Ambient air pollution, lung function, and airway responsiveness in asthmatic children.

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Ambient air pollution, lung function, and airway responsiveness in asthmatic children.

J Allergy Clin Immunol. 2015 Jun 29;

Authors: Ierodiakonou D, Zanobetti A, Coull BA, Melly S, Postma DS, Boezen HM, Vonk JM, Williams PV, Shapiro GG, McKone EF, Hallstrand TS, Koenig JQ, Schildcrout JS, Lumley T, Fuhlbrigge AN, Koutrakis P, Schwartz J, Weiss ST, Gold DR, Childhood Asthma Management Program Research Group

Abstract
BACKGROUND: Although ambient air pollution has been linked to reduced lung function in healthy children, longitudinal analyses of pollution effects in asthmatic patients are lacking.
OBJECTIVE: We sought to investigate pollution effects in a longitudinal asthma study and effect modification by controller medications.
METHODS: We examined associations of lung function and methacholine responsiveness (PC20) with ozone, carbon monoxide (CO), nitrogen dioxide, and sulfur dioxide concentrations in 1003 asthmatic children participating in a 4-year clinical trial. We further investigated whether budesonide and nedocromil modified pollution effects. Daily pollutant concentrations were linked to ZIP/postal code of residence. Linear mixed models tested associations of within-subject pollutant concentrations with FEV1 and forced vital capacity (FVC) percent predicted, FEV1/FVC ratio, and PC20, adjusting for seasonality and confounders.
RESULTS: Same-day and 1-week average CO concentrations were negatively associated with postbronchodilator percent predicted FEV1 (change per interquartile range, -0.33 [95% CI, -0.49 to -0.16] and -0.41 [95% CI, -0.62 to -0.21], respectively) and FVC (-0.19 [95% CI, -0.25 to -0.07] and -0.25 [95% CI, -0.43 to -0.07], respectively). Longer-term 4-month CO averages were negatively associated with prebronchodilator percent predicted FEV1 and FVC (-0.36 [95% CI, -0.62 to -0.10] and -0.21 [95% CI, -0.42 to -0.01], respectively). Four-month averaged CO and ozone concentrations were negatively associated with FEV1/FVC ratio (P < .05). Increased 4-month average nitrogen dioxide concentrations were associated with reduced postbronchodilator FEV1 and FVC percent predicted. Long-term exposures to sulfur dioxide were associated with reduced PC20 (percent change per interquartile range, -6% [95% CI, -11% to -1.5%]). Treatment augmented the negative short-term CO effect on PC20.
CONCLUSIONS: Air pollution adversely influences lung function and PC20 in asthmatic children. Treatment with controller medications might not protect but rather worsens the effects of CO on PC20. This clinical trial design evaluates modification of pollution effects by treatment without confounding by indication.

PMID: 26187234 [PubMed – as supplied by publisher]

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Effects of weight loss on airway responsiveness in obese asthmatics: Does weight loss lead to reversibility of asthma?

Effects of weight loss on airway responsiveness in obese asthmatics: Does weight loss lead to reversibility of asthma?

Chest. 2015 Mar 12;

Authors: Pakhale S, Baron J, Dent R, Vandemheen K, Aaron SD

Abstract
Background: Growing epidemics of obesity and asthma are major public health concerns. Despite that asthma-obesity links are widely studied, the effects of weight loss on asthma severity measured by airway hyper-responsiveness (AHR) have received limited attention. Our main study objective was to examine whether weight reduction reduces asthma severity in adult obese-asthmatics.
Methods: In a prospective controlled parallel group study, we followed 22 obese-asthmatic subjects aged 18-75 years, with a body mass index (BMI) >32.5kg/m2 and airway hyper-responsiveness (PC20<16mg/mL of methacholine). Sixteen subjects followed a behavioural weight reduction program for 3 months and 6 subjects were controls. The primary outcome was change in AHR over 3 months. Changes in lung function, asthma control and quality of life were secondary outcomes.
Results: At study entry, subjects’ mean age was 44 years (SD±9), 95% were females with mean BMI of 45.7kg/m2 (SD±9.2). After 3 months, mean weight loss was 16.5kg (SD± 9.9) in the weight loss group but controls had a mean weight gain of 0.6kg (SD±2.6). There were significant improvements in PC20 to methacholine (p=0.009), FEV1 (p=0.009), FVC (p=0.010), asthma-control (p<0.001) and asthma quality of life (p=0.003) in the intervention group whilst these parameters remained unchanged in the control group. Physical activity levels also increased significantly in the intervention group but not in the controls.
Conclusion: Weight loss in obese-asthmatics can improve asthma severity and result in improvements in AHR, asthma control, lung function, and quality of life. These findings support the need to actively pursue healthy weight loss measures in obese-asthmatics.

PMID: 25763936 [PubMed – as supplied by publisher]

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