The respiratory health effects of nitrogen dioxide in children with asthma

RESULTS

At baseline 58.6% of children were male and the average age was 9.6 yrs (range 6–13 yrs) (table 1). The study had a higher proportion of Mäori and Pacific children than the national average of children aged 5–14 yrs (22.5% and 11.1%, respectively), but the percentage of New Zealand-European participants was similar to the national average of 61.7%. The indoor NO₂ geometric mean was 11.4 μg·m⁻³ while the outdoor NO₂ geometric mean was 7.4 μg·m⁻³.

The mean of the cough symptom scores ranged between 0.44 and 0.59 on a scale of 0 to 3 (table 2). Similarly for wheeze, the average scores ranged between 0.27 and 0.37. Among all children the mean FEV₁ morning and evening readings were 2,065 mL and 2,507 mL, respectively, and the mean PEFR morning and evening readings were 282.7 L·min⁻¹ and 283.0 L·min⁻¹, respectively.

The effects per logged unit increase in NO₂ on daily symptom scores are reported as mean ratios in table 3. This table shows a consistent and significant increase in lower (change in mean symptom rate per unit increase in NO₂ 1.14, 95% CI 1.12–1.16) and upper (change in mean symptom rate per unit increase in NO₂ 1.03, 95% CI 1.00–1.05) respiratory tract symptoms with exposure to increased NO₂. The change in mean symptom rate per unit increase in NO₂ was also significant for the positive associations between indoor NO₂ and all cough and wheeze symptoms. An increase in indoor NO₂ exposure was also significantly related to reliever use during the day. Indoor NO₂ had no effect on preventer use.

A log scale was used as NO₂ is log normally distributed. To help interpret the tables a one unit change in both outdoor and indoor NO₂ is approximately the same as moving from the 25th percentile to the 75th percentile i.e. if someone was to move from a “low” NO₂ (5.5 μg·m⁻³) house or area to a “high” NO₂ (15.9 μg·m⁻³) house or area this would, on average, result in increasing their cough at night symptoms by 1.16 times.

The results for the association between indoor NO₂ and lung function are reported in table 4. These show a consistent decrease in lung function with increasing indoor NO₂, which is significant for morning and evening FEV₁ readings.

Outdoor NO₂ was measured only during the last 4-weeks of the winter period. Table 5 shows that in this restricted sample mean outdoor NO₂ was not significantly associated with any of the asthma symptoms or medication use.

The results for the association between outdoor NO₂ and lung function are reported in table 6. A unit change in outdoor NO₂ was associated with a greater change in lung function than a unit change in indoor NO₂, although none of the outdoor NO₂ associations were significant.

While table 4 shows the effect of indoor NO₂ on lung function, it was also of interest how much of this relationship was due to outdoor NO₂. As outdoor NO₂ was measured in the final 4 weeks of the study rather than over the entire study period, it was necessary to restrict the analysis of indoor NO₂ adjusted for outdoor NO₂ to the final 4 weeks of the study. When this restriction was applied to the results in table 4, the sample size was greatly reduced and, thus, there was a reduction in power; this is seen in the reduction in number of child days (e.g. 22,516 to 5,257, for evening FEV₁). However, the adjustment for outdoor NO₂ did not significantly reduce the effect size of indoor NO₂ on symptoms or lung function, indicating that the effect of indoor NO₂ on lung function was independent of the effect of outdoor NO₂. Similarly, the effect of outdoor NO₂ was independent of the effect of indoor NO₂ (data not shown).

The results presented in tables 3–⇑⇑6 were also adjusted for a range of confounders (age, sex, smoking, the outcome at baseline, parental history of asthma, region, ethnicity, the effect of the intervention and low income). These adjustments made no substantial change to the results. However, when the models were adjusted for temperature, while most results were unchanged, the significant association between indoor NO₂ and wheezing disappeared and the association between indoor NO₂ and preventer use became significant.

DISCUSSION

The NO₂ levels reported in this study are higher than those previously reported indoors in the UK (Ashford), Spain (Menorca) and Sweden (Uppsala) [25, 26], and are comparable to those previously measured in New Zealand (Nelson), Italy (Po River Delta) and the USA [3, 27, 28]. However, NO₂ levels in our study were lower than those reported in Barcelona (Spain) [25]. The WHO annual average outdoor NO₂ guideline of 40 μg·m⁻³ [29] was exceeded during the 2006 winter period in 13.8% of homes and 1.9% of the outdoor samples.

Our findings that indoor NO₂ was associated with greater daily reports of lower and upper respiratory tract symptoms, more frequent coughing and wheezing and a reduction in morning and evening FEV₁ are consistent with previous findings from observational studies [1, 12, 20, 28, 30]. The conclusion of one systematic review stated that average hourly NO₂ values of 80 ppb (∼154 μg·m⁻³) are likely to cause respiratory symptoms in the general population of children [20]. Furthermore, a study by Jarvis et al. [31] reported a 3.1% reduction in the lung function (FEV₁ % predicted) of females who used gas stoves in comparison to females who used other forms of cooking. In a later publication by Jarvis et al. [32], it was noted that burning gas appliances indoors may produce more of an effect on respiratory health than is reflected by NO₂ levels due to the failure to account for the adverse effects of nitrous acid, which is generated directly from gas combustion and indirectly from NO₂.

Increasing levels of outdoor NO₂ were not significantly associated with an increase in respiratory symptoms or a reduction in lung function. The relatively large estimated effect for reduced lung function may be an accidental finding due to the smaller sample size for outdoor NO₂ measurement or it may be a consequence of the respiratory effects of other combustion products and fine particulates associated with outdoor sources of NO₂ [33]. The effect estimates of both indoor and outdoor NO₂ changed little when mutually adjusted, indicating that these factors may be independent. This suggests that indoor NO₂ mainly reflects differing sources and/or mechanisms for reducing lung function than outdoor NO₂.

The pathophysiological effect of NO₂ on the respiratory system may include early alterations in airway calibre and/or viscoelastic properties of the peripheral lung and delayed or impaired gas exchange and pulmonary function abnormalities [34]. Children are particularly vulnerable to the effects of air pollution as they breathe 50% more air per kg of body weight than adults [35]. Our findings are based on a post hoc secondary analysis of a study designed to investigate the effects of a heating intervention. We acknowledge the shortcomings of this design for investigating the study hypothesis, but are also aware that due to having two groups with different heating systems, we are guaranteed a large spread of indoor NO₂, and increased power. Furthermore, while the heating intervention itself was not quite significant in improving lung function (p = 0.051) [22], the overall negative effect of indoor NO₂ on lung function suggests that the intervention may have been effective in those houses where there was a marked reduction in NO₂.

A further limitation of our study is that while we took daily health measures, the NO₂ levels were measured as 4-week averages. Therefore, in the analysis the daily outcome from the first day of a sampling period is associated with a 4-week average that includes future NO₂ levels. Another limitation of this study is that short-term peak levels of exposure were not measured. Repeated exposures to short-term peaks of NO₂ have been suggested to be a more important determinant of airway symptoms than total dose or absolute background exposure levels [36–38]. Pilotto et al. [39] reported that exposure to hourly peak levels of ∼80 ppb in comparison to background levels of 20 ppb were associated with an increase in sore throats, colds and absences from school in children aged 6–11 yrs. However, as the design of our study was a household intervention trial involving 409 homes, measuring NO₂ peak levels was not practical.

Another limitation of this study was that ventilation rates were not measured. However, in the New Zealand population, people tend to ventilate a dwelling at levels higher than the natural ventilation rates of an unoccupied, fully closed-up building [40]. Furthermore, as New Zealand homes are generally built out of timber frames with single glazing, they tend to be draughty.

The final limitation of this study was that participants were not blinded to the replacement of their heater, which could have affected the reporting of symptoms and led to an overestimation of the effect of reduced NO₂ exposure. However, outcome measures also included objective (PEFR and FEV₁) measures and these also declined with increasing NO₂. Moreover, after randomisation, children in both groups had similar characteristics, including previous use of gas heaters, parental history of asthma, smoking indoors and sex, thus, confounding by indoor factors is unlikely to explain the findings. We did not collect information on potential outdoor confounders or effect modifiers, such as traffic volume, which may explain the influence of outdoor NO₂ on lung function measurements.

Indoor NO₂ was significantly associated with an increase in asthma symptoms and reduced lung function (FEV₁), while outdoor NO₂ was not significantly associated with reduced lung function (FEV₁ and PEFR) or asthma symptoms. These findings indicate that reducing NO₂ exposure indoors is important in improving the respiratory health of children with asthma.