Air pollution and multiple acute respiratory outcomes

Introduction

The impact of air pollutants on the respiratory system has been widely and consistently reported in recent years. The short-term effects include decreases in pulmonary function [1], increases in inflammatory markers [2] and respiratory symptoms [3], exacerbations of chronic obstructive pulmonary disease (COPD) and infections [4–9], and increases in respiratory mortality [10–12].

The risk of dying from respiratory diseases associated with particulate matter (PM) (defined either as particles with a 50% cut-off aerodynamic diameter of 10 μm (PM₁₀) or 2.5 μm (PM_2.5)) is close to 1% per 10 μg·m⁻³ in several studies worldwide [13], whereas PM effects on hospitalisations or emergency visits for respiratory diseases tend to be higher (2–3%) and affect all ages [4, 6–9]. Nitrogen dioxide (NO₂) and ozone (O₃) are associated with even larger increases per 10 μg·m⁻³ (near 3–6% and 5–6%, respectively) in asthma exacerbations in children [6, 7, 14–16].

We have recently reported the results of the Italian EpiAir multi-city study (Air Pollution and Health: Epidemiological Surveillance and Primary Prevention) on respiratory mortality that had effects ranging from 2.3% per 10 μg·m⁻³ PM₁₀ to 3.5% per 10 μg·m⁻³ NO₂ [17, 18]. To complete the assessment of PM₁₀ and NO₂ effects on respiratory health, we studied emergency hospitalisations for respiratory diseases and for COPD. We also considered out-of-hospital respiratory mortality, since our hypothesis was that the multiple immediate respiratory effects of air pollutants should be considered together to give complete and valid estimates of air pollution effects.

It has already been reported that latency differs with the type of respiratory event. Mortality is a prolonged effect of PM (lasting 4–6 days) [19, 20], while hospitalisations and emergency visits are immediate (lag 0–1 days and up to 3 days, respectively) [7–9], suggesting that subjects' characteristics and patient management may affect the probability of these different events. The stronger increase in out-of-hospital than in-hospital mortality [17, 21] and recent studies on the protective effects of drugs against air pollutant effects [22, 23] give support to our hypothesis that various respiratory outcomes have to be analysed together as multiple effects of air pollutants.

Results

There were 100 690 hospitalisations due to respiratory diseases in the study population from 2001 to 2005. A total of 38 577 (39%) were due to COPD (24% of which had a principal diagnosis of respiratory failure) and 9886 (10%) to LRTI in COPD sufferers. There were 5490 out-of-hospital respiratory deaths, accounting for 30.7% of all respiratory deaths (n = 17 862). Most hospitalisations for respiratory diseases and COPD, and most out-of-hospital deaths, were observed in Rome, Milan and Palermo, in decreasing order of frequency (table 1). Hospitalisations for LRTI differed slightly; Florence joined Rome and Milan among the cities with the highest values. Respiratory events were more frequent in the cold seasons (October to March), when 56.6% of hospitalisations and 59.7% of out-of-hospital deaths occurred (table 1).

There were 185 out-of-hospital deaths related to asthma and 1874 asthma hospitalisations in the six cities over the 5-year period.

Daily mean concentrations of PM₁₀ ranged from 53.9 μg·m⁻³ in Turin to 34.8 μg·m⁻³ in Palermo. NO₂ showed greater variability, with the lowest value in Florence (46.1 μg·m⁻³) and the highest in Milan, Turin and Rome (59.2, 66.0 and 62.4 μg·m⁻³, respectively). The apparent temperature showed a clear North–South gradient, with the lowest values in Milan, Turin and Bologna (11.5–13.8°C) and the highest in Palermo and Rome (15.7–19.4°C). No important differences in humidity or atmospheric pressure were observed between the cities. Complete data on pollutants and meteorological conditions have been reported in previous papers [17, 21, 26].

The effects of both PM₁₀ and NO₂ on hospitalisations for respiratory diseases were immediate (lag 0–1 days), and notable on hospitalisations for COPD, which increased the same day the pollutants increased and decreased immediately after. Hospitalisations for LRTI increased later, on the second day (for PM₁₀) or on the third day (for NO₂), and reached the strongest values on the fourth day (lag 3 days), suggesting that COPD patients with pulmonary infections are hospitalised later. Finally, out-of-hospital mortality was prolonged (lag 0–5 days), increased steadily until the third day and remained high until the sixth day (fig. 1).

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Figure 1–

Pooled results showing the association between multiple respiratory outcomes and particles with a 50% cut-off aerodynamic diameter of 10 μm (PM₁₀) or nitrogen dioxide (NO₂), by lag (from constrained distributed lag models), for six cities in 2001–2005. Data are presented as percentage increases of risk of respiratory outcome, and 95% confidence intervals, relative to a 10 μg·m⁻³ increase in PM₁₀. In distributed lag models, a third-degree polynomial constrain for lags from 0 to 5 days has been applied.

A 10 μg·m⁻³ rise in PM₁₀ gave an increased risk (IR) (95% CI) of hospitalisations for all respiratory diseases of 0.59% (0.10–1.08%) and for COPD of 0.67% (-0.02–1.35%). Greater increases in risk were observed for LRTI hospitalisations (1.91% (0.06–3.79%)) and for out-of-hospital respiratory mortality (3.95% (1.53–6.43%)) (table 2).

A 10 μg·m⁻³ rise in NO₂ gave an IR (95% CI) of hospitalisations for all respiratory diseases of 1.19% (0.23–2.15%) and for COPD of 1.20% (0.17–2.23%). Greater increases were observed for LRTI (1.79% (95% CI -1.16–4.83%)) and for out-of-hospital mortality (6.92% (95% CI 3.53–10.42%)) (table 2). The heterogeneity of the effects across cities was very low for both pollutants.

The effect estimates on asthma hospitalisations were estimated only for Rome (the city with the highest frequency). We found the highest values at lag 0–5 days with important but not statistically significant IR (95% CI) of 6.59% (-2.27–16.27%) for 10 μg·m⁻³ PM₁₀ and 9.26% (-2.66–22.64%) for 10 μg·m⁻³ NO₂ (data not shown). The low number of asthma events did not allow further consideration in the analysis.

To compare the effect sizes between the two pollutants, we estimated the strength of the effects of both pollutants by the interquartile ranges of their concentrations (24.9 μg·m⁻³ and 25.9 μg·m⁻³ for PM₁₀ and NO₂, respectively). NO₂ had slightly stronger effects than PM₁₀ at the best lag for each pollutant. The effects on respiratory hospitalisations were 1.94% versus 1.47% at lag 0–1 days and 3.10% versus 1.53% at lag 0–5 days, respectively. The effects on COPD hospitalisations were 3.13% versus 1.66% at lag 0–1 days; those on LRTI hospitalisations were 4.71% versus 3.75%, respectively, at lag 0–5 days; and those on out-of-hospital deaths were 16.26% versus 11.25%, respectively, at lag 0–5 days. The complete results are reported in the online supplementary table A.

The association between PM₁₀ and hospitalisations was stronger in warm seasons, when compared with cold seasons, for all respiratory events; it was 12 times stronger for respiratory diseases, 7.5 times stronger for COPD and five times stronger for LRTI, indicating that seasons are also an effect modifier (online supplementary table B). Out-of-hospital mortality differed slightly; although it increased 1.7 times in warm seasons, the ratio was much lower than for hospitalisations and no effect modification was statistically supported (online supplementary table B). The pattern of associations between NO₂ and hospitalisations by season was very similar to what has been seen for PM₁₀.

In the two-pollutant models, when both PM₁₀ and NO₂ were considered, the effects remained but were lower, especially for all respiratory diseases and out-of-hospital mortality, and statistical significance was not reached (table 3). The correlation between NO₂ and PM₁₀ varied between 0.22 and 0.79 across cities, as a result of different sources and dispersion of the pollutants. This could explain the indeterminate results regarding possible independent effects.

Table 4 (and online supplementary table C) shows the pooled estimates of PM₁₀ effects on respiratory hospitalisations and out-of-hospital mortality, stratified by age group, sex and hospital discharge diagnoses in the previous 2 years. Age was clearly an effect modifier of out-of-hospital mortality, and people were more likely to die at home if they were older: IR (95% CI) rose to 5.07% (1.01–9.30%) for subjects aged 75–84 years and to 4.82% (1.81–7.92%) for those aged ≥85 years. Sex was a mild effect modifier, with females (6.15% (3.06–9.33%)) being more likely to die at home than males (1.98% (-1.32–5.40); p-value for interaction 0.076). In contrast, cancer patients were less likely to die at home (-5.32% (95% CI -16.64–7.53); p-value for interaction 0.134).

There was a higher IR (95% CI) for subjects aged ≥85 years being hospitalised for all respiratory disease of 1.24% (0.25–2.23%), compared with younger subjects, but the difference was not statistically significant. In contrast, a previous diagnosis of ischaemic heart disease gave an increased risk of hospitalisation, suggesting a possible effect modification on all respiratory diseases, with IR (95% CI) of 1.59% (0.41–2.79%), on COPD exacerbation (1.93% (0.33–3.55%)), and on LRTI in COPD sufferers (4.89% (0.29–9.69%)). Among non-cardiac diseases, only chronic liver disease possibly increased the likelihood of a hospitalisation for LRTI. We did not find any evidence of modification of the effects of air pollution on respiratory diseases for diseases of pulmonary circulation (ICD-9: 415–417), conduction disorders (ICD-9: 426), arrhythmias (ICD-9: 427), heart failure (ICD-9: 428) and, among non-cardiac diseases, for cancer (ICD-9: 140–208), diabetes (ICD-9: 250), cerebrovascular diseases (ICD-9: 430–438), chronic pulmonary diseases (ICD-9: 490–505) or renal failure (ICD-9: 584–588).

Discussion

We found an immediate increase in emergency hospitalisations for respiratory diseases associated with PM₁₀, and even more strongly associated with NO₂. The largest and longest lasting effect was observed on hospitalisations due to LRTI in COPD sufferers. All effects on hospitalisations were stronger in warm seasons compared with cold seasons. Subjects with a previously diagnosed ischaemic heart disease showed the strongest effects of PM₁₀. The risk of dying out of hospital was much higher than that of being hospitalised; it did not decrease over the cumulative 6-day exposure and did not show seasonal differences.

The immediate effect on hospitalisations for respiratory diseases confirms most results from previous studies on adults [5, 8]. Longer cumulative lags have been consistently reported for respiratory hospitalisations in children [14, 15]. The greatest effect has been observed on hospitalisations due to LRTI in COPD sufferers; it lasted longer, up to 4 or 6 days for different pollutants, and it was consistent across cities. Since we studied only pneumonia in COPD, we concluded that worsening COPD causes immediate recourse to hospitalisation, while pulmonary infections in COPD patients took more time to become serious, resulting in more time elapsed before hospitalisation for COPD patients who developed pulmonary infections. Important increases in hospitalisations for LRTI associated with rises in PM₁₀ or NO₂ were reported both in adults [31, 32] and in children [33]. Also, hospitalisations for chronic respiratory diseases (COPD) associated with rising PM₁₀ showed higher increases than those for all respiratory diseases, as has already been reported [34]. Clearly, COPD patients are very likely to be susceptible to the short-term effects of air pollutants [9, 31, 35–37].

A slightly stronger effect of NO₂ than PM₁₀ on respiratory hospitalisations has been reported in some previous studies of both pollutants [6, 14], but the difference was small or not appreciable. However, the literature shows that NO₂ had a stronger effect than PM₁₀ on child morbidity and on adult mortality, and in our study the NO₂ effects on hospitalisation for respiratory diseases and for COPD were almost twice as large as those due to PM₁₀. While this supports the conclusion that NO₂ has a greater effect on respiratory health, the variability of the correlation between the two pollutants prevents us from drawing a clear conclusion regarding their independent effects.

The warm season exacerbates the effects of pollutants, especially those related to NO₂, although a complete explanation for this can still not be found in the literature.

The elderly and those with previous ischaemic disease were more likely to be hospitalised following PM increases, but no effect modification was appreciated. The same effect has been previously reported for other cardiac diseases [22] and the most elderly subjects [38]. It is noteworthy that we did not find any modification with age of the risk of hospitalisations due to specific respiratory diseases (COPD and LRTI), which are likely to be influenced by other factors.

The high estimates of out-of-hospital mortality we found here for PM₁₀, and even more for NO₂, were consistent with the results we found for total respiratory mortality [17, 18], and confirm the stronger effect of NO₂ than PM reported in other studies [19, 39]. However, the higher increases in mortality than in hospitalisations, which we found for both pollutants, contrast with the results of most previous studies that reported higher risks of respiratory hospitalisations than of respiratory mortality [7–9, 13]. Although not excluding the possibility that different habits of recourse to hospitals may explain this disagreement, the more likely explanation is, in our opinion, the shorter lag time (0–1 days) used in most studies in contrast to the prolonged lag (0–5 days) we used here and in previous studies analysing total respiratory mortality [17, 18]. Shorter lag times have usually been considered more suited for natural mortality; however, previous studies that used a lag of 0–6 days [19, 20, 39] found higher estimates of respiratory mortality associated with both PM and NO₂. Conversely, it has been demonstrated that the effect of air pollution on mortality spreads over 2 days [27].

Having no previous hospitalisations has previously been recognised as increasing mortality risk [17–19], since it assumes hospitalisation functions as a temporary protective factor against air pollution and death, because it reduces exposure and provides effective treatment for chronic diseases. This is the first time that the factors linked to dying out of hospital were specifically analysed, and the results would suggest that very old people are hospitalised less frequently, while the risk of dying related to air pollution does not seem to be influenced by the presence of chronic diseases.

This study takes a new approach to assess the health effects of air pollution by analysing hospitalisations and out-of-hospital mortality simultaneously as multiple effects. Not having been able to include emergency visits among the respiratory effects of air pollution is clearly a limit of our analysis, given their importance in assessing air pollutant effects [7, 16, 40]. However, this approach allowed us to obtain a more complete picture of air pollution effects and to detect conditions of susceptibility for different outcomes.

Several conclusions can be drawn from the present study. 1) PM₁₀ and NO₂ increased hospitalisations and mortality for respiratory diseases. 2) Subjects with previous cardiac ischaemic diseases were affected more strongly by PM₁₀ than their healthier counterparts. 3) Air pollution effects on hospitalisation in Italy are stronger during the warm period of the year, confirming what has been already observed for mortality. 4) A more complete picture of the short-term respiratory effects of air pollutants is obtained when both hospitalisations and out-of-hospital deaths are examined. Air pollution suddenly aggravates COPD, leading to immediate hospitalisation, and/or promotes respiratory infections that slowly lead to hospitalisation or to death at home.