Active clinical trials for "Bronchopulmonary Dysplasia"

Background: Non-invasive forms of respiratory support have been developed to manage respiratory distress and failure in premature newborns without exposing them to the risks associated with invasive mechanical ventilation. It has been difficult to synchronize non-invasive ventilation due to the large air leaks, high respiratory rates, and small tidal volumes inherent to this interface and population. Neurally adjusted ventilatory assist (NAVA) is a novel mode of ventilation that uses a functional naso/orogastric tube with embedded electrodes which detect diaphragmatic contractions (called the Edi signal). NAVA uses this Edi signal to synchronize ventilator support to the patient's own respiratory efforts and to support these efforts as needed. Few studies have examined the use of NAVA with non-invasive ventilation (NIV) in preterm neonates. A group at Arkansas Children's Hospital recently completed a study, looking at work of breathing in an animal model comparing NIV NAVA with the unsynchronized nasal intermittent positive pressure (NIPPV) mode currently used at this hospital. They were able to show that work of breathing was lower with NAVA in this model. This study will take what was shown in the animal model and translate this to the bedside. Using respiratory inductance plethysmography to measure thoracoabdominal asynchrony, this study will compare work of breathing during NIPPV versus NIV NAVA in preterm neonates with respiratory insufficiency. Hypothesis: Work of breathing as estimated by the phase angle (θ) using respiratory inductance plethysmography will be decreased with the use of NIV NAVA in comparison to unsynchronized NIPPV in premature neonates with respiratory insufficiency. Methods: Fifteen premature neonates of between 1-2 kilograms' current weight, with gestational age at birth between 24-34 weeks, and receiving non-invasive ventilation will be enrolled in the study after consent is obtained. The infants will be ventilated using NIV NAVA and NIPPV applied in random order for 15 minutes each while using respiratory inductance plethysmography to measure thoracoabdominal asynchrony as an estimate of work of breathing. Significance: This study will identify whether or not NIV NAVA has advantages over NIPPV for improving work of breathing in premature neonates.

This pilot study was a randomized, placebo-controlled, clinical trial to measure changes in blood and urine levels of inositol in premature infants at high risk for retinopathy of prematurity (ROP) following a single intravenous dose of inositol. Based on previous studies, the premise is that maintaining inositol concentrations similar to those occurring naturally in utero will reduce the rates of ROP and bronchopulmonary dysplasia in premature infants. The objective was to evaluate the single-dose pharmacokinetics and safety of different amounts of intravenous myo-inositol (provided by Ross Products Division, Abbott Laboratories) in very low birth weight neonates, in preparation for a future Phase III multi-center randomized controlled trial. This study enrolled 74 infants at high risk for retinopathy at 9 NICHD Neonatal Research Network sites, and randomly assigned them to receive either 60mg/kg of 5% inositol, 120 mg/kg of 5% inositol, 60 mg/kg of 5% glucose (the placebo), or 120 mg/kg of 5% glucose.

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.

Based on success with telephone follow up for other groups of medically fragile infants, we designed an innovative model of post-hospital comprehensive and coordinated follow-up for infants with chronic lung disease. In this model, which we refer to as community-based follow-up, medical management was coordinated by a nurse specialist, through frequent telephone contacts with the infants' primary caregiver. This model of follow up care was compared, in a randomized trial, with the more traditional model - multidisciplinary medical center-based care. We hypothesized that community-based care would lead to health and developmental outcomes similar to those observed with center-based care.

This study compared the use of continuous positive airway pressure initiated at birth with the early administration of surfactant administered through a tube in the windpipe within 1 hour of birth for premature infants born at 24 to 27 weeks gestation. In addition, these infants within 2 hours of birth, had a special pulse oximeter placed to continuously monitor their oxygen saturation in two different target ranges (85-89% or 91-95%). This study helped determine whether or not these two management strategies affect chronic lung disease and survival of premature infants.

The primary aim of this study is to quantify and compare changes in lung volumes (as measured by functional residual capacity) in premature infants stable on continuous positive airway pressure (CPAP), and then randomized to two additional weeks of CPAP and room air versus room air alone. We hypothesize that infants randomized to additional CPAP will demonstrate an increased functional residual capacity (at the end of the two week study period and prior to discharge) compared to those randomized to room air.

Preterm birth alters the normal sequence of lung development with lasting respiratory consequences. It is still unclear whether observed respiratory morbidities in preterm born individuals reflect sequelae from a non-progressive lung disease that occurred early in life or result from ongoing active disease that, if left undiagnosed and untreated, could increase the risk of a COPD-like phenotype. We propose to examine micro-structural abnormalities of the lung using innovative non-invasive imaging technologies in relation to pulmonary function and markers of inflammation and oxidative stress in young adults born preterm.

Premature infants are at risk for a variety of diseases, the investigators would like to learn more about why some premature babies are at higher risk and some are protected from these diseases. Scientists at UC Davis and other universities have developed new ways to measure the bacteria and a large number of small molecules in specimens of infant blood, urine, stomach fluid and poop and in mother's milk. These discoveries allow us to consider questions that were impossible to answer before these new techniques were developed. One such question is whether the bacteria in the poop of a premature baby can help us predict the baby's risk for developing infection or a common and serious disease of premature infants called necrotizing enterocolitis. A second question is whether the DNA of a premature baby (obtained from saliva with a q-tip) can predict higher risk for diseases of premature babies.

Infants will be monitored by TcCO2 during three consecutive time periods of one hour each on a high and low rate of NIPPV, when in a stable condition. NIPPV rate will start high/low, changed to low/high and switched back to starting rate.

BACKGROUND Treatment of neonatal respiratory distress syndrome with exogenous surfactant and mechanical ventilation made millions of preterm infants survived in neonatal intensive care unit (NICU). Endotracheal intubation surfactant administration is related to invasive intubation and short periods of positive pressure ventilation and implies the risk of lung injury. Continuous positive airway pressure (CPAP) or NIPPV (Non-invasive positive pressure ventilation) with surfactant but without intubation may work synergistically. This randomized trial investigated a minimal invasive surfactant administration (MISA). To test the hypothesis that MISA increases survival without bronchopulmonary dysplasia (BPD) at 36 weeks' gestational age in very low birth weight infants. DESIGN, SETTING, AND PARTICIPANTS The Minimal Invasive Surfactant Administration (MISA) was a multicenter, randomized, clinical, parallel-group study conducted between July 1st, 2017, and November 30, 2018, in 8 level III neonatal intensive care units in Beijing, Tianjin, and Hebei province, China. The final follow-up date was March 30, 2019. Participants enrolled spontaneously breathing preterm infants born between 26.1 and 31.9 weeks' gestational age with signs of respiratory distress syndrome. In an intention-to-treat design, infants were randomly assigned to receive surfactant (Calf pulmonary surfactant, Double-Crane Pharmaceutical Co., China) either via a 5Fr nasogastric tube during CPAP/NIPPV-assisted spontaneous breathing (minimal invasive surfactant administration group, MISA group) or after conventional endotracheal intubation during mechanical ventilation (endotracheal intubation surfactant administration group, EISA group). INTERVENTION MISA via a 5Fr nasogastric tube with an ophthalmic surgery straight forceps.