Date of most recent amendment: 14/07/1999
Date of most recent substantive amendment: 13/07/1999
Date next stage expected: / /
Contact
Dr Roger F. Soll
Associate Professor of Pediatrics
Department of Pediatrics
University of Vermont College of Medicine
A-121 Medical Alumni Building
Burlington
VT USA
05405-0068
Telephone 1: +1-802-656-2392
Facsimile: +1-802-656-2077
E-mail: rsoll@salus.med.uvm.edu
Sources of support for the review
Acknowledgements
We would like to thank Nancy Moreland for her help in preparing the
manuscript.
Potential conflict of interest
Dr. R. Soll has acted as a paid consultant and invited speaker for
several of the pharmaceutical companies which manufacture surfactant preparations
(Abbott Laboratories, Ross Laboratories, Chiesi Pharmaceuticals, Dey Laboratories,
Burroughs Wellcome).
Although both prophylactic surfactant administration and surfactant treatment of infants with established respiratory distress syndrome are successful treatment strategies, prophylactic strategies appear to have greater clinical benefit. In a systematic overview of trials comparing prophylactic surfactant administration to surfactant treatment of established respiratory distress syndrome, infants who received prophylactic therapy had a decreased incidence of pneumothorax, pulmonary interstitial emphysema, and mortality (Soll 1999). However, the approaches used to select treatment vary greatly in these studies. Selective treatment in infants with respiratory distress syndrome ranged from 1.5 hours to 8 hours of age.
Earlier treatment of infants with evolving respiratory distress syndrome may offer many of the advantages of prophylactic therapy. Early treatment may decrease the need for ventilatory support and avoid barotrauma that results from even short periods of assisted ventilation (Nilsson 1978). However, surfactant treatment reserved for infants with more severe respiratory distress syndrome offers the advantage of treating only infants with serious clinical disease, eliminating the potential risks and costs of treating relatively mildly affected infants.
As noted above, previous reviews have addressed the clinical issue of
prophylactic surfactant administration (intubation and surfactant administration
to infants at high risk of developing RDS) compared to surfactant treatment
of RDS (Soll 1999). This review will evaluate early selective treatment
of RDS (within the first two hours of life) compared with late selective
treatment in infants with established respiratory distress syndrome.
Types of participants
Premature infants with respiratory distress syndrome, requiring intubation
and assisted ventilation at <2 hours of life.
Types of intervention
Early selective surfactant administration (surfactant administration
via the endotracheal tube in infants intubated for respiratory distress,
not specifically for surfactant dosage), within the first two hours of
life, versus delayed selective administration to such infants when they
develop established respiratory distress syndrome.
Types of outcome measures
Data of the following clinical outcomes are included in the meta-analyses:
1. Pneumothorax
2. Pulmonary interstitial emphysema
3. Pulmonary hemorrhage
4. Patent ductus arteriosus
5. Necrotizing enterocolitis
6. Intraventricular hemorrhage
7. Severe intraventricular hemorrhage
8. Retinopathy of prematurity
9. Bronchopulmonary dysplasia (oxygen requirement at 28 days of life)
10. Chronic lung disease (oxygen requirement at 36 weeks adjusted age)
11. Neonatal mortality
12. Mortality prior to hospital discharge
13. Bronchopulmonary dysplasia or death at 28 days of life
14. Chronic lung disease or death at 36 weeks adjusted age
15. Number of doses per infant
Subgroup analyses evaluated the effect of surfactant type (natural surfactant extract or synthetic surfactant).
While each of the studies sought to compare early with delayed surfactant administration, significant differences were noted in the timing of the first dose. Konishi (1992) administered the early dose of surfactant within the first 30 minutes of life. The European Exosurf Trial (1992) and the OSIRIS Trial (1992) both defined early treatment as prior to 2 hours of life. Gortner (1998) used 1 hour of life as the cut-off for early treatment.
All studies attempted to evaluate a population at high risk for RDS, but differed slightly in their inclusion criteria. Konishi (1992) included babies of 500-1500g whose weight was appropriate for gestational age and whose surfactant deficiency had to be documented by analysis of the gastric aspirate. The European Exosurf Trial (1992) included infants between 26 -29 weeks, while Gortner (1998) included 27-32 weeks and OSIRIS (1992) did not specify specific inclusion criteria for gestational age or weight. All studies excluded infants with pre or post-natal congenital anomalies, as well as infants with oligohydramnios or prolonged rupture of membranes > 72 hours; all studies required informed consent.
The surfactant preparations differed between studies. Konishi (1992) and Gortner (1998) used natural bovine surfactant extract, Surfactant TA and Alveofact respectively. The European Exosurf Trial (1992) and OSIRIS (1992) treated infants with Exosurf Neonatal, a synthetic surfactant containing dipalmitoylphosphatidyl choline, tyloxapol, and hexadecanol. This review includes sub-group analyses by surfactant type.
Primary outcomes were survival and survival without BPD in both the OSIRIS (1992) and European Exosurf trials (1992). In the studies utilizing a natural surfactant extract, Konishi (1992) measured ventilatory requirements in the first 7 days of life, and Gortner (1998) measured length of mechanical ventilation as primary outcomes. Secondary outcomes included complications of prematurity.
All studies reported incidence of antenatal steroid use in experimental and control groups and demonstrated no significant difference between the study groups. Gortner (1998) was the only included study carried out in a population where the majority of infants' mothers had received a complete course of antenatal steroids. Three of the studies allowed for multiple surfactant doses. Konishi (1992) gave only 1 surfactant dose to infants in control and experimental groups.
Randomization: Methods varied between studies. Konishi (1992) did not describe any blinding of randomization, stating only that the 32 included infants were randomized after meeting inclusion criteria. Gortner (1998) provided randomization lists to the 6 participating centers from a central statistical center for medical informatics. The European Exosurf Trial (1992) generated a unique trial number corresponding to an opaque sealed envelope located at the various trial centers. OSIRIS (1992) randomized trial entrants by telephone from a central location after entry criteria were met and prognostic variables recorded.
Blinding of Treatment: Only the European Exosurf Trial (1992) maintained full blinding of treatment. Konishi (1992) and Gortner (1998) failed to comment on any blinding of treatment, and OSIRIS (1992) was unblinded to treatment by design.
Blinding of Outcome Assessment: The European Exosurf Trial (1992) demonstrated full blinding of outcome assessment. The sequential design of the trial allowed for assessment of the data by an independent, non-clinical analysis team after every 20th baby. Results that might warrant termination of the trial were to be submitted to an independent advisory board with authority to terminate the trial. The other trials did not comment on blinding at the outcome assessment level.
Exclusion after Randomization: All data were analyzed from an intent-to-treat perspective after initial randomization. The European Exosurf Trial (1992), Gortner (1998), and OSIRIS (1992) excluded no patients after the initial randomization. Konishi (1992) excluded 8 of 40 infants initially randomized, because they did not meet the prospective inclusion criteria.
The combined sample sizes of the trials using natural surfactant were
approximately one tenth the size of the trials using synthetic surfactant
(349 infants enrolled in trials utilizing natural surfactant compared to
3110 infants enrolled in trials utilizing synthetic surfactant).
The meta-analysis of all trials supports a decrease in risk of pneumothorax with early selective surfactant treatment (Typical RR: 0.70, 95%CI 0.59, 0.82; Typical RD: -0.05, 95%CI -0.08, -0.03).
PULMONARY INTERSTITIAL EMPHYSEMA: Two studies reported on the incidence of pulmonary interstitial emphysema (PIE) with early versus delayed selective surfactant. The European Exosurf Trial (1992) showed a significant decrease in the risk of PIE with early surfactant treatment (RR: 0.62, 95%CI 0.40,0.94; RD: -0.08, 95%CI -0.16, -0.01). Gortner (1998) found no significant decrease in the risk of PIE with early surfactant treatment (RR: 0.71, 95%CI 0.26, 1.94; RD: -0.16, 95%CI -0.06, 0.03).
The meta-analysis supports a significant decrease in the incidence of PIE associated with early selective surfactant administration (Typical RR: 0.63, 95%CI 0.43, 0.93; Typical RD: -0.06, 95%CI -0.10, -0.01).
PULMONARY HEMORRHAGE: Gortner (1998) reported on the risk of pulmonary hemorrhage associated with early selective surfactant treatment and found no significant effect on pulmonary hemorrhage (RR: 0.21, 95%CI 0.01, 4.37; RD: -0.01, 95%CI -0.03, 0.01). OSIRIS (1992) also failed to document a significant increase in the risk of pulmonary hemorrhage with early surfactant administration (RR: 1.01, 95%CI 0.75, 1.37; RD: 0.00, 95%CI -0.02, 0.02).
The meta-analysis found no evidence of effect on pulmonary hemorrhage with early selective surfactant treatment (Typical RR: 0.99, 95%CI 0.73, 1.34; Typical RD: -0.00, 95%CI -0.02, 0.02).
PATENT DUCTUS ARTERIOSUS: None of the 4 studies supported a decrease in the risk of patent ductus arteriosus (PDA) with early selective surfactant administration.
The meta-analysis demonstrated no evidence of effect on the risk of PDA with early selective surfactant treatment (Typical RR: 1.03, 95%CI 0.92,1.15; Typical RD: 0.01, 95%CI -0.02, 0.04).
NECROTIZING ENTEROCOLITIS: Three studies evaluated the effect of early selective surfactant treatment on the incidence of necrotizing enterocolitis (NEC). None demonstrated a significant effect.
The meta-analysis demonstrated no evidence of effect on the risk of NEC with early selective surfactant treatment (Typical RR: 1.08, 95%CI 0.77, 1.51; Typical RD: 0.00, 95%CI -0.01, 0.02).
RETINOPATHY OF PREMATURITY (Stage III or greater): Three of the included studies reported on the incidence of retinopathy of prematurity (ROP) associated with early selective surfactant treatment. No significant effect was reported.
The meta-analysis demonstrated no evidence of effect on the risk of ROP with early surfactant therapy (Typical RR: 1.06, 95%CI 0.58,1.91; Typical RD: 0.00, 95%CI -0.01, 0.01).
INTRAVENTRICULAR HEMORRHAGE (all grades): Only Konishi (1992) reports on the incidence of any intraventricular hemorrhage (IVH) associated with early selective surfactant treatment. No significant change in the rate of any IVH was noted (RR: 1.00, 95%CI 0.30, 3.32; RD: 0.00, 95%CI -0.30, 0.30).
INTRAVENTRICULAR HEMORRHAGE (Severe): The OSIRIS trial (1992) and Gortner (1992) reported on the incidence of severe IVH (Grades 3 and 4) associated with early selective surfactant treatment. No significant change in the risk of severe IVH was detected.
The meta-analysis does not support a significant effect on the risk of severe IVH associated with early selective surfactant administration (Typical RR: 0.97, 95%CI 0.83,1.14; Typical RD: -0.01, 95%CI -0.03, 0.02).
BRONCHOPULMONARY DYSPLASIA: Three of the included studies reported on the effect of early selective surfactant treatment on bronchopulmonary dysplasia (BPD). The stated definition of BPD in all studies but Konishi (1992) was any oxygen supplementation at 28 days of life. Konishi (1992) defined BPD as FIO2 greater than or equal to 0.3 at 28 days of life. Using data provided by the Konishi (1992) study, the more liberal and standard definition of BPD was applied to their results and included in this review. No study documented a significant reduction in BPD with early selective surfactant treatment.
The meta-analysis found no evidence of a significant reduction in the risk of BPD with early selective surfactant (Typical RR: 0.97, 95%CI 0.88, 1.06; Typical RD: -0.01, 95%CI -0.05, 0.02).
CHRONIC LUNG DISEASE: Gortner (1998) reported on the effect on chronic lung disease (CLD) of early selective surfactant administration. Gortner defined CLD as a requirement for supplemental oxygen at 36 weeks adjusted age. No significant effect of early surfactant treatment was noted (RR: 0.62, 95%CI 0.25, 1.53; RD: -0.03, 95%CI -0.08, 0.02). OSIRIS (1992) defined CLD as a supplemental oxygen requirement at the "expected delivery date," and showed a significant reduction in risk of CLD associated with early surfactant treatment (RR: 0.70, 95%CI 0.55, 0.89; RD: -0.03, 95%CI -0.06, -0.01).
The meta-analysis estimated a significant reduction in CLD with early selective surfactant treatment (Typical RR: 0.70, 95%CI 0.55, 0.88; Typical RD: -0.03, 95%CI -0.05, -0.01).
NEONATAL MORTALITY: All four included studies reported on the effect of early selective surfactant administration on neonatal mortality. None of the four studies found a significant effect on neonatal mortality, although in each of two studies, the European Exosurf trial (1992) and OSIRIS (1992), there was a trend towards decreased neonatal mortality with early surfactant treatment.
The meta-analysis estimated a significant reduction in neonatal mortality with early selective surfactant therapy (Typical RR: 0.87, 95%CI 0.77, 0.99; Typical RD: -0.03, 95%CI -0.06, -0.00).
MORTALITY PRIOR TO DISCHARGE: Three included studies reported on mortality prior to discharge. OSIRIS (1992) demonstrated a trend toward decreased risk of mortality prior to discharge with early surfactant treatment (RR: 0.89, 95%CI 0.79, 1.01; RD: -0.03, 95%CI -0.07, 0.00).
The meta-analysis estimates a similar trend (Typical RR: 0.90, 95%CI 0.79, 1.01; Typical RD: -0.03, 95%CI -0.06, 0.00).
BRONCHOPULMONARY DYSPLASIA OR DEATH AT 28 DAYS: Only the European Exosurf Trial (1992) did not comment on the effect of early selective surfactant on BPD or death at 28 days. Of the other three studies, Konishi (1992) (RR: 0.54, 95%CI 0.29, 0.98; RD: -0.38, 95%CI -0.68, -0.07) and OSIRIS (RR: 0.94, 95%CI 0.88, 1.00; RD: -0.04, 95%CI -0.08, -0.00) both showed a trend toward reduction of BPD or death with early surfactant. Gortner (1998) failed to show any reduction in incidence of the two outcomes with early surfactant (RR: 1.09, 95%CI 0.74, 1.59; RD: 0.02, 95%CI -0.08, 0.12).
The meta-analysis estimates a trend towards reduction in BPD or death at 28 days (Typical RR: 0.94, 95%CI 0.88, 1.00; Typical RD: -0.04, 95 % CI -0.07, -0.00).
CHRONIC LUNG DISEASE OR DEATH: Two studies reported on CLD or death. Gortner (1998) failed to show any reduction in incidence of the two unfavorable outcomes at 36 weeks adjusted gestational age (RR: 0.85, 95%CI 0.41, 1.75; RD: -0.01, 95%CI -0.08, 0.05). OSIRIS (1992) showed significant reductions in the rate of CLD or death at the "expected delivery date" with early selective surfactant treatment (RR: 0.84, 95%CI 0.75, 0.93; RD: -0.06, 95%CI -0.10, -0.03).
The meta-analysis supports a significant reduction in CLD or death at 36 weeks with early selective surfactant therapy (Typical RR: 0.84, 95%CI 0.75, 0.93; Typical RD: -0.06, 95%CI -0.09, -0.03).
NUMBER OF DOSES: The OSIRIS Trial (1992) and the study of Gortner (1998) reported on the number of surfactant doses given to infants. In the OSIRIS trial, infants randomized to receive early surfactant treatment received more surfactant treatments (WMD 0.49 doses per infant, 95% CI 0.41, 0.47). Gortner (1998) found no evidence of effect on the number of surfactant treatments. There was marked statistical heterogeneity for this outcome, so no typical effect was calculated.
In this review, we evaluate the merits of early selective surfactant treatment compared to delayed selective surfactant treatment in infants with RDS. Four studies were identified which compared the use of early versus delayed selective surfactant administration in a population of premature infants at risk for respiratory distress syndrome. Of the four studies, the OSIRIS trial (1992), which utilized synthetic surfactant, is by far the largest study, and dominates the estimates of the effect of these treatment strategies. Given the relatively small number of infants studied in the trials of natural surfactant extracts, it is hard to draw conclusions regarding any differences in the effects of natural vs. synthetic surfactant when used early in the treatment of respiratory distress. Overall, early selective surfactant administration decreased the risk of acute pulmonary injury (decreased risk of pneumothorax and pulmonary interstitial emphysema) and decreased the risk of neonatal mortality and chronic lung disease compared to delayed selective treatment of infants with established RDS. Based on these data, recommendations favoring earlier treatment seem reasonable.
It is hard to judge the relative value of early surfactant treatment compared to true prophylactic use of surfactant in the absence of any randomized trials that have directly compared these policies. Prophylactic rather than delayed administration of surfactant to all infants deemed at high risk for RDS reduces the risk of pneumothorax, pulmonary interstitial emphysema, bronchopulmonary dysplasia or death, as well as mortality (Soll 1999). Similar benefits are associated with early selective rather than delayed surfactant administration in premature infants intubated for respiratory distress within the first two hours of life. With prophylactic rather than delayed surfactant, the number of infants that would need to be treated to avoid one pneumothorax was 50, and only 20 to prevent one death; the present meta-analysis suggests that with early rather than delayed surfactant treatment, 20 infants need be treated to prevent one pneumothorax, and 35 to prevent one neonatal death.
Although there are no randomized trials that compare prophylactic surfactant treatment with early selective surfactant treatment, studies suggest that the greatest benefit may come from the earliest care. Prophylactic delivery room treatment is effective whether given before or after the onset of respiration. Kendig (1998) demonstrated that the benefits of prophylactic surfactant administration were preserved even if the initial therapy was delayed to the first 10 minutes of life.
However, even small delays in treating infants with established RDS appear to be clinically important. Kattwinkel (1993) conducted a study comparing prophylactic versus early surfactant therapy in the 29 - 32 week gestational age population of premature neonates. Criteria for intubation and early selective surfactant treatment were liberal; an FIO2 requirement of 0.30 with radiographic findings not consistent with another respiratory process prompted intubation for surfactant therapy. In the studies of early treatment, criteria for the early selective treatment group were frequently more stringent than in the selective treatment group of Kattwinkel (1993). OSIRIS (1992) required intubation for respiratory distress prior to surfactant dosing; no child was intubated for the sole purpose of surfactant administration. The European Exosurf Trial (1992) enrolled only infants at high risk for RDS and intubated for respiratory distress before two hours of life. Gortner (1998) administered the first dose of surfactant within the first hour of life if respiratory distress required intubation. Clearly, Kattwinkel (1993) had a lower threshold for selective surfactant treatment, and surfactant was given earlier than in most of the included studies in this review. The selective treatment group of Kattwinkel (1993) had a median time to first surfactant dose of 90 minutes versus the 118 minutes noted in the OSIRIS (1992) trial for early selective treatment. The meta-analysis of prophylactic versus delayed surfactant (Soll 1999) estimated a relative risk reduction of 41 % for neonatal mortality and 25 % for mortality prior to hospital discharge. The current analysis estimates a 13 % reduction in relative risk for neonatal mortality and a strong trend towards a 10 % reduction in relative risk of mortality prior to discharge with early versus delayed selective surfactant treatment.
This meta-analysis suggests that the substantial benefits accompanying early versus delayed selective surfactant therapy may be a part of the greater trend towards improved outcomes with earlier treatment. This is consistent with evidence of lung injury from animal studies that demonstrate leakage of proteins into the alveolar spaces of the surfactant deficient lung that act as surfactant inhibitors (Jobe 1983). Exogenous surfactant has reduced the leakage of such surfactant inhibiting proteins in animal models (Jobe 1983, Ikegami 1986).
Despite evidence supporting the efficacy of prophylactic and early surfactant therapy, estimates show that not all infants judged to be at high risk for RDS are surfactant deficient. Of the trials included in this meta-analysis, only Konishi (1992) estimated surfactant deficiency prior to surfactant administration. He found only 66% of those judged at risk for RDS based on a birth weight criterion of 500 - 1500 grams to have surfactant deficiency at birth. Kattwinkel (1993) noted that of those randomized to early selective surfactant treatment only 43% of 621 infants required surfactant as indicated by their admittedly liberal criteria. Clearly prophylaxis with surfactant would overtreat a large number of infants judged at risk for RDS, and this overtreatment may be justified to save the life of every 20th child. It appears, however, that treatment with surfactant within the first two hours of life in those infants intubated for respiratory distress confers the benefits of reduced mortality and pneumothorax while treating a substantially smaller portion of those infants judged at risk prenatally.
Antenatal steroids improve the outcome of premature infants at risk
for RDS (Crowley 1998). Gortner (1998) provided the only included study
carried out in a population where the majority of infants' mothers had
received a complete course of antenatal steroids. He failed to document
a significant reduction in rates of pneumothorax or neonatal mortality.
The review of studies comparing prophylactic versus delayed selective surfactant
administration was also carried out in populations not fully benefiting
from the documented effects of antenatal steroids. Gortner questions the
impact of prophylactic or early treatment in the population of steroid
treated infants, who are at less risk of RDS. However, most other studies
of surfactant replacement have suggested a synergistic effect of these
two therapies (Jobe 1993).
Study: Gortner 1998
Method: Randomized Multicenter Trial Blinding of Randomization:
Yes. Blinding of Intervention: can't tell
Complete Follow-up: Yes.
Blinding of Outcome Measurements: can't tell.
Stratification: None.
Participants: Early selective treatment: 154 randomized
Delayed selective treatment: 163 randomized
Inclusion Criteria:
1. Prenatal informed consent obtained.
2. Gestational age between 27 - 32 weeks.
3. No congenital anomalies leading to cardio-respiratory compromise
detected at or before deliver.
4. No rupture of membranes with oligo-or poly-hydramnios > 3 weeks
prior to delivery.
Interventions: Early Treatment: Intratracheal bovine surfactant
(100 mg/kg) during first hour of life if intubation and mechanical ventilation
required (FiO2 > 0.5, PaCO2 >60, pH< 7.25 during spontaneous respiration).
Delayed Treatment: Intratracheal bovine surfactant (100 mg/kg)
at 2-6 hours of life if intubated and requiring FIO2 > 0.4 to adequately
oxygenate. Repeat surfactant administrations given as needed with
cumulative dose ceiling of 200 mg/kg with 50 mg/kg repeat doses given no
more frequently than every 8 hours.
Outcomes: PRIMARY OUTCOME: Duration of mechanical ventilation
SECONDARY OUTCOMES: Survival, survival without BPD, and complications
of prematurity.
Study: Konishi 1992
Method: Randomized single Center Trial
Blinding of Randomization: can't tell
Blinding of Intervention: can't tell
Complete follow-up: Yes
Blinding of Outcome Measurement: can't tell
Stratification: None.
Participants: Early selective treatment: 16 randomized
Delayed selective treatment: 16 randomized
Inclusion Criteria:
1. AGA 500 -1500 gram infants.
2. Intubated for early respiratory distress.
3. Immature surfactant assay of gastric aspirates.
4. No PROM > 72 hours, maternal fever prenatally, 5 minute Apgar score
of 4 or less, oligo- or poly-hydramnios, congenital malformations, WBC
> 10 per HPF in gastric contents.
5. Informed consent obtained.
Interventions: Early Treatment: Surfactant TA (3ml/kg)
per ETT in 5 aliquots over 5 minutes given within the first 30 minutes
of life. Average age of administration = 18 minutes. Delayed
Treatment: Surfactant TA (3ml/kg() as above given around 6 hours
of life. Average age of administration = 6 hours.
Outcomes: PRIMARY OUTCOMES:
1. a/A PO2 Gradient and Mean Airway Pressure over first 72 hours of
life.
2. Ventilatory Index (FIO2 x MAP/ PaO2)
3. 5 Clinical Outcomes at 7 and 28 days of life (No support, O2, IMV
with O2 < 0.3, IMV with O2 > 0.3, Death)
SECONDARY OUTCOMES: Complications of Prematurity
Study: OSIRIS 1992
Method: Randomized Multicenter Trial. Blinding of randomization:
Yes. Blinding of Intervention: No. Complete Follow-up:
Yes. Blinding of Outcome measurement: can't tell. Stratification:
None
Participants: Early selective treatment: 1344 randomized
Delayed selective treatment: 1346 randomized
Inclusion criteria:
1. Informed Consent.
2. Premature infants with high risk of RDS.
3. Less than 2 hours of life old at trial entry.
4. Intubation for ventilatory assistance.
5. No major congenital malformations.
Interventions: Early Treatment: Exosurf (5ml/kg) x2 doses
administered intratracheally in unblinded fashion at less than 2 hours
of life.
Delayed Treatment: same Exosurf dosage and protocol give to participants
greater than 2 hours of age with clinical signs of RDS. Administration
unblinded.
Outcomes: PRIMARY OUTCOMES:
1. Death or BPD at 28 days.
2. Death
3. Death or CLD at "expected delivery date."
SECONDARY OUTCOME:
Complications of prematurity.
Gortner L, et al. Early versus late surfactant treatment in preterm infants of 27 to 32 weeks' gestational age: A multicenter controlled clinical trial. Pediatrics 1998;102:1153-1160.
Konishi M, et al. A prospective randomized trial of early versus late administration of a single dose of surfactant-TA. Early Human Development 1992;29:275-282.
The OSIRIS Collaborative Group. Early versus delayed neonatal administration
of a synthetic surfactant - The judgement of OSIRIS. Lancet 1992;
340:1363-1369.
Ikegami M, Jacobs H, Jobe A. Surfactant function in respiratory distress syndrome. J Pediatr 1983; 102: 443-447.
Jobe AH, Mitchell BR, Gunkel JH. Beneficial effects of the combined use of prenatal corticosteroids and postnatal surfactant in preterm infants. Am J Obstet Gynecol 1993;168:508-513.
Kattwinkel J, et al. Prophylactic administration of calf lung surfactant extract is more effective than early treatment of respiratory distress syndrome in neonates of 29 through 32 week's gestation. Pediatrics 1993; 92: 90 - 98.
Kendig JW, et al. Comparison of two strategies for surfactant prophylaxis in very premature infants: A multicenter randomized trial. Pediatrics 1998;101:1006-1012.
Nilsson R, Grossman G, Robertson B. Lung surfactant and the pathogenesis of neonatal bronchiolar lesions induced by artificial ventilation. Pediatr Res 1978;12:249-255.
Soll RF, McQueen MC. Respiratory Distress Syndrome. In: Sinclair JC, Bracken MB, eds Effective Care of the Newborn Infant. Oxford, England: Oxford University Press; 1992:325-358.
Soll RF, Morley CJ. Prophylactic versus selective use of surfactant
for preventing morbidity and mortality in preterm infants (Cochrane Review).
In: The Cochrane Library, issue 1, 1999. Oxford: Update Software.
01.01.00 Pneumothorax (RR)
01.01.00 Pneumothorax (RD)
01.01.01 Synthetic surfactant
01.01.02 Natural surfactant
01.02.00 Patent ductus arteriosus (RR)
01.02.00 Patent ductus arteriosus (RD)
01.02.01 Synthetic surfactant
01.02.02 Natural surfactant
01.03.00 Pulmonary intersitial emphysema (RR)
01.03.00 Pulmonary intersitial emphysema (RD)
01.03.01 Synthetic surfactant
01.03.02 Natural surfactant
01.04.00 Pulmonary hemorrhage (RR)
01.04.00 Pulmonary hemorrhage (RD)
01.04.01 Synthetic surfactant
01.04.02 Natural surfactant
01.05.00 Necrotizing enterocolitis (RR)
01.05.00 Necrotizing enterocolitis (RD)
01.05.01 Synthetic surfactant
01.05.02 Natural surfactant
01.06.00 Retinopathy of prematurity stage 3 or greater (RR)
01.06.00 Retinopathy of prematurity stage 3 or greater (RD)
01.06.01 Synthetic surfactant
01.06.02 Natural surfactant
01.07.00 Intraventricular hemorrhage (any) (RR)
01.07.00 Intraventricular hemorrhage (any) (RD)
01.07.01 Synthetic surfactant
01.07.02 Natural surfactant
01.08.00 Intraventricular hemorrhage (severe) (RR)
01.08.00 Intraventricular hemorrhage (severe) (RD)
01.08.01 Synthetic surfactant
01.08.02 Natural surfactant
01.09.00 Bronchopulmonary dysplasia (RR)
01.09.00 Bronchopulmonary dysplasia (RD)
01.09.01 Synthetic surfactant
01.09.02 Natural surfactant
01.10.00 Chronic lung disease (RR)
01.10.00 Chronic lung disease (RD)
01.10.01 Synthetic surfactant
01.10.02 Natural surfactant
01.11.00 Neonatal mortality (RR)
01.11.00 Neonatal mortality (RD)
01.11.01 Synthetic surfactant
01.11.02 Natural surfactant
01.12.00 BPD or death at 28 days (RR)
01.12.00 BPD or death at 28 days (RD)
01.12.01 Synthetic surfactant
01.12.02 Natural surfactant
01.13.00 CLD or death (RR)
01.13.00 CLD or death (RD)
01.13.01 Synthetic surfactant
01.13.02 Natural surfactant
01.14.00 Mortality at discharge (RR)
01.14.00 Mortality at discharge (RD)
01.14.01 Synthetic surfactant
01.14.02 Natural surfactant
01.15.00 Number of doses per infant
01.15.01 Synthetic surfactant
01.15.02 Natural surfactant