- Open Access
Porcine versus bovine surfactant therapy for RDS in preterm neonates: pragmatic meta-analysis and review of physiopathological plausibility of the effects on extra-pulmonary outcomes
Respiratory Research volume 21, Article number: 8 (2020)
While porcine seems to be superior to bovine surfactants in terms of respiratory outcomes, it is unclear if a surfactant can improve extra-pulmonary outcomes in preterm neonates with respiratory distress syndrome and if there is any physiopathological/biological mechanism linking surfactant therapy to these outcomes. We aim to fill these knowledge gaps.
Systematic and pragmatic review coupled with meta-analysis of randomized controlled trials of bovine or porcine surfactants administered to treat RDS in preterm neonates; common extra-pulmonary neonatal intensive care outcomes were considered. As additional analysis, animal or human translational studies about mechanisms linking surfactant replacement to extra-pulmonary neonatal outcomes were also systematically reviewed.
Porcine surfactant is associated with lower incidence of patent ductus arteriosus (OR:0.655; 95%CI:0.460–0.931); p = 0.018; 12 trials; 1472 patients); prenatal steroids (coeff.:-0.009, 95%CI:-0.03–0.009, p = 0.323) and gestational age (coeff.:0.079, 95%CI:-0.18–0.34, p = 0.554) did not influence this effect size. No significant differences were found between porcine and bovine surfactants on neonatal intensive care unit length of stay (mean difference (days):-2.977; 95%CI:-6.659–0.705; p = 0.113; 8 trials; 855 patients), intra-ventricular hemorrhage of any grade (OR:0.860; 95%CI:0.648–1.139); p = 0.293; 15 trials; 1703 patients), severe intra-ventricular hemorrhage (OR:0.852; 95%CI:0.624–1.163); p = 0.313; 15 trials; 1672 patients), necrotizing entero-colitis (OR:1.190; 95%CI:0.785–1.803); p = 0.412; 9 trials; 1097 patients) and retinopathy of prematurity (OR:0.801; 95%CI:0.480–1.337); p = 0.396; 10 trials; 962 patients).
Physiopathological mechanisms explaining the effect of surfactant have been found for patent ductus arteriosus only, while they are lacking for all other endpoints. Porcine surfactant is associated with lower incidence of PDA than bovine surfactants. As there are no differences in terms of other extra-pulmonary outcomes and no physiopathological plausibility, these endpoints should not be used in future trials.
Respiratory distress syndrome (RDS) represents the main cause of respiratory failure in preterm neonates and is associated with an increasing burden of care . Since RDS is caused by primary surfactant deficiency, the availability of exogenous surfactants allows an effective replacement therapy, which is recommended by current international guidelines, in neonates failing continuous positive airway pressure (CPAP) [2, 3]. The combined use of CPAP early from birth and surfactant replacement has provided significant benefits in terms of mortality and broncho-pulmonary dysplasia (BPD) . Meta-analyses have demonstrated that surfactant replacement is more effective if performed: 1) within the first 2-3 h of life , and 2) with current animal-derived surfactants preparations, rather than with older synthetic, protein-free surfactants . Moreover, our recent meta-analysis demonstrated the superiority of high dose poractant-α over bovine surfactants at their licensed dose in terms of respiratory outcomes, using a pragmatic design . This has been possible because earlier meta-analysis showed clinical equivalence between bovine surfactants  and this has a strong biological plausibility given their similar biochemical composition and pharmacological features [7, 9, 10]. The biochemical and pharmacological characteristics of different surfactant preparations are detailed in our previous work . The beneficial effect of surfactant replacement on BPD and other respiratory outcomes is physiopathologically sound, as surfactant increases compliance and alveolar recruitment reducing the need for distending pressure and invasive mechanical ventilation, which is a main pro-inflammatory trigger involved in BPD development . Surfactant replacement also stimulates the endogenous surfactant production  and reduces the incidence of air leaks , since the improved compliance allows an efficacious ventilation with a lower transpulmonary pressure.
However, it is not clear if surfactant can actually have any effect on extra-pulmonary outcomes [14, 15]. Trials published so far have reported the more common complications of prematurity as secondary outcomes and, subsequently, these have been taken into account by meta-analyses. Nonetheless, these were mere statistical investigations without any focus on the physiopathological or biological plausibility of their results. In our opinion, it is extremely important to couple data coming from randomized trials with the relevant biological and physiopathological knowledge in order to reduce misinterpretations and to avoid creating hopes that can hardly be confirmed. Given the clinical equivalence of bovine surfactants of different extraction method (minced or lung lavage) , and their similar biochemical/pharmacological features [7, 9], we decided to perform a pragmatic meta-analyses of porcine versus bovine surfactants with regard to extra-pulmonary outcomes, following the same pragmatic design adopted for the analysis of respiratory outcomes . To provide more useful data we also comprehensively reviewed the available physiopathological informations regarding the possible links between surfactant replacement and neonatal non-respiratory outcomes.
Prior to commencing the search, a systematic review protocol was agreed to determine the databases to be searched, search modality, eligibility criteria, data extraction/aggregation methodology, timing of meetings and methods for dispute resolution in case of disagreement. Following the agreement, this review was registered in the international prospective register of systematic review (PROSPERO n.CRD42018100906). Regular meetings between the authors were scheduled and the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) guidelines were followed through the entire project . This study has no funding.
The systematic review included randomized controlled trials fulfilling the following criteria: 1) published as full articles; 2) enrolled preterm neonates (gestational age < 37 weeks) with clinical and/or radiological evidence of RDS; 3) compared porcine and bovine surfactants (irrespective of their preparation method), and 4) reported at least one of the selected extra-pulmonary outcomes (see below). Studies were included in the meta-analysis, if they compared surfactants internationally available on the market. Since early selective surfactant treatment is currently advised by international guidelines [2, 3], we did not consider trials on surfactant prophylaxis. No language or year restrictions were applied. We excluded “grey” literature, unpublished or non-peer reviewed reports.
Information sources, search strategy and study selection
These details are reported in the Additional file 1.
Data collection process
We used a data extraction sheet based on the Cochrane Consumers and Communication Review Group’s data extraction template that had been already used in our previous work . Data from included trials were extracted independently by the two authors and then cross-verified. Discrepancies were resolved through discussion between the two reviewers. Where further clarifications were needed or when data could not be statistically aggregated authors were contacted to provide clarification and/or raw data. At least two emails were sent to authors 2 weeks apart.
Data collected included study design, number of enrolled patients, prenatal steroid, mean gestational age, inclusion and exclusion criteria, surfactant type and doses, outcomes, and variables used to assess study quality. The extra-pulmonary outcomes were: 1) length of stay in neonatal intensive care units (NICU); 2) hemodynamically significant patent ductus arteriosus (PDA), defined with any of the previously published criteria ; 3) intra-ventricular hemorrhage (IVH) of any grade according to Papile’s classification ; 4) Grade III-IV IVH according to Papile’s classification ; 5) necrotizing entero-colitis (NEC) of any stage, according to Bell’s classification ; 6) retinopathy of prematurity (ROP) of any stage according to current international classification ; The choice of focusing on newborn outcomes mainly irrespective of their stage/grade was pragmatic. In fact, these are relatively rare outcomes and trials seldom report them homogenously, reflecting real life differences in their bedside definition and management. Thus, our pragmatic choice allowed to have larger datasets to analyze.
Assessment of risk of Bias
The Cochrane Risk of Bias assessment tool was used to evaluate quality of reviewed studies . Two reviewers (DDL, SF) independently assessed the risk of bias for each trial, including: 1) selection bias (inadequate random sequence generation, failure to conceal treatment allocation); 2) performance bias (inadequate blinding of patients and investigators/personnel); 3) detection bias (failure to adequately blind the outcome assessors); 4) attrition bias (incomplete outcome data evaluation and failure to follow intention-to-treat analysis); 5) reporting bias (selective outcome reporting); 6) any other bias and any potential conflict of interest. Each item was assessed as at “low” or “high risk” of bias, or unclear (when the authors were unable to determine, on the basis of the available information). Discrepancies were resolved through discussion between the two reviewers. The presence of publication bias was explored, as recently suggested , through multiple methods including visual assessment of Funnel plot, Egger regression and the searching in trials’ registries and conference proceedings, as described above. More details are available in the Additional file 1.
Summary measures and synthesis of results
Our previous meta-analysis about respiratory outcomes demonstrated similar results when we compared 100 mg/kg bovine surfactants versus 200 mg/kg or versus any dose of poractant-α (i.e.: pooling the data from all study arms in which poractant-α was administered, irrespective of the dosage used) . Results of these comparisons were similar because only three trials randomized small newborn populations to receive a lower poractant-α dose: thus, these trials had a minor impact on the analyses. Moreover, non-respiratory outcomes are not always reported in each trial and this may reduce the sample size. Therefore, we pragmatically decided here to compare 100 mg/kg bovine surfactants versus any dose of poractant-α in order to have larger datasets. For the same reasons we did not perform a meta-analysis comparing 100 mg/kg poractant-α versus 100 mg/kg bovine surfactants, as this would have been unreliable, given the low number of patients. Outcomes were analyzed using weighted average odds ratios (OR) or mean difference and 95% confidence interval (95% CI), as appropriate. We used the DerSimonian-Laird random-effects or the continuous random-effects models, for binary and continuous outcomes, respectively. Such approach is more conservative than the fixed-effects model, as it assumes the presence of heterogeneity among aggregated studies, based on the assumption that the studies considered are estimating different underlying effect sizes . Consistency across the studies was evaluated using the I2 statistic (variation in ORs attributable to heterogeneity) and performing a χ2 test for heterogeneity; an I2 value greater than 50% was considered as indicative of substantial heterogeneity. When no significant heterogeneity was found, we also repeated the analysis using fixed-effects or continuous fixed-effects inverse variance method, for binary and continuous outcomes, respectively.
Prenatal steroid prophylaxis and gestational age (GA) can be confounders, as they might influence the incidence of some of our outcomes . Furthermore, since trials have been published across several years (from 1995 to 2017), steroids have been variously administered in the enrolled populations. Thus, when results of the meta-analysis were statistically significant, we performed two random-effects model meta-regressions  and we inserted as covariates: 1) prenatal steroids (as % of neonates treated in each study), and 2) the mean GA (in weeks) of each study population. We only used one covariate for each model to reduce false positive conclusions and we expressed results using coefficients (and 95%CI) . All statistics were performed with Open-MetaAnalyst 10.1  and Meta-essentials .
Finally, as further additional analysis, we aimed to understand why, from a physiopathological standpoint, surfactant replacement therapy (with any surfactant) would be able to improve extra-pulmonary outcomes, as this is actually debated [14, 15]. Thus, we performed a comprehensive review of possible physiopathological and biological mechanisms by which surfactant could influence extra-pulmonary outcomes. To do this, we searched information in the studies identified through the search strategy described above. Additionally, we also searched PubMed, using key words and/or MeSH terms as described in the Additional file 1, looking for animal or human translational investigations on these mechanisms.
Fig.1 illustrates the project flow-chart: we included 17 studies in the systematic review [28,29,30,31,32,33,34,35,36,37,38,39,40,41,42,43,44,45] and we excluded two papers from the meta-analysis, as they investigated two non-internationally marketed porcine surfactants [43, 44]. Compared to our previous meta-analysis on respiratory endpoints, there was one more study reporting on the extra-pulmonary outcomes . This study did not report the exact dose of surfactant . Moreover, Fujii et al. reported hemodynamically significant PDA in one paper and other extra-pulmonary outcomes in a second manuscript [30, 31]. Data were extracted from these two distinct papers, as appropriate: since the enrolled population was the same, they were considered as a single study and 15 studies were finally included in the meta-analysis. The other trials have been already described  and their characteristics are summarized in the Additional file 1. A total of 1721 neonates were enrolled in the 15 trials. Evaluation of biases is reported in the Additional file 1. The studies performed mostly well in completeness of outcome analysis and reporting, but generally suffered from performance bias due to imperfect blinding for interventions and outcome assessments (apart from one ). The methods of randomization and allocation concealment were unclear for the majority of studies. There seemed to be no significant Funnel plot asymmetry and, consistently, we found no unpublished project focusing on our extra-pulmonary outcomes in any trial registries. Fig.2 shows that there is no significant difference between poractant-α and bovine surfactants in terms of NICU stay (p = 0.113). Heterogeneity is at the border of significance. We also repeated the analysis using continuous fixed-effects model and found similar results (mean difference (days): -2.07; 95%CI: − 4.51-0.36; p = 0.094). Poractant-α is associated with significantly lower incidence of hemodynamically significant PDA (Fig.3: p = 0.018) and studies showed a statistically significant heterogeneity. We performed meta-regressions as additional analyses and the effect size of poractant-α on PDA did not result significantly associated neither with gestational age (coefficient: 0.079, 95%CI:-0.18–0.34, p = 0.554), nor with prenatal steroids (coefficient: -0.009, 95%CI: − 0.03-0.009, p = 0.323). There are no significant differences between poractant-α and bovine surfactants in terms of IVH of any grade (Fig.4a: p = 0.293) or grade III-IV IVH (Fig.4b: p = 0.313), or in terms of NEC (Fig.4c: p = 0.412) and ROP (Fig.4d: p = 0.396). There is a significant heterogeneity only for ROP. We repeated the meta-analyses for IVH and NEC using fixed effects-inverse variance method obtaining similar results (IVH any grade: OR: 0.86, 95%CI: 0.65–1.14, p = 0.293; grade III-IV IVH: OR: 0.85, 95%CI: 0.62–1.16, p = 0.313; NEC: OR: 1.19, 95%CI: 0.78–1.80, p = 0.412). Table 1 shows possible mechanisms by which surfactant could influence extra-pulmonary outcomes [34, 46,47,48,49,50,51,52,53,54,55,56,57,58,59,60,61,62,63,64,65,66,67,68,69]. Of note, a physiopathological link between surfactant administration and non-respiratory neonatal outcomes could have been demonstrated only for hemodynamically significant PDA.
Summary of evidence
Our meta-analysis compared for the first time the effects of poractant-α with all bovine surfactants on extra-pulmonary outcomes, using an aggregate sample larger than the ones used in previous meta-analyses [8, 70]. This has been possible by including recently published studies and using a particular data aggregation. This latter is fully justified by the previously demonstrated clinical equivalence of different bovine surfactants and their similar biochemical and pharmacological features [7,8,9,10]. To summarize, our results show a significantly reduced incidence of hemodynamically significant PDA in neonates treated with poractant-α, compared to those treated with bovine surfactants. The effect size of poractant-α on PDA is not influenced by antenatal steroids or gestational age. The clinical relevance of PDA in preterm neonates is currently debated, thus it is not clear if the surfactant effect on PDA incidence can actually represent a clinically important benefit. All other outcomes (NICU stay, NEC, ROP and IVH) are similar between patients treated with poractant-α and other surfactants. Heterogeneity is significant for PDA, ROP and nearly significant for NICU stay. This is likely due to: 1) the different criteria used in the studies for the diagnosis of hemodynamically significant PDA ; 2) the different screening policies for ROP, and PDA [17, 71]; 3) the influence of several different factors on NICU stay. This is an extremely complex variable that may be affected also by clinical problems occurring much later than surfactant administration, as well as logistic, social and psychological factors. However, all these issues contribute to actual NICU care and we aimed to perform a pragmatic meta-analysis focusing on the available data in the context of the real NICU care, rather than in a controlled experimental setting.
These results are only partially similar to those of the earlier Cochrane meta-analysis  but they are also stronger. In fact, compared to the previous work we: 1) included five more trials (accounting for ≈600 neonates); 2) used a trials aggregation based on the current best knowledge, that is, on the clinical equivalence of bovine surfactant ; 3) analyzed the effect of possible confounders, such as antenatal steroids or gestational age, and finally, 4) reviewed the possible physiopathological mechanisms linking surfactant replacement and extra-pulmonary outcomes. In fact, ours was intended to be not only a statistical work but also a multidisciplinary project coupling clinical outcomes with their physiopathological plausibility.
Interestingly, a convincing physiopathological link seems evident only between PDA and the choice of a particular surfactant. A surfactant more efficient from a biophysical point of view may be able to increase lung compliance and recruit alveoli more quickly, thus allowing to reduce supplemental oxygen. The oxygen exposure is important for the PDA closure  and the reduction in circulating reactive oxygen species may crosstalk with the inflammation pathway and contribute to reduce the synthesis of prostaglandins, which are also crucial for ductal patency . Finally, a more efficient surfactant may quickly lower pulmonary vascular resistance through the alveolar recruitment and the increment in alveolar oxygen tension: this will facilitate the inversion of blood flow through the ductus arteriosus . We cannot clarify if the effect of poractant-α on PDA incidence is due to his different phospholipid/protein profile or to the higher concentration allowing the use of higher doses, as already specified in our previous work on respiratory outcomes . However, from a clinically pragmatic point of view this question is useless because: 1) pharmacokinetic and clinical data show that the high dose poractant-α has to be preferred over the low dose regimen, as it provides longer half-life, less re-treatments, better response in terms of oxygenation and improved respiratory outcomes [7, 74, 75]; 2) high dose regimens are unfeasible with bovine surfactants given their lower concentration and higher viscosity [9, 10]. These characteristics of bovine surfactants might negatively impact on hemodynamics and peripheral perfusion, yet a low doses regimen , while larger doses could cause tube occlusions, ventilation troubles and lung edema, potentially increasing the need for more aggressive ventilation.
Conversely, there are no convincing physiopathological data allowing to assume that one surfactant should be better than others in reducing the incidence of extra-pulmonary outcomes other than PDA. Some mechanisms have been hypothesized (Table 1) but they have not been confirmed for several reasons. For instance, surfactant administration and IVH incidence could theoretically be linked by the reduction of cerebral blood flow due to improved oxygenation and lower level of PaCO2. However, significant hypercarbia and hypoxia are rarely seen in the natural course of RDS (especially if antenatal steroids are given and early CPAP is efficiently provided) : thus, when CPAP fails and surfactant is optimally administered, a significant change of PaCO2 is unlikely to be observed . A reduced incidence of hemodynamically significant PDA could also theoretically influence the occurrence of IVH, but there are no convincing data linking PDA to IVH occurrence . The achievement of a better peripheral perfusion in the peri-administration period has also been linked to IVH and NEC reduced incidence, however available data are not consistent and not all variables related to peripheral perfusion coherently change during surfactant dosing [34, 42]. A reduction in oxidative damage has been hypothesized as link between surfactant replacement and reduced incidence of ROP and NEC. However, all these disorders are often developing well after the early neonatal period, following genetic predisposition, long oxygen exposure and/or several cofactors (nutritional troubles, infections, transfusions, other pro-inflammatory triggers) [78, 79]. Therefore, it seems unlikely that a single drug administration, performed several days/weeks earlier, in another organ, could interfere with such a complex physiopathology. It is important to remind that the incidence of these extra-pulmonary neonatal outcomes have never been changed with the use of any surfactant, neither in the early trials conducted decades ago [80, 81], nor in the more recent ones, as acknowledged by the American Academy of Pediatrics both in 2008 and 2014 guidelines [3, 59]. Moreover, these outcomes were not changed when comparing surfactant therapy with prophylaxis and surfactant replacement increases survival rates without a change in the incidence of long-term neuro-developmental injury [45, 59]. Therefore, the lack of clear physiopathological plausibility and the preponderance of evidence suggest that the incidence of these outcomes is not significantly affected by any type of surfactant therapy. This is an important information in order to avoid false hopes and to help designing more physiopathologically solid trials. In fact, other questions remain open about surfactant replacement therapy and future investigation plans should concentrate on these, rather than asking surfactants to magically reduce various complications of prematurity.
We have chosen outcomes easily defined to allow data aggregation, albeit there are differences in outcomes’ diagnostic criteria amongst trials. However, we decided to use this pragmatic approach, as differences reflect the reality of NICU care. This approach helps to have larger patient populations and, when it obtains any positive results, they are very likely to be robust and generalizable . Thus, the pragmatic design is known to be more appropriate when evaluating interventions which are refinements of current care : as surfactant is already a cornerstone of neonatal critical care, this seemed the best strategy to apply. Studied populations were relatively small and the quality of the studies varied: potentially relevant biases were detected in almost every trial and this can impact on our findings, although they represent the best currently available evidence on the topic. We did not perform an individual patient meta-analysis, but rather meta-regressions and therefore some results might be subjected to the limitations of this technique or some confounders may have been missed. Finally, since the majority of studies investigated poractant-α at 200 mg/kg, we cannot draw any conclusion about the low dose poractant-α regimen. However, given the known clinical and pharmacokinetic advantages of 200 mg/kg dose of poractant-α [7, 74, 75], it seems unethical to design a trial only to verify if the higher dose or the biochemical composition is responsible for the clinical effects. Conversely, trials with high doses of bovine surfactant would be almost technically impossible [9, 10, 34]. In fact, as bovine surfactants are less concentrated and more viscous, higher doses can cause lung edema requiring more aggressive ventilation. Also, hemodynamic impairment has already been described with usual doses of bovine surfactants . For these reasons, also the more recent animal studies only investigated bovine surfactants at their licensed dose .
Poractant-α is associated with lower incidence of hemodynamically significant PDA than bovine surfactants; this effect is not influenced by gestational age or the use of prenatal steroids. There are no differences between porcine and bovine surfactants in terms of other extra-pulmonary outcomes. Since there is no physiopathological plausibility linking surfactant replacement to non-respiratory outcomes other than PDA, these endpoints should not be used in future trials.
Availability of data and materials
All raw data generated or analyzed during this study are included in this published article [and its supplementary information files].
Continuous positive airway pressure
Neonatal intensive care unit
Hemodynamically significant patent ductus arteriosus
Preferred Reporting Items for Systematic Reviews and Meta-Analyses
Respiratory distress syndrome
Retinopathy of prematurity
Donda K, Vijayakanthi N, Dapaah-Siakwan F, Bhatt P, Rastogi D, Rastogi S. Trends in epidemiology and outcomes of respiratory distress syndrome in the United States. Pediatr Pulmonol. 2019. https://doi.org/10.1002/ppul.24241 [Epub ahead of print].
Sweet DG, Carnielli V, Greisen G, Hallman M, Ozek E, Plavka R. European consensus guidelines on the Management of Respiratory Distress Syndrome – 2016 update. Neonatology. 2017;111:107–25. https://doi.org/10.1159/000448985.
Polin RA, Carlo WA. American Academy of Pediatrics, Committee on Fetus and Newborn. Surfactant replacement therapy for preterm and term neonates with respiratory distress. Pediatrics. 2014;133:156–63. https://doi.org/10.1542/peds.2013-3443.
Subramaniam P, Ho JJ, Davis PG. Prophylactic nasal continuous positive airway pressure for preventing morbidity and mortality in very preterm infants. Cochrane Database Syst Rev. 2016;6:CD001243. https://doi.org/10.1002/14651858.CD001243.pub3.
Bahadue FL, Soll R. Early versus delayed selective surfactant treatment for neonatal respiratory distress syndrome. Cochrane Database Syst Rev. 2012;11:CD001456. https://doi.org/10.1002/14651858.CD001456.pub2.
Ardell S, Pfister RH, Soll R. Animal derived surfactant extract versus protein free synthetic surfactant for the prevention and treatment of respiratory distress syndrome. Cochrane Database Syst Rev. 2015;8:CD000144. https://doi.org/10.1002/14651858.CD000144.pub3.
Tridente A, De Martino L, De Luca D. Porcine vs bovine surfactant therapy for preterm neonates with RDS: systematic review with biological plausibility and pragmatic meta-analysis of respiratory outcomes. Respir Res. 2019;20:28. https://doi.org/10.1186/s12931-019-0979-0.
Singh N, Halliday HL, Stevens TP, Suresh G, Soll R, Rojas-Reyes MX. Comparison of animal-derived surfactants for the prevention and treatment of respiratory distress syndrome in preterm infants. Cochrane Database Syst Rev. 2015;12:CD010249. https://doi.org/10.1002/14651858.CD010249.pub2.
Blanco O, Pérez-Gil J. Biochemical and pharmacological differences between preparations of exogenous natural surfactant used to treat respiratory distress syndrome: role of the different components in an efficient pulmonary surfactant. Eur J Pharmacol. 2007;568:1–5. https://doi.org/10.1016/j.ejphar.2007.04.035.
Lu KW, Pérez-Gil J, Taeusch HW. Kinematic viscosity of therapeutic pulmonary surfactants with added polymers. Biochim Biophys Acta. 2009;1788:632–7. https://doi.org/10.1016/j.bbamem.2009.01.005.
Morty RE. Recent advances in the pathogenesis of BPD. Semin Perinatol. 2018;42:404–12. https://doi.org/10.1053/j.semperi.2018.09.001.
Bunt JE, Carnielli VP, Janssen DJ, Wattimena JL, Hop WC, Sauer PJ, et al. Treatment with exogenous surfactant stimulates endogenous surfactant synthesis in premature infants with respiratory distress syndrome. Crit Care Med. 2000;28:3383–8.
Seger N, Soll R. Animal derived surfactant extract for treatment of respiratory distress syndrome. Cochrane Database Syst Rev. 2009;2:CD007836. https://doi.org/10.1002/14651858.CD007836.
Lutchman D. Have we been down this road before? J Perinatol. 2010;30:698–9. https://doi.org/10.1038/jp.2010.88.
Holm B, Cummings J. Is there evidence for a mortality difference between exogenous surfactant preparations in neonatal RDS? J Appl Res. 2008;8:78–83.
Shamseer L, Moher D, Clarke M, Ghersi D, Liberati A, Petticrew M, et al. Preferred reporting items for systematic review and meta-analysis protocols (PRISMA-P) 2015: elaboration and explanation. BMJ. 2015;349:g7647. https://doi.org/10.1136/bmj.g7647.
Jain A, Shah PS. Diagnosis, evaluation, and Management of Patent Ductus Arteriosus in preterm neonates. JAMA Pediatr. 2015;169:863. https://doi.org/10.1001/jamapediatrics.2015.0987.
Papile LA, Burstein J, Burstein R, Koffler H. Incidence and evolution of subependymal and intraventricular hemorrhage: a study of infants with birth weights less than 1,500 gm. J Pediatr. 1978;92:529–34.
Bell MJ, Ternberg JL, Feigin RD, Keating JP, Marshall R, Barton L, et al. Neonatal necrotizing enterocolitis. Therapeutic decisions based upon clinical staging. Ann Surg. 1978;187:1–7.
The International Classification of Retinopathy of Prematurity Revisited. Arch Ophthalmol. 2005;123:991. https://doi.org/10.1001/archopht.123.7.991.
Higgins JPT, Altman DG, Gotzsche PC, Jüni P, Moher D, Oxman AD, et al. The Cochrane Collaboration’s tool for assessing risk of bias in 17ecrotizin trials. BMJ. 2011;343:d5928. https://doi.org/10.1136/bmj.d5928.
Lin L, Chu H, Murad MH, Hong C, Qu Z, Cole SR, et al. Empirical comparison of publication Bias tests in meta-analysis. J Gen Intern Med. 2018;33:1260–7. https://doi.org/10.1007/s11606-018-4425-7.
Sterne JAC, Egger M, Smith GD. Systematic reviews in health care: investigating and dealing with publication and other biases in meta-analysis. BMJ. 2001;323:101–5. https://doi.org/10.1136/bmj.323.7304.101.
Roberts D, Brown J, Medley N, Dalziel SR. Antenatal corticosteroids for accelerating fetal lung maturation for women at risk of preterm birth. Cochrane Database Syst Rev. 2017;3:CD004454. https://doi.org/10.1002/14651858.CD004454.pub3.
Thompson SG, Higgins JPT. How should meta-regression analyses be undertaken and interpreted? Stat Med. 2002;21:1559–73. https://doi.org/10.1002/sim.1187.
Wallace BC, Schmid CH, Lau J, Trikalinos TA. Meta-analyst: software for meta-analysis of binary, continuous and diagnostic data. BMC Med Res Methodol. 2009;9. https://doi.org/10.1186/1471-2288-9-80.
Suurmond R, van Rhee H, Hak T. Introduction, comparison, and validation of meta-essentials : a free and simple tool for meta-analysis. Res Synth Methods. 2017;8:537–53. https://doi.org/10.1002/jrsm.1260.
Baroutis G, Kaleyias J, Liarou T, Papathoma E, Hatzistamatiou Z, Costalos C. Comparison of three treatment regimens of natural surfactant preparations in neonatal respiratory distress syndrome. Eur J Pediatr. 2003;162:476–80. https://doi.org/10.1007/s00431-002-1144-0.
Dizdar E, Sari F, Aydemir C, Oguz SS, Erdeve O, Uras N, et al. A randomized, controlled trial of Poractant Alfa versus Beractant in the treatment of preterm infants with respiratory distress syndrome. Am J Perinatol. 2012;29:95–100. https://doi.org/10.1055/s-0031-1295648.
Fujii AM, Patel SM, Allen R, Doros G, Guo C-Y, Testa S. Poractant alfa and beractant treatment of very premature infants with respiratory distress syndrome. J Perinatol. 2010;30:665–70. https://doi.org/10.1038/jp.2010.20.
Fujii A, Allen R, Doros G, O’Brien S. Patent ductus arteriosus hemodynamics in very premature infants treated with poractant alfa or beractant for respiratory distress syndrome. J Perinatol. 2010;30:671–6. https://doi.org/10.1038/jp.2010.21.
Gharehbaghi MM, Sakha SHP, Ghojazadeh M, Firoozi F. Complications among premature neonates treated with beractant and poractant alfa. Indian J Pediatr. 2010;77:751–4. https://doi.org/10.1007/s12098-010-0097-y.
Mostafa Gharehbaghi M, Yasrebi S. Comparing the Efficacy of two Natural Surfactants, Curosurf and Alveofact, in Treatment of Respiratory Distress Syndrome in Preterm Infants. Int J Women’s Health Reprod Sci. 2014;2:245–8. https://doi.org/10.15296/ijwhr.2014.36.
Karadag N, Dilli D, Zenciroglu A, Aydin B, Beken S, Okumus N. Perfusion index variability in preterm infants treated with two different natural surfactants for respiratory distress syndrome. Am J Perinatol. 2014;31:1015–22. https://doi.org/10.1055/s-0034-1370344.
Lemyre B, Fusch C, Schmölzer GM, Rouvinez Bouali N, Reddy D, Barrowman N, et al. Poractant alfa versus bovine lipid extract surfactant for infants 24+0 to 31+6 weeks gestational age: a randomized controlled trial. PLoS One. 2017;12:e0175922. https://doi.org/10.1371/journal.pone.0175922.
Malloy C, Nicoski P, Muraskas J. A randomized trial comparing beractant and poractant treatment in neonatal respiratory distress syndrome. Acta Paediatr. 2005;94:779–84. https://doi.org/10.1080/08035250510028740.
Mercado VV, Cristea I, Ali N, Pham CC, Buescher E, Yang J, et al. Does surfactant type cause a differential proinflammatory response in preterm infants with respiratory distress syndrome? Adv Ther. 2010;27:476–82. https://doi.org/10.1007/s12325-010-0044-3.
Mussavi M, Mirnia K, Asadollahi K. Comparison of the efficacy of three natural surfactants (Curosurf, Survanta, and Alveofact) in the treatment of respiratory distress syndrome among neonates: a randomized controlled trial. Ir J Pediatr. 2016;26:e5743. https://doi.org/10.5812/ijp.5743.%20e.
Najafian B, Karimi-Sari H, Khosravi MH, Nikjoo N, Amin S, Shohrati M. Comparison of efficacy and safety of two available natural surfactants in Iran, Curosurf and Survanta in treatment of neonatal respiratory distress syndrome: a randomized clinical trial. Contemp Clin Trials Commun. 2016;3:55–9. https://doi.org/10.1016/j.conctc.2016.04.003.
Ramanathan R, Rasmussen MR, Gerstmann DR, Finer N, Sekar K, The North American Study Group. A randomized, multicenter masked comparison trial of Poractant Alfa (Curosurf) versus Beractant (Survanta) in the treatment of respiratory distress syndrome in preterm infants. Am J Perinatol. 2004;21:109–19. https://doi.org/10.1055/s-2004-823779.
Speer CP, Gefeller O, Groneck P, Laufkötter E, Roll C, Hanssler L, et al. Randomised clinical trial of two treatment regimens of natural surfactant preparations in neonatal respiratory distress syndrome. Arch Dis Child Fetal Neonatal Ed. 1995;72:F8–13.
Terek D, Gonulal D, Koroglu OA, Yalaz M, Akisu M, Kultursay N. Effects of two different exogenous surfactant preparations on serial peripheral perfusion index and tissue carbon monoxide measurements in preterm infants with severe respiratory distress syndrome. Pediatr Neonatol. 2015;56:248–55. https://doi.org/10.1016/j.pedneo.2014.11.004.
Rebello CM, Precioso AR, Mascaretti RS. A multicenter, randomized, double-blind trial of a new porcine surfactant in premature infants with respiratory distress syndrome. Einstein (São Paulo). 2014;12:397–404. https://doi.org/10.1590/S1679-45082014AO3095.
Sanchez-Mendiola M, Martinez-Natera O, Herrera-Maldonado N, Ortega-Arroyo J. Estudio controlado del tratamiento de la enfermedad de membrana hialina del recién nacido pretérmino con surfactante pulmonar exógeno (porcino vs. bovino). Gac Med Mex. 2005;141:267–71.
Eras Z, Dizdar E, Kanmaz G, Guzoglu N, Aksoy HT, Altunkaya GB, et al. Neurodevelopmental outcomes of very low birth weight preterm infants treated with Poractant Alfa versus Beractant for respiratory distress syndrome. Am J Perinatol. 2013;31:463–8. https://doi.org/10.1055/s-0033-1351659.
Kääpä P, Seppänen M, Kero P, Saraste M. Pulmonary hemodynamics after synthetic surfactant replacement in neonatal respiratory distress syndrome. J Pediatr. 1993;123:115–9.
Seppänen M, Kääpä P, Kero P. Acute effects of synthetic surfactant replacement on pulmonary blood flow in neonatal respiratory distress syndrome. Am J Perinatol. 1994;11:382–5. https://doi.org/10.1055/s-2007-994602.
Weir EK, Obreztchikova M, Vargese A, Cabrera JA, Peterson DA, Hong Z. Mechanisms of oxygen sensing: a key to therapy of pulmonary hypertension and patent ductus arteriosus: oxygen-sensitive ion channels: a key to therapy. Br J Pharmacol. 2009;155:300–7. https://doi.org/10.1038/bjp.2008.291.
Tonks A, Parton J, Tonks AJ, Morris RH, Finall A, Jones KP, Jackson SK. Surfactant phospholipid DPPC downregulates monocyte respiratory burst via modulation of PKC. Am J Physiol Lung Cell Mol Physiol. 2005;288:L1070–80.
Kandasamy P, Zarini S, Chan ED, Leslie CC, Murphy RC, Voelker DR. Pulmonary surfactant Phosphatidylglycerol inhibits mycoplasma pneumoniae-stimulated eicosanoid production from human and mouse macrophages. J Biol Chem. 2011;286:7841–53. https://doi.org/10.1074/jbc.%20M110.170241.
Földes-Filep E, Sirois P, Filep JG. Pulmonary surfactant lipids inhibit prostanoid production of Guinea pig alveolar macrophages. J Leukoc Biol. 1994;56:475–80.
Sehgal A, Mak W, Dunn M, Kelly E, Whyte H, McCrindle B, et al. Haemodynamic changes after delivery room surfactant administration to very low birth weight infants. Arch Dis Child Fetal Neonatal Ed. 2010;95:F345–51. https://doi.org/10.1136/adc.2009.173724.
Evans N, Kluckow M. Early ductal shunting and intraventricular haemorrhage in ventilated preterm infants. Arch Dis Child Fetal Neonatal Ed. 1996;75:F183–6.
Kluckow M, Evans N. Low superior vena cava flow and intraventricular haemorrhage in preterm infants. Arch Dis Child Fetal Neonatal Ed. 2000;82:F188–94.
Ambalavanan N, Carlo WA, Wrage LA, Das A, Laughon M, Cotten CM, et al. PaCO2 in surfactant, positive pressure, and oxygenation randomised trial (SUPPORT). Arch Dis Child Fetal Neonatal Ed. 2015;100:F145–9. https://doi.org/10.1136/archdischild-2014-306802.
Hill A, Perlman JM, Volpe JJ. Relationship of pneumothorax to occurrence of intraventricular hemorrhage in the premature newborn. Pediatrics. 1982;69:144–9.
Lipscomb AP, Thorburn RJ, Reynolds EO, Stewart AL, Blackwell RJ, Cusick G, Whitehead MD. Pneumothorax and cerebral haemorrhage in preterm infants. Lancet. 1981;1:414–6.
Wigglesworth JS, Keith IH, Girling DJ, Slade SA. Hyaline membrane disease, alkali, and intraventricular haemorrhage. Arch Dis Child. 1976;51:755–62.
American Academy of Pediatrics. Committee on Fetus and Newborn. Surfactant-Replacement Therapy for Respiratory Distress in the Preterm and Term Neonate. Pediatrics. 2008;121:419–32. https://doi.org/10.1542/peds.2007-3283.
Ghio AJ, Fracica PJ, Young SL, Piantadosi CA. Synthetic surfactant scavenges oxidants and protects against hyperoxic lung injury. J Appl Physiol. 1994;77:1217–23. https://doi.org/10.1152/jappl.19220.127.116.117.
Ikegaki J, Mikawa K, Obara H. Effects of surfactant on lung injury induced by hyperoxia and mechanical ventilation in rabbits. J Anesth. 1993;7:66–74. https://doi.org/10.1007/s0054030070066.
Dunham-Snary KJ, Hong ZG, Xiong PY, Del Paggio JC, Herr JE, Johri AM, et al. A mitochondrial redox oxygen sensor in the pulmonary vasculature and ductus arteriosus. Pflugers Arch. 2016;468:43–58. https://doi.org/10.1007/s00424-015-1736-y.
Tubman TR, Rankin SJ, Halliday HL, Johnston SS. Surfactant replacement therapy and the prevalence of acute retinopathy of prematurity. Biol Neonate. 1992;61(Suppl 1):54–8.
Canpolat FE, Yurdakök M, Ersin SC. Effects of Enterally administered surfactant in a rat model of necrotizing Enterocolitis. Neonatology. 2012;102:53–8. https://doi.org/10.1159/000336571.
Boyle E, Menon G, Elton R, McIntosh N. 18 Factors Influencing Neonatologists in Feeding of Preterm and Very Low Birth Weight Infants. Paediatr Child Health 2004; 9(suppl_a): 23A. https://doi.org/10.1093/pch/9.suppl_a.23aa
Giannì ML, Sannino P, Bezze E, Plevani L, di Cugno N, Roggero P, et al. Effect of co-morbidities on the development of oral feeding ability in pre-term infants: a retrospective study. Sci Rep. 2015;5. https://doi.org/10.1038/srep16603.
Corvaglia L, Fantini MP, Aceti A, Gibertoni D, Rucci P, Baronciani, et al. Predictors of Full Enteral Feeding Achievement in Very Low Birth Weight Infants. PloS One. 2014;9:e92235. https://doi.org/10.1371/journal.pone.0092235.
Park J, Knafl G, Thoyre S, Brandon D. Factors Associated With Feeding Progression in Extremely Preterm Infants. Nurs Res. 2015;64:159–67. https://doi.org/10.1097/NNR.0000000000000093.
Mcmurphy DM, Heymann MA, Rudolph AM, Melmon KL. Developmental changes in constriction of the Ductus Arteriosus: responses to oxygen and vasoactive agents in the isolated Ductus Arteriosus of the fetal lamb. Pediatr Res. 1972;6:231–8. https://doi.org/10.1203/00006450-197204000-00004.
Singh N, Hawley KL, Viswanathan K. Efficacy of porcine versus bovine surfactants for preterm newborns with respiratory distress syndrome: systematic review and meta-analysis. Pediatrics. 2011;128:e1588–95. https://doi.org/10.1542/peds.2011-1395.
Vartanian RJ, Besirli CG, Barks JD, Andrews CA, Musch DC. Trends in the screening and treatment of retinopathy of prematurity. Pediatrics. 2017;139:e20161978. https://doi.org/10.1542/peds.2016-1978.
Hung Y-C, Yeh J-L, Hsu J-H. Molecular mechanisms for regulating postnatal Ductus Arteriosus closure. Int J Mol Sci. 2018;19:1861. https://doi.org/10.3390/ijms19071861.
Hooper SB, Binder-Heschl C, Polglase GR, Gill AW, Kluckow M, Wallace EM, et al. The timing of umbilical cord clamping at birth: physiological considerations. Matern Health Neonatol Perinatol. 2016;2. https://doi.org/10.1186/s40748-016-0032-y.
Cogo PE, Facco M, Simonato M, De Luca D, De Terlizi F, Rizzotti U, et al. Pharmacokinetics and clinical predictors of surfactant redosing in respiratory distress syndrome. Intensive Care Med. 2011;37:510–7. https://doi.org/10.1007/s00134-010-2091-2.
Cogo PE, Facco M, Simonato M, Verlato G, Rondina C, Baritussio A, et al. Dosing of porcine surfactant: effect on kinetics and gas exchange in respiratory distress syndrome. Pediatrics. 2009;124:e950–7. https://doi.org/10.1542/peds.2009-0126.
Lin H-J, Huang C-T, Hsiao H-F, Chiang M-C, Jeng M-J. End-tidal carbon dioxide measurement in preterm infants with low birth weight. PLoS One. 2017;12:e0186408. https://doi.org/10.1371/journal.pone.0186408.
Vesoulis ZA, Herco M, Mathur AM. Divergent risk factors for cerebellar and intraventricular hemorrhage. J Perinatol. 2018;38:278–84. https://doi.org/10.1038/s41372-017-0010-x.
Hartnett ME, Cotten CM. Genomics in the neonatal nursery: focus on ROP. Semin Perinatol. 2015;39:604–10. https://doi.org/10.1053/j.semperi.2015.09.007.
Cuna A, George L, Sampath V. Genetic predisposition to necrotizing enterocolitis in premature infants: current knowledge, challenges, and future directions. Semin Fetal Neonatal Med. 2018;23:387–93. https://doi.org/10.1016/j.siny.2018.08.006.
Soll R, Özek E. Prophylactic animal derived surfactant extract for preventing morbidity and mortality in preterm infants. Cochrane Database Syst Rev. 1997. https://doi.org/10.1002/14651858.CD000511.
Soll R. Prophylactic synthetic surfactant for preventing morbidity and mortality in preterm infants. Cochrane Database Syst Rev. 1998. https://doi.org/10.1002/14651858.CD001079.
Gattinoni L, Marini JJ, Quintel M. Time to Rethink the Approach to Treating Acute Respiratory Distress Syndrome. JAMA. 2018;319:664. https://doi.org/10.1001/jama.2017.21900.
De Luca D, Harrison D, Peters MJ. ‘Lumping or splitting’ in Paediatric acute respiratory distress syndrome (PARDS). Intensive Care Med. 2018;44:1548–50.
We are grateful to trials’ authors who helped to retrieve data and details of their works.
There was no funding source for this study.
Not applicable as this is a review and meta-analysis. Trials meta-analysed have all received their original ethical approval.
Consent for publication
A/Prof. D. De Luca has received grants for research and educational projects from Chiesi Pharmaceuticals spa and ABBVIE inc. He also received travel grants from ABBVIE inc. He served as consultant and lecturer for both Chiesi Pharmaceuticals spa and ABBVIE inc. Finally, he was member of the advisory boards for both Chiesi Pharmaceuticals spa and ABBVIE inc. These companies produce two surfactants analyzed in the paper, but they had no role in design and conduct of the study; collection, management, analysis and interpretation of the data; preparation, review, approval of the manuscript or decision to submit it for publication.
The other author declares no competing interests.
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
The authors confirm that the Principal Investigator for this paper is A/Prof. D. De Luca and that he had direct clinical responsibility.
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Foligno, S., De Luca, D. Porcine versus bovine surfactant therapy for RDS in preterm neonates: pragmatic meta-analysis and review of physiopathological plausibility of the effects on extra-pulmonary outcomes. Respir Res 21, 8 (2020). https://doi.org/10.1186/s12931-019-1267-8
- Non-respiratory outcome