Curosurf and Survanta Treatment(CAST)of RDS in Very Premature Infants

Phase 4

Terminated

Conditions: Prematurity
Respiratory Distress Syndrome
Patent Ductus Arteriosus

Interventions: Drug: Survanta (beractant)
Drug: Curosurf (poractant)

Registration Number: NCT00767039

Lead Sponsor: Alan Fujii

Brief Summary: Approval of surfactant by the FDA in 1989 for the treatment of Respiratory Distress Syndrome (RDS) in premature infants greatly improved survival rates. Newer surfactants approved by the FDA were more concentrated and had a more rapid onset of action. The overall efficacy of newer surfactants appeared similar until in 2004, Ramanathan and colleagues suggested that a double dose of Curosurf improved survival in infants 25-32 weeks gestational age, compared to infants treated with Survanta, the most commonly used surfactant preparation in the United States. While the data was suggestive, it was not clear that the improvement in survival was reproducible or that Curosurf was responsible for the improved survival rates.

The purpose of this study was to investigate the role of Curosurf in improving lung function and survival rates and reducing the complications of prematurity in very premature infants \< 30 weeks gestational age at birth.

Detailed Description: Specific Aims:

* To determine whether there is a sustained difference in the level of respiratory support during the first 3 days of life in extremely premature infants treated with Curosurf versus Survanta

* To determine whether Curosurf is associated with a higher incidence of hemodynamically significant PDA, compared with Survanta

* To determine whether there is a difference in the cerebral blood flow response to Curosurf versus Survanta

* To determine whether there is a difference in morbidity in very premature infants treated with Curosurf versus Survanta

We reasoned that if Curosurf was primarily responsible for improved survival rates, compared with Survanta, then there should be a sustained improvement in respiratory function in the first three days of life, when the direct pulmonary effects of the surfactant preparations would be most easily detected. It was also possible that Curosurf and Survanta could have effects on other systems that could secondarily affect long-term survival of the infant. These other organ systems would include, but not be limited to, the development of a hemodynamically significant Patent Ductus Arteriosus, Intraventricular Hemorrhage or Periventricular Leukomalacia, or Necrotizing Enterocolitis. We propose to examine how surfactant administration affected the hemodynamic precursors of these common morbidities of very premature infants.

Recruitment & Eligibility

Status: TERMINATED

Sex: All

Target Recruitment: 52

Inclusion Criteria

<29 6/7 and >24 0/7 weeks gestational age
Inborn at the participating institution enrolling the patient
FIO2 >25% and Intubated with mean airway pressure > 5 cm H20
<8 hours age at randomization
Signed informed consent from parent(s)

Exclusion Criteria

<500 g birth weight
<24 0/7 weeks gestational age (best estimate)
Prolonged Premature Rupture of membranes >3 weeks (21 days)
Apgar score < 3 at 5 minutes
Impending death anticipated within the first 3 days of life, moribund
Severe congenital anomalies

Study & Design

Study Type: INTERVENTIONAL

Study Design: PARALLEL

Arm && Interventions

Group	Intervention	Description
1	Survanta (beractant)	Surfactant (beractant, Survanta initial dose 100 mg/kg and subsequent doses 100 mg/kg phospholipids every 6-12 hours, as needed for up to 4 doses), intratracheal administration to very premature infants with RDS requiring mechanical ventilation
2	Curosurf (poractant)	Surfactant (poractant, Curosurf initial dose 200 mg/kg and subsequent doses 100 mg/kg phospholipids every 12-24 hours as needed for up to 3 doses), intratracheal administration to very premature infants with RDS requiring mechanical ventilation

Primary Outcome Measures

Name	Time	Method
Comparison Respiratory Support (Mean Airway Pressure) for Survanta (Beractant) and Curosurf (Poractant) at 48 Hours After Surfactant Administration.	48 hours after surfactant administration	Mean Airway Pressure delivered by mechanical ventilator or nasal CPAP (cm H20) at 48 hours following surfactant administration. A volume cycle ventilator strategy that allowed airway pressure to vary with changes in lung and chest wall compliance was used for mechanically ventilated infants, while inspired oxygen concentration was controlled by the clinical team.
Comparison of Respiratory Support (Mean Airway Pressure) for Curosurf (Poractant) and Survanta (Beractant) 72 Hours After Surfactant Administration	72 hours after surfactant administration	Mean Airway Pressure delivered by mechanical ventilator or nasal CPAP (cm H20) at 72 hours following surfactant administration. A volume cycle ventilator strategy that allowed airway pressure to vary with changes in lung and chest wall compliance was used for mechanically ventilated infants, while oxygen concentration was controlled by the clinical team.
Comparison Respiratory Support (Mean Airway Pressure x Percent Fraction of Inspired Oxygen) for Survanta (Beractant) and Curosurf (Poractant) at 48 Hours After Surfactant Administration.	48 hours after surfactant administration	Mean Airway Pressure x Percent Fraction of Inspired Oxygen (FIO2) at 48 hours after surfactant administration, delivered by mechanical ventilator or nasal CPAP assesses the components of respiratory support primarily affecting blood oxygenation. This index combines these parameters so that a systematic difference in clinical management of mean airway pressure or FIO2 between groups is not mistaken for a drug effect.
Comparison Respiratory Support (Mean Airway Pressure x Percent Fraction of Inspired Oxygen) for Survanta (Beractant) and Curosurf (Poractant) at 72 Hours After Surfactant Administration.	72 hours after surfactant administration	Mean Airway Pressure x Percent Fraction of Inspired Oxygen (FIO2) at 72 hours after surfactant administration, delivered by mechanical ventilator or nasal CPAP assesses the components of respiratory support primarily affecting blood oxygenation. This index combines these parameters so that a systematic difference in clinical management of mean airway pressure or FIO2 between groups is not mistaken for a drug effect.

Secondary Outcome Measures

Name	Time	Method
Comparison of Infants Successfully Extubated at 48 Hours for Curosurf (Poractant) and Survanta (Beractant) Groups	48 hours after surfactant administration	Subjects successfully extubated and no longer needing positive pressure endotracheal mechanical ventilation at 48 hours after surfactant administration helps to explain the difference in mean airway pressure observed between groups.
Comparison of Infants Successfully Extubated at 72 Hours for Curosurf (Poractant) and Survanta (Beractant) Groups	72 hours after surfactant administration	Subjects successfully extubated and no longer needing positive pressure endotracheal mechanical ventilation at 72 hours after surfactant administration helps to explain the difference in mean airway pressure observed between groups.
Comparison of Hemodynamically Significant Patent Ductus Arteriosus (PDA) in Patients Treated With Curosurf (Poractant) and Survanta (Beractant)	Hemodynamically significant PDA at > 2 days	Hemodynamically significant PDA, considered significant by the clinical team and having at least 2 objective echocardiographic signs (PDA \> 1.5 mm diameter, retrograde diastolic flow in the descending aorta, and left atrial enlargement) were tallied. Hemodynamically significant PDA may increase lung water and decrease lung compliance, requiring increased mechanical ventilator support.
Changes in Blood Flow Through the Patent Ductus Arteriosus (PDA) Following Second Dose of Survanta (Beractant) and Poractant Alfa (Curosurf)	First hour after 2nd surfactant dose	Maximal changes in blood flow were assessed using Doppler echocardiography following the second surfactant dose of Survanta (beractant) or Curosurf (poractant alfa), to determine whether there was a direct effect of surfactant type on PDA size or pulmonary volume overload through the PDA. The hour interval following the second surfactant dose was selected for study, when the subjects were otherwise clinically stable, not needing additional stabilization procedures.
Change in Anterior Cerebral Artery Blood Flow Velocity Following Second Dose of Surfactant	One hour following second surfactant dose at 12-24 hours after initial dose	Percent change in Anterior Cerebral Artery blood flow velocity following the second dose of beractant, reflects the change in brain blood flow associated with surfactant administration. Blood flow velocity is measured by range gated Doppler ultrasound and brain blood flow changes in proportion to changes in arterial carbon dioxide levels, induced by surfactant administration. Variability in brain blood flow is associated with increased risk for intraventricular hemorrhage.
Patients With Bronchopulmonary Dysplasia (Supplemental Oxygen at 36 Week Post Menstrual Age)	36 weeks post menstrual age	Patients with Bronchopulmonary Dysplasia (BPD), had chronic lung disease requiring supplemental oxygen support at \>/= 36 weeks post menstrual age, were tallied. BPD is a chronic lung disease that develops, at least in part, as a consequence of NICU respiratory management of premature infants with Respiratory Distress Syndrome.
Bronchopulmonary Dysplasia (Supplemental Oxygen at 36 Week Post Menstrual Age) or Death Before Discharge From NICU.	NICU hospitalization, up to 42 weeks post menstrual age	Bronchopulmonary Dysplasia + death outcome for all patients enrolled in the study were tallied and used to determine whether neonatal death decreased the frequency of chronic lung disease in one group vs the other.