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| | [[op_fi:Seturi]] |
| | {{assessment|moderator=Erkki Kuusisto}} |
| | '''SETURI''' is a research project that estimates and compares the health impacts of the major environmental stressors in Finland. The common metric applied is [[:en:disability-adjusted life year|disability-adjusted life year]] (DALY). |
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| The purpose of this page is to serve as a forum for estimating DALYs due to exposure to environmental and other risks.
| | A large part of the project is presented in Finnish: [[:op_fi:Seturi|Seturi]]. |
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| ==General==
| | The detailed project website is in Heande, which is a protected area. [[:heande:Seturi|SETURI website]]. |
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| ===General procedure===
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| The aim is to analyze current chemical and physical exposures in Finland and their health consequences. The procedures used a similar to a project done in the Netherlands [[Media:Hollander.pdf|(de Hollander 1999)]] and the Global burden of disease project of WHO (http://www.who.int/topics/global_burden_of_disease/en/). The work is expected to contribute to a comparative study between Finland, the Netherlands, and Norway [[Media:Study_plan.doc|(Jantunen: Study plan)]] | |
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| The work will start with selected exposures after which more exposures will be analyzed. The emphasis is on comparability, not comprehensiveness. The selected procedure requires good data on exposure and dose-response, which means that all exposures and all outcomes can not be included.
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| First, the current exposure distribution is estimated for all Finns (or only those exposed). Based on this exposure distribution and the uncertainties in its estimations, the best guess for the average exposure in Finland (or among those exposed) is estimated together with its uncertainty. The uncertainty in the average exposure is expressed by almost lowest possible (5th percentile) and the almost highest possible (95th percentile) value for the average exposure (i.e. as a distribution, more details below).
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| To be able to calculate attributable cases, in addition to current average exposure, one needs to determine, which is the lowest feasibly achievable average exposure in Finland. For several substances this is not zero, e.g. there is a natural background for particulate air pollution.
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| Second, exposure/dose-response functions and their uncertainties (5th and 95th percentiles, as above) are derived for all outcome with sufficient data. It is important that the exposure/dose-response function uses exactly the same exposure/dose marker that was used in the exposure estimation above (more details below).
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| Third, attributable number of cases is estimated by multiplying the exposure difference with exposure/dose-response and number of exposed using probabilistic methods (Monte-Carlo)
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| ===List of potential exposures that could be considered in the evaluation===
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| Criteria
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| 1) Public health effects
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| 2) Concern
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| 3) High exposures in specific groups, e.g. '''occupational exposures'''
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| * Alcohol, ''metanol''
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| * ''Particulate air pollution by source''
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| * Ozone
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| * ''CO and NO2'' (probably included in the above)
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| * ''PAHs''* ''Environmental tobacco smoke''
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| * ''CO'' indoors
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| * ''Benzene''* ''Formaldehyde'', naphthalene, hexane, asetaldehyde
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| * 1,3-butadiene
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| * ''Lead''
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| * Damp housing
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| * ''Noise''* Foodborn epidemics
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| * Waterborn epidemics
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| * Chlorination by-products
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| * ''Arsenic''
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| * Fluoride
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| * Dioxin, PCBs, phtalates
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| * Methyl mercury, mercury
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| * Radon
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| * UV radiation
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| * EMF
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| * ''Man-made radiation''
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| * Chemicals in food (acrylamide, pesticides, food additives)
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| * ''Accidents'' (traffic, occupational, domestic/other)
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| ===Provisional list of selected exposures and responsible persons===
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| * Indoor radon, STUK/Päivi Kurttio and ?
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| * Fine particles, KTL/Juha Pekkanen, Olli Leino?
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| * Formaldehyde, TTL, Eero Priha
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| * Alcohol, STAKES/Timo Ståhl
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| * Dioxins, KTL/Juha Pekkanen, Olli Leino?
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| * ?Damp housing, KTL/Aino Nevalainen, Ulla Haverinen
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| * Arsenic, KTL/Hannu Komulainen
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| * ?Methyl mercury, KTL/Juha Pekkanen, Olli Leino?
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| ==Methods==
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| ===Exposure estimation===
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| Below link to the exposure assessment done for the earlier exposure seminar of our group
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| http://www.ttl.fi/Internet/Suomi/Aihesivut/Kemikaaliturvallisuus/Valittua+kemikaalitietoa/suomaltkemsateil.htm
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| Occupational exposure data is based on environmental measurements, modelling and other information on exposure factors (e.g. exposure times, skin contact, consumption data etc.). In workplaces exposure varies considerably depending on the sector of industry and even within a factory depending on work task. Also exposure level also changes often during a work day.
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| The following table outlines some occupationally important exposures on Finnish workplaces:
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| ===Dose-response assessment===
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| Dose-response information can based on epidemiological studies or in toxicological tests. Epidemiological data is normally preferred to animal tests. However, in most cases dose-response data (e.g. IRIS database) is based animal tests and consequent calculations. In some cases epidemilogical data is suitable for quantitative estimates of risk. In majority of cases, the available epidemiological studies are inadequate and then cancer risks assessment is based on animal bioassays.
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| ===Estimation of DALYs===
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| ===Probabilistic risk assessment===
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| Probabilistic exposure/risk assessment methods can be used to analyze the exposure and risk more closely. The needed parameters of the used formula/algoritm are given as distributions (e.g. log-normal, normal, uniform, triangular) and the result of simulation are also distributions. Thus different recentiles of risk are obtained.
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| ==Exposures and dose-responses for selected exposures==
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| ===Indoor radon===
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| ===Alcohol (ethanol)===
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| ===Fine particles===
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| '''Target population''': All Finnish subjects aged 35 and above
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| '''Average, population weighted, PM2.5 concentration''': So far we don’t have any available data on fine particles concentrations in Finland. The population average concentration can be estimated to be somewhere between 5 and 10 µg/m3 based on measurements done in Helsinki.
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| *Population average concentration (mean; min-max estimate mean): 7.0; 6.0-8.0
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| *Distribution of population PM exposure 5%; 50%; 95%;: 2; 6; 12;
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| '''All non-accidental mortality in Finland (year 2000)''': Mortality counts can be estimated from WHO-mortality database (http://www.who.int/healthinfo/morttables/en/index.html). The number of non-accidental deaths in Finnish subjects aged 35 and above in year 2000 was ?.
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| '''Concentration-response function for PM2.5 (RR/(10ug/m3))''': Based on Pope et al. 2002 study, the relative risk estimate for 10 µg/m3 changes in PM2.5 concentration is 1.06 and 95% confidence interval 1.02 – 1.11.
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| *Relative risk for PM2.5 (mean; min; max): 1.06; 1.02; 1.11
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| '''Low exposure/threshold''': Although current scientific knowledge has not revealed any threshold value for fine particles, for the analysis we use threshold value 5 µg/m3.
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| *Threshold value: 5 µg/m3
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| '''Exposure above threshold''': This is the average fine particles exposure above the threshold limit. Estimated by subtracting the threshold from the average exposure.
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| *Population average concentration above threshold (mean; min; max): 2.0; 1;0; 3.0
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| '''Relative risk above threshold''': Relative risk estimate for the given exposure. This is estimated from RR-values with formula exp(ln(RR)/10*exposure), that is, for mean estimate exp(ln(1.02)/10*2.0.
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| *Relative risk above threshold (mean; min; max): 1.01; 1.00; 1:03
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| '''Attributable risk above threshold''': Percentage change in all-cause mortality due to exposure. Estimate from Relative Risk above threshold with formula -> (RR-1)/RR
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| *Attributable death above threshold (mean; min; max): 1.2%; 0.2%; 3.1%
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| '''Number of excess deaths in Finnish population''': Mortality with the current information.
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| *Number of excess deaths in Finnish population (mean; min; max): 877; 150; 2333
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| The excel sheet with the calculations: http://heande.pyrkilo.fi/heande/images/5/5a/Tainio_Finland.xls
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| ===Formaldehyde===
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| Formaldehyde has been classified as a human carcinogen by WHO/IARC (2004). Formaldehyde causes sinonasal cancer in rats (Kerns 1983) already at exposure levels (2-6 ppm) close those occurring at workplaces in the 1970s. In the epidemiological studies, there was sufficient evidence thatformaldehyde causes nasopharyngeal cancer and limited evidence that formaldehyde causes sinonasal cancer in humans.
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| '''Dose-response data'''
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| US EPA has established a unit risk for formaldehyde which is 1.3x10-5 per ug/m3. This unit risk (for sinonasal cancer) is based on animal inhalation tests and linearized multistage (LMS) model (upper bound extrapolation from 10% response level). Unit risk means lifetime excess risk at exposure level of 1 ug/m3. The unit determined for formaldehyde can be applied to exposure level under 800 ug/m3.
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| The most important epidemiological study (Hauptman 2004) found SMR 2.1 (1.05-4.21)to nasopharyngeal cancer in workers exposed in formaldehyde/resin industry. For sinonasal cancer excess was less clear, SMR=1.19 (0.38-3.29).
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| '''Exposure'''
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| People are widely exposed to formaldehyde in homes and at workplaces in Finland. Exposure levels have decreased to less formaldehyde emitting products (particle board, MDF board, textiles, wallpaper etc.). It has been evaluated that about 12000 Finns are exposed to formaldehyde at workplaces (exposure level over background). Of these workers about 2000 has been evaluated (in 2003) to be more heavily exposed so formaldehyde concentration in air may at least occasionally reach the current occupational exposure limit which is 0.3 ppm as 8.h TWA. Background exposure level in Finland is today less than 1 ug/m3 in countryside but it may exceed this (max about 5 ug/m3) in cities due to traffic etc. The highest average exposure levels are in formaldehyde and resin glue industry, in woodboard factories, in woodworking and furniture industries as well as in foundries using furane resin.
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| In Finnish family dwellings formaldehyde levels are currently about 20-80 ug/m3 (mean about 45 ug/m3) and in single family houses (mean about 20 ug/m3). These concentrations have consideravble ´deceased since the beginning of the 1980s.
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| '''Risk calculations'''
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| The following risks were obtained by combining exposure and unit risks:
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| Table 5 Calculated occupational sinonasal and pharyngeal cancer risk and number of cases using KymCAREX-database and IRIS unit risk estimates (1.3x10-5 per µg/m3)
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| Code Branch of industry Estimated exposure level,
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| mg/m3 Number of exposed Lifetime risk of sinonasal and pharyngeal cancer Cases /lifetime
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| 159 Manufacture of beverages 0.125 39 0.000203 0.007922
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| 17 Manufacture of textiles 0.125 216 0.000203 0.043875
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| 18 Production of clothing 0.0625 648 0.000102 0.065813
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| 20 Manufacture of wood and products of wood and cork 0.50 3400 0.000813 2.7625
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| 21 Manufacture of pulp, paper and paper products 0.125 208 0.000203 0.04225
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| 241 Manufacture of basic chemicals 0.375 114 0.000609 0.069469
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| 243 Manufacture of paints, varnishes and similar coatings, printing ink 0.125 17 0.000203 0.003453
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| 252 Manufacture of plastic products 0.125 153 0.000203 0.031078
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| 261 Manufacture of glass and glass products 0.125 18 0.000203
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| 268 Manufacture of other non-metallic mineral products 0.125 92 0.000203
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| 275 Casting of metals 0.125 655 0.000203 0.133047
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| 28 Manufacture of fabricated metal products, except machinery and equipment 0.125 57 0.000203 0.011578
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| 29 Manufacture of machinery and equipment n.e.c. 0.125 70 0.000203 0.014219
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| 361 Manufacture of furniture 0.25 4144 0.000406 1.6835
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| 45 Lacqueringof floors with acid-cured lacquers (construction workers)
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| 0.50 375 0.000813 0.304688
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| 73 Research and development 0.125 25 0.000203 0.005078
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| 80 Education 0.125 23 0.000203 0.004672
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| 851 Human health activities 0.125 309 0.000203
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| 92 Recreational, cultural and sporting activities 0.0625 11 0.000102
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| 93 Other service activities 0.0625 11 0.000102
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| 10685 (total) 5.27 (total)
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