Molter et al. reported the effects of long-term exposure to particulate matter with aerodynamic diameter <10 micrometer (PM10) and nitrogen dioxide (NO2) on the prevalence of asthma and wheeze within a population-based birth cohort (1). They concluded that no significant association between long-term exposure to PM10 and NO2 and the prevalence of either asthma or wheeze was found. In contrast, the same authors reported that lifetime exposure to PM10 and NO2 was associated significantly with reductions in lung volume growth by using the same cohort (2).

On this point, Gehring et al. conducted meta-analysis with random- effect model on the effects of air pollution on lung function in children (3). They concluded that that current levels of NO2, total nitrogen oxides, and particulate matter with aerodynamic diameter <2.5 micrometer (PM2.5) were significantly associated with the change in forced expiratory volume in 1 second (FEV1), but PM10 showed no significance. As the level of statistical significance in studies by Molter et al. or Gehring et al. was not highly enough, final conclusion cannot be determined. Relating to these studies, Urman et al. reported health survey to assess the effects of near-roadway air pollution (NRAP) and regional pollution on childhood lung function (4). They concluded that the contribution of regional pollution to adverse lung function, evaluated by FEV1 and forced vital capacity (FVC), was relatively larger than that of NRAP, and NO2 contributed little to the decrease in FEV1 and FVC than other air pollution indicators such as PM2.5 and PM10.

I have some concerns on the study outcomes. First, physiological lung functions and subjective respiratory complains for dependent variables would sometimes lead to the different study outcome, and both dependent factors should be evaluated to know the adverse effect of air pollution on respiratory organs. As one of the co-authors, I conducted questionnaire survey for 16,663 pairs of junior high school students and their mothers in Indonesian cities to measure the effect of air pollution on respiratory health (5). Nine communities were set and there were inter-class and intra -class variation of NO2. As a main result, the prevalence rates of the symptoms of cough, phlegm, persistent cough, wheezing without a cold, and asthma of the student were significantly correlated with the NO2 emitted along large roads near their residences.

Second, the superiority of PM2.5 compared with PM10 could not be confirmed, and the best aerodynamic diameter of particulate matter as an air pollution indicator should be specified by further studies.

Finally, I recommend for considering indoor air pollution especially by smoking (6). Anyway, cause-effect relationship would be clarified by epidemiological cohort studies.

References

1 Molter A, Agius R, de Vocht F, et al. Effects of long-term exposure to PM10 and NO2 on asthma and wheeze in a prospective birth cohort. J Epidemiol Community Health 2014;68:21-8.

2 Molter A, Agius RM, de Vocht F, et al. Long-term exposure to PM10 and NO2 in association with lung volume and airway resistance in the MAAS birth cohort. Environ Health Perspect 2013;121:1232-8.

3 Gehring U, Gruzieva O, Agius RM, et al. Air Pollution Exposure and Lung Function in Children: The ESCAPE Project. Environ Health Perspect 2013;121:1357-64.

4 Urman R, McConnell R, Islam T, et al. Associations of children's lung function with ambient air pollution: joint effects of regional and near-roadway pollutants. Thorax 2013 Nov 19. doi: 10.1136/thoraxjnl-2012- 203159.

5 Duki MI, Sudarmadi S, Suzuki S, et al. Effect of air pollution on respiratory health in Indonesia and its economic cost. Arch Environ Health 2003;58:135-43.

6 Guerra S, Stern DA, Zhou M, et al. Combined effects of parental and active smoking on early lung function deficits: a prospective study from birth to age 26 years. Thorax 2013;68:1021-8.

Conflict of Interest:

None declared

Sir, the recent report on "extreme temperatures and paediatric emergency" is very interesting [1]. Xu et al. concluded that "children are at particular risk of a variety of diseases which might be triggered by extremely high temperatures [1]."Xu et al. also mentioned for the effect of climate change. In fact, Xu et al. reported a highly similar publication in Occup Environ Med and also noted for the effect of climate change on childhood illness with special focus on asthma [2]. The two works should share the same groups of patients but the conclusion is different. In the present report, Xu et al. make a conclusion that "children aged 10-14 years were more sensitive to both hot and cold effects [1]" whereas they proposed that "children aged 10-14 years were most vulnerable to cold effects [2]." This implies that there are many bias in both reports. Hence, it cannot conclude on any effects from hot and cold temperature on pediatric illness. In addition, not only temperature but also other climatic factors can affect the disease incidence. The good example is the effect of humidity [3], pollutants [3] and ozone levels [4].

References

1. Xu Z, Hu W, Su H, Turner LR, Ye X, Wang J, Tong S. Extreme temperatures and paediatric emergency department admissions. J Epidemiol Community Health. 2013 Nov 23. doi: 10.1136/jech-2013-202725. [Epub ahead of print] 2. Xu Z, Huang C, Hu W, Turner LR, Su H, Tong S. Extreme temperatures and emergency department admissions for childhood asthma in Brisbane, Australia. Occup Environ Med. 2013 Oct;70(10):730-5. 3. Vandini S, Corvaglia L, Alessandroni R, Aquilano G, Marsico C, Spinelli M, Lanari M, Faldella G. Respiratory syncytial virus infection in infants and correlation with meteorological factors and air pollutants. Ital J Pediatr. 2013 Jan 11;39(1):1. 4. Jones GN, Sletten C, Mandry C, Brantley PJ. Ozone level effect on respiratory illness: an investigation of emergency department visits. South Med J. 1995 Oct;88(10):1049- 56.

Conflict of Interest:

None declared

This is a great contribution to the literature on fuel poverty, cold housing, and health.

The authors call for a review of qualitative and intervention research related to this topic. It may be useful for readers to be made aware of a recently updated version of a systematic review of the health and socio-economic impacts of housing improvement published by the Campbell and Cochrane Collaborations 1. In this review we looked at physical improvements to housing infrastructure and this included a group of 15 quantitative (including five RCTs) and seven qualitative studies of warmth & energy efficiency improvements. We did not include studies which only looked at financial help with fuel bills, for example the winter fuel allowance distributed to the elderly in the UK.

1. Thomson H, Thomas S, Sellstrom E, Petticrew M. Housing improvements for health and associated socio-economic outcomes. Cochrane Database of Systematic Reviews 2013;2:Art. No.: CD008657 DOI: 10.1002/14651858.CD008657.pub2. http://onlinelibrary.wiley.com/doi/10.1002/14651858.CD008657.pub2/pdf/standard

Conflict of Interest:

Flagging up my own work.

It cannot be denied that TTC (Threshold of Toxicological Concern) was originally proposed in the U.S., as Dr Harris states in her commentary on our article,[1] but her industry-sponsored organisation, the International Life Sciences Institute (ILSI) played a major role in developing it further to the form in which it was accepted by European Food Safety Authority (EFSA).

This process took place in an EFSA working group, in which ten out of 13 members had previously developed and promoted the tool with ILSI.[2] While EFSA communicators have attempted damage control in their online Q&A, the biased work on TTC raised such concerns in the European Parliament that EFSA was forced to ban ILSI-linked people from being members of expert panels and working groups. Any link with ILSI now has to be cut in order to qualify as an EFSA expert.

Apart from this industry infiltration of EFSA, the tool as delivered by ILSI is far from being "scientifically supported", as Dr Harris suggests. The database underpinning the TTC for non-genotoxic substances[3] is entirely made up of (potentially biased) industry studies. Many of these studies are 40-60 years old and non-retrievable (cannot be accessed), meaning that their quality cannot be assessed. In addition, the old protocols used means that current scientific knowledge will not be taken into account in calculating TTCs. In utero exposure is generally missing and important risks will be overlooked because of the limited endpoints considered at that time. The grouping of chemicals for TTC is artificial and is based on the Cramer classification,[4] which relies on expert judgement only and is subjective. ILSI has also manipulated the genotoxin database to get to an apparently desired outcome. For example, it has removed aflatoxin-like, azo- and N-nitroso- substances.[5] Another unscientific shortcoming of TTC is its disregard of cumulative effects.

The TTC is derived by arbitrarily removing from the calculation the most toxic effects found in the database of NOELs (no adverse effect levels). The TTC sets the 'level of no concern' at the 5th percentile, resulting in a 1 in 20 chance that a random substance in any one group of chemicals is toxic at this exposure level. Thus 5% of the chemicals in the group are more toxic than the 'level of no concern' that is set for any one group of chemicals.

TTC is promoted as a screening tool while in practice it is already being used as a cut-off criterion (safe level) for pesticide metabolites.[6] Industry is now trying to extend TTC to other fields such as any chemical found in food,[7] outcomes of developmental testing,[8] drinking water,[9] and inhaled chemicals.[10] In many cases, and not coincidentally, advocates of TTC are pursuing these aims through opinions published in Regulatory Toxicology and Pharmacology, the controversial chemical/pharmaceutical industry-sponsored journal. The journal was one of several entities that were investigated by a US Congressional Committee in 2008 over their role in the Food and Drug Administration (FDA) decision allowing bisphenol A in infant formula and other foods.[11-13]

Analysing the TTC tool and the background of its development can only lead to the conclusion that industry has invested massively in a tool that does not safeguard human health, as Dr Harris misleadingly claims, but exactly the opposite. The tool serves industry's agenda of fast-tracking chemicals to the market and avoids the costs of testing. The tool undermines European legislation and policy. It aims to replace the existing EU policy of 'no safe level' for genotoxic substances with claimed 'safe levels' arrived at through the TTC. It also aims to replace the EU policy that health of citizens should be protected by adequate testing and the precautionary principle with a tool that enables avoidance of testing for chemicals, metabolites and impurities.

The tool, which serves industry's agenda but places public health at risk, has been introduced into European agencies by people who have served as members of expert panels while maintaining conflicts of interest with industry. Dr Harris's reference to the Danish study[14] as a balanced review of TTC is a case in point. Its author, John Christian Larsen, worked in ILSI scientific bodies from 2002 till 2008[15] and has published studies with ILSI-affiliated people who have promoted TTC.[16] TTC has made its way into the regulatory policy of the food safety authority EFSA because of industry's massive resources and a lack of awareness on the part of EFSA's staff, not for reasons of sound science.

References

1. Robinson C, Holland N, Leloup D, et al. Conflicts of interest at the European Food Safety Authority erode public confidence. J Epidemiol Community Health Published Online First: 8 March 2013. doi:10.1136/jech-2012-202185

2. Muilerman H, Tweedale T. A toxic mixture? Industry bias found in EFSA working group on risk assessment for toxic chemicals, Pesticide Action Network Europe 2011.

3. EFSA Scientific Committee. Scientific opinion on exploring options for providing advice about possible human health risks based on the concept of Threshold of Toxicological Concern (TTC). EFSA Journal 2012;10: 2750.

4. Cramer GM, Ford RA, Hall RL. Estimation of toxic hazard - a decision tree approach. Food Cosmet Toxicol 1978;16: 255-276.

5. Kroes R, Renwick AG, Cheeseman M, et al. Structure-based thresholds of toxicological concern (TTC): guidance for application to substances present at low levels in the diet. Food Chem Toxicol 2004; 42: 65-83.

6. European Commission Health and Consumer Protection Directorate- General (DG SANCO). Guidance document on the assessment of the relevance of metabolites in groundwater of substances regulated under Council Directive 91/414/EEC: Sanco/221/2000-rev.10-final. 25 February 2003.

7. Koster S, Boobis AR, Cubberley R, et al. Application of the TTC concept to unknown substances found in analysis of foods, Food and Chemical Toxicology 2011; 49: 1643-1660.

8. Van Ravenzwaay B, Dammann M, Buesen R, et al. The threshold of toxicological concern for prenatal developmental toxicity. Regulatory Toxicology and Pharmacology 2011;59: 81-90.

9. Melching-Kollmuss S, Dekant W, Kalberlah F. Application of the ''threshold of toxicological concern" to derive tolerable concentrations of ''non-relevant metabolites" formed from plant protection products in ground and drinking water. Regulatory Toxicology and Pharmacology 2010; 56: 126-134.

10. Escher SE, Tluczkiewicz I, Batke M, et al. Evaluation of inhalation TTC values with the database RepDose. Regulatory Toxicology and Pharmacology 2010; 58: 259-274.

11. Michaels, D. Doubt Is Their Product: How Industry's Assault on Science Threatens Your Health. Oxford University Press. 2008: 53-54.

12. Layton L. Studies on chemical in plastics questioned. Washington Post 27 April 2008.

13. Dingell JD. Letter to Jack N Gerard, president and CEO, American Chemistry Council. 2 April 2008. http://bit.ly/ZWMbi6 (accessed 15 April 2013).

14. Nielsen E, Larsen JC. The Threshold of Toxicological Concern (TTC) concept: Development and regulatory applications. Danish Ministry of the Environment, Environmental Protection Agency. Environmental Project No. 1359. 2011. http://www2.mst.dk/udgiv/publications/2011/03/978-87-92708 -86-1.pdf (accessed 15 April 2013).

15. European Food Safety Authority (EFSA). Declarations of interests (DoIs). http://www.efsa.europa.eu/en/efsawho/doi.htm (accessed 15 April 2013).

16. Pratt I, Barlow S, Kleiner J, et al. The influence of thresholds on the risk assessment of carcinogens in food. Mutation Research 2009; 678: 113-117.

Conflict of Interest:

Hans Muilerman is employed at Pesticide Action Network Europe, which receives funding from trusts and foundations, including the European Endocrine Health Initiative.