View clinical trials related to Pediatric Respiratory Diseases.
Filter by: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.
This pilot study will evaluate study processes and feasibility of a future large-scale clinical trial that proposes to test whether low-risk children managed as outpatients with community-acquired pneumonia (CAP) and procalcitonin (PCT) levels <0.25 ng/mL treated with placebo have a similar clinical response to those treated with antibiotics and fewer adverse effects.
Prospective cohort study of COVID-19 infection among children in Norway.
The use of POCUS in pediatrics is gaining momentum, and whilst pediatric specific data remains limited when compared to adult critical care, there is growing pediatric evidence demonstrating the high sensitivity and specificity of lung POCUS in the diagnosis of pneumonia, bronchiolitis, pleural effusion and pneumothorax. the American Academy of Pediatrics policy statement cautions that "clinicians should be aware that point of care ultrasonography is better used as a rule in and not a rule out diagnostic modality".
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.
The purpose of this study is to determine the utility of point-of-care lung ultrasound (POC-LUS) in identifying the etiology of acute respiratory failure in pediatric patients admitted to the pediatric intensive care unit.
Non-invasive ventilation (NIV, delivered via a mask or cannulas) permits to reduce the need for tracheal intubation in infants who needs a ventilatory support. NIV can be delivered with nasal CPAP (continuous positive airway pressure) or NIPPV (nasal intermittent positive pressure ventilation). The synchronization of the respiratory support according to the patient's demand is very difficult to obtain in infants with the conventional ventilatory modes. In all these ventilatory modes, the end-expiratory pressure (PEEP) is fixed and set by the clinician. However, since infants are prone to alveolar collapse and must compensate for a non-compliant chest wall, an active and ongoing management of PEEP is very important to prevent the lung de-recruitment. A new respiratory support system (NeuroPAP) has been developed to address these issues of synchronization and control of PEEP. This new system uses diaphragmatic tonic activity (Edi) that reflects the patient's efforts to increase lung recruitment and therefore it continuously controls the delivery of assist continuously both during inspiration (like NAVA) and during expiration, allowing a unique neural control of PEEP. A new device, the NeuroBOX, permits to deliver NIV with NeuroPAP, CPAP, or NIPPV, and also to serve as a cardio-respiratory monitor, tracking and displaying cardiac and respiratory signals, trends, and cardio-vascular events. The two main objectives of this study are: 1- To evaluate the clinical impact of NeuroPAP in infants with high tonic Edi; 2- To characterize the cardio-respiratory pattern and its relationship with cerebral perfusion of infants with noninvasive support, using the monitoring capacity of the NeuroBOX. The investigators expect that NeuroPAP will permit to improve the efficiency of NIV in infants, through the better synchronization and the personalization of the expiratory pressure level in response to the patient needs. This study will be conducted in two subgroups of patients at high risk of elevated tonic Edi and of cardio-respiratory events: a subgroup of premature infants and a subgroup of infants with bronchiolitis.
Obstructive airways disease is the most common group of acute illnesses leading to hospital treatment in children. This group consists of different age-related diagnoses, such as bronchiolitis in infants or wheezing and asthma in older children. Though these entities overlap with each other, they have common characteristics and the same leading symptom breathing distress. The investigators aim conduct an observational cohort study to examine if the clinical course of respiratory distress be quantified and the treatment improved in children with acute breathing difficulty using a new non-touch non-invasive SLP measurement device? Thora3Di is a new CE- and FDA-approved medical device able to measure chest and abdominal wall movements during tidal breathing with a method called structured light plethysmography (SLP). The method is non-touch and non- invasive, it does not need any connection with the child. One-month- to 12-years-old infants and children are recruited from the paediatric wards at Evelina London Children's hospital. The child lies or sits within the field of vision of the SLP device with their chest and abdomen exposed. A grid pattern of normal light will be projected onto the chest and changes in the format of the grid as the infant or child breathes will be recorded by the SLP device. Data will be collected for each child for 3-5 minutes once in 24 hour periods for 2-10 times during hospital stay. The aim is to reduce duration of hospital stay by finding predicting parameters for obstructive airways diseases with the new SLP method, and further aim to standardization of treatment strategies, to reduce expenditure.
The purpose of the study is to prospectively assess the use of a modified tracheal balloon dilator in children (<13 years old) with subglottic or tracheal stenosis. The hypothesis is that the device will effectively dilate the stenotic segment, whilst maintaining oxygenation (if applicable). The primary aim is to measure the stenosis prior to, and after dilatation; using diameter and the modified Myer-Cotton grading system. Secondary aims include assessment of stenosis at six-week follow-up and monitoring arterial oxygenation nadir (using peripheral plethysmography) during the procedure.
This study is a Phase II controlled clinical trial that will obtain comprehensive, serial assessments of respiratory muscle strength and architecture to understand the evolution of ventilator-induced respiratory muscle weakness in critically ill children, and test whether a novel computer-based approach (Real-time Effort Driven ventilator management (REDvent)) can preserve respiratory muscle strength and reduce time on MV. REDvent offers systematic recommendations to reduce controlled ventilation during the acute phase of MV, and uses real-time measures from esophageal manometry to adjust supported ventilator pressures such that patient effort of breathing remains in a normal range during the ventilator weaning phase. This phase II clinical trial is expected to enroll 276 children with pulmonary parenchymal disease, anticipated to be ventilated > 48 hrs. Patients will be randomized to REDvent-acute vs. usual care for the acute phase of MV (interval from intubation to first spontaneous breathing trial (SBT)). Patients in either group who fail their first Spontaneous Breathing Trial (SBT), will also be randomized to REDvent-weaning vs. usual care for the weaning phase of MV (interval from first SBT to passing SBT). The primary clinical outcome is length of weaning (time from first SBT until successful passage of an SBT or extubation (whichever comes first)). Mechanistic outcomes surround multi-modal serial measures of respiratory muscle capacity (PiMax), load (resistance, compliance), effort (esophageal manometry), and architecture (ultrasound) throughout the course of MV. Upon completion, this study will provide important information on the pathogenesis and timing of respiratory muscle weakness during MV in children and whether this weakness can be mitigated by promoting more normal patient effort during MV via the use of REDvent. This will form the basis for a larger, Phase III multi-center study, powered for key clinical outcomes such as 28-day Ventilator Free Days.