To the Editor:
The application of domestic cleaning agents increases the risk of asthma and respiratory symptoms in adults [1], in particular when products are applied in spray form [2]. Despite the associations observed in adults, the potential effects of passive exposure on children’s respiratory health have not been extensively explored. Analyses of data from birth cohorts have suggested that frequent use of cleaning agents and their use in spray form increased the risk of wheezing and lower respiratory tract infections (LRTIs) during the first year of life [3, 4] and the risk of persistent wheezing at school age [5, 6]. By contrast, a cross-sectional study reported protective effects of using bleach at home on the prevalence of asthma and allergic sensitisation at school age [7]. Our study investigates the effects of the use of 10 common cleaning products on exhaled nitric oxide fraction (FeNO) and on lung function (forced vital capacity (FVC) and forced expiratory volume in 1 s (FEV1)) during childhood in a population-based birth cohort in Menorca, Spain [8].
Recruitment was performed during pregnancy and 482 children were enrolled at birth. Written informed consent was obtained from all participants and the study was approved by a committee on ethical practice. Questionnaires on wheezing, asthma, treatment and allergies (rhinitis, eczema or hay fever) were administered by the mother repeatedly from birth until the age of 10 years. At the age of 10–13 years, FeNO (NIOX MINO; Aerocrine AB, Solna, Sweden) and forced spirometry (EasyOne; ndd Medical Technologies, Inc., Andover, MA, USA) testing was carried out. In addition, an interviewer-led questionnaire on the frequency of use of 10 different cleaning products (bleach, ammonia, polishes or waxes, acids, solvents, furniture sprays, glass cleaning sprays, degreasing sprays, air freshening sprays, and air freshening plug-in devices) was carried out. A total of 295 individuals completed the 10-year follow-up visit and the cleaning products questionnaire and performed the FeNO and/or the lung function test.
For statistical analyses, we computed a combined spray variable incorporating the four sprays (furniture, glass cleaning, degreasing and air freshening sprays) and a semiquantitative total score for cleaning product use. The means of the reported days of use per week (never=0, <1 day per week=0.5, 1–3 days per week=2 and 4–7 days per week=5.5) for each product were summed providing a score ranging from 0 (no exposure) to 55 (exposed to all 10 products used 4–7 days per week). Multivariable linear regression models were developed to predict log-transformed FeNO concentration and non-transformed levels of FVC and FEV1. Models were adjusted for sex, age, maternal education, parental smoking indoors, asthma medication, season of respiratory test measurement, and for height and weight for lung function measurements only. The coefficients obtained from the log-transformed FeNO models were back-transformed to obtain geometric mean ratios. Potential effect modification of the associations by children’s lifetime wheezing, asthma or reported allergies, were evaluated by the p-value for multiplicative interaction.
The geometric mean FeNO was 13.7 ppb and the mean lung function values were 2.9 L and 2.4 L for FVC and FEV1, respectively. The prevalence of persistent or late onset wheezing was 14%, and any history of asthma or allergies from 4 to 10 years of age were reported as 9% and 36%, respectively. Bleach was the most commonly used product, while sprays were used in almost three-quarters of the homes (table 1). FeNO levels were significantly higher in children exposed to sprays and furniture sprays. The use of air freshening sprays was significantly associated with lower FEV1. No statistically significant associations were observed between the FVC and any of the cleaning products.
After stratifying the analyses for asthma or allergies, the associations between the use of cleaning products, FeNO and lung function were not consistently different for the two groups of children (data not shown). Cleaning product-related health outcome changes were either higher or lower (p-value for interaction <0.1) in children with asthma or allergies.
Our study suggests that bystander exposure to domestic cleaning sprays may have adverse effects on school-age children’s airway inflammation by increasing exhaled nitric oxide. In addition, exposure to air freshening sprays may decrease lung function at school age. Domestic cleaning involves exposure to a large variety of chemicals including both irritant and sensitising agents that can have adverse effect on respiratory health [9]. The use of sprays for domestic cleaning may lead to a higher degree of inhalatory exposure compared with liquid products [2, 10].
Our results are consistent with those reported in infants and children of the younger INMA (INfancia y Medio Ambiente (Environment and Childhood) Project) cohorts, the PARIS (Pollution and Asthma Risk: an Infant Study) and ALSPAC (Avon Longitudinal Study of Parents and Children) cohorts, and with those observed in a Belgian cross-sectional study [3–7]. However, the main findings reported in these studies are mostly based on the associations with reported symptoms or diseases. Our study adds statistically significant associations with objective measurements of airway inflammation and lung function. In line with our findings, the ALSPAC studies [5, 6] showed positive associations between prenatal exposure to a composite score of cleaning products and persistent wheezing at 3 and 7 years of age, and lower spirometric volumes at aged 8.5 years. The INMA and PARIS studies showed an increased risk of wheezing and LRTI in infants exposed to sprays [3, 4], which is consistent with our findings in FeNO at school age. Furthermore, the previous INMA study observed adverse respiratory health effects in infants exposed to air fresheners. Finally, the Belgian cross-sectional study [7] observed a protective effect of using bleach for home cleaning on reporting of asthma and allergic sensitisation in school-aged children. We did not find significant associations between the use of bleach and the respiratory outcomes monitored in this study.
Our cross-sectional study is nested in a longitudinal birth cohort with a long follow-up that includes prospectively collected data, starting at pregnancy and continuing for >10 years. This prospective design provides our cross-sectional analysis with more detailed information on environmental exposures and health outcomes. In addition, our study benefits from the objective measurement of the outcomes. However, we must consider a few limitations when interpreting our results. First, the sample size was relatively small and may have limited the power of our study. Nevertheless, several associations in our study reached statistical significance. Secondly, 35% of the recruited population were excluded because information on the household use of cleaning products and/or on respiratory tests was not available. Nevertheless, the children included were not different from those excluded regarding most characteristics (sex, atopy, asthma, parental asthma and parental smoking at home). However, as anticipated, mothers of participants were more likely to have higher education. Finally, exposure to cleaning products was assessed through parental report. Unfortunately, measurements of indoor volatile organic compounds or home inspections were not performed. Thus, some parents may have over-reported the use of cleaning products or changed their cleaning behaviour according to the asthmatic or atopic status of the parents or the child. Nevertheless, sensitivity analyses suggested that asthma, wheezing, allergy or parental asthma did not modify the observed associations and associations with the objectively measured respiratory health outcomes were apparent in children without asthma or allergic disorders.
In conclusion, the domestic use of household sprays may increase children's airway inflammation and may have adverse effects on lung function. The use of cleaning products in private homes is common and many of these products are applied in a spray formulation. Therefore, our findings may have significant implications for public health. Further investigation is required to obtain a better assessment of exposure and validation of the reported exposure, as well as to identify the underlying pathophysiological mechanisms.
Acknowledgments
The authors would like to acknowledge all the teachers and parents of the children from Menorca Island for patiently answering the questionnaires, all the psychologists who coordinated the fieldwork, and the nurses and administrative staff from the Primary Health Care Centre of Maó, Menorca, for administrative, technical and material support.
Footnotes
Support statement: This work was funded by Fondo de Investigacion Sanitaria, ISCIII, Ministerio de Sanidad y Servicios Sociales, Spain (Grant numbers 97/0588, 00/0021-2, G03/176, PI061756 and PS0901958), EC Contract QLK4-CT-2000-00263 and Fundacio Roger Torne (Barcelona, Spain). In addition, this work was supported by the European Commission as part of HITEA (Health Effects of Indoor Pollutants: integrating microbial, toxicological and epidemiological approaches), grant agreement no. 211488 under the Seventh Framework Programme, Topic ENV.2007.1.2.1.1. “Indoor air pollution in Europe: An emerging environmental health issue”.
Conflict of interest: None declared.
- Received April 15, 2013.
- Accepted May 9, 2013.
- ©ERS 2013