View clinical trials related to Bronchopulmonary Dysplasia.
Filter by:We hypothesis a period of early NCPAP before surfactant treatment is effective for treating RDS and preventing BPD in very premature infants.
The study aims to investigate efficacy and safety of nasal mask and prongs used in non-invasive ventilation in newborns by using esophageal pressure transducer. The parameters including ventilation duration, hospitalization duration, pulmonary outcomes and side effects will be evaluated.
Background Ventilator induced lung injury (VILI) remains a problem in neonatology. High frequency oscillatory ventilation (HFOV) provides effective gas exchange with minimal pressure fluctuation around a continuous distending pressure and therefore small tidal volume. Animal studies showed that recruitment and maintenance of functional residual capacity (FRC) during HFOV ("open lung concept") could reduce lung injury. "Open lung HFOV" is achieved by delivering a moderate high mean airway pressure (MAP) using oxygenation as a guide of lung recruitment. Some neonatologists suggest combining HFOV with recurrent sigh-breaths (HFOV-sigh) delivered as modified conventional ventilator-breaths at a rate of 3/min. The clinical observation is that HFOV-sigh leads to more stable oxygenation, quicker weaning and shorter ventilation. This may be related to improved lung recruitment. Electric Impedance Tomography (EIT) enables measurement and mapping of regional ventilation distribution and end-expiratory lung volume (EELV). EIT generates cross-sectional images of the subject based on measurement of surface electrical potentials resulting from an excitation with small electrical currents and has been shown to be a valid and safe tool in neonates. Purpose, aims: - To compare HFOV-sigh with HFOV-only and determine if there is a difference in global and regional EELV (primary endpoints) and spatial distribution of ventilation measured by EIT - To provide information on feasibility and treatment effect of HFOV-sigh to assist planning larger studies. We hypothesize that EELV during HFOV-sigh is higher, and that regional ventilation distribution is more homogenous. Methods: Infants at 24-36 weeks corrected gestational age already on HFOV are eligible. Patients will be randomly assigned to HFOV-sigh (3 breaths/min) followed by HFOV-only or vice versa for 4 alternating 1-hours periods (2-treatment, double crossover design, each patient being its own control). During HFOV-sigh set-pressure will be reduced to keep MAP constant, otherwise HFOV will remain at pretrial settings. 16 ECG-electrodes for EIT recording will be placed around the chest at study start. Each recording will last 180s, and will be done at baseline and at 30 and 50 minutes after each change in ventilator modus. Feasibility No information of EIT-measured EELV in babies on HFOV-sigh exists. This study is a pilot-trial. In a similar study-protocol of lung recruitment during HFOV-sigh using "a/A-ratio" as outcome, 16 patients was estimated to be sufficient to show an improvement by 25%. This assumption was based on clinical experience in a unit using HFOV-sigh routinely. As the present study examines the same intervention we assume that N=16 patients will be a sufficient sample size. We estimate to include this number in 6 months.
Background: Ventilator induced lung injury (VILI) remains a problem in neonatology. High frequency oscillatory ventilation (HFOV) provides effective gas exchange with minimal pressure fluctuation around a continuous distending pressure and therefore small tidal volume. Animal studies showed that recruitment and maintenance of functional residual capacity (FRC) during HFOV ("open lung concept") could reduce lung injury. "Open lung HFOV" is achieved by delivering a moderate high mean airway pressure (MAP) using oxygenation as a guide of lung recruitment. Some neonatologists suggest combining HFOV with recurrent sigh-breaths (HFOV-sigh) delivered as modified conventional ventilator-breaths at a rate of 3/min. The clinical observation is that HFOV-sigh leads to more stable oxygenation, quicker weaning and shorter ventilation. This may be related to improved lung recruitment. This has however to our knowledge not been tested in a clinical trial using modern ventilators. Purpose, aims: - To compare HFOV-sigh with HFOV-only and determine if there is a difference in oxygenation expressed as a/A-ratio and/or stability of oxygenation expressed as percentage time with oxygen saturation outside the reference range. - To provide information on feasibility and treatment effect of HFOV-sigh to assist planning larger studies. We hypothesize that oxygenation is better during HFOV-sigh. Methods: Infants at 24-36 weeks corrected gestational age already on HFOV are eligible. Patients will be randomly assigned to HFOV-sigh (3 breaths/min) followed by HFOV-only or vice versa for 4 alternating 1-hours periods (2-treatment, double crossover design, each patient being its own control). During HFOV-sigh set-pressure will be reduced to keep MAP constant, otherwise HFOV will remain at pretrial settings. Outcome will be calculated from normal clinical parameters including pulx-oximetry and transcutaneous monitoring of oxygen and carbon-dioxide partial pressures.
Bronchopulmonary Dysplasia (BPD) is a multi-factorial disease process that is the end result of an immature, surfactant deficient lung that has been exposed to hyperoxia, mechanical ventilation and infection. These conditions initiate an inflammatory response characterized by elevated inflammatory cell infiltrates and proinflammatory cytokines that lead to the development of significant acute and chronic lung injury. The study drug, rhCC10, is a recombinant version of natural human CC10 protein. Native CC10 is produced primarily by non-ciliated respiratory epithelial cells, called Clara cells and is the most abundant protein in the mucosal fluids in normal healthy lungs. The purpose of this study is to evaluate the pharmacokinetics, safety, tolerability and anti-inflammatory effects of a single intratracheal (IT) dose of rhCC10 to intubated premature infants receiving positive pressure ventilation for treatment of respiratory distress syndrome (RDS) to prevent long term respiratory complications referred to as bronchopulmonary dysplasia, and, more recently, as Chronic Pulmonary Insufficiency of Prematurity (CPIP; asthma, cough, wheezing, multiple respiratory infections). CC10 regulates inflammatory responses and protects the structural integrity of pulmonary tissue while preserving pulmonary mechanical function during various insults (eg. viral infection, bacterial endotoxin, ozone, allergens, hyperoxia). Together these properties suggest that administration of rhCC10 may help to facilitate development of normal airway epithelia and prevent the inflammation that leads to CPIP in these infants. This study is funded by the FDA Office of Orphan Product Development (OOPD).
This is a follow-up study to investigate the long-term safety and efficacy of PNEUMOSTEM® versus placebo, for the treatment of BPD in premature infants. Subjects who participated in and completed the initial stage of the Phase II trial (NCT01828957) will be followed-up until 60 months of corrected age.
Bronchopulmonary dysplasia (BPD) is one of the most important morbidities of preterm infants with a high incidence and significant impact on resource utilization and long-term outcome. Systemic corticosteroids have been shown to be effective in the prevention of BPD through their potent anti-inflammatory effects but there are serious concerns on their potential detrimental effects on neurodevelopment of infants. In contrast, inhaled corticosteroids administered to ventilated infants are thought to be safer due to their topical effect but have not been shown to improve outcomes including BPD. To date, there have been few studies evaluating the effect of inhaled corticosteroids administered to non-ventilated infants for the prevention of BPD. Hence, we are conducting a double-blind randomized controlled pilot trial to examine the impact of inhaled budesonide on non-ventilated infants. The study objectives, in a cohort of very preterm infants with signs of early BPD are: 1) to evaluate the effect of aerosolized budesonide on 'days on supplemental oxygen', and 2) to gain an estimate of the impact on BPD and 3) to assess the safety of the intervention in a small cohort of preterm infants. This will be a single-center randomized double-blind controlled pilot trial. We will recruit a total of 50 infants born at less than 30 weeks gestation who are on continuous positive airway pressure (CPAP) with fraction of inspired oxygen ≥25% on day 14 of life or later. Inhaled budesonide 1mg (intervention group) or normal saline (placebo) will be administered three times a day until the infants do not need CPAP or supplemental oxygen or reach 36+0/7 weeks corrected gestational age. We will evaluate 'days on supplemental oxygen', BPD, re-intubation rates, days on mechanical ventilation and days on CPAP as well as adverse outcomes. The prevention of BPD would have a significant positive impact on patient quality of life and medical resource utilization and costs. The study hypothesis is that inhaled budesonide on non-ventilated infants with early signs of BPD will reduce the 'days on supplemental oxygen' indicating a positive effect for the prevention of BPD. The result of this pilot study might also justify and support to proceed to a large confirmatory study to evaluate an effect of the intervention on BPD, in which the estimate of the impact on BPD gained in this pilot trial may be used to calculate a sample size.
The objective of this study is to evaluate the efficacy and safety of a single intratracheal administration of Pneumostem® for treatment of Bronchopulmonary Dysplasia (BPD) in high-risk premature infants by comparing Pneumostem-treated group with a control group.
Background: - Some premature babies develop bronchopulmonary dysplasia (BPD) and retinopathy of prematurity (ROP). BPD and ROP are long-term chronic diseases of the lungs and eyes, respectively. BPD is associated with receiving mechanical ventilation to treat respiratory distress syndrome, and causes lung inflammation and scarring. ROP is caused by poor development of blood vessels in the eyes, and may lead to blindness. Because not all premature babies develop BPD or ROP, researchers want to study the genes that could be associated with these diseases. They will look at both premature infants and their parents to see if there is a genetic component to BPD and ROP. Objectives: - To study genes that may be associated with BPD and ROP. Eligibility: - Premature babies born with a weight less than or equal to 1,250 grams. - Parents of the premature babies. Design: - Parents will answer questions about the mother s health and pregnancy. - Delivery and medical information will be collected during the baby s hospitalization for the first month after birth. - Parents will provide a saliva sample from the inside of the cheek. - A saliva sample will also be collected from the baby within 28 days of birth. If the baby needs tracheal aspiration (removal of fluid from the throat), tracheal fluid samples will also be collected. - Parents will have followup interviews about their child s health 6 months, 12 months, and yearly for up to 6 years after birth. - This is a genetic study only. Treatment will not be provided as part of this study.
The purpose of this study is to identify biological markers that might predict premature infants who are at a higher risk for developing BPD, and to correlate the presence of these markers with infant symptoms and lung function in the first year after discharge from the hospital.