Active clinical trials for "Respiratory Insufficiency"

Oxygen therapy is first-line treatment in the management of acute respiratory failure (ARF). Different oxygen devices have become available over recent decades, such as low-flow systems (nasal cannula, simple facemask, non-rebreathing reservoir mask) and high-flow systems (Venturi mask) . Since the 90's, non-invasive ventilation (NIV) has been largely used with strong level of evidence in cardiogenic pulmonary edema and chronic obstructive pulmonary disease (COPD) exacerbation. NIV improves gas exchange and reduces inspiratory effort through positive pressure. However, good tolerance to NIV is sometimes difficult to achieve due to frequent leaks around the mask, possibly leading to patient-ventilator asynchrony and even to intubation . High-flow nasal oxygen therapy (HFNO) is an innovative high-flow system that allows for delivering up to 60 liters\ min of heated and fully humidified gas with a FIO2 ranging between 21% and 100% . It is a new method of respiratory support in adults that has been used in neonatal ARF for some years. The reason this study is necessary is because, even though NIV has been demonstrated to prevent endotracheal intubation (and its associated complications) in a broad range of ARF patients, HFNC has been proposed to have the same effect as NIV while being easier tolerated, more physiological , allowing patients to continue to talk, eat and drink through mouth while on HFNC

A retrospective, single centre observational study to validate use of the HACOR score (Duan et al, 2017) in determining efficacy of non-invasive ventilation in Covid-19 respiratory failure.

High-intensity noninvasive positive pressure ventilation (NPPV), which can well improve the gas exchange and reduce the work of breathing of patients, is a new strategy targeted at maximally reducing arterial carbon dioxide. However, no definitive conclusions have been drawn to decide whether high-intensity NPPV is the best setting for treating patients with chronic hypercapnic COPD. For now, no unified method for setting up high-pressure NPPV has been established. Most of the trials utilized gradually increased inspiratory positive airway pressure depending on the patient's tolerance. However, from a respiratory physiology point of view, excessive inspiratory positive airway pressure may lead to lung hyperinflation, increased intrinsic positive end expiratory pressures, increased oxygen consumption, and ineffective work of breathing.Therefore, seeking a method to establish individualized high-intensity NPPV is of vital importance.

Rationale: Fluid overload is a common complication in children who are admitted to the pediatric intensive care for mechanical ventilation. Acute lung infection is a frequent cause for admission to the PICU and forms an uniform group with a single organ failure. In these critically ill children, fluid overload is associated with adverse outcome. Restricting the volume of fluids already in an early stage of ICU admission may prevent fluid overload during mechanical ventilation and thus improve clinical outcome. However, at the same time fluid restriction may interfere with appropriate energy and macronutrient intake that is needed for recovery. Objective: The main goal of this pilot study is to evaluate the feasibility of a restrictive fluid management protocol and investigate its effect on the occurrence of fluid overload in mechanically ventilated children with acute infectious lung disease. Study design: Single-center prospective randomized feasibility and pilot study in preparation of a multi-center randomized controlled trial (RCT). Study population: Mechanically ventilated children with (suspicion of) acute infectious lung disease admitted to the pediatric intensive care unit (PICU) of the Emma Children's Hospital, Academic Medical Center, Amsterdam. Intervention: Patients receive either liberal (control group) or a restrictive (experimental group) fluid treatment, while ensuring appropriate caloric intake. Main study parameters/endpoints: Primary outcomes are cumulative fluid balance and body weight during the first week of mechanical ventilation. Secondary outcomes (in preparation of the larger multi-center RCT) include: mortality, duration of mechanical ventilation and oxygenation indices. To determine the feasibility, in- and exclusion rate, adherence to treatment arms, need for fluid bolus, need for diuretics and hemodynamic indices as well as energy and protein intake are studied. Both fluid management protocols reflect a variant of current clinical practice, hence will not provide extra burden or risk to patients included in the study. Patients will be randomized to either of the fluid protocol arms on admission to the PICU (at start of mechanical ventilation). Patients included in the restrictive fluid treatment arm might have direct benefit from the study if indeed fluid overload is less common in this group.

Assessment of the effect and safety of noninvasive positive pressure ventilation for severe stable chronic obstructive pulmonary disease

The goal of this interventional crossover study in morbidly obese intubated and mechanically ventilated patients is to describe the respiratory mechanics and the heart-lung interaction at titrated positive end-expiratory pressure levels following a recruitment maneuver with transthoracic echocardiography and electric impedance tomography imaging.

Poor glycemic control in critically ill patients can increase their mortality, while safe and efficient glucose control is laborious and time-consuming. The Space GlucoseControl which is installed with eMPC(enhanced Model Predictive Control) can get the blood glucose target range safely and effectively through regulating insulin dose rate. This study is a random controlled trial involving the patients with mechanical ventilation in intensive care unit in order to evaluate the difference of safety and efficacy of blood glucose control between SGC directed and conventional treatment. At last, the trial results can determine whether the Space GlucoseControl can control blood glucose safely and effectively in the patients with mechanical ventilation in intensive care units.

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.

Non emergent scheduled cesarean sections will be consented to participate in this study of patients who have screened negative for obstructive sleep apnea and who are also BMI>/= 35 to have capnography monitoring postoperatively. The capnography and pulse oximetry will be initiated in the post anesthesia care unit and be worn for 12-24 hours after delivery. Data will be retrieved after that time period in a deidentified fashion. Medication usage will be reviewed as well as the standard of care information from the duramorph monitoring will be retrieved.

To research the effect of Bi-Level Positive Airway Pressure (BiPAP) for neonatal respiratory failure.