its success or failure.

Background: Patients with COVID-19 have a range of clinical spectrum from asymptomatic infection, mild illness, moderate infection requiring supplemental oxygen and severe infection requiring intensive care support. High flow nasal cannula (HFNC) oxygen therapy and noninvasive ventilation (NIV) may offer respiratory support to patients with COVID-19 complicated by acute hypoxemic respiratory failure if conventional oxygen therapy (COT) fails to maintain satisfactory oxygenation but whether these respiratory therapies would lead to airborne viral transmission is unknown. Aims: This study examines whether SARS-2 virus can be detected in small particles in the hospital isolation rooms in patients who receive a) HFNC, b) NIV via oronasal masks and c) conventional nasal cannula for respiratory failure. Method: A field test to be performed at the Prince of Wales hospital ward 12C single bed isolation room with 12 air changes/hr on patients (n=5 for each category of respiratory therapy) with confirmed COVID-19 who require treatment for respiratory failure with a) HFNC up to 60L/min, b) NIV via oronasal masks and c) conventional nasal cannula up to 5L/min of oxygen. While the patient is on respiratory support, we would position 3 stationary devices in the isolation room (one next to each side of the bed and another at the end of the bed) of the patient with confirmed COVID-19 infection, and sample the air for four hours continuously. Results & implications: If air sampling RTPCR and viral culture is positive, this would objectively confirm that HFNC and NIV require airborne precaution by healthcare workers during application.

Investigate effects of PEEP on pulmonary regional ventilation and perfusion assessed by EIT

Hypercapnia is a frequent clinical situation defined as an elevation of the partial pressure of carbon dioxide (PaCO2) above 45 mmHg. Several physiopathological parameters such as respiratory minute volume, dead space volume or CO2 production influence the PaCO2. Therefore, hypercapnia can affect the time of various diseases. Available epidemiological data regarding hypercapnia are from studies investigating the efficacy of non-invasive ventilation (NIV), with different population cohorts. However, their interpretation must be cautious given the heterogeneity in patient case-mix and results. Then, whether hypercapnia is a common reason for intensive care unit (ICU) admission, epidemiological data is scarce and heterogeneous. The aim of this study is to investigate the epidemiological, clinical determinants and outcomes of patients admitted to ICU with hypercapnic respiratory failure.

To enable weaning from mechanical ventilation, two different strategies may be distinguished: continuous weaning and discontinuous weaning. There is a lack of evidence of the superiority of one of both strategies is currently weak among early neurological rehabilitation patients. To the best of our knowledge, only one study including stroke patients compared different weaning strategies and showed a significantly shorter duration of mechanical ventilation during continuous than during discontinuous weaning, which is in contrast to the results of the largest weaning study with patients on medical-surgical intensive care units. In addition, further inconsistent results were reported from studies with chronic obstructive pulmonary disease patients, which might be due to disease duration and/or duration of prior mechanical ventilation in the acute care hospital. This small number of studies with controversial results indicates that there is a considerable need for further research. The current study intended to compare the rehabilitation outcome of early neurological rehabilitation patients, weaned by different strategies (continuous vs. discontinuous) through a matched-pair analysis.

An observational study will be conducted in 20 hospitalized surgical patients routinely managed with opioids for anesthesia and post-operative pain control. Trachea Sound Sensor measurements and reference respiratory measurements will be recorded and analyzed to develop diagnostic algorithms that produce a risk-index score that detects/predicts progression from mild hypoventilation, to moderate hypoventilation, to severe hypoventilation due to opioids and other medications that cause respiratory depression. Our current Trachea Sound Sensor (TSS) has a wired Sony commercial microphone integrated into a commercial pediatric stethoscope, coupled to the skin surface over the trachea at the sternal notch. The Trachea Sound Sensor will measure and record the sounds of air moving within the proximal trachea during inhalation and exhalation. The microphone signal will be converted into an accurate measurement of the patient's respiratory rate and tidal volume (during inhalation & exhalation) over time, to determine the minute ventilation trend, breathing patterns, apnea episodes, and degree of snoring (due to partial upper airway obstruction). A commercial respiratory facemask and two pneumotachs (gas flow sensors) will also be used to accurately and continuously measure the patient's respiratory rate and tidal volume (during inhalation & exhalation) to determine the minute ventilation trend, breathing patterns, and apnea episodes. TSS data and reference respiratory data will be collected prior to surgery with the patient breathing normally (baseline), in the Operating Room (OR) during the induction and maintenance of anesthesia, in the Post Anesthesia Care Unit (PACU), and on the general nursing floors of Thomas Jefferson University Hospital (TJUH). The sounds of air flowing through the proximal trachea will be correlated with the reference breathing measurements using signal processing methods to optimize the measurement accuracy of RR, TV, breathing pattern, apnea episodes, and degree of snoring. A commercial accelerometer may be coupled to the skin surface of the neck (with tape) to measure body position and activity level. The TSS and vital sign trend data will be analyzed to produce a Risk-Index Score every 30 seconds with alerts and alarms that warn the patient and caregivers about progressive Opioid Induced Respiratory Depression (OIRD).

Introduction: The main manifestation of COVID-19 pneumonia is acute respiratory distress syndrome (ARDS), which in some cases can be more severe than intubation, extracorporeal membrane venous oxygenation (VV-ECMO) to ensure hematosis. Despite support from VV-ECMO, some patients may remain hypoxemic. One possible therapeutic procedure for these patients is the application of the prone position. Objective: The main aim of this study was to investigate the modification of the PaO2/FiO2 ratio, the compliance of the respiratory system in VV-ECMO with refractory hypoxemia. The secondary objective was to evaluate the safety and feasibility of the inclined position for ECMO. Methods: the investigators reviewed the electronic records and lists of all 23 COVID-19 patients. were placed for the first time in PP with an average duration of 16 h . patient characteristics, pre-ECMO characteristics, ventilator/ECMO settings, and changes in ventilator/ECMO settings and blood gas analysis before and after PP.

Prone position (PP) is standard of care for mechanically ventilated patients with severe acute respiratory distress syndrome in the intensive care unit (ICU). Recommendations suggest PP durations of at least 16 hours. In 2020, COVID-19 pandemic led to a great number of patients requiring mechanical ventilation and PP in the ICU. Risk of ICU staff viral contamination and work overload led to prolongation of PP duration up to 48 hours. Here investigators report outcomes of prolonged PP sessions in terms of skin complications (pression injuries) and ventilatory improvement.