Streptococcus pneumoniae colonizes a large percentage of the population and while it can cause mild respiratory infections it is also responsible for more severe illnesses, such as invasive pneumococcal disease. Patient co-morbidities, concomitant viral infection, low temperature and environmental pollutants all have a synergistic effect that predisposes to pneumococcal infection, exerting deleterious effects on respiratory epithelium and local immune system, diminishing bacterial clearance and favouring infection [1].
Short abstract
Fossil fuel derived pollutants (SO2, NO), dry air and cold increase the incidence of S. pneumoniae infections http://ow.ly/RnLW30gogb1
To the Editor:
Streptococcus pneumoniae colonizes a large percentage of the population and while it can cause mild respiratory infections it is also responsible for more severe illnesses, such as invasive pneumococcal disease. Patient co-morbidities, concomitant viral infection, low temperature and environmental pollutants all have a synergistic effect that predisposes to pneumococcal infection, exerting deleterious effects on respiratory epithelium and local immune system, diminishing bacterial clearance and favouring infection [1].
The objective of this study was to analyse the influence of environmental factors on the incidence of pneumococcal infection. For this purpose we designed a retrospective study where data on all cases of S. pneumoniae at the University and Polytechnic Hospital La Fe (located in the city of Valencia which has a population density of about 6000 inhabitants·km−2 [2]) during a 2-year period (2011–2012) was gathered and grouped by week. A case was considered confirmed when a consistent clinical syndrome occurred in association with the isolation of S. pneumoniae or the detection of pneumococcal antigen in urine (BinaxNOW® Streptococcus pneumoniae Antigen Card, Alere, Scarborough, ME, USA). Invasive pneumococcal infection was defined as the isolation of S. pneumoniae from a normally sterile site (i.e. blood, cerebrospinal fluid or pleural fluid).
Meteorological data including temperature (°C), relative humidity (%) and atmospheric pressure (mb) for the period from 2011 to 2012 was obtained from weather stations located in the health area of the hospital. Information pertaining to air quality during the years of interest included the concentrations of nitrogen oxides (NOx, NO, NO2; µg·m−3), ozone (O3; µg·m−3), sulfur dioxide (SO2; µg·m−3), carbon monoxide (CO; mg·m−3), solar radiation (W·m−2) and particles with a 50% cut-off aerodynamic diameter of 10 µm (PM10), 2.5 µm (PM2.5) and 1 µm (PM1). The arithmetic weekly means of the air quality values were used as exposure variables.
The relationship between the weekly cases of S. pneumoniae and the environmental factors was studied by logistic linear regression using SPSS Statistics 15.0 (IBM, Armonk, NY, USA). Initially a univariate analysis was carried out, followed by a multivariate analysis of the factors significantly associated with the number of infections caused by S. pneumoniae. Different models were tried, with different combinations of factors that could affect S. pneumoniae incidence, and the model that best fitted the data was chosen.
A total of 619 pneumococcal infections were included (58.8% men, 41.2% women) of which 117 (18.9%) were invasive pneumococcal infections (59.2% men, 40.8% women). Age presented a bimodal distribution with two local maxima at 0 years and 65 years. In adult patients, co-morbid conditions were chronic obstructive pulmonary disease (COPD; 33.9%), chronic cardiovascular disease (22.0%), chronic renal failure (11.7%), diabetes (21.8%), cirrhosis (2.3%) and chronic neurological disease (25.5%), while a number of patients were smokers (9.6%) and alcohol abusers (2.5%).
A seasonal pattern was observed with the highest incidence of disease in winter, when temperatures drop and more fossil fuel is consumed, and the lowest incidence in summer (ANOVA test, p<0.001). It was found that SO2, NOx, NO2, NO and CO showed a significant positive relationship with the number of pneumococcal infections in univariate analysis, whereas temperature, solar radiation, relative humidity, PM2.5, PM1, PM10 and O3 had a negative relationship (table 1). As for invasive pneumococcal infections, only SO2, NOx and NO showed a significant positive relationship, whereas temperature and solar radiation presented a negative relationship.
TABLE 1.
Univariate and multivariate models
| Model | Pneumococcal infection | Invasive pneumococcal infection | ||
| Coefficient (95% CI) | p-value | Coefficient (95% CI) | p-value | |
| Univariate | ||||
| SO2 | 1.411 (0.94–1.881) | <0.0001 | 0.243 (0.088–0.398) | 0.002 |
| CO | 9.303 (0.956–17.651) | 0.03 | ||
| O3 | −0.08 (−0.115– −0.044) | <0.0001 | ||
| NOx | 0.103 (0.078–0.127) | <0.0001 | 0.009 (0.0003–0.018) | 0.04 |
| NO | 0.261 (0.198–0.323) | <0.0001 | 0.025 (0.002–0.048) | 0.04 |
| NO2 | 0.208 (0.152–0.265) | <0.0001 | ||
| PM1 | −0.146 (−0.247– −0.045) | 0.005 | ||
| PM2.5 | −0.122 (−0.2– −0.044) | 0.002 | ||
| PM10 | −0.121 (−0.201– −0.04) | 0.004 | ||
| Relative humidity | −0.119 (−0.189– −0.05) | 0.001 | ||
| Temperature | −0.456 (−0.546– −0.367) | <0.0001 | −0.073 (−0.108– −0.038) | <0.0001 |
| Solar radiation | −0.029 (−0.039– −0.019) | <0.0001 | −0.004 (−0.008– −0.001) | 0.008 |
| Multivariate | ||||
| SO2 | 0.732 (0.342–1.121) | 0.0003 | 0.158 (−0.005–0.322) | 0.058 |
| Temperature | −0.196 (−0.326– −0.065) | 0.003 | −0.052 (−0.090– −0.014) | 0.008 |
| Relative humidity | −0.054 (−0.105– −0.002) | 0.04 | ||
| NO | 0.139 (0.065–0.212) | 0.0003 | ||
PMx: particles with a 50% cut-off aerodynamic diameter of x μm.
The multivariate model which best fitted the data for pneumococcal infection included temperature, SO2, NO and relative humidity, and was able to explain 61% of the variation observed (R2 0.61; F statistic p<0.001). For invasive infection only temperature and SO2 were included (R2 0.17; F statistic p<0.001) (table 1). It is worth mentioning that although the model for invasive infection was significant, SO2 had a 95% confidence interval that barely passed above zero, probably due to the paucity of data.
Univariate analysis found many possible factors related to the occurrence of S. pneumoniae infection but, by multivariate analysis, it was possible to build a solid model with just four variables. This reduction can be explained by the interrelationship between atmospheric factors. Using univariate analysis, Kim et al. [1] found the same associations of SO2 and O3 with pneumococcal infection; however, they used SO2 as a marker for other air pollutants, whereas in our study we tested each of them individually.
In our models, gaseous air pollutants characteristic of fossil fuel combustion processes positively influenced the appearance of S. pneumoniae and this effect can be explained by the local damage which occurs in the respiratory mucosa. In fact, SO2 and NOx impair mucociliary activity by decreasing ciliary beating and altering cellular metabolism and morphology [3–6].
Surprisingly, our data showed that particulate matter had a protective effect with respect to pneumococcal disease. A recently published paper [7] linked particulate matter exposure to higher risk of admission for pneumonia, especially in older patients or patients with cardiovascular disease, although no specific aetiological agent was studied. Interestingly, PM2.5 enhances macrophage S. pneumoniae binding but decreases internalization and phagocytosis [8]. This binding may render bacteria unable to establish infection. In any case, associations with S. pneumoniae and other pathogens should be further studied.
As described in other studies [1, 9, 10], solar radiation, higher temperatures and high humidity levels reduce the number of cases. Cold stress has a local immunomodulatory effect on respiratory mucosa but may also influence microbiota composition. This effect has been described by Bogaert et al. [11] who found seasonal variability in the nasopharyngeal microbiota of children, with a less-balanced microbiota being observed during autumn and winter. However, pneumococcal disease does not necessarily increase in colder regions and population density may play an important role as well [12]. Likewise, low humidity levels affect mucus, which is rich in water, altering its function and composition. Overall, cold stress and low air humidity levels may favour infection.
Finally, chronic exposure to different pollutants and the interactions between them need to be studied to completely understand their effects on the respiratory tract. Beyond local and immediate damage, De Jong et al. [13] have found that chronic exposure to air pollutants is associated with restrictive ventilatory patterns, favouring pulmonary disease and infection. Within this context, O3 illustrates the interaction between air pollutants and atmospheric conditions. Although it has a well-known detrimental effect on the respiratory tract, O3 was associated with lower levels of pneumococcal disease. A possible explanation is that ground level O3 is produced by solar radiation, reaching its peak during spring and summer, while NOx and O3 are inextricably linked such that high levels of O3 are accompanied by low levels of NOx [14]. As such, high levels of O3 are associated with high levels of a protector (solar radiation) and low levels of noxious gases (NOx).
To conclude, our paper studies the interactions between pneumococcal infection and environmental conditions using a global approach and makes evident how relevant they are, although more studies are needed to better define relations and causality. Lastly, not all cases of pneumococcal infection are explained by environmental conditions. Indeed, factors specific to the individual and concomitant infections have an undeniable weight in the predisposition to this disease, especially for invasive pneumococcal infection.
Acknowledgements
The authors would like to express their gratitude to José Luis Pisón and Ana Viciano Pastor from the Acoustic Pollution Service of the city of Valencia for providing environmental data.
Footnotes
Conflict of interest: None declared.
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