View clinical trials related to Respiratory Failure.
Filter by:Newborns and children with life-threatening heart and lung failure may require support with ECMO (extracorporeal membrane oxygenation). With ECMO, oxygen and carbon dioxide are exchanged and circulated throughout the body even if the heart is unable to do so. Unfortunately, ECMO can cause breakdown of the red blood cells (known as hemolysis). For unclear reasons, newborns are at particularly high risk of hemolysis while being supported by ECMO. The amount of hemolysis is measured with concentrations of a breakdown product from red blood cells known as free hemoglobin. One possible reason for high free hemoglobin levels in newborns on ECMO could be related to another blood protein called haptoglobin. Haptoglobin is known to help in clearing free hemoglobin through the kidneys into the urine. However, haptoglobin levels in newborns can be very low and increases slowly during the first few months of life. Free hemoglobin may be inappropriately high in newborns supported by ECMO because of low levels of haptoglobin. The purpose of this study is to characterize haptoglobin, free hemoglobin, and hemolysis in newborns and children supported by ECMO and compare those values to age-matched newborns and children not on ECMO.
Patients who survive critical illness usually experience long-lasting physical and psychological impairments, which are often debilitating. Rehabilitation interventions started in the ICU may reduce this morbidity. In-bed cycling, which uses a special bicycle that attaches to the hospital bed, allows critically ill patients who are mechanically ventilated (MV) to gently exercise their legs while in the ICU. The main goal of this study is to determine whether critically ill MV adults recover faster if they receive early in-bed cycling than if they do not. Another objective is to determine whether in-bed cycling is a cost-effective intervention. 360 patients admitted to the ICU and receiving MV will be enrolled in the study. Following informed consent, patients will be randomized to either (1) early in-bed cycling and routine physiotherapy or (2) routine physiotherapy alone. Patients' strength and physical function will be measured throughout the study. If early in-bed cycling during critical illness improves short-term physical and functional outcomes, it could accelerate recovery and reduce long-term disability in ICU survivors.
Although non-invasive ventilation (NIV) usage has increased significantly over time in COPD exacerbation, a great percentage of patients (~30%) present contraindications to NIV or cannot tolerate it. Nasal high flow (NHF) has been introduced for the management of hypoxemic respiratory failure in adults with favorable effects on ventilation and respiratory mechanics. The above mentioned NHF positive effects has been observed also in stable COPD patients with or without chronic hypercapnia. In this study, the investigators hypothesize that NHF is not inferior to NIV for respiratory support in patients with COPD exacerbation and acute or acute on chronic hypercapnic respiratory failure.
The aim of the study is to examine if automated oxygen delivery with O2matic is better than manually controlled oxygen therapy for patients admitted to hospital with an exacerbation in Chronic Obstructive Pulmonary Disease (COPD). O2matic is a closed -loop system based on continuous non-invasive measurement of pulse and oxygen-saturation that is processed in an algorithm that controls the flow of oxygen to the patient. The primary hypothesis is that O2matic increases time within acceptable oxygen-saturation interval. Secondary hypotheses are that O2matic compared to manual control reduces time with severe hypoxia (SpO2 < 85 %), hypoxi (SpO2 below intended interval) and hyperoxia (SpO2 above intended interval).
Although recent global trends indicate reduced postoperative mortality after esophagectomy, major morbidity, in particular pulmonary, remains high, with considerable health and economic costs. In a recent modern international collaborative series of 2704 patients from high-volume centers, with an approximate equal mix of open and minimally invasive approaches, respiratory complications were evident in 28% of patients, pneumonia in 15%, and respiratory failure in 7%.1 In other series, respiratory failure is reported in up to 15% of patients and is the most common cause of mortality. Prediction of risk and prevention of respiratory morbidity is therefore of considerable importance, and in this context baseline assessment of respiratory physiology compliments clinical assessment, history and enhanced recovery pathways representing key elements of current patient management. In this study, which will include all prospective patients with locally advanced esophageal cancer treated at a National Center, pulmonary function will be systematically measured before and after neoadjuvant therapy. The investigators seek to evaluate the incidence of radiation induced lung injury (RILI), as well as subclinical changes in pulmonary physiology that may be linked to postoperative complications, and quality-of-life in survivorship, and to compare cohorts who received radiation therapy or chemotherapy alone, preoperatively.
Collapsibility (CI-IVC), distensibility (dIVC) and delta (ΔIVC) indices, which are dynamic measures of inferior vena cava (IVC) diameter, are used to assess the intravascular volume status in critically ill patients. Positive pressure support (PS) has been shown to induce IVC diameter distention by increasing intrathoracic pressure, and high positive expiratory pressure (PEEP) decreases the CI-IVC percentage (4). During Triggered positive pressure support it is necessary to clarify which IVC index is valid for measuring the volume status.it is aimed to compare the IVC indexes (CI-IVC, DIVC, ΔIVC), positive rate of change with pressure, correlation with central venous pressure and accurate prediction of volume status in patients with different positive pressure support.
A retrospective cohort study of all patients treated for type II (hypercapnic) respiratory failure with either High-Flow Oxygen Therapy or Non-Invasive Ventilation in a general adult hospital.
Patients admitted to the ICU with diagnosis of sepsis and requiring mechanical ventilation for at least 24-hours and receiving enteral or parenteral nutrition will be prospectively randomized to one of two arms. Patients allocated to the estimated energy expenditure group will receive nutrition with caloric intake calculated based on the Penn State equation. Patients randomized to the measured group will receive nutrition with caloric intake calculated based on IC measurement present in the GE ventilator. Patients in the estimated group will have IC performed, but these data will not be used for prescription of nutrition. An equal number of beds within the ICU will be allocated to the measured group and the estimated group. The primary objective is to assess whether the utilization of indirect calorimetry for caloric goal calculation results in improvement in muscular structure, and consequent reduction of mechanical ventilation duration in patients with sepsis in comparison to utilizing the Penn State estimation equation for caloric goal calculation. The secondary objective is to assess whether the utilization of indirect calorimetry for caloric goal calculation results in improved adequacy of nutritional delivery in comparison to the adequacy of nutritional delivered when utilizing the Penn State estimation equation. Adult patients (> 18 years of age) admitted to the hospital with diagnosis of sepsis, and who require mechanical ventilation during hospitalization will be considered. Patients newly ventilated for at least one day but less than three days will be included in the study. Informed consent will be obtained from the legal authorized representative (LAR).
Daily interruption of sedation is one of the modalities which is known to enhance early weaning and separation from mechanical ventilation . Daily sedation interruption is also known to help decreasing incidence of ventilator associated pneumonia. The new modality is no sedation.
Non-invasive respiratory support has been emerging in the management of respiratory distress syndrome (RDS) in preterm infants to minimise the risk of lung injury. Intermittent positive pressure ventilation (NIPPV) provides a method of augmenting continuous positive airway pressure (CPAP) by delivering ventilator breaths via nasal prongs.It may increase tidal volume, improve gas exchange and reduce work of breathing. However, NIPPV may associate with patient-ventilator asynchrony that can cause poor tolerance and risk of intubation. It may also in increased risk of pneumothorax and bowel perforation because of increase in intrathoracic pressure. On the other hand, neurally adjusted ventilatory assist (NAVA) is a newer mode of ventilation, which has the potential to overcome these challenges. It uses the electrical activity of the diaphragm (EAdi) as a signal to synchronise the mechanical ventilatory breaths and deliver an inspiratory pressure based on this electrical activity. Comparing NI-NAVA and NIPPV in preterm infants, has shown that NI-NAVA improved the synchronization between patient and ventilator and decreased diaphragm work of breathing . There is lack of data on the use of NI-NAVA in neonates post extubation in the literature. To date, no study has focused on short-term impacts. Therefore, it is important to evaluate the need of additional ventilatory support post extubation of NI-NAVA and NIPPV and also the risk of developing adverse outcomes. Aim: The aim is to compare NI-NAVA & NIPPV in terms of extubation failure in infants< 32 weeks gestation. Hypothesis: Investigators hypothesized that infants born prematurely < 32 weeks gestation who extubated to NI-NAVA have a lower risk of extubation failure and need of additional ventilatory support.