Accumulating evidence implicates early life factors in the aetiology of non-communicable diseases, including asthma/wheezing disorders. We undertook a systematic review investigating risks of asthma/wheezing disorders in children born preterm, including the increasing numbers who, as a result of advances in neonatal care, now survive very preterm birth.
Methods and Findings
Two reviewers independently searched seven online databases for contemporaneous (1 January 1995–23 September 2013) epidemiological studies investigating the association between preterm birth and asthma/wheezing disorders. Additional studies were identified through reference and citation searches, and contacting international experts. Quality appraisal was undertaken using the Effective Public Health Practice Project instrument. We pooled unadjusted and adjusted effect estimates using random-effects meta-analysis, investigated “dose–response” associations, and undertook subgroup, sensitivity, and meta-regression analyses to assess the robustness of associations.
We identified 42 eligible studies from six continents. Twelve were excluded for population overlap, leaving 30 unique studies involving 1,543,639 children. Preterm birth was associated with an increased risk of wheezing disorders in unadjusted (13.7% versus 8.3%; odds ratio [OR] 1.71, 95% CI 1.57–1.87; 26 studies including 1,500,916 children) and adjusted analyses (OR 1.46, 95% CI 1.29–1.65; 17 studies including 874,710 children). The risk was particularly high among children born very preterm (<32 wk gestation; unadjusted: OR 3.00, 95% CI 2.61–3.44; adjusted: OR 2.81, 95% CI 2.55–3.12). Findings were most pronounced for studies with low risk of bias and were consistent across sensitivity analyses. The estimated population-attributable risk of preterm birth for childhood wheezing disorders was ≥3.1%.
Key limitations related to the paucity of data from low- and middle-income countries, and risk of residual confounding.
There is compelling evidence that preterm birth—particularly very preterm birth—increases the risk of asthma. Given the projected global increases in children surviving preterm births, research now needs to focus on understanding underlying mechanisms, and then to translate these insights into the development of preventive interventions.
Please see later in the article for the Editors' Summary
Most pregnancies last around 40 weeks, but worldwide, more than 11% of babies are born before 37 weeks of gestation (the period during which a baby develops in its mother's womb). Preterm birth is a major cause of infant death—more than 1 million babies die annually from preterm birth complications—and the number of preterm births is increasing globally. Multiple pregnancies, infections, and chronic (long-term) maternal conditions such as diabetes can all cause premature birth, but the cause of many preterm births is unknown. The most obvious immediate complication that is associated with preterm birth is respiratory distress syndrome. This breathing problem, which is more common in early preterm babies than in near-term babies, occurs because the lungs of premature babies are structurally immature and lack pulmonary surfactant, a unique mixture of lipids and proteins that coats the inner lining of the lungs and helps to prevent the collapse of the small air sacs in the lungs that absorb oxygen from the air. Consequently, preterm babies often need help with their breathing and oxygen supplementation.
Why Was This Study Done?
Improvements in the management of prematurity mean that more preterm babies survive today than in the past. However, accumulating evidence suggests that early life events are involved in the subsequent development of non-communicable diseases (non-infectious chronic diseases). Given the increasing burden of preterm birth, a better understanding of the long-term effects of preterm birth is essential. Here, the researchers investigate the risks of asthma and wheezing disorders in children who are born preterm by undertaking a systematic review (a study that uses predefined criteria to identify all the research on a given topic) and a meta-analysis (a statistical method for combining the results of several studies). Asthma is a chronic condition that is caused by inflammation of the airways. In people with asthma, the airways can react very strongly to allergens such as animal fur and to irritants such as cigarette smoke. Exercise, cold air, and infections can also trigger asthma attacks, which can sometimes be fatal. The symptoms of asthma include wheezing (a high-pitched whistling sound during breathing), coughing, chest tightness, and shortness of breath. Asthma cannot be cured, but drugs can relieve its symptoms and prevent acute asthma attacks.
What Did the Researchers Do and Find?
The researchers identified 30 studies undertaken between 1995 and the present (a time span chosen to allow for recent changes in the management of prematurity) that investigated the association between preterm birth and asthma/wheezing disorders in more than 1.5 million children. Across the studies, 13.7% of preterm babies developed asthma/wheezing disorders during childhood, compared to only 8.3% of babies born at term. Thus, the risk of preterm babies developing asthma or a wheezing disorder during childhood was 1.71 times higher than the risk of term babies developing these conditions (an unadjusted odds ratio [OR] of 1.71). In analyses that allowed for confounding factors—other factors that affect the risk of developing asthma/wheezing disorders such as maternal smoking—the risk of preterm babies developing asthma or a wheezing disorder during childhood was 1.46 times higher than that of babies born at term (an adjusted OR of 1.46). Notably, compared to children born at term, children born very early (before 32 weeks of gestation) had about three times the risk of developing asthma/wheezing disorders in unadjusted and adjusted analyses. Finally, the population-attributable risk of preterm birth for childhood wheezing disorders was more than 3.1%. That is, if no preterm births had occurred, there would have been more than a 3.1% reduction in childhood wheezing disorders.
What Do These Findings Mean?
These findings strongly suggest that preterm birth increases the risk of asthma and wheezing disorders during childhood and that the risk of asthma/wheezing disorders increases as the degree of prematurity increases. The accuracy of these findings may be affected, however, by residual confounding. That is, preterm children may share other, unknown characteristics that increase their risk of developing asthma/wheezing disorders. Moreover, the generalizability of these findings is limited by the lack of data from low- and middle-income countries. However, given the projected global increases in children surviving preterm births, these findings highlight the need to undertake research into the mechanisms underlying the association between preterm birth and asthma/wheezing disorders and the need to develop appropriate preventative and therapeutic measures.
Please access these websites via the online version of this summary at http://dx.doi.org/10.1371/journal.pmed.1001596.
- The March of Dimes, a nonprofit organization for pregnancy and baby health, provides information on preterm birth (in English and Spanish)
- Nemours, another nonprofit organization for child health, also provides information (in English and Spanish) on premature babies and on asthma (including personal stories)
- The UK National Health Service Choices website provides information about premature labor and birth and a real story about having a preterm baby; it provides information about asthma in children (including real stories)
- The MedlinePlus Encyclopedia has pages on preterm birth, asthma, asthma in children, and wheezing (in English and Spanish); MedlinePlus provides links to further information on premature birth, asthma, and asthma in children (in English and Spanish)
Citation: Been JV, Lugtenberg MJ, Smets E, van Schayck CP, Kramer BW, Mommers M, et al. (2014) Preterm Birth and Childhood Wheezing Disorders: A Systematic Review and Meta-Analysis. PLoS Med 11(1): e1001596. doi:10.1371/journal.pmed.1001596
Academic Editor: Bruce P. Lanphear, Simon Fraser University, Canada
Received: July 25, 2013; Accepted: December 6, 2013; Published: January 28, 2014
Copyright: © 2014 Been et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Funding: This work was supported by a Maastricht University Medical Centre Kootstra Talent Fellowship (JVB) and by the International Pediatric Research Foundation Young Investigator Exchange Program (JVB). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript. AS is supported by The Commonwealth Fund, a private independent foundation based in New York City. The views presented here are those of the author and not necessarily those of The Commonwealth Fund, its directors, officers, or staff.
Competing interests: AS is a member of the Editorial Board of PLOS Medicine. The authors have declared that no other competing interests exist.
Abbreviations: BPD, bronchopulmonary dysplasia; OR, odds ratio; PAR, population-attributable risk
The impact of early life exposures on subsequent health and disease is increasingly recognised . Preterm birth is a common early life event, the adverse consequences of which can affect the entire life course. Worldwide, over 11% of babies are born preterm, a number that continues to rise in most regions . Prevention of preterm birth is currently limited by a knowledge gap regarding the mechanisms of normal and pathological labour onset . Given the increasing burden of preterm birth and the restricted scope for prevention, a focus on appreciating and containing its consequences is warranted.
Respiratory distress syndrome is the most obvious direct manifestation of immaturity in preterm newborns. The combination of structural lung immaturity and pulmonary surfactant deficiency results in regional atelectasis and a varying degree of respiratory compromise . Ventilatory support and additional oxygen supplementation are common necessities, and many very preterm babies go on to develop chronic lung disease (bronchopulmonary dysplasia [BPD]) . The majority of preterm babies are, however, born close to term, when respiratory compromise is a less common event. Whereas late preterm babies have long been regarded a normal variation of term babies, it is increasingly recognised that they are at risk of a range of adverse outcomes, including respiratory disease .
Accumulating evidence now implicates preterm birth in the development of respiratory disease in later life. Small airway obstruction is evident through decreased forced expiratory volume in 1 s (FEV1) in children and adults born preterm , and a hypothesized link with chronic obstructive pulmonary disease in adulthood was recently confirmed . Along this line of evidence, a meta-analysis published in 2006 identified preterm birth as a risk factor for asthma in a mixed paediatric and adult population . Asthma is the most common chronic disease affecting children, and its link with preterm birth is of significant public health relevance given the increasing incidence of both entities ,. Of note, the majority of cohorts aggregated in this meta-analysis were born before the 1990s . Important changes in neonatal clinical management have been introduced since, including increased use of antenatal steroids and postnatal surfactant, and a shift towards less aggressive respiratory management . These changes have selectively impacted the survival of extremely preterm infants, and shifted the occurrence of acute respiratory problems towards lower gestational age groups . Associated changes in long-term pulmonary outcomes may have occurred, and there is therefore a need for a comprehensive, rigorous assessment of the contemporaneous evidence base.
We aimed to investigate the association between preterm birth and childhood wheezing disorders through a systematic review and meta-analysis of studies with populations born from the 1990s onwards. We focused on wheezing disorders in general rather than just asthma, given the difficulty in differentiating between the two, particularly among young children . Unlike previous work , we also considered the potential impact of confounding factors and explored the association by degree of prematurity. Based on aggregated association measures, we have furthermore estimated population-attributable risks (PARs) to quantify associated disease burden.
This review was performed following the methods detailed in a systematic review protocol registered with PROSPERO (CRD42013004965; Text S1). Online databases were searched independently by two authors using the following search terms: PubMed and Embase: (preterm OR prematur*) AND (asthma OR wheez*); Google Scholar: asthma, wheeze, wheezing, preterm, premature, child, children, childhood; World Health Organization Global Health Library, World Health Organization Library Information System, SciELO, and Trip : ((preterm OR premature OR preterms OR prematurity) AND (asthma OR wheeze OR wheezing)). The searches covered the period from 1 January 1995 to 23 September 2013. No language restrictions were applied. Additional studies were identified by screening reference lists of articles of interest and tracing citations of articles through ISI Web of Knowledge. We asked an international panel of experts in the field (Text S2) to report any additional published, unpublished, or in progress studies that might have been missed.
Epidemiological studies were eligible for inclusion if they reported an association between preterm birth (<37 wk versus ≥37 wk gestation [term]) and asthma or wheezing in children (aged 0.5 to 18 y). Studies reporting on populations that included children born before 1995 were eligible for inclusion only when at least 50% of the cohort was born from 1995 onwards and none of the children was born before 1990, so as to primarily include studies conducted in the period following the important changes in neonatal practice outlined earlier. When studies with overlapping data were identified, the most informative study was selected for inclusion in this report; the determination of which study was considered most informative was based on consensus, study size being an important determinant. Final study selection was based on a consensus decision between reviewers, with arbitration by a third reviewer in case of disagreement.
Data were independently extracted from eligible studies by two reviewers (J. V. B. and M. J. L.); disagreements were resolved through discussion, with arbitration by a third reviewer if necessary (A. S.). The following study characteristics were extracted: authors, full reference, study design, location, sample size, inclusion and exclusion criteria, age range and birth year of study participants, method of ascertainment of exposure and outcomes, and outcome measure.
Post-term (>42 wk gestation) births were excluded from the analyses, if possible. If studies reported follow-up at different time points, the most recent was selected. Similarly to previous work , we used only one outcome measure from each study in the analyses; for studies with multiple outcome measures, the following hierarchy was used to select the outcome measure used in the analyses, from most preferred to least preferred: asthma, persistent wheezing, recurrent wheezing, severe wheezing, and wheezing. Furthermore, we used the following hierarchy to select the highest ascertainment level if the outcome was measured multiple ways: clinician diagnosis, documented medication use as a wheezing disorder proxy, routinely collected health-care data, parent- or patient-reported clinician diagnosis, parent- or patient-reported medication use, and parent- or patient-reported symptoms. “Ever” wheezing or asthma was favoured over recent and current wheezing or asthma.
Absolute patient counts were extracted to compose 2×2 tables according to preterm birth and wheezing disorder status, and these were used to calculate univariate odds ratios (ORs); in instances where relevant crude data were missing, we approached authors to request these. If needed, count data were calculated from provided percentages, and these were then rounded off to the nearest integer. Adjusted association measures were extracted from the most adjusted model presented.
Study quality was assessed independently by two investigators using the Effective Public Health Practice Project quality assessment tool for quantitative studies . Sex, maternal smoking during pregnancy, and maternal atopy or asthma, or a family history of atopy or asthma, were deemed the most important confounders. Any disagreement was resolved by consensus and arbitration by a third reviewer, where necessary.
Univariate association measures were pooled using Mantel-Haenszel analysis. Random-effects models were applied because of anticipated heterogeneity given between-country variation in clinical practice and differences in inclusion and exclusion criteria, outcome specification, and ascertainment level of exposure and outcome. Adjusted association measures were pooled via random-effects generic inverse variance analysis. Standard errors for study point estimates were calculated from the respective 95% confidence intervals as described in the Cochrane Handbook .
For studies reporting adjusted association measures according to multiple gestational age strata, the least preterm stratum was selected to obtain the most conservative estimate. In a separate analysis, a linear association between gestational age at birth and wheezing disorder risk was investigated, pooling individual studies by random-effects generic inverse variance analysis. For this purpose, adjusted association measures for multiple gestational age strata were aggregated within studies using a fixed-effects log-linear dose–response regression model . The Q-statistic and I2-test were used to assess heterogeneity among studies. Small-study effects were assessed using funnel plots and Harbord's modified regression test for unadjusted data and Egger's regression test for adjusted association measures.
Subgroup analyses were performed according to age group (<5 y versus ≥5 y) and degree of prematurity (<32 wk versus 32–36 wk). When studies reported the association between preterm birth and wheezing disorders for both subgroups (i.e., follow-up at <5 y and at ≥5 y, and/or reported for <32 wk and 32–36 wk gestation), the corresponding association measures were included in both sides of the comparison.
Sensitivity analyses were performed according to risk of bias (low, moderate, or high), study size (n<10,000 versus n≥10,000), and outcome definition (asthma versus wheezing) and ascertainment (clinician diagnosis and/or medication use versus parent-reported outcomes).
Meta-regression analysis was performed to assess the independent effects of study size, mean age, wheezing type (wheezing versus asthma), diagnosis ascertainment, and publication year on the association between preterm birth and wheezing disorders.
PAR was calculated using the following formula:(1)where Pe is the exposure prevalence and RRe is the relative risk due to exposure . RRe was calculated as follows:(2)where PEER is the patient expected event rate. As estimations of PAR based on unadjusted association measures can be biased by confounding of the exposure–outcome relationship, we additionally calculated PAR using aggregated adjusted association measures via the following formula:(3)where pd is the proportion of cases exposed .
Analyses were performed using Stata 12 (StataCorp).
Forty-two eligible studies were identified –. Study selection is summarised in Figure 1. Five studies from Sweden ,,,, and two from northern California, US, had significant population overlap ,. Furthermore, several eligible studies described the same cohort: the Epicure cohort, UK and Ireland (n = 4) ,,,; the Boston Birth Cohort, Boston, US (n = 3) ,,; a birth cohort from southern New England, US (n = 2) ,; and cross-sectional surveys from Liverpool, UK (n = 2) ,. The most relevant study was selected from each set of overlapping studies. Characteristics of the 12 studies that were excluded, as well as reasons for exclusion, are given in Table S1. Meta-analysis was performed on the remaining 30 unique studies (Tables 1 and 2), which reported on a total of 1,543,639 individuals ,–,–,,,–,,–,–.
WHO GHL, World Health Organization Global Health Library; WHOLIS, World Health Organization Library Information System.
Four studies were deemed to have low risk of bias, 12 had moderate risk of bias, and 14 had high risk of bias (Table S2). Studies with high risk of bias were generally smaller (median size 756; range 90–7,925) than those with moderate risk (median size 10,246; range 560–397,852) and low risk (median size 6,992; range 1,448–708,907).
Meta-Analysis of Unadjusted Data
Crude data were provided by authors of five studies ,,,,, and were calculated for seven additional studies ,–,,,. Crude data could not be retrieved for four studies, and these were included in the adjusted meta-analysis only ,,,. Pooling of the 26 studies (1,500,916 individuals) for which unadjusted data were available showed a significant association between preterm birth and wheezing disorders (OR 1.71, 95% CI 1.57–1.87, p<0.001; Figure 2). Out of 93,616 children born preterm, 12,858 (13.7%) were diagnosed with a wheezing disorder, compared to 116,732 out of 1,407,300 children born at term (8.3%).
Meta-Analysis of Adjusted Data
Seventeen studies provided adjusted association measures that could be pooled in a meta-analysis (874,710 individuals). Although the variables for which individual studies adjusted varied (Table S3), the majority included the important confounders: sex, maternal smoking, and parental atopy or asthma. The final summary OR for the association between preterm birth and wheezing disorders was slightly attenuated as compared to the unadjusted analysis (OR 1.46, 95% CI 1.29–1.65, p<0.001; Figure 3).
Subgroups taken from individual studies noted in parentheses. Heterogeneity: I2 = 80% (95% CI 68%–86%). Individual study adjustment for the primary confounders is depicted. Additional confounders adjusted for are outlined in Table S3. FH, family history; LRI, lower respiratory infection; PTB, preterm birth; WD, wheezing disorders.
In order to investigate a possible “dose–response” relationship between gestational age at birth and wheezing disorder risk, we aggregated corresponding adjusted association measures from 17 studies (1,105,828 individuals; Figure 4). The pooled estimate of the linear association between gestational age and wheezing disorder risk thus obtained (OR 0.94, 95% CI 0.92–0.96, p<0.001) indicated a 6% (95% CI 4%–8%) decrease in wheezing disorder risk for every week increase in gestation length up to 40 wk.
The strength of the association between preterm birth and wheezing disorders was similar between children aged <5 y and older children in both unadjusted and adjusted analyses (Figures S1, Figures S2, S3). The risk was considerably higher among children born very preterm (unadjusted: OR 3.00, 95% CI 2.61–3.44, p<0.001; adjusted: OR 2.81, 95% CI 2.52–3.12, p<0.001; Figure 5) when compared to moderately preterm children (unadjusted: OR 1.49, 95% CI 1.34–1.66, p<0.001; adjusted: OR 1.37, 95% CI 1.17–1.62, p<0.001; Figure 6).
(A) unadjusted effect estimates; (B) adjusted effect estimates. Subgroups taken from individual studies noted in parentheses. Heterogeneity: I2 (unadjusted) = 62% (95% CI 9%–79%); I2 (adjusted) = 0% (95% CI 0%–68%). Confounders adjusted for in individual studies are outlined in Figure 3 and Table S3. LRI, lower respiratory infection; PTB, preterm birth; WD, wheezing disorders.
(A) unadjusted effect estimates; (B) adjusted effect estimates. Subgroups taken from individual studies noted in parentheses. Heterogeneity: I2 (unadjusted) = 92% (95% CI 87%–94%); I2 (adjusted) = 89% (95% CI 82%–93%). Confounders adjusted for in individual studies are outlined in Figure 3 and Table S3. LRI, lower respiratory infection; PTB, preterm birth; WD, wheezing disorders.
In adjusted analyses, the association between preterm birth and wheezing disorders was most pronounced in the higher quality studies, whereas studies with a high risk of bias had the highest point estimate in the unadjusted analysis (Figures S4, S5, S6). Aggregate ORs did not differ much between subgroups according to study size (Figures S7, S8, S9), diagnosis ascertainment (Figures S10, S11, S12), or wheezing type (Figures S13, S14, S15).
To further investigate the independent effects of study size, population age, diagnosis ascertainment, wheezing type, and publication year, meta-regression analysis was performed. None of these factors had an independent effect on the strength of association between preterm birth and wheezing disorders (Table 3). The models' residual I2 values suggested that additional unmeasured factors contributed to between-study heterogeneity.
Funnel plot asymmetry was minimal for both unadjusted and adjusted association measures (Figure 7). Accordingly, Harbord's test (p = 0.55; unadjusted association measures) and Egger's test (p = 0.43; adjusted association measures) revealed no important small-study effects potentially indicative of publication bias.
Based on unadjusted association measures, the PAR for childhood wheezing disorders associated with preterm birth was estimated at 4.0% overall, comprising 1.6% (95% CI 1.3%–1.9%) for very preterm birth and 2.4% (95% CI 1.7%–3.1%) for moderately preterm birth. PAR based on adjusted association measures was 3.1%: 1.2% (95% CI 1.1%–1.3%) for very preterm birth and an additional 1.9% (95% CI 1.0%–2.7%) for moderately preterm birth.
In this meta-analysis of observational studies, using data from over 1.5 million children from across six continents, preterm birth was found to be associated with a 1.71 (95% CI 1.57–1.87) times increased risk of childhood wheezing disorders. The association was slightly attenuated by adjustment for potential confounding within individual studies (OR 1.46, 95% CI 1.29–1.65). Additional analyses strongly support a dose–response relationship between length of gestation and wheezing disorders (OR 0.94, 95% CI 0.92–0.96, per week increase), with children born very preterm having three times the risk of that of children born at term (OR 3.00, 95% CI 2.61–3.44). Consistency across sensitivity analyses further supports the robustness of the findings. Moderate preterm birth accounted for the majority of the explained variation in childhood wheezing disorders by preterm birth. Together, these findings are in line with the increasing recognition of the impact that early life influences have on subsequent health and disease, including pulmonary outcomes ,. Furthermore, they highlight the pressing need for prioritisation of research into prevention of preterm birth and the aetiology of its adverse consequences for subsequent respiratory health.
As with any systematic review we cannot exclude the possibility that potentially relevant studies were missed by our search strategy, although it included the primary online databases for medical research and the most rational search terms relevant to the research question. Identification of additional studies was performed through screening of reference lists and citations, and contacting an international panel of experts. Absence of important small-study effects suggests that bias resulting from selective study inclusion is likely to be minor.
I2 values suggested that considerable heterogeneity was present among the studies included in the meta-analysis, although these values may be inflated by the inclusion of some very large studies . Heterogeneity was handled by applying random-effects models . Low I2 values in subgroup analyses according to age group suggest that between-study population age differences may contribute. Variation furthermore exists among doctors and parents, and between doctors and parents regarding the definition and perception of wheeze, as well as asthma. We therefore performed sensitivity analyses separating wheezing from asthma, and physician diagnoses from parental reports. The results suggest that, although perceptions may differ, this did not affect the estimation of the association between preterm birth and childhood wheezing disorders. Indeed, residual heterogeneity remained after adjustment for these and other factors via meta-regression analysis. Although study quality may be another responsible factor, the observation that aggregated association measures were most pronounced in studies with low risk of bias supports the validity of the conclusions.
Several factors potentially confound the association between preterm birth and wheezing disorders . We therefore performed separate analyses aggregating adjusted association measures. This attenuated the association between preterm birth and wheezing disorders to some degree, as expected. The vast majority of studies adjusted for important potential confounders, although their number and nature varied between studies. A varying degree of residual confounding thus remains, which should be taken into account when interpreting the findings. From studies reporting association measures according to multiple gestational age strata we included the least preterm stratum. The aggregated point estimate is therefore likely to underestimate the actual association.
Different methods for gestational age estimation exist. Although most studies failed to report their approach, first trimester ultrasound is increasingly used in higher income countries. Alternative estimation is usually based on the last menstrual period, which is known to overestimate the numbers of preterm and post-term births . Again, this is expected to result in underestimation of the association between preterm birth and wheezing disorders .
In a previous meta-analysis, preterm birth was associated with a 1.37 (95% CI 1.30–1.43) times increased risk of asthma . To better reflect current neonatal practice, we included only cohorts born from the 1990s onwards, resulting in a much larger sample size and negligible overlap with the report by Jaakkola and colleagues . The substantially greater numbers of events in our review enabled us—for the first time—to investigate aggregated adjusted association estimates to account for potential confounding, explore the association with degree of prematurity (i.e., a dose-dependent relationship), and estimate the associated disease burden (i.e., PAR). These additional steps are crucial to interpreting these data, as the evidence is of necessity derived from observational studies, which are inherently at risk of bias. We can only speculate as to the underlying reasons for the association being more pronounced in our report, even after adjustment for confounding. The former review mainly included children born in the 1960s–1980s . These older cohorts are likely to be less preterm on average, which may explain their somewhat lower risk of developing asthma. Analysis by study characteristics in both meta-analyses suggests that the study characteristics are unlikely to explain the difference. The apparent increase over time in wheezing disorder risk associated with preterm birth indicates that changes in neonatal practice have generally failed to improve obstructive pulmonary outcomes in children born preterm.
The current findings do not support prior suggestions that the association between preterm birth and wheezing disorders becomes less prominent with increasing age . Instead, the strength of the association was similar across age groups, suggesting that the pulmonary consequences of preterm birth tend to persist throughout the life course. This observation is supported by evidence from longitudinal studies showing temporal tracking of small airway disease among individuals born preterm ,,, and by recent confirmation of a link between preterm birth and chronic obstructive pulmonary disease . The contribution of atopy to this association is unclear and requires further study.
The processes underlying preterm birth are poorly understood . The incidence as well as the underlying causes of preterm birth are known to vary both geographically and temporally, at least partially driven by meteorological, socioeconomic, ethnic, and (epi)genetic variation ,–. Environmental exposures, such as pollution and tobacco smoke, and individual behavioural differences (i.e., hygiene, smoking during pregnancy) furthermore contribute ,. Many such factors have also been linked to the development of wheezing disorders ,,. Through interference with the foetus's natural environment during critical windows of development, the processes underlying preterm birth challenge the developmental plasticity of the lungs and airways ,,. Common antecedents of preterm birth such as inflammation, maternal smoking, metabolic derangement, hypoxia, and growth restriction have well-recognised adverse effects on lung maturation and structure, T cell polarisation and development, and airway reactivity ,,–. Such alterations can differentially affect susceptibility of the lungs to injurious exposures that commonly follow preterm birth, including sepsis, respiratory infections, mechanical ventilation, and hyperoxia ,–. For any of these factors, the likelihood of being exposed increases with decreasing gestational age at birth. Immediate adverse effects are seen in very preterm infants developing BPD, which is an independent risk factor for reactive airway disease ,,,,. Preterm birth furthermore augments the association of several of these risk factors, such as antenatal inflammation and smoke exposure, with childhood wheezing ,. Such mechanisms may all contribute to the observed dose–response relationship between gestational age and adverse respiratory outcomes, including wheezing disorders ,. Genetic influences and gene–environment interactions are furthermore likely to play a role, and the link between preterm birth and asthma has been suggested to at least partially reflect a common genetic background ,.
The magnitude of the problem having been established, there is now a pressing need to address several knowledge gaps. Epidemiological studies should concentrate on temporal tracking of respiratory status into adulthood following preterm birth, with particular focus on different wheezing phenotypes, and estimating the relative impact of distinct early life factors on these patterns. Recent accomplishments in combining European birth cohorts can help provide the required numbers . There is, furthermore, a need for additional studies from low- and middle-income countries. More high-quality research is required to identify the underlying mechanisms and accordingly develop appropriate preventive and therapeutic measures. Innovative approaches may combine these aspects, as recently highlighted by a randomised controlled trial of repeated administration of a monoclonal respiratory syncytial virus antibody in moderately preterm infants . The intervention induced an important decrease in wheezing in the first year, establishing the causal link between respiratory syncytial virus and wheezing, as well as offering a possible solution . Immune modulation is beginning to fulfil its promise in neonatal medicine, and preterm babies may well prove particularly favourable targets for the immunomodulatory therapies that are likely to shape the future of asthma management ,,. The potential for stratified medicine to benefit children born preterm needs to be more generally explored through appropriately designed trials and pre-specified subgroup analyses in future trials.
This work provides compelling evidence that preterm birth is an important early life risk factor for wheezing disorders in childhood. Given the increasing incidence of both entities and their potentially lifelong consequences, there is an urgent need to identify the underlying mechanisms and explore the potential for preventive and therapeutic approaches.
Meta-analysis of unadjusted association between preterm birth and childhood wheezing disorders according to age group. Since estimates from Boyle  and Vrijlandt  are included on both sides of the comparison, overall association measures are not displayed. Subgroups taken from individual studies noted in parentheses. Heterogeneity: I2 (<5 y) = 56% (95% CI 0%–76%); I2 (≥5 y) = 48% (95% CI 0%–72%). PTB, preterm birth; WD, wheezing disorders.
Meta-analysis of adjusted association between preterm birth and childhood wheezing disorders according to age group. Since estimates from Boyle  are included on both sides of the comparison, overall association measures are not displayed. Subgroups taken from individual studies noted in parentheses. Confounders adjusted for in individual studies are outlined in Figure 3 and Table S3. Heterogeneity: I2 (<5 y) = 31% (95% CI 0%–77%); I2 (≥5 y) = 41% (95% CI 0%–69%). PTB, preterm birth; WD, wheezing disorders.
Meta-analysis of adjusted dose–response association between gestational age (per week increase) and childhood wheezing disorders according to age group. Since estimates from Boyle  are included on both sides of the comparison, overall association measures are not displayed. Subgroups taken from individual studies noted in parentheses. Confounders adjusted for in individual studies are outlined in Figure 4 and Table S3. Heterogeneity: I2 (<5 y) = 0% (95% CI 0%–68%); I2 (≥5 y) = 37% (95% CI 0%–69%). WD, wheezing disorders.
Meta-analysis of unadjusted association between preterm birth and childhood wheezing disorders according to risk of bias. Heterogeneity: I2 (high risk of bias) = 60% (95% CI 10%–77%); I2 (moderate risk of bias) = 63% (95% CI 0%–80%); I2 (low risk of bias) = 0% (95% CI 0%–68%). PTB, preterm birth; WD, wheezing disorders.
Meta-analysis of adjusted association between preterm birth and childhood wheezing disorders according to risk of bias. Subgroups taken from individual studies noted in parentheses. Confounders adjusted for in individual studies are outlined in Figure 3 and Table S3. Heterogeneity: I2 (high risk of bias) = 56% (95% CI 0%–82%); I2 (moderate risk of bias) = 46% (95% CI 0%–73%); I2 (low risk of bias) = 0% (95% CI 0%–68%). PTB, preterm birth; WD, wheezing disorders.
Meta-analysis of adjusted dose–response association between gestational age (per week increase) and childhood wheezing disorders according to risk of bias. Confounders adjusted for in individual studies are outlined in Figure 4 and Table S3. Heterogeneity: I2 (high risk of bias) = 39% (95% CI 0%–76%); I2 (moderate risk of bias) = 63% (95% CI 0%–81%); I2 (low risk of bias) = 8% (95% CI 2%–90%). WD, wheezing disorders.
Meta-analysis of unadjusted association between preterm birth and childhood wheezing disorders according to study size. Heterogeneity: I2 (n<10,000) = 47% (95% CI 0%–67%); I2 (n≥10,000) = 95% (95% CI 93%–97%). PTB, preterm birth; WD, wheezing disorders.
Meta-analysis of adjusted association between preterm birth and childhood wheezing disorders according to study size. Subgroups taken from individual studies noted in parentheses. Confounders adjusted for in individual studies are outlined in Figure 3 and Table S3. Heterogeneity: I2 (n<10,000) = 42% (95% CI 0%–68%); I2 (n≥10,000) = 94% (95% CI 89%–96%). PTB, preterm birth; WD, wheezing disorders.
Meta-analysis of adjusted dose–response association between gestational age (per week increase) and childhood wheezing disorders according to study size. Confounders adjusted for in individual studies are outlined in Figure 4 and Table S3. Heterogeneity: I2 (n<10,000) = 39% (95% CI 0%–68%); I2 (n≥10,000) = 97% (95% CI 95%–98%). WD, wheezing disorders.
Meta-analysis of unadjusted association between preterm birth and childhood wheezing disorders according to diagnosis ascertainment. Heterogeneity: I2 (parent reported) = 19% (95% CI 0%–55%); I2 (doctor diagnosed) = 93% (95% CI 89%–95%). PTB, preterm birth; WD, wheezing disorders.
Meta-analysis of adjusted association between preterm birth and childhood wheezing disorders according to diagnosis ascertainment. Subgroups taken from individual studies noted in parentheses. Confounders adjusted for in individual studies are outlined in Figure 3 and Table S3. Heterogeneity: I2 (parent reported) = 43% (95% CI 0%–71%); I2 (doctor diagnosed) = 90% (95% CI 82%–93%). PTB, preterm birth; WD, wheezing disorders.
Meta-analysis of adjusted dose–response association between gestational age (per week increase) and childhood wheezing disorders according to diagnosis ascertainment. Confounders adjusted for in individual studies are outlined in Figure 4 and Table S3. Heterogeneity: I2 (parent reported) = 54% (95% CI 0%–76%); I2 (doctor diagnosed) = 95% (95% CI 92%–96%). WD, wheezing disorders.
Meta-analysis of unadjusted association between preterm birth and childhood wheezing disorders according to wheezing type. Heterogeneity: I2 (wheezing) = 52% (95% CI 0%–76%); I2 (asthma) = 86% (95% CI 79%–90%). PTB, preterm birth; WD, wheezing disorders.
Meta-analysis of adjusted association between preterm birth and childhood wheezing disorders according to wheezing type. Subgroups taken from individual studies noted in parentheses. Confounders adjusted for in individual studies are outlined in Figure 3 and Table S3. Heterogeneity: I2 (wheezing) = 41% (95% CI 0%–74%); I2 (asthma) = 86% (95% CI 76%–90%). PTB, preterm birth; WD, wheezing disorders.
Meta-analysis of adjusted dose–response association between gestational age (per week increase) and childhood wheezing disorders according to wheezing type. Confounders adjusted for in individual studies are outlined in Figure 4 and Table S3. Heterogeneity: I2 (wheezing) = 52% (95% CI 0%–78%); I2 (asthma) = 92% (95% CI 87%–94%). WD, wheezing disorders.
Characteristics of studies excluded because of population overlap. *Selected inhaled or systemic adrenergics, anticholinergics, xantines, antiallergics, leukotriene receptor antagonists, and/or steroids; ** as compared to preterm babies without BPD. GA, gestational age; KFHP, Kaiser Foundation Health Plan; KPMCP, Kaiser Permanente Medical Care Program; N/R, not reported; LMP, last menstrual period; SD, standard deviation.
Assessment of study quality. Scoring according to the Effective Public Health Practice Project quality assessment tool for quantitative studies. For study design “7” indicates cross-sectional design in all cases. N/A, not applicable.
Covariates in multivariate models of individual studies associating preterm birth with wheezing disorders. amonth of conception, maternal urinary tract infection, pre-labour rupture of membranes, prostaglandin induction, neonatal jaundice, neonatal sepsis; bthreatened miscarriage, infections, asphyxia, birth trauma, premature rupture of membranes, umbilical cord knots, placenta problems; cCC10 G+38A polymorphisms, cord blood IgE.
PROSPERO-registered review protocol.
We thank Professor Paul Brand, Dr. Liesbeth Duijts, Dr. Gabriel Escobar, Dr. Neera Goyal, Dr. Gibby Koshy, Professor Bulent Sekerel, and Dr. Agnes Sonnenschein-van der Voort for kindly providing additional data and information to facilitate data analysis. Furthermore, we thank Dr. Liesbeth Duijts, Professor Bengt Källén, Professor Scott Weiss, and other members of the expert panel for providing advice. We thank Dr. Niall Anderson and Dr. Ulugbek Nurmatov for statistical advice.
Conceived and designed the experiments: JVB BWK MM AS. Performed the experiments: JVB MJL ES. Analyzed the data: JVB MJL. Wrote the first draft of the manuscript: JVB MJL AS. Contributed to the writing of the manuscript: JVB MJL ES BWK CPvS MM AS. ICMJE criteria for authorship read and met: JVB MJL ES CPvS BWK MM AS. Agree with manuscript results and conclusions: JVB MJL ES CPvS BWK MM AS. Secured funding: JVB CPvS. Systematic literature review: JVB MJL ES. Quality assessment: JVB MJL ES. Data-extraction: JVB MJL.
- 1. Gluckman PD, Hanson MA, Cooper C, Thornburg KL (2008) Effect of in utero and early-life conditions on adult health and disease. N Engl J Med 359: 61–73.
- 2. Blencowe H, Cousens S, Oestergaard MZ, Chou D, Moller AB, et al. (2012) National, regional, and worldwide estimates of preterm birth rates in the year 2010 with time trends since 1990 for selected countries: a systematic analysis and implications. Lancet 379: 2162–2172.
- 3. Chang HH, Larson J, Blencowe H, Spong CY, Howson CP, et al. (2013) Preventing preterm births: analysis of trends and potential reductions with interventions in 39 countries with very high human development index. Lancet 381: 223–234.
- 4. Jobe AH (2010) “Miracle” extremely low birth weight neonates: examples of developmental plasticity. Obstet Gynecol 116: 1184–1190.
- 5. Jobe AH (2011) The new bronchopulmonary dysplasia. Curr Opin Pediatr 23: 167–172.
- 6. Colin AA, McEvoy C, Castile RG (2010) Respiratory morbidity and lung function in preterm infants of 32 to 36 weeks' gestational age. Pediatrics 126: 115–128.
- 7. Kotecha SJ, Edwards MO, Watkins WJ, Henderson AJ, Paranjothy S, et al. (2013) Effect of preterm birth on later FEV1: a systematic review and meta-analysis. Thorax 68: 760–766.
- 8. Brostrom EB, Akre O, Katz-Salamon M, Jaraj D, Kaijser M (2013) Obstructive pulmonary disease in old age among individuals born preterm. Eur J Epidemiol 28: 79–85.
- 9. Jaakkola JJ, Ahmed P, Ieromnimon A, Goepfert P, Laiou E, et al. (2006) Preterm delivery and asthma: a systematic review and meta-analysis. J Allergy Clin Immunol 118: 823–830.
- 10. Anandan C, Nurmatov U, van Schayck OC, Sheikh A (2010) Is the prevalence of asthma declining? Systematic review of epidemiological studies. Allergy 65: 152–167.
- 11. Robison RG, Singh AM (2013) Chapter 11: the infant and toddler with wheezing. Allergy Asthma Proc 33: S36–S38.
- 12. (2013) Trip [database]. Available: http://www.tripdatabase.com. Accessed 22 September 2013.
- 13. Nurmatov U, Devereux G, Sheikh A (2011) Nutrients and foods for the primary prevention of asthma and allergy: systematic review and meta-analysis. J Allergy Clin Immunol 127: 724–733.
- 14. Effective Public Health Practice Project (2013) Quality assessment tool for quantitative studies. Available: http://www.ephpp.ca/PDF/Quality%20Assessment%20Tool_2010_2.pdf. Accessed 2 May 2013.
- 15. Higgins JP, Green S (2011) Cochrane handbook for systematic reviews of interventions. Oxford: The Cochrane Collaboration.
- 16. Berlin JA, Longnecker MP, Greenland S (1993) Meta-analysis of epidemiologic dose-response data. Epidemiology 4: 218–228.
- 17. Rockhill B, Newman B, Weinberg C (1998) Use and misuse of population attributable fractions. Am J Public Health 88: 15–19.
- 18. Alm B, Erdes L, Mollborg P, Pettersson R, Norvenius SG, et al. (2008) Neonatal antibiotic treatment is a risk factor for early wheezing. Pediatrics 121: 697–702.
- 19. Alvarez Mingorance P, Buron Martinez E, Blanco Quiros A (2011) Morbilidad de los niños prematuros en edad escolar (II): patología respiratoria, alteraciones del crecimiento y presión arterial. Acta Pediatr Esp 69: 235–240.
- 20. Aspberg S, Dahlquist G, Kahan T, Kallen B (2010) Confirmed association between neonatal phototherapy or neonatal icterus and risk of childhood asthma. Pediatr Allergy Immunol 21: e733–e739.
- 21. Bérard A, Le Tiec M, De Vera MA (2012) Study of the costs and morbidities of late-preterm birth. Arch Dis Child Fetal Neonatal Ed 97: F329–F334.
- 22. Boyle EM, Poulsen G, Field DJ, Kurinczuk JJ, Wolke D, et al. (2012) Effects of gestational age at birth on health outcomes at 3 and 5 years of age: population based cohort study. BMJ 344: e896.
- 23. Brehm JM, Acosta-Perez E, Klei L, Roeder K, Barmada M, et al. (2012) Vitamin D insufficiency and severe asthma exacerbations in Puerto Rican children. Am J Respir Crit Care Med 186: 140–146.
- 24. Castro-Rodriguez JA, Garcia-Marcos L, Sanchez-Solis M, Perez-Fernandez V, Martinez-Torres A, et al. (2010) Olive oil during pregnancy is associated with reduced wheezing during the first year of life of the offspring. Pediatr Pulmonol 45: 395–402.
- 25. Cheraghi M, Dadgarinejad A, Salvi S (2012) A cross-sectional study to find prevalence and risk factors for childhood asthma in Pune City, India. ISRN Public Health 2012: 361456.
- 26. Civelek E, Cakir B, Orhan F, Yuksel H, Boz AB, et al. (2011) Risk factors for current wheezing and its phenotypes among elementary school children. Pediatr Pulmonol 46: 166–174.
- 27. Collier CH, Risnes K, Norwitz ER, Bracken MB, Illuzzi JL (2013) Maternal infection in pregnancy and risk of asthma in offspring. Matern Child Health J 17: 1940–1950 doi: 10.1007/s10995-013-1220-2.
- 28. Escobar GJ, Ragins A, Li SX, Prager L, Masaquel AS, et al. (2010) Recurrent wheezing in the third year of life among children born at 32 weeks' gestation or later: relationship to laboratory-confirmed, medically attended infection with respiratory syncytial virus during the first year of life. Arch Pediatr Adolesc Med 164: 915–922.
- 29. Fawke J, Lum S, Kirkby J, Hennessy E, Marlow N, et al. (2010) Lung function and respiratory symptoms at 11 years in children born extremely preterm: the EPICure study. Am J Respir Crit Care Med 182: 237–245.
- 30. Gessner BD, Chimonas MA (2007) Asthma is associated with preterm birth but not with small for gestational age status among a population-based cohort of Medicaid-enrolled children <10 years of age. Thorax 62: 231–236.
- 31. Getahun D, Strickland D, Zeiger RS, Fassett MJ, Chen W, et al. (2010) Effect of chorioamnionitis on early childhood asthma. Arch Pediatr Adolesc Med 164: 187–192.
- 32. Gorman BK, Landale NS (2005) Premature birth and asthma among young Puerto Rican children. Popul Res Policy Rev 24: 335–358.
- 33. Goyal NK, Fiks AG, Lorch SA (2011) Association of late-preterm birth with asthma in young children: practice-based study. Pediatrics 128: e830–e838.
- 34. Hennessy EM, Bracewell MA, Wood N, Wolke D, Costeloe K, et al. (2008) Respiratory health in pre-school and school age children following extremely preterm birth. Arch Dis Child 93: 1037–1043.
- 35. Joshi S, Powell T, Watkins WJ, Drayton M, Williams EM, et al. (2013) Exercise-induced bronchoconstriction in school-aged children who had chronic lung disease in infancy. J Pediatr 162: 813–818.
- 36. Källén B, Finnstrom O, Nygren KG, Otterblad Olausson P (2013) Association between preterm birth and intrauterine growth retardation and child asthma. Eur Respir J 41: 671–676.
- 37. Kang EM, Lundsberg LS, Illuzzi JL, Bracken MB (2009) Prenatal exposure to acetaminophen and asthma in children. Obstet Gynecol 114: 1295–1306.
- 38. Koshy G, Akrouf KA, Kelly Y, Delpisheh A, Brabin BJ (2013) Asthma in children in relation to pre-term birth and fetal growth restriction. Matern Child Health J 17: 1119–1126.
- 39. Kumar R, Yu Y, Story RE, Pongracic JA, Gupta R, et al. (2008) Prematurity, chorioamnionitis, and the development of recurrent wheezing: a prospective birth cohort study. J Allergy Clin Immunol 121: 878–884.
- 40. Kumar R, Tsai HJ, Hong X, Gignoux C, Pearson C, et al. (2012) African ancestry, early life exposures, and respiratory morbidity in early childhood. Clin Exp Allergy 42: 265–274.
- 41. Lum S, Kirkby J, Welsh L, Marlow N, Hennessy E, et al. (2011) Nature and severity of lung function abnormalities in extremely pre-term children at 11 years of age. Eur Respir J 37: 1199–1207.
- 42. Miyake Y, Tanaka K (2013) Lack of relationship between birth conditions and allergic disorders in Japanese children aged 3 years. J Asthma 50: 555–559.
- 43. Rautava L, Hakkinen U, Korvenranta E, Andersson S, Gissler M, et al. (2010) Health and the use of health care services in 5-year-old very-low-birth-weight infants. Acta Paediatr 99: 1073–1079.
- 44. Robison RG, Kumar R, Arguelles LM, Hong X, Wang G, et al. (2012) Maternal smoking during pregnancy, prematurity and recurrent wheezing in early childhood. Pediatr Pulmonol 47: 666–673.
- 45. Taveras EM, Camargo CA Jr, Rifas-Shiman SL, Oken E, Gold DR, et al. (2006) Association of birth weight with asthma-related outcomes at age 2 years. Pediatr Pulmonol 41: 643–648.
- 46. Visser CA, Garcia-Marcos L, Eggink J, Brand PL (2010) Prevalence and risk factors of wheeze in Dutch infants in their first year of life. Pediatr Pulmonol 45: 149–156.
- 47. Vogt H, Lindstrom K, Braback L, Hjern A (2011) Preterm birth and inhaled corticosteroid use in 6- to 19-year-olds: a Swedish national cohort study. Pediatrics 127: 1052–1059.
- 48. Vrijlandt EJ, Kerstjens JM, Duiverman EJ, Bos AF, Reijneveld SA (2013) Moderate preterm children have more respiratory problems during their first five years of life than children born full term. Am J Respir Crit Care Med 187: 1234–1240.
- 49. Welsh L, Kirkby J, Lum S, Odendaal D, Marlow N, et al. (2009) The EPICure study: maximal exercise and physical activity in school children born extremely preterm. Thorax 65: 165–172.
- 50. Yang KD, Ou CY, Chang JC, Chen RF, Liu CA, et al. (2007) Infant frequent wheezing correlated to Clara cell protein 10 (CC10) polymorphism and concentration, but not allergy sensitization, in a perinatal cohort study. J Allergy Clin Immunol 120: 842–848.
- 51. Yuan W, Fonager K, Olsen J, Sorensen HT (2003) Prenatal factors and use of anti-asthma medications in early childhood: a population-based Danish birth cohort study. Eur J Epidemiol 18: 763–768.
- 52. Algert CS, Bowen JR, Lain SL, Allen HD, Vivian-Taylor JM, et al. (2011) Pregnancy exposures and risk of childhood asthma admission in a population birth cohort. Pediatr Allergy Immunol 22: 836–842.
- 53. Koshy G, Delpisheh A, Brabin BJ (2010) Trends in prevalence of childhood and parental asthma in Merseyside, 1991–2006. J Public Health (Oxf) 32: 488–495.
- 54. Sonnenschein-van der Voort AM, Jaddoe VW, Raat H, Moll HA, Hofman A, et al. (2012) Fetal and infant growth and asthma symptoms in preschool children: the Generation R Study. Am J Respir Crit Care Med 185: 731–737.
- 55. Ortqvist AK, Lundholm C, Carlstrom E, Lichtenstein P, Cnattingius S, et al. (2009) Familial factors do not confound the association between birth weight and childhood asthma. Pediatrics 124: e737–e743.
- 56. Escobar GJ, Masaquel AS, Li SX, Walsh EM, Kipnis P (2013) Persistent recurrent wheezing in the fifth year of life after laboratory confirmed, medically attended respiratory syncytial virus infection in infancy. BMC Pediatr 13: 97.
- 57. Fauroux B, Gouyon JB, Roze JC, Guillermet-Fromentin C, Glorieux I, et al. (2013) Respiratory morbidity of preterm infants of less than 33 weeks gestation without bronchopulmonary dysplasia: a 12-month follow-up of the CASTOR study cohort. Epidemiol Infect E-pub ahead of print. doi:10.1017/S0950268813001738.
- 58. Herrera AB, Rodriguez LA, Niederbacher J (2011) Contaminación biológica intradomiciliaria y su relación con síntomas respiratorios indicativos de asma bronquial en preescolares de Bucaramanga, Colombia. Biomédica 31: 357–371.
- 59. Nantanda R, Ostergaard MS, Ndeezi G, Tumwine JK (2013) Factors associated with asthma among under-fives in Mulago hospital, Kampala Uganda: a cross sectional study. BMC Pediatr 13: 141.
- 60. Rucker G, Schwarzer G, Carpenter JR, Schumacher M (2008) Undue reliance on I(2) in assessing heterogeneity may mislead. BMC Med Res Methodol 8: 79.
- 61. Haglund B (2007) Birthweight distributions by gestational age: comparison of LMP-based and ultrasound-based estimates of gestational age using data from the Swedish Birth Registry. Paediatr Perinat Epidemiol 21 (Suppl 2) 72–78.
- 62. Been JV, Sheikh A (2013) Gestational age misclassification and its effect on disease outcomes after preterm birth. Eur J Epidemiol 28: 525–526.
- 63. Vollsaeter M, Roksund OD, Eide GE, Markestad T, Halvorsen T (2013) Lung function after preterm birth: development from mid-childhood to adulthood. Thorax 68: 767–776.
- 64. Goldenberg RL, Culhane JF, Iams JD, Romero R (2008) Epidemiology and causes of preterm birth. Lancet 371: 75–84.
- 65. Strand LB, Barnett AG, Tong S (2011) The influence of season and ambient temperature on birth outcomes: a review of the epidemiological literature. Environ Res 111: 451–462.
- 66. Culhane JF, Goldenberg RL (2011) Racial disparaties in preterm birth. Semin Perinatol 35: 234–239.
- 67. Stocks J, Hislop A, Sonnappa S (2013) Early lung development: lifelong effect on respiratory health and disease. Lancet Respir Med 1: 728–742 doi:10.1016/S2213-2600(13)70118-8.
- 68. Gantert M, Been JV, Gavilanes AW, Garnier Y, Zimmermann LJ, et al. (2010) Chorioamnionitis: a multiorgan disease of the fetus? J Perinatol 30 (Suppl) S21–S30.
- 69. Holgate ST (2012) Innate and adaptive immune responses in asthma. Nat Med 18: 673–683.
- 70. Been JV, Rours IG, Kornelisse RF, Jonkers F, de Krijger RR, et al. (2010) Chorioamnionitis alters the response to surfactant in preterm infants. J Pediatr 156: 10–15.
- 71. Busse WW, Lemanske RF, Gern JE (2010) Role of viral respiratory infections in asthma and asthma exacerbations. Lancet 376: 826–834.
- 72. Lahra MM, Beeby PJ, Jeffery HE (2009) Intrauterine inflammation, neonatal sepsis, and chronic lung disease: a 13-year hospital cohort study. Pediatrics 123: 1314–1319.
- 73. Su MW, Tung KY, Liang PH, Tsai CH, Kuo NW, et al. (2012) Gene-gene and gene-environmental interactions of childhood asthma: a multifactor dimension reduction approach. PLoS ONE 7: e30694 doi:10.1371/journal.pone.0030694.
- 74. Larsen PS, Kamper-Jorgensen M, Adamson A, Barros H, Bonde JP, et al. (2013) Pregnancy and birth cohort resources in Europe: a large opportunity for aetiological child health research. Paediatr Perinat Epidemiol 27: 393–414.
- 75. Blanken MO, Rovers MM, Molenaar JM, Winkler-Seinstra PL, Meijer A, et al. (2013) Respiratory syncytial virus and recurrent wheeze in healthy preterm infants. N Engl J Med 368: 1791–1799.
- 76. Alfaleh K, Anabrees J, Bassler D, Al-Kharfi T (2011) Probiotics for prevention of necrotizing enterocolitis in preterm infants. Cochrane Database Syst Rev 2011: CD005496.
- 77. Manzoni P, Rinaldi M, Cattani S, Pugni L, Romeo MG, et al. (2009) Bovine lactoferrin supplementation for prevention of late-onset sepsis in very low-birth-weight neonates: a randomized trial. JAMA 302: 1421–1428.