en POLSKI
eISSN: 2300-8660
ISSN: 0031-3939
Pediatria Polska - Polish Journal of Paediatrics
Current issue Archive Manuscripts accepted About the journal Editorial board Abstracting and indexing Contact Instructions for authors Ethical standards and procedures
Editorial System
Submit your Manuscript
SCImago Journal & Country Rank
3/2024
vol. 99
 
Share:
Share:
Original paper

Time-dependent, cumulative and threshold effects of air pollution – RSV interaction: a narrative review

August Edwin Wrotek
1
,
Artur Badyda
2
,
Teresa Jackowska
1

  1. Department of Paediatrics, Centre of Postgraduate Medical Education, Warsaw, Poland
  2. Department of Informatics and Environment Quality Research, Warsaw University of Technology, Warsaw, Poland
Pediatr Pol 2024; 99 (3): 194-202
Online publish date: 2024/09/30
Article file
- Time-dependent.pdf  [0.17 MB]
Get citation
 
PlumX metrics:
 

INTRODUCTION

Respiratory syncytial virus (RSV) is one of the most common and important etiologic agents of respiratory tract infections, especially in the field of paediatrics; global assessments of children aged 0–60 months report over 30 million RSV-associated acute respiratory tract infections annually, with approximately 10% of the cases requiring hospital admission and as many as 100,000 children per year with a fatal outcome [1]. The highest hospitalisation rate is observed in the youngest patients (i.e. 0–6 months old), in whom about 1.4 million (21%) out of 6.6 million cases are hospitalised, although it must be emphasized that RSV is a common aetiological factor of respiratory infections in patients of all ages, and a recent improvement in access to diagnostic tests, including rapid antigen tests, has changed the paradigm of RSV, affecting only the youngest patients and raised social awareness of the disease [1, 2]. Nevertheless, most data, especially large epidemiological datasets, come from paediatric studies, mostly based on hospital surveillance or final diagnosis-based hospital reports. Polish data show a hospitalisation rate of 267.5/100,000 children under 5 years of age and 1132.1/100,000 children under one year of age, although these results seem to be underestimated compared to other European countries [3]. Although a fairly stable seasonal pattern of RSV morbidity has been observed in the northern hemisphere, with peak months between December and March, a significant shift in epidemiologic trends was observed after the COVID-19 pandemic, probably related to the use of non-pharmaceutical interventions and their relaxation [3–5].
Air pollution is recognised as a global health threat, and the World Health Organisation (WHO) has identified 6 air pollutants as the most harmful: particulate matter (PM2.5 and PM10, i.e. particulate matter with a diameter ≤ 2.5 µm and ≤ 10 µm, respectively), ozone (O3), carbon monoxide (CO), nitrogen dioxide (NO2), and sulphur dioxide (SO2) [6]. Increased RSV morbidity may be related to the influence of air quality, and a significant association between exposure to factors such as particulate matter, O3, CO, NO2, or benzene has been reported [7–12]. On the other hand, some studies have not only failed to confirm the association between increased air pollution and RSV morbidity, but also have even found an inverse association [13]. The results may be influenced by meteorological conditions, social behavioural patterns, or locally implemented information campaigns advising people to limit outdoor activities when air quality is poor, but also by time dependence, including immediate versus delayed effects of increased air pollutant concentrations. In addition, a significant cumulative effect may be observed, thresholds for some air pollutants may play a role, and an additive effect of mixed air pollution may be expected.This complex relationship needs to be thoroughly investigated to determine the role of air pollution in RSV morbidity. In this narrative review, we aimed to explore the body of evidence on the association between specific air pollutants and RSV morbidity, focusing on time-dependency, cumulative and threshold effects.

MATERIAL AND METHODS

DATA SOURCE
A structured search was performed in 3 databases (PubMed/Medline, Scopus and Cochrane) to answer 2 main questions regarding the interaction between RSV and air pollution: which air pollutants have been associated with increased RSV morbidity, and which time period plays the most important role for RSV disease? In the latter case, 4 types of association were considered: a direct effect of increased concentration of air pollutants (without a lag period), a lagged effect (with different lag periods according to the literature), a cumulative effect, and a threshold effect (i.e. if the effect is observed above a certain concentration of air pollutant).
STUDY ELIGIBILITY
All studies that included human subjects younger than 18 years were eligible for review, regardless of study design (retrospective or prospective), number of patients, or type of data analysed, including epidemiologic studies. We included only papers presenting analyses of confirmed RSV cases or presumed RSV cases (with low probability of bias, as in the case of epidemiologic studies based on final hospital diagnosis of RSV disease registered in local/national systems). Exclusion criteria were lack of direct reporting of the association between air pollution and RSV infection, e.g. studies assessing only a general association between air quality and upper/lower respiratory tract infections, including pneumonia, bronchiolitis or bronchitis, unless a separate analysis for RSV upper/lower respiratory tract infection was performed. Prenatal exposure was also not considered, because in utero effects may be very different from postnatal effects and are more likely to be associated with a general increased susceptibility. The results are presented separately for each pollutant (list of 6 WHO-recognised air pollutants, followed by “other” pollutants for which published data are available), and the time-dependency of the association for particulate matter is presented with appropriate comments on the literature. To facilitate reading and understanding, we underline the study group and methodology in each study the first time it is mentioned, but a general suggestion has to be made: while the vast majority of studies are based on hospitalisation data and actually assess the impact of air pollution on RSV hospitalisations, other studies present data from primary care and aim to assess the association with RSV incidence.

RESULTS

PM2.5
Our previous study reviewed data from nearly 50,000 paediatric RSV lower respiratory tract infection hospitalisations, and showed a significant direct effect of elevated PM2.5 levels on morbidity; a 10 μg/m3 increase in the PM2.5 concentration was associated with an average increase in hospitalisations of 0.134, ranging 0.087– 0.16 across study sites (Table 1) [12].
The study by Horne et al. assessed general acute lower respiratory infection, but also performed a secondary analysis on laboratory-confirmed RSV cases, showing that the influence of PM2.5 is seen mostly in patients aged 0–2 years old, with a lag of 1, 2, and 3 weeks (the peak association was observed within a 2-week lag, followed by a 3-week lag and a 1-week lag, while in those aged 3–17 years old, only a 3-week lag remained statistically significant [14].
In the Italian study, higher PM2.5 concentrations were found during the months of peak RSV activity, although the study did not find a direct correlation between mean PM2.5 concentrations in the week before hospitalisation for bronchiolitis [10]. A synergistic effect of RSV with a lag of 8 and 10 days in the model explained an increase in respiratory hospitalisations in Chile due to elevated PM2.5 concentrations [15].
A study by Ye et al. found a weak correlation between RSV concentrations and the number of RSV-positive results (rho = 0.446) in the samples collected at the outpatient clinic in Hangzhou, China; in addition, PM2.5 above 150 μg/m3 began to affect RSV rates [7]. However, no significant cumulative effect was found, and the lag period studied (0–5 days) showed a gradual decrease with increasing lag period [7].
An Italian study by Vandini et al. found a statistically significant but weak (correlation coefficient, rho = 0.26) correlation between the PM2.5 concentrations in the week preceding RSV referral to the emergency unit, while there was no significant correlation between the number of RSV cases and mean weekly PM2.5 concentrations without a lag period (0 weeks lag) in the group of 327 children under 2 years of age [11]. Mean daily exposure for 7, 30, and 60 days and a lifetime period in a matched case-control group of patients analysed in the Karr et al. study showed no statistically significant effect on hospitalisation for bronchiolitis (including RSV bronchiolitis), although a trend toward an association was reported [9].
A study conducted in Bogota, Colombia included all children < 2 years of age hospitalised due to bronchiolitis and used a comparative analysis of RSV detection to identify independent factors associated with RSV presence – in this context, PM2.5 showed no statistical significance [16]. The authors underline the need for cautious interpretation of these results because misclassification bias may have occurred [16]. Moreover, the study included only children hospitalised due to bronchiolitis, whereas other studies, such as an analysis by Yitshak-Sade et al. of bronchiolitis hospitalisations in 4,069 children aged 0–2 years old, showed that air pollution, including PM2.5 (OR = 1.04, 95% CI: 1.02–1.06), may increase the risk of hospitalisation for bronchiolitis, so a comparison of RSV versus non-RSV cases may be related to a preselection bias [17].
A Canadian study of climatic and geographic factors influencing RSV hospitalisations included the air quality health index in general and PM2.5 as a covariate in the analysis and found no significant differences in the annual mean of maximum daily PM2.5 concentrations in relation to RSV hospitalisations among 1670 diagnosed children matched with 6680 controls [19].
In contrast, the study by Lee et al. conducted in Singapore showed that PM2.5 is associated with a decreased risk of RSV hospitalisation for certain PM2.5 concentrations at 2, 3, 6, 7, and 8 days lag, and with an increased risk only for a limited concentration at 1 day lag [13].
In addition, the cumulative effect of PM2.5 concentration (26.2 μg/m3) was associated with a 16.3% cumulative reduction (relative risk [RR] 90%: 0.837, 95% CI: 0.794–0.884) in the risk of RSV infection over 8 days [13]. The authors explain this by the fact that the authorities put a strong emphasis on avoidance/reduction of outdoor exposure during periods of worsened air quality [13].
PM10
A direct effect of PM10 on RSV hospitalisations was shown in Poland; a 10 μg/m3 increase in PM10 levels was associated with a 0.097 increase in RSV hospitalisations, ranging 0.031–0.087 depending on the locations analysed (Table 2) [12].
A correlation between PM10 and the number of RSV-positive cases was significant for the mean PM10 concentration in the week before hospitalisation (rho = 0.34), but not in the case of a 0-week lag [11].
A comprehensive analysis of the time course of the relationship between PM10 and RSV bronchiolitis hospitalisation was offered by Carugno et al. [20]. The authors analysed both single day lags (0–30 days), type of cumulative effect (averaged daily lags in different lag periods from 0–1 to 0–30), and week lags (1–4 weeks) prior to hospitalisation [20]. Individual daily lags were significantly associated with increased risk of hospitalisation between lag 0–11 and were no longer significantly associated from lag 12, with estimated incidence rate ratios (IRRs) ranging 1.03–1.05 for a 10 µg/m3 increase in PM10 concentration [20]. Averaged daily lags increased from IRR = 1.08 (at lag 0–1) to peak values of IRR = 1.15 (at lags 0–11 and 0–13) and then declined to become insignificant at lag 0–28 [20]. In terms of weekly lags, weeks 1 and 2 immediately preceding hospitalisation were associated with an increased IRR of 1.06 and 1.07, respectively [20].
Similarly, a lagged effect of each 10 µg/m3 increase in PM10 was observed in New Zealand (for patients aged 0–19 years) for both shorter (i.e. 1-6 days) and longer (i.e. 7–14 days) lags, whereas no significant effect was observed for lag 0 [21]. The highest percentage increase in RSV hospitalisations was estimated to occur at lag 5 and lag 7, respectively; when all-year data were analysed, the increase reached 2.87% and 3.16%, respectively, while cool-season-only data showed values of 1.8% and 2.09%, respectively [21]. The Chinese study by Ye et al. showed a significant but weak correlation between PM10 levels and RSV cases (rho = 0.397); of note, PM10 became harmful after a lag of 3 days and showed no cumulative effect (like PM2.5) [7].
Nenna et al. found that PM10 levels, like PM2.5 levels, were higher during peak RSV activity months, although again a very important component of seasonality has to be taken into account because a strong negative relationship between temperature and PM10 concentrations was observed [10].
The Korean study examined the association between monthly RSV incidence and levels of air pollutants, including PM10, in a group of 9,113 nasopharyngeal swabs from children under 3 years of age, but found no statistically significant association for PM10 [22].
Similar to PM2.5 concentrations, the Colombian study found no significant difference in PM10 concentrations with respect to RSV detection in children hospitalised for bronchiolitis [16].
Similar to PM2.5, an increase in PM10 was found to be negatively associated with RSV hospitalisation in Singapore – at a concentration of 40.4 μg/m3, PM10 was associated with almost a 15% cumulative reduction in the risk of RSV infection [13].
OZONE
Data on the relationship between ozone and RSV are rather scarce and show conflicting results. The Canadian study showed a positive association between elevated O3 levels and RSV hospitalisations (OR = 1.03, 95% CI: 1.01–1.06) [19]. Conversely, an Italian study by Nenna et al. found lower O3 concentrations in the months of peak RSV activity and increased O3 levels in the absence of RSV; the inverse correlation may be due to the fact that O3 concentrations tend to peak in summer when RSV activity is generally low in the northern hemisphere [10]. The association between ozone levels was also tested in Singapore, which found no significant association, and in the Colombian study, which found no difference in RSV detection [13, 16].
CARBON MONOXIDE
Jung et al. reported a moderate correlation between CO concentrations and RSV activity (rho = 0.58), while Nenna et al. found no significant difference when comparing months with high and low RSV activity (Table 3) [10, 22].
The most comprehensive analysis was performed by Ye et al. and showed a positive correlation between CO and RSV infection rate (rho = 0.532) [7]. Carbon monoxide was associated with an increased risk of RSV at low concentrations, and the risk increased as CO levels increased [7]. The lag effect played the opposite role, i.e. the risk gradually decreased as the lag period increased [7]. A cumulative effect was also observed with a peak value at CO levels of approximately 1.5 mg/m3 (RR approximately = 2) [7].
However, RSV infection rates were inversely correlated with CO levels (RR 90%: 0.863, 95% CI: 0.801–0.929) in the study by Lee et al. [13]. It was also an independent factor associated with lower RSV detection in the trial by Villamil-Osorio et al. (OR = 0.99) [16].
NITROGEN DIOXIDE
We previously reported a direct effect of increased NO2, with an upward shift of 10 μg/m3 corresponding to an average increase in RSV hospitalisations of 0.212 (0.04– 0.29 across study sites) [12].
Higher NO2 levels were found during peak-RSV-activity months compared to low activity season [10]. Similar NO2-RSV correlation coefficients were found by Jung et al. (rho = 0.40) and Ye et al. (rho = 0.365); Ye noticed the greatest increase in RSV RR with a lag of 3 days, and the association was attenuated for NO2 concentrations above 40 μg/m3 [7, 22]. No cumulative effect was observed for NO2 concentrations [7].
Lifetime exposure to NO2 and average exposure in the month preceding RSV hospitalisation showed no statistically significant relationship in the analysis by Karr et al. [9].
In the Canadian study, the annual mean maximum daily NO2 was lower in cases than in controls; the Colombian study also identified NO2 as an independent factor associated with a lower risk of RSV infection (OR = 0.97) [16, 19]. No effect of increasing NO2 concentration was found by Lee et al. [13].
SULPHUR DIOXIDE
A positive SO2-RSV correlation coefficient was reported by Jung et al. (rho = 0.41) and Ye et al. (rho = 0.389) [7, 22]. Similarly to NO2, there was a lag time and the greatest risk was observed with a 3-day lag, the risk increased gradually with increasing SO2 levels; and similarly to NO2, there was no cumulative effect [7]. On the other hand, while no significant differences in SO2 levels were found between RSV high and low seasons in the study by Nenna et al. or with respect to RSV detection in the trial by Villamil-Osorio et al., an increase in SO2 levels was associated with a 12.2% cumulative decrease in RSV infection (RR 90%: 0.878, 95% CI: 0.807–0.956) in the study by Lee et al. [10, 13, 16].
OTHER POLLUTANTS
Benzene was an independent factor associated with RSV incidence (Poisson Regression Model Estimate 0.1736) in the study by Nenna et al., and markedly higher benzene concentrations were observed during the months of peak RSV activity [10]. In addition to benzene, 9 other pollutants have been reported to be associated with an increased risk of RSV infection in a follow-up study of 888 infants (up to age 3 years) that evaluated spatial clusters of lower respiratory tract disease in relation to community-associated risk factors, showing that being in an RSV cluster was associated with exposure to air pollutants [23]. The pollutants included polycyclic organic matter (OR = 2.28), manganese (OR = 2.22), 1,2-dichloropropene (OR = 2.17), benzene (OR = 2.08), butadiene (OR = 2.05), perchloroethylene (OR = 1.96), methylene chloride (OR = 1.77), ethylene oxide (OR = 1.61), mercury (OR = 1.56), and beryllium (OR = 1.53).
Use of kerosene as a cooking fuel was another identified risk factor for the first episode of RSV lower respiratory tract infection in a prospective surveillance of infants and children under 5 years of age in Indonesia; the patients underwent weekly visits aimed at screening for lower respiratory tract infection signs, and in case of infection, RSV test was performed [24]. The effects of kerosene might be mediated by other air pollutants, since combustion of kerosene is related to the emission of particulate matter (including PM2.5), CO, SO2 or nitric oxide [25].
Nitric oxide (NO) has been linked with the risk of RSV infection in in vitro studies, although the concentrations used were high; the study by Mohammed et al. performed on 208 hospitalised children showed no significant association for either single-day lags (0 to 6 days lag) or average NO concentration of different lag periods (0–1 to 0–6 days) [26].

DISCUSSION

The study shows the complexity of the interaction between air pollution and RSV and its susceptibility to potential confounding factors, and the existing body of knowledge requires further studies to draw definitive conclusions; however, some important conclusions need to be underlined. PM2.5 and PM10 have been studied most extensively, and although there are some conflicting results, both PM2.5 and PM10 appear to be associated with increased RSV risk with some time-specific differences.
PM2.5 appears to be associated with RSV disease both in the short and medium term; the studies from China, Chile and Poland confirm the direct effect or the influence of PM2.5 with a delay of a few days, while the American study shows the importance of a delay of 1–3 weeks [7, 12, 14, 15]. However, the trial from Singapore reported an inverse correlation, but the results of this study, as underlined by the authors, could raise some concerns about the influence of local government advice to limit outdoor time when air pollution levels are high [13]. PM2.5 may be associated with some kind of a threshold effect, i.e. higher PM2.5 concentrations may play a more important role [7]. A cumulative effect of PM2.5 was estimated in one study and was related to a cumulative decrease in Singapore [7, 13]. The long-term effects of PM2.5 would also require further confirmation because existing studies do not support this theory [9].
PM10 also appears to be associated with RSV infection in both the short and medium term, and the lag period is of great importance. While a direct effect of elevated PM10 concentrations has been reported, other studies show the importance of the lag, with lag times varying 1–14 days, and peaks observed on days 1, 3, 5, or 7 [7, 12, 20, 21]. Consistent with the daily lag period are estimates of the weekly lag, which show that week 1 or week 1 and 2 are significantly associated [11, 20]. A role of cumulative effect might be expected because the averaged daily lags played a role up to 0–28 days lag (with peaks at 0–11 and 0–13 lag), although a cumulative decrease was also observed [13, 20]. No confirmation of threshold level or long-term effects was found.
Previous studies in human models indicated the highest deposition fraction of PM10 in the head/throat region, followed by the tracheobronchial (TB) and pulmonary (P) regions; the highest PM2.5 deposition in sleeping or sitting children was observed in the P region, followed by the head and TB [27]. This could be a plausible explanation for the differences in the lag periods of PM2.5 and PM10 effects, because PM10 may mainly promote upper respiratory tract infection, i.e. make it easier to contract the disease, whereas PM2.5 may increase the severity of the disease due to high deposition in the lower respiratory tract. Thus, the time needed to observe the effects of increased PM10 levels would be longer compared to the time needed to observe the effects of PM2.5. It should be underlined that differences in the proportion of ambient aerosol as well as the composition of aerosol, including variations in its chemical content, may lead to different PM deposition in the human body and different health effects [28–30]. Moreover, although the deposition of PM10 in the respiratory tract appears to be similar in adults and children (i.e. deposition in the head of the respiratory tract, followed by the TB region and the lung region), the fraction of PM10 that penetrates into the TB and P region is higher in children compared to adults [27]. The average deposition of PM2.5 is about 2 times higher in children than in adults [27]. This raises awareness of the increased susceptibility of the paediatric population to air pollutants; the structure and physiology of the respiratory tract not only favours the deposition of smaller particles in children, but these particles are more toxic relative to body mass [31].
In contrast to particulate matter, there are pollutants that show balanced contradictory results, as in the case of ozone, while SO2 and NO2, for example, appear to be harmful in terms of RSV infections, and the data (although still inconsistent) show that they may act in a very similar way, with a peak lag effect on day 3 and no cumulative effect [7]. On the other hand, a cumulative effect has been reported for CO, although some conflicting results must be emphasised, as 2 studies conducted at different sites found a negative association between CO levels and RSV, while others confirmed the expected positive association [7, 13, 16, 22]. In general, the lack of a positive or negative association, regardless of the pollutant studied (CO, SO2, or NO2), was most often reported in studies comparing longer time periods, such as high versus low RSV activity seasons or lifetime exposure, but also in studies looking at minute differences, such as RSV detection in hospitalized bronchiolitis patients [9, 10, 16]. Taken together, these discrepancies indicate the complexity of the problem and the need for further studies. And the results presented above refer to the 6 most harmful pollutants (according to the WHO), while other pollutants, although each of them deserves in-depth analysis, have been studied in single studies.
The body of knowledge is limited by several factors impeding comparisons. First, it must be emphasized that due to limited RSV testing, the vast majority of studies are based on data from hospitalisations (where RSV testing is much more frequent due to higher availability), so the time frames of the relationship between air pollution and RSV may be somewhat blurred. The results in this review are presented with respect to the source data, but the true timing may be shifted because RSV hospitalisations usually occur after a few days and not at the onset of signs/symptoms, as in the case of RSV bronchiolitis, which tends to require hospitalisation after 3–5 days of illness [32]. As a result, the authors use different time-dependency strategies to assess the influence of air pollution on RSV morbidity. Even if all data were adjusted for the first day of signs/symptoms, there would still be room for bias, because the most important question is not whether air pollution increases RSV morbidity, but whether it increases the risk of RSV severity, which would lead to hospitalisation, for example. Second, the results themselves are often inconsistent or even contradictory, especially in the case of the less studied contaminants. These issues can only be resolved by studies involving large numbers of patients and conducted under similar conditions. Reproducibility of studies also requires comparable study settings, including the social perspective, the problem raised by Lee et al. who unexpectedly found an inverse relationship between some of the pollutants and RSV disease [13]. The authors discussed the possible explanatory effect of local policies that emphasised deteriorating air quality and advised citizens to limit outdoor activities [13]. In fact, environmental risk perception is crucial for the range of exposure to pollution, and personal differences between patients might be expected; the study conducted in London showed significant differences in air pollution exposure depending on the mode of transport used by primary school children [33, 34]. There are other aspects that make direct comparisons between studies difficult, such as meteorological factors that affect air pollution levels, inter-seasonal differences, or differences between study sites. In addition, some authors include meteorological factors as variables while others do not, which introduces an additional risk of misinterpretation.
Understanding the molecular mechanisms underlying the interaction between air pollution and RSV is essential to understanding the timing. While certain pollutants may promote RSV infection itself, others may increase viral load leading to a prolonged disease course, or result in an enhanced/prolonged inflammatory response, or even cause airway hyperresponsiveness, which would show clinical effects after longer lag times [35]. As shown above, PM10 may promote RSV infection itself, and molecular studies show that RSV entry into epithelial cells may be facilitated in the presence of PM10; on the other hand, the inflammatory response may also be enhanced by PM10, leading to delayed clinical effects [36].
There are some limitations of the review that need to be emphasised. In addition to the above-mentioned limitations and inconsistencies in the source papers, we have not presented (due to lack of data) the results of interactions between air pollutants, which could be significant and might more accurately reflect the conditions in the real environment, since a mixture of pollutants affects humans rather than single molecules [12]. We did not assess the quality of the data presented nor the power of the studies (e.g., assessed by the number of participants) in order to present all available literature on the topic. Third, methodological differences make it difficult to compare results directly, and although some studies did not confirm the relationship, or even found an inverse one, the results of these studies may differ from those of other studies due to different study settings or social behaviour (as mentioned above).

CONCLUSIONS

It would appear that there is a positive association between air pollution and RSV morbidity, mostly assessed in hospital-based studies, but the range of pollutants varies widely in terms of the available evidence: while the majority of studies show an association between PM2.5 and/or PM10 and RSV, this relationship is not as clear for NO2, SO2 or CO, and is even less clear for ozone or nitric oxide. The complexity of the relationship, including likely interactions between pollutants, makes conclusions regarding time and concentration dependence a challenge for future studies, which are guaranteed.
DISCLOSURES
Institutional review board statement: Not applicable.
Assistance with the article: None.
Financial support and sponsorship: None.
Conflicts of interest: None.
REFERENCES
1. Li Y, Wang X, Blau DM, et al. Global, regional, and national disease burden estimates of acute lower respiratory infections due to respiratory syncytial virus in children younger than 5 years in 2019: a systematic analysis. Lancet 2022; 399: 2047-2064.
2. Ruiz-Galiana J, Cantón R, de Lucas Ramos P, et al. Respiratory syncytial virus: a new era. Rev Esp Quimioter 2024; 37: 134-148.
3. Borszewska-Kornacka MK, Mastalerz-Migas A, Nitsch-Osuch A, et al. Respiratory syncytial virus infections in Polish pediatric patients from an expert perspective. Vaccines (Basel) 2023; 11: 1482.
4. Wrotek A, Czajkowska M, Jackowska T. Seasonality of respiratory syncytial virus hospitalization. Adv Exp Med Biol 2020; 1279: 93-100.
5. Stein RT, Zar HJ. RSV through the COVID-19 pandemic: burden, shifting epidemiology, and implications for the future. Pediatr Pulmonol 2023; 58: 1631-1639.
6. WHO. WHO Global Air Quality Guidelines. World Health Organization. Available from: https://www.who.int/news-room/questions-and-answers/item/who-global-air-quality-guidelines (accessed: 5.10. 2023).
7. Ye Q, Fu JF, Mao JH, Shang SQ. Haze is a risk factor contributing to the rapid spread of respiratory syncytial virus in children. Env Sci Pollution Res 2016; 23: 20178-20185.
8. Horne BD, Joy EA, Hofmann MG, et al. Short-term elevation of fine particulate matter air pollution and acute lower respiratory infection. Am J Respir Critical Care Med 2018; 198: 759-766.
9. Karr CJ, Rudra CB, Miller KA, et al. Infant exposure to fine particulate matter and traffic and risk of hospitalization for RSV bronchiolitis in a region with lower ambient air pollution. Environ Res 2009; 109: 321-327.
10. Nenna R, Evangelisti M, Frassanito A, et al. Respiratory syncytial virus bronchiolitis, weather conditions and air pollution in an Italian urban area: An observational study. Env Res 2017; 158: 188-193.
11. Vandini S, Corvaglia L, Alessandroni R, et al. Respiratory syncytial virus infection in infants and correlation with meteorological factors and air pollutants. Ital J Pediatr 2013; 39: 1.
12. Wrotek A, Badyda A, Czechowski PO, Owczarek T, Dąbrowiecki P, Jackowska T. Air pollutants’ concentrations are associated with increased number of RSV hospitalizations in Polish children. J Clin Med 2021; 10: jcm10153224.
13. Lee MH, Mailepessov D, Yahya K, Loo LH, Maiwald M, Aik J. Air quality, meteorological variability and pediatric respiratory syncytial virus infections in Singapore. Sci Rep 2023; 13: 1001.
14. Horne BD, Joy EA, Hofmann MG, et al. Short-term elevation of fine particulate matter air pollution and acute lower respiratory infection. Am J Respir Crit Care Med 2018; 198: 759-766.
15. Matus CP, Oyarzún GM. [Impact of Particulate Matter (PM 2,5) and children’s hospitalizations for respiratory diseases. A case cross-over study]. Rev Chil Pediatr 2019; 90: 166-174.
16. Villamil-Osorio M, Moyano-Ariza LF, Camacho-Moreno G, RestrepoGualteros SM, Sossa-Briceño MP, Rodriguez-Martinez CE. Multilevel analysis identifying the factors associated with RSV detection in infants admitted for viral bronchiolitis in the era of the COVID-19 pandemic. Pediatr Pulmonol 2023; 58: 2795-2803.
17. Yitshak-Sade M, Yudovitch D, Novack V, Tal A, Kloog I, Goldbart A. Air pollution and hospitalization for bronchiolitis among young children. Ann Am Thorac Soc 2017; 14: 1796-1802.
18. Radhakrishnan D, Ouedraogo A, Shariff SZ, McNally JD, Benchimol EI, Clemens KK. The association between climate, geography and respiratory syncitial virus hospitalizations among children in Ontario, Canada: a population-based study. BMC Infect Dis 2020; 20: 157.
19. Radhakrishnan D, Ouedraogo A, Shariff SZ, McNally JD, Benchimol EI, Clemens KK. The association between climate, geography and respiratory syncitial virus hospitalizations among children in Ontario, Canada: a population-based study. BMC Infect Dis 2020; 20: 157.
20. Carugno M, Dentali F, Mathieu G, et al. PM10 exposure is associated with increased hospitalizations for respiratory syncytial virus bronchiolitis among infants in Lombardy, Italy. Env Res 2018; 166: 452-457.
21. Fukuda K, Hider PN, Epton MJ, Jennings LC, Kingham SP. Including viral infection data supports an association between particulate pollution and respiratory admissions. Aust N Z J Public Health 2011; 35: 163-169.
22. Jung JH, Chu SY, Kim JY, Han TH, Park SH, Chung JY, Kim HB. Correlation of respiratory syncytial virus infection with climate parameters and air pollution levels in Korean children during 2005–2012. Allergy Asthma Respir Dis 2018; 6: 206-210.
23. Beamer PI, Lothrop N, Lu Z, et al. Spatial clusters of child lower respiratory illnesses associated with community-level risk factors. Pediatr Pulmonol 2016; 51: 633-642.
24. Crow R, Mutyara K, Agustian D, Kartasasmita CB, Simões EAF. Risk factors for respiratory syncytial virus lower respiratory tract infections: evidence from an Indonesian cohort. Viruses 2021; 13: 331.
25. Lam NL, Smith KR, Gauthier A, Bates MN. Kerosene: a review of household uses and their hazards in low- and middle-income countries. J Toxicol Environ Health B Crit Rev 2012; 15: 396-432.
26. Mohammed NI, Everard ML, Ayres JG, Barker NJ, Litchfield IJ. A preliminary assessment of the role of ambient nitric oxide exposure in hospitalization with respiratory syncytial virus bronchiolitis. Int J Env Res Public Health 2016; 13: 578.
27. Sánchez-Soberón F, Mari M, Kumar V, Rovira J, Nadal M, Schuhmacher M. An approach to assess the Particulate Matter exposure for the population living around a cement plant: modelling indoor air and particle deposition in the respiratory tract. Environ Res 2015; 143: 10-18.
28. Kodros JK, Volckens J, Jathar SH, Pierce JR. Ambient Particulate Matter size distributions drive regional and global variability in particle deposition in the respiratory tract. Geohealth 2018; 2: 298-312.
29. Behera SN, Betha R, Huang X, Balasubramanian R. Characterization and estimation of human airway deposition of size-resolved particulate-bound trace elements during a recent haze episode in Southeast Asia. Environ Sci Pollut Res Int 2015; 22: 4265-4280.
30. Bell ML, Committee HHR. Assessment of the health impacts of particulate matter characteristics. Res Rep Health Eff Inst 2012; (161): 5-38.
31. Sarigiannis D, Karakitsios SP, Zikopoulos D, Nikolaki S, Kermenidou M. Lung cancer risk from PAHs emitted from biomass combustion. Environ Res 2015; 137: 147-156.
32. Bronchiolitis in children: diagnosis and management. London: National Institute for Health and Care Excellence (NICE); 2021 Aug 9. Available from: https://www.nice.org.uk/guidance/ng9 (accessed: 19.03.2024).
33. Yalçin SS, Gezgen Kesen G, Güçiz Doğan B, Yalçin S, Acar Vaizoğlu S. Mother’s knowledge for environmental risks and self-awareness for the presence of pollutants in her living area in West and Central Anatolia: a cross-sectional survey. BMC Public Health 2023; 23: 1780.
34. Varaden D, Leidland E, Lim S, Barratt B. “I am an air quality scientist” – using citizen science to characterise school children’s exposure to air pollution. Environ Res 2021; 201: 111536.
35. Wrotek A, Jackowska T. Molecular mechanisms of RSV and air pollution interaction: a scoping review. Int J Mol Sci 2022; 23: 12704.
36. Cruz-Sanchez TM, Haddrell AE, Hackett TL, et al. Formation of a stable mimic of ambient particulate matter containing viable infectious respiratory syncytial virus and its dry-deposition directly onto cell cultures. Anal Chem 2013; 85: 898-906.
Copyright: © 2024 Polish Society of Paediatrics. This is an Open Access article distributed under the terms of the Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International (CC BY-NC-SA 4.0) License (http://creativecommons.org/licenses/by-nc-sa/4.0/), allowing third parties to copy and redistribute the material in any medium or format and to remix, transform, and build upon the material, provided the original work is properly cited and states its license.
 
Quick links
© 2024 Termedia Sp. z o.o.
Developed by Bentus.