View clinical trials related to Pediatric Respiratory Diseases.
Filter by:Tobacco smoking in pregnancy is now widely accepted as having adverse health outcomes for both the mother and fetus. Tobacco smoking in pregnancy is associated with increased incidence of miscarriage, stillbirth and preterm birth as well as low birthweight, respiratory infections, wheeze and asthma in childhood. E-cigarettes are a popular method for trying to quit smoking in Ireland and there has been an explosion in the use of e-cigarettes over the past ten years. However, there is currently insufficient evidence on their long-term safety and effectiveness as a smoking cessation tool. E-cigarettes contain varying combinations of compounds and flavours which are used differently in different e-cigarette types, with unknown long-term effects. Research has shown that pregnant women perceive e-cigarettes to be a healthier option when compared with tobacco smoking. But, there is very little known about the long-term health impact of exposure of unborn babies to e-cigarettes during pregnancy. The ECHO study will determine what the long-term health outcomes are in children born to mothers who use e-cigarettes during pregnancy. Specifically, we will focus on birth, nutritional, brain development and respiratory outcomes in children. To answer this research question, the ECHO study will recruit infants born to women who use e-cigarettes during pregnancy across three maternity hospitals and follow them up over 2 years. We will invite women at their booking visit to take part in this research study. We plan to also recruit a similar number of both non-smoking and tobacco smoking pregnant women for comparison. We will record a detailed record of e-cigarette and tobacco use by women during pregnancy as well as checking smoking using special monitoring tools. After the baby is born, we will perform growth measurements, neurocognitive assessments and a respiratory questionnaire at 6 months, one year and two years of age.
Prospective observational cohort study within the Pediatric Intensive Care Unit (PICU). We will perform point-of-care-ultrasound (POCUS) to quantify tricuspid regurgitant jet velocity (TRJV) on mechanically ventilated (MV) children. Mechanically ventilated (MV) children approaching extubation as per the discretion of the PICU clinical team will undergo a positive end expiratory pressure (PEEP) titration protocol in a safe and timely manner in the PICU. During this PEEP titration, POCUS will be performed by a pediatric intensivist and interpreted by a pediatric cardiologist. Medical demographics will be collected from the electronic medical record and recorded.
The purpose of this study is to evaluate the efficacy of tracheal suctioning associate with expiratory pause maneuver in children on invasive mechanical ventilation.
Bronchiolitis is a common viral infection of the small airways of infants and some affected infants will require hospital admission. Severe bronchiolitis is a marker for greatly increased risk of developing both preschool wheeze and subsequent school age asthma. Since epidemiological studies suggest that exposure to microbial products protects against preschool wheeze, lysates of bacteria may prevent the development of wheeze after bronchiolitis, with long-term beneficial consequences. BLIPA is a phase 2b, randomised, double blind, placebo-controlled study, investigating the efficacy superiority of bacterial lysate (Broncho Vaxom) capsules over placebo, in reducing wheeze in infants after severe bronchiolitis. The primary end point of the study is parent-reported, healthcare-professional confirmed wheeze at 19-24 months. The study aims to test bacterial lysate capsules (3.5mg over 24 months) for safety, efficacy, and to advance mechanistic understanding of its action.
The study presents an alternative method of tracheal dilatation in pediatric patients with acquired tracheal stenosis. Dilatation is performed by the use of balloon catheter connected with manometer, that is bronchoscopic guided into trachea in the stenotic area, through the wide canal of supraglottic device i-Gel. Every dilatation cession consists of three consequent tracheal balloon dilatations of maximum 3 minutes duration each, followed by 10-15minutes interval of controlled ventilation. The balloon is inflated for 60 seconds to reach predefined pressure, and then deflated. This method is minimal traumatic for tracheal mucosa, and application of several dilatation procedures every 2-3months, in pediatric patients with acquired tracheal stenosis, may lead to a relative reopening of trachea and recession of clinical symptoms.For the right performance of the dilatation procedure, patients receive general anesthesia with cessation of spontaneous ventilation. During procedure, controlled ventilation-oxygenation is impossible, because the i-Gel canal is occupied by bronchoscope and balloon catheter, so patients will remain apneic for a short period of time. For pediatric patients is important to perform proper preoxygenation prior to procedure, and to maintain oxygenation as long as possible during procedure. This is achieved by application of apneic oxygenation, through a small catheter, connected to high flow oxygen. Participants are exposed during first dilation to no oxygenation, while during second and third dilatation to apneic oxygenation. Aim of the study is to investigate primarily whether application of apneic oxygenation, in pediatric patients during tracheal balloon dilatation, maintains regional cerebral oxygen saturation rSO2 in significant higher levels, compared with no application of oxygenation. rSO2 levels are a sensitive index of oxygenation efficacy of the brain, accordingly this refers to a safe procedure. Secondary issues are whether application of apneic oxygenation maintains pulse oximetry SpO2 and artierial oxygen partial pressure PaO2 in higher levels, and what are the effects on arterial carbon dioxide partial pressure PaCO2 and on haemodynamic parameters (heart rate, blood pressure), compared with no application of apneic oxygenation.
Prospective cohort study of COVID-19 infection among children in Norway.
The term ''Non-invasive ventilation'' (NIV) refers to various methods of respiratory assistance, in the absence of an indwelling endotracheal tube. In recent years, the use of NIV has increased for the treatment of both acute and chronic pediatric respiratory failure. Patient tolerance to the technique is a critical factor determining its success in avoiding endotracheal intubation. One of the key factors determining tolerance to NIV is optimal synchrony between the patient's spontaneous breathing activity and the ventilator's set parameters, known as ''patient-ventilator interaction''. Indeed, synchronization of the ventilator breath with the patient's inspiratory effort, optimizes comfort, minimizes work of breathing and reduces the need for sedation. During NIV, several factors can significantly interfere with the function of the ventilator, leading to an increased risk of asynchrony. Indeed, the presence of unintentional leaks at the patient-mask interface, the sensitivity of inspiratory and expiratory triggers, the ability to compensate for intentional and unintentional leaks and the presence/absence of expiratory valves are all factors that likely play a role in determining patient-ventilator synchronization. The investigators therefore designed the present crossover trial in order to compare the degree of respiratory asynchronies during NIV using different ventilators (Turbine-driven ventilator vs. compressed air-driven ICU ventilators) and different setups (single circuit vs. double circuit) in children with acute respiratory failure.