Abstract
Background
Postnatal systemic corticosteroids reduce the risk of bronchopulmonary dysplasia but the effect depends on timing, dosing, and type of corticosteroids. Animal studies may provide valuable information on these variable effects. This systematic review summarizes the effects of postnatal systemic corticosteroids on lung development in newborn animals.
Methods
A systematic search was performed in PubMed and Embase in December 2022. The protocol was published on PROSPERO (CRD42021177701).
Results
Of the 202 eligible studies, 51 were included. Only newborn rodent studies met the inclusion criteria. Most studies used dexamethasone (98%). There was huge heterogeneity in study outcome measures and corticosteroid treatment regimens. Reporting of study quality indicators was mediocre and risk of bias was unclear due to poor reporting of study methodology. Meta-analysis showed that postnatal corticosteroids caused a decrease in body weight as well as persistent alveolar simplification. Subgroup analyses revealed that healthy animals were most affected.
Conclusion
In newborn rodents, postnatal systemic corticosteroids have a persistent negative effect on body weight and lung development. There was huge heterogeneity in experimental models, mediocre study quality, unclear risk of bias, and very small subgroups for meta-analysis which limited firm conclusions.
Impact
-
Postnatal corticosteroids reduce the risk of bronchopulmonary dysplasia but the effect depends on timing, dosing, and type of corticosteroids while the underlying mechanism of this variable effect is unknown.
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This is the first systematic review and meta-analysis of preclinical newborn animal studies reviewing the effect of postnatal systemic corticosteroids on lung development.
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In newborn rodent models, postnatal corticosteroids have a persistent negative effect on body weight and lung alveolarization, especially in healthy animals.
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Background
Postnatal corticosteroids in preterm infants are used to prevent and/or treat developing bronchopulmonary dysplasia (BPD).1 BPD is a chronic lung disease and the most common complication of preterm birth.2 It is characterized by an arrest in alveolar and pulmonary vascular development and is accompanied by long-term pulmonary and neurological sequelae.3,4 Acute and/or chronic inflammation is considered the most important risk factor in the multifactorial etiology of evolving BPD, while chorioamnionitis, oxygen therapy, postnatal sepsis, and mechanical ventilation are the most common causes for this inflammatory response in preterm infants.5,6,7,8 The rationale for postnatal systemic corticosteroid administration to attenuate the inflammatory process and subsequent development of BPD seems therefore plausible.9 Although randomized controlled trials in humans have shown that systemic corticosteroids can reduce BPD, the reported treatment regimens according to (inter)national guidelines are highly variable and the treatment effects seem to be related to patient characteristics and type, timing, and dose of corticosteroids.10,11,12,13 In addition, studies have shown an increase in neurodevelopmental complications in preterm infants exposed to postnatal corticosteroids, indicating that corticosteroids can have a negative effect on the developing brain and other organs.9,13,14,15,16,17 The underlying mechanism for these inconsistent effects of corticosteroids is poorly understood.
Over the last decades, multiple animal studies have been done to investigate the effects of postnatal corticosteroids on lung development and in most of these studies in-depth microscopic analyses of whole lungs were performed, something that is not feasible in human studies. The results of these animal studies might provide insight into underlying mechanisms of why the treatment effects of corticosteroids are so variable in preterm infants. In order to optimize the interpretation of these studies, a systematic review is urgently needed.18 Therefore, the aim of this systematic review and meta-analysis was to identify, appraise, and summarize all current literature on the effects of the different types and regimens of postnatal systemic corticosteroids on lung development in healthy and diseased newborn animal models.
Methods
Protocol and registration
The review methodology for this work was pre-specified in a protocol registered at PROSPERO (CRD42021177701). The following amendments to the review protocol were made: (1) inclusion of research using systemic corticosteroids only; (2) we adjusted our method for duplicate outcome data extraction because of limited resources (see below). This review is reported according to PRISMA guidelines (see Supplement 1 for the completed PRISMA checklist).19
Search strategy and study selection process
A comprehensive search was performed in PubMed and Embase (via Ovid) to identify all published animal studies investigating the effects of postnatal corticosteroids on lung development. Databases were searched for published articles from inception until December 27th, 2022. The search strategy included the components “animal”, “corticosteroids”, “lung”, and “newborn animal”. The full search strings can be found in Supplement 2. Articles were included if the study was an original full-length paper reporting unique outcome data on lung development in newborn mammals receiving postnatal systemic corticosteroids before complete alveolarization. Studies were excluded when: (1) publication types were other than a full-length research article (e.g., reviews and conference abstracts), (2) the study was not performed in mammals, (3) no postnatal corticosteroids were administered, (4) there were no outcomes related to lung development or lung injury reported, or animals were terminated within 24 h after treatment, (5) corticosteroids were administered after complete alveolarization, (6) a non-prematurity related lung disease model was used (e.g., persistent pulmonary hypertension of the neonate, congenital diaphragmatic hernia or meconium aspiration syndrome), (7) there was an unsuitable co-intervention or co-morbidity (e.g., artificial placenta), or (8) the full text was unavailable. All reference lists of retrieved articles were searched for additional studies, which did not lead to any new articles. No language restriction was applied. Inclusion of eligible articles was done in two phases in Rayyan (https://www.rayyan.ai): first screening for eligibility based on title and abstract and a second screening for final inclusion based on the full text. In both phases, two reviewers (IL and RV) independently performed the study selection. In case of discrepancies, a third reviewer (MvT) was consulted.
Study characteristics and outcome data extraction
We extracted the following characteristics from the included studies: animal species and strain, age at the start of the experiment and at the start of corticosteroid treatment, sex, model for lung injury (if applicable), type of corticosteroid, duration of treatment, route of administration, frequency, dose, age of termination, and co-interventions (if applicable). Study characteristics were extracted by one reviewer (IL).
We extracted the mean, standard deviation, and sample size (n) for the control and treated groups for the following outcome measures: all-cause mortality, body length and -weight, lung volume, -weight, -morphometry, -inflammation, -function, -proliferation, -matrix, and vascular morphometry. Outcome data displayed in figures were extracted using ImageJ if no numerical data were available.20
Risk of bias and quality assessment
We assessed the reporting quality of five key quality indicators (“yes” versus “no”), namely any randomization, any blinding, a sample size or power calculation, a conflict of interest statement, and any apparent experimental unit of analysis error (e.g., assigning treatment to a litter, while using individual pups as the unit of analysis). Risk of bias was assessed using SYRCLE’s risk of bias tool for animal studies.21 Risk of bias for each bias domain was classified as “low”, “high”, or “unclear”. To be classified as low risk of bias for baseline characteristics, the supplier and strain of the animal, (ratio of) sex, and weight at the start of the experiment had to be specified. Both assessments were performed independently by two reviewers (IL and MvT), with consultation of a third reviewer (KW) in case of discrepancies. The assessors were not blinded to the names of the authors during this process.
Data synthesis and statistical analyses
Meta-analyses were performed using Review Manager 5.4 (The Cochrane Collaboration, Copenhagen, Denmark) on all outcomes reported in a minimum of five studies. All meta-analyses were performed by computing the standardized difference in means (SMD) with the corresponding 95% confidence intervals (CI) to account for the differences between species and different units of measurement. Data were pooled using a random effects model in all analyses, accounting for anticipated heterogeneity. Heterogeneity was assessed and reported as the I2 statistic. Subgroup analyses were performed post hoc and a minimum of three studies per subgroup was required. The subgroup injury included animals that were exposed to hyperoxia, lipopolysaccharides (LPS), or bleomycin. Exposure to retinoic acid was not injurious hence those animals were categorized as healthy. To differentiate between acute and chronic effects of corticosteroids on lung development, subgroup analysis based on age at evaluation of these effects was performed. Peak alveolarization was taken as the cut-off for this subgroup, which is around postnatal day 15 in small rodents.22,23 For outcomes that did not meet the threshold for meta-analysis a descriptive synthesis was performed. We aimed to assess publication bias using visual inspection of funnel plots for all analyses containing ≥20 studies; however, for none of the outcomes this threshold was reached. No sensitivity analyses were performed.
Results
Study selection
A total of 10,409 articles were retrieved by the search on December 27th, 2022. After deduplication, a total of 3909 unique articles were screened based on title and abstract. The majority (n = 132) of the 202 articles eligible for full-text screening were excluded due to the administration of corticosteroids after complete alveolarization. A total of 51 studies were included in this review, which were all in English and published between 1985 and 2022 (Supplement 3).24,25,26,27,28,29,30,31,32,33,34,35,36,37,38,39,40,41,42,43,44,45,46,47,48,49,50,51,52,53,54,55,56,57,58,59,60,61,62,63,64,65,66,67,68,69,70,71,72,73,74
Study characteristics
Study characteristics and outcome measures are described in Table 1. Although the search included all newborn animals, only rodent studies met the inclusion criteria; 39 studies used rats (76%), 11 used mice (22%), and one used guinea pigs. We found substantial differences in study design regarding the start of corticosteroid treatment, route of administration, duration, and frequency of treatment, and length of follow-up. Some studies compared multiple time points at which treatment was initiated, multiple durations of treatment, and/or multiple doses. As a result, a total of 87 treatment protocols were identified. Dexamethasone was the most frequently used corticosteroid (98%).
In the majority of protocols, corticosteroids were administered subcutaneously (65%), followed by intraperitoneal injection (24%). Two studies did not report the route of administration.38,61 Six studies started corticosteroids at multiple time points, resulting in a total of 64 different age cohorts. In 73% of cohorts, corticosteroids were started in the first 4 days of life, and 86% of protocols started within the first week of life. One study did not report the age at which corticosteroids were started.33
The studies that used a weight-based cumulative dose administered a range from 0.02 µg/g to 100 µg/g. In forty-five protocols a standard cumulative dose ranging from 0.4 µg to 75 µg was used. The total number of doses varied between a single dose (35% of studies) up to 14 doses. Twelve studies (24%, nineteen protocols) used tapered doses of corticosteroids. In one study, corticosteroids were administered via breastmilk, which resulted in a plasma concentration of ~15 ng/ml in the newborn animals.55
Fifteen studies (31%) used a lung injury model to study the effects of corticosteroids. Ten studies used hyperoxia, while three studies used either hypoxia, intraperitoneal bleomycin, or intra-amniotic LPS.34,36,37 One study used a double hit model combining prenatal LPS and hyperoxia, whereas another study in guinea pigs combined prematurity with hyperoxia.37,74 All other studies made use of healthy newborn animals. Twelve studies (24%) used retinoic acid as a co-intervention.
Reporting of study quality indicators
The overall reporting of key study quality indicators was mediocre (Fig. 1a). Of the 51 included studies, 32 (63%) mentioned the term randomization at any stage of the experiment and nine studies (18%) reported blinding during any phase of the experiment. In most cases, only the outcome histology assessment was blinded. Only one study reported a power calculation to justify the sample size.47 A conflict of interest statement was reported in thirteen studies (25%). Forty-one studies (80%) had an error in the experimental unit of analysis, most often because treatment was assigned per litter or not reported, while in the analysis the individual pups were used as the experimental unit.
Key indicators of study quality (a) and risk of bias assessment (b) using SYRCLE’s risk of bias tool for animal studies.21 The type of bias assessed with each signaling question is indicated between brackets.
Risk of bias
In most studies, multiple risks of bias domains were assessed as unclear (Fig. 1b) due to poor reporting of the study methodology. Five studies (10%) had groups with similar characteristics at baseline, while all other studies were assessed as unclear. Fifteen studies (29%) used some form of random selection during outcome assessment, there was some form of blinding in nine studies (18%), and the risk of attrition bias was high in six studies (12%). Three studies (8%) were assessed as high risk for selective outcome reporting.30,59,71 Furthermore, two studies were assessed as high risk for other bias.55,71
Outcome assessment
A description of the outcome mortality can be found in Supplement 4. We were unable to identify five or more studies reporting on similar outcome measures for lung inflammation, -function, -proliferation, -matrix, or vascular morphometry. Therefore, no meta-analysis could be performed for these outcomes and because of heterogeneity between these studies, no pattern in these outcomes could be found.
Meta-analyses
All meta-analyses and subgroup analyses can be found in Table 2.
Body weight (growth)
Meta-analysis showed that newborn animals exposed to corticosteroids had a decrease in body weight compared to controls (SMD −1.72 [95% CI −2.08, −1.35], p < 0.01, I2 = 85%, 22 studies; 88 comparisons; 1487 animals). Subgroup analysis for age at evaluation of outcome showed a larger decrease in body weight in newborn animals analyzed before 15 days of age (Supplement 5, subgroup difference p < 0.00001, I2 = 97.1%). There was no subgroup difference in the effect of corticosteroids between healthy newborn animals and newborn animals with lung injury (Table 2).
Lung volume and -weight
There was no effect of corticosteroids on lung volume and lung weight, nor was there an effect of corticosteroids on lung volume based on age at evaluation of outcome (Table 2). Due to a lack of studies no subgroup analysis was possible for the subgroup age for lung weight, nor was it possible for the subgroup healthy versus injured newborn animals for both lung weight and -volume.
Radial alveolar count (RAC)
RAC is a measure of the number of alveoli. Meta-analysis showed that corticosteroid treatment resulted in a decrease in RAC compared to the control group (SMD −2.04 [95% CI −2.93, −1.16], P < 0.01, I2 = 90%; 11 studies; 35 comparisons; 513 animals). Subgroup analysis based on age at evaluation of outcome showed no differences. However, subgroup analysis based on health status showed a larger reduction in RAC in healthy newborn animals compared to newborn animals with lung injury (Fig. 2, test for subgroup difference P < 0.0001, I2 = 93.5%).
Effect size is calculated as Standardized Mean Difference (SMD), with a 95% confidence interval (95% CI) in a random effects model. RAC radial alveolar count, PND postnatal day, NORM normoxia, CSO cottonseed oil, RA retinoic acid, CON control, WT wild-type, HYP hyperoxia, BLEO bleomycin, BMS betamethasone, VEH vehicle, DEX dexamethasone, HCS hydrocortisone, MPS methylprednisolone, KO knock out.
Alveolar mean chord length (Lm)
Lm is a measure of the acinar air space complex (alveoli and alveolar ducts combined). Meta-analysis showed that corticosteroid exposure increased Lm (SMD 2.14 [95% CI 1.42, 2.86], P < 0.01, I2 = 81%; 13 studies; 40 comparisons; 455 animals). A subgroup difference was found based on age at evaluation of outcome (test for subgroup difference, P < 0.01, I2 = 88.2%) showing that analysis after 15 days of age revealed a more profound increase in Lm than analysis before 15 days. Furthermore, subgroup analysis comparing the effect of corticosteroids in healthy versus injured newborn animals showed that corticosteroids had no effect on Lm in the injured group (Fig. 3, test for subgroup difference, P < 0.01, I2 = 94.5%).
Effect size is calculated as Standardized Mean Difference (SMD), with a 95% confidence interval (95% CI) in a random effects model. PND postnatal day, DEX dexamethasone, HCS hydrocortisone, CON control, F female, M male, NORM normoxia, BLEO bleomycin, BMS betamethasone, HYP hyperoxia, VEH vehicle, MPS methylprednisolone. CHRONO, DOSE, ROUTE, DURATION, and MORPHO: different experimental protocols. FVB, ICR, and NIH: different mouse strains.
Wall thickness
Wall thickness is a measure of the width of inter-alveolar septal walls. Overall, meta-analysis showed no difference in wall thickness between newborn animals exposed to corticosteroids or the control group. A subgroup difference was however found based on age at evaluation of outcome showing a larger decrease in wall thickness in newborn animals analyzed before 15 days of age compared to analysis after 15 days (test for subgroup difference, P = 0.03, I2 = 78.3%). Subgroup comparison based on health status was not possible due to a paucity of study data (Table 2).
Airspace volume and lung surface area
No apparent effect of corticosteroid treatment was found for the outcome airspace volume. Subgroup analysis based on age at evaluation of outcome did not change this finding while subgroup analysis based on health status was not possible due to a lack of study data. For lung surface area meta-analysis showed that surface area was decreased in newborn animals exposed to corticosteroids compared to controls (SMD −1.51 [95% CI −2.09, −0.93], p < 0.01, I2 75%, 13 studies; 45 comparisons; 433 animals). No subgroup differences based on age at evaluation of outcome or health status were found for lung surface area (Table 2).
Discussion
This systematic review provides insight into the size, variability, and validity of the preclinical evidence of the effects of postnatal systemic corticosteroids on lung development in newborn animals in order to support its use in preterm infants at risk of BPD. Overall study quality was mediocre and the risk of bias was unclear in all domains because of poor reporting. Meta-analyses showed that corticosteroids in healthy conditions had a negative impact on lung development as well as on body weight of newborn animals. Administration of corticosteroids to healthy animals resulted in alveolar simplification shown as a persistent decrease in the number of alveoli (RAC) and surface area, a persistent increase in Lm, and an early transient decrease in alveolar septal wall thickness. Conversely, in animals with lung injury corticosteroids appeared to have little effect on most outcomes; RAC and surface area did not decrease, nor did Lm increase compared to newborn animals with lung injury but without corticosteroid treatment. A few findings are noteworthy:
First, alveolar simplification as a result of postnatal systemic corticosteroids in healthy newborn animals is concerning. Hypothetically, this finding could be explained by a (temporary) increase in lung maturation with an increase in cellular differentiation and thinning of alveolar septal walls at the expense of proliferation (septation), eventually resulting in a structurally simplified and smaller lung.75,76,77 Acceleration of maturation in its broadest sense, including upregulation of surfactant production and its release and improvement of hemodynamics is essentially also the key rationale for the use of prenatal corticosteroids in imminent preterm labour.78
Second, the reduced effect of corticosteroids in newborn animals with lung injury is puzzling. One explanation for the absence of differences in RAC and Lm could be the fact that lung injury by itself, especially hyperoxia, causes alveolar simplification and corticosteroids simply do not aggravate (or ameliorate) this effect.26 Another explanation could be that the inflicted injury is so overwhelming that any effect of corticosteroids is completely overshadowed. Interestingly, these different effects of corticosteroids in healthy and injured lungs may in part explain the results from human randomized controlled trials, which showed that the effect of corticosteroids on the reduction of BPD is less profound with prophylactic treatment.14 A prophylactic treatment strategy unavoidably includes preterm infants with less severe lung injury (i.e., healthier lungs) who are at lower risk of a protracted course of invasive ventilation. Hence, the reduction in days on invasive ventilation will be modest and we speculate that instead the direct (negative) effects of corticosteroids on lung development will dominate and might even contribute to some form of alveolar simplification in these infants.
Third, subgroup analysis on age at evaluation differentiated between acute and long-term (persistence of) effects of postnatal corticosteroids. This analysis showed that the decrease in body weight and thinning of the alveolar septal walls was most notable during peak alveolarization (<15 days of age) and resolved (septal wall thinning) or partially came back up (body weight) thereafter (≥15 days of age). On the contrary, the effect on Lm (Lm increased) was visible before 15 days of age and increased with time (≥15 days of age). The effect on surface area (decreased) was only manifested after 15 days of age. The decrease in RAC was an early (<15 days of age) effect that did not resolve with time. Together these observations suggest that postnatal systemic corticosteroids in newborn animals have an early negative impact on body weight and lung structure that results in persistent alveolar simplification. The effect on thinning of the alveolar walls was not persistent and disappeared when analyzed after 15 days. This finding seems to be in line with the clinical observation that courses of pre- and postnatal corticosteroids improve the preterm infant’s lung condition as revealed by a reduced need for oxygen and respiratory support but that this effect wears off over time.78,79
Fourth, human randomized controlled trials have shown clear evidence for a reduction in BPD with (timed and targeted) postnatal corticosteroid treatment in preterm infants. The underlying mechanism for this effect is believed to be a reduction of inflammation which improves lung condition and allows for earlier weaning of invasive ventilation and supplemental oxygen, thereby preventing ongoing inflammation with further lung injury and subsequent development of BPD.9 We speculate that a maturational effect of corticosteroids could also be part of this underlying mechanism especially the temporary thinning of alveolar walls. Unfortunately, we found no evidence for either of these explanatory mechanisms in this systematic review due to a paucity of studies reporting on (comparable) inflammatory markers or on alveolar wall thickness in newborn animals with lung injury and corticosteroid treatment.
Overall, in spite of the widespread use of postnatal systemic corticosteroids and the great clinical controversy of treating versus withholding corticosteroids for preterm infants, we found surprisingly limited preclinical research on this topic, especially the use of corticosteroids in lung injury models. The limited number of available studies prevented us from performing a publication bias analysis, and it is therefore uncertain to which extent this bias may be influencing our meta-analyses results. Furthermore, it is important to realize that subgroup analyses are hypothesis-generating, and further studies are needed to confirm (or reject) our findings. The identified small amount of evidence is tremendously heterogeneous in terms of used treatment regimens, which limits our ability to assess the impact of clinically relevant modifiers such as dose, duration, and timing of corticosteroid efficacy through subgroup analysis or meta-regression. Also, nearly all studies (98%) used dexamethasone, while a recently published French cohort study showed that the only corticosteroid given to preterm infants from 2017 to 2021 was hydrocortisone.1 Comparing outcomes across studies was equally challenging because different methods of measurement to assess RAC, Lm, wall thickness, lung surface area, and airspace volume were used among studies.
Additionally, we expected to find more common outcomes related to inflammation, lung matrix, and lung function as inflammation, with an imbalance in pro-inflammatory and anti-inflammatory cytokines is assumed to play a crucial role in the development of BPD, and compromised lung function and impaired exercise tolerance are significant long-term sequelae in preterm infants surviving with BPD.80,81,82,83,84,85
The used animal models had several limitations which compromised their external validity for BPD as well. For example, models combining more than two injurious insults are lacking, while (evolving) BPD is of multifactorial origin.5,8 Also, most studies exposed newborn animals to hyperoxia as high as 50–97% oxygen and some used hyperoxia exposure times as long as 3 weeks, which significantly exceeds the oxygen exposure of human preterm infants in contemporary clinical settings. Furthermore, we found only one study that exposed animals to LPS before administering corticosteroids, while sepsis is a major risk factor for BPD.86
Some studies used a 10-day course of dexamethasone which resembles the human (modified) Dexamethasone: A Randomized Trial (DART) protocol that is used in many clinical units.87,88 However, direct comparisons of these studies with the human situation is complex since lung development in rodents progresses much faster than in humans. A 10-day course in newborn rats or mice comprises most saccular and half of the total alveolar stage of lung development, while a 10-day course in an extremely preterm infant of 26 weeks comprises only the beginning of the saccular stage of lung development.89,90 Also, more differences exist between rodent and human lung development. For example, while term rodents and extremely preterm infants are both born in the saccular stage of lung development, term rodents are surfactant sufficient while extreme preterm infants are not.89,90 We therefore emphasize that direct comparisons of corticosteroid treatment regimes in experimental rodent studies on lung development to the human situation should be interpreted with caution.
Furthermore, new BPD with alveolar simplification is of highest risk in the most extreme preterm infants which is not well translated in a term rodent model. Iatrogenic prematurity is however possible in large (non-rodent) animals and several research groups have studied the effects of prenatal corticosteroids on respiratory distress syndrome in preterm animal models.91,92,93 Unfortunately, studies that administered postnatal corticosteroids to large (preterm) animals did not meet the inclusion criteria of this systematic review because follow-up times were less than 24 h or corticosteroids were administered intra-tracheal instead of systemic.94,95,96
All these issues raise concerns about the translatability of the worrying experimental findings of this systematic review. Future preclinical studies should therefore minimize risks of bias, enhance reporting and methodological quality, and strive for more standardization in (measurement of) outcome parameters, corticosteroid treatment regimens, and lung injury models to enhance comparability. Also, (large) animal models should represent the current clinical setting more closely and address the multifactorial nature of BPD in order to elucidate the delicate balance between the detrimental and beneficial effects of corticosteroids on lung development and BPD.
Conclusion
This is the first systematic review and meta-analysis of the effects of postnatal systemic corticosteroids on lung development in animal studies. We found that postnatal corticosteroids have a negative effect on body weight and lung development resulting in persistent alveolar simplification. This detrimental effect on lung structure was mainly observed in healthy animals, which might suggest that corticosteroids should only be considered in preterm infants with lung injury who are at high risk of developing BPD. We do want to emphasize that studies were extremely heterogeneous in design (for example for dosages and duration of corticosteroid treatment), had unclear quality due to insufficient methodological reporting, and used animal models not accurately representing the clinical conditions of high-risk BPD infants.
There is a need for new preclinical studies that mimic the current clinical situation more truly in multi-hit animal models. Those models should investigate different regimens and types of postnatal corticosteroids and should ideally not only focus on short-term outcomes like lung morphology and -inflammation but on long-term physiologic outcomes like lung function as well.
Data availability
The datasets generated during and/or analyzed during the current study are available from the corresponding author upon reasonable request.
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This study was supported by a ZonMW grant: More Knowledge with Fewer Animals, project number 114024903, and titled: Effects of postnatal corticosteroids on lung development in newborn animals. A systematic review and meta-analysis.
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All authors revised the article critically and approved the final version to be published. I.M.L., K.E.W., and M.v.T. made substantial contributions to concept and design of the study, acquisition, analysis, and interpretation of data, and draft of the article; R.J.S.V. made substantial contribution to acquisition of data; W.O. and A.H.v.K made substantial contribution to concept and design of the study, interpretation of data, and draft of the article.
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Lok, I.M., Wever, K.E., Vliegenthart, R.J.S. et al. Effects of postnatal corticosteroids on lung development in newborn animals. A systematic review. Pediatr Res (2024). https://doi.org/10.1038/s41390-024-03114-6
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DOI: https://doi.org/10.1038/s41390-024-03114-6
