Hämeenkyrö MSWI risk assessment: Dioxin

Dioxins are produced unintentionally as by-products of many chemical industrial processes and of all combustion processes. Sources include metal industry, power plants, industrial combustion plants, small combustion units (mostly domestic), waste incineration, road transport and mineral products production.

Total dioxin emissions are usually reported in toxic equivalency values (TEQ), which enables comparison of the toxicity of different combinations of dioxins and dioxin-like compounds. A TEQ is calculated by multiplying the actual grams weight of each dioxin and dioxin-like compound by its corresponding toxic equivalency factor (TEF) and then summing the results. The number that results from this calculation is referred to as grams TEQ.

(Comment: The emissions sources of dioxin are known pretty well. Although it is unlikely that these factories have direct dioxin measurements, emission estimates for the sources of this size should be available. You should ask Juhani Ruuskanen (KuY) or Päivi Ruokojärvi (KTL)).

Possible dioxin sources in Hämeenkyrö:

Currently: the local gas power plant, landfills, traffic, domestic combustion (cardboard factory, sawmill) R↻

Future: Municipal solid waste incinerator, biofuel power plant

Emission factors for different processes (UNEP 1999a):

Municipal solid waste incineration (µg TEQ/t MSW burned)

Low technology combustion, no APC system: air 3500, fly ash 0, bottom ash 75

Controlled combustion, minimal APC: air 350, fly ash 500, bottom ash 75

Controlled combustion, good APC: air 30, fly ash 200, bottom ash 7

High technology combustion, sophisticated APC system: air 0.5, fly ash 15, bottom ash 1.5

Energy production (µg TEQ/TJ)

Natural gas fired power boiler: 0.5

Mixed biomass fired power boiler: air 500, residue NA

Clean wood fired power boiler: air 50, residue 15

Domestic energy production (µg TEQ/TJ)

Household heating and cooking (contaminated wood/ biomass fired stoves): air 1500, residue 2000

Virgin wood/ biomass fired stoves: air 100, residue 20

Domestic heating (coal fired stoves): air 70, residue 5000

Domestic heating (Oil fired stoves): air 10, residue NA

Domestic heating (natural gas fired stoves): air 1.5, residue NA

Transport (µg TEQ/t of fuel burned)

4-stroke engines

leaded fuel without catalyst: air

unleaded fuel without catalyst: air 0.1

unleaded fuel with catalyst

Diesel engines: air 0.5

Production of pulp and paper products

Emissions from landfills (pg TEQ/L of leachate released)

Hazardous wastes: air 0, water 200

Non-hazardous wastes: air 0, water 30

Landfill fires (µg TEQ/t of material burned): air 1000

http://www.chem.unep.ch/pops/pdf/toolkit/toolkit.pdf#search=%22UNEP%20dioxin%20toolkit%22

UNEP (1999b). United Nations Environment Programme. Dioxin and furan inventories, National and regional emissions of PCDD/PCDF, May 1999. http://www.oztoxics.org/ipepweb/library/DioxinInventory.pdf#search=%22dioxine%20emissions%20from%20traffic%22

SYKE 2004. Finnish Environment Institute. Air pollutant emissions in Finland 1990-2002. National inventory report. http://www.ymparisto.fi/download.asp?contentid=13512#search=%22dioxine%20emissions%20from%20traffic%22

Margni and coworkers have estimated an iF for Western European sources. The iF is approximately 3.5.10(-3) for emissions of dioxin in Western Europe. This iF compares well to the traditional non-spatial multi-media/-pathway model predictions of 3.9.10(-3) for the same region and to 2.10(-3) for the USA. Approximately 95% of the intake from Western European emissions occurs within the same region, 5% being transferred out of the region in terms of food contaminants and atmospheric advective transport. (Margni et al., 2004) However, when the emission source is in the North-Eastern corner of Europe like Hämeenkyrö is, the population exposed is likely smaller than on average, especially because the predominant wind direction is from southwest and away from densely populated areas. Therefore, the published value is likely an overestimate.

Bennett DH, Margni MD, McKone TE, Jolliet O. Intake fraction for multimedia pollutants: a tool for life cycle analysis and comparative risk assessment. Risk Anal. 2002 Oct;22(5):905-18.

Here we will use the daily PCDD/F intake estimated for the Finnish population in average as a starting point. In addition, the other variable in this model, "Dioxin emissions in Hämeenkyrö", may affect the estimate of baseline dioxin exposure in Hämeenkyrö.

For the adipose tissue PCDD/F concentration the value estimated for the general population living in Finnish inland is used.

It is noteworthy, that some subgroups within society, such as nursing babies and people consuming lot of fish may be more highly exposed to dioxins than the average people.

PCBs, another group of persistent environmental contaminants, were included as they behave similarly in the food chain and have partly similar health effects as dioxins.D↷

Intake fraction for dioxin emissions from Hämeenkyrö

2) Adipose tissue concentration: WHO-TEQ pg/g fat

Average daily intake of PCBs 0.74 pg/kg bw

Average adipose tissue PCDD/F concentration 26.4 pg/g

Average adipose tissue PCB concentration 18.1 pg/g

Note: During the nursing period, the PCDD/F intake of a child can be 1-2 orders of magnitude higher than that of an adult.

Kiviranta H, Ovaskainen ML, Vartiainen T. Market basket study on dietary intake of PCDD/Fs, PCBs, and PBDEs in Finland. Environ Int. 2004 Sep;30(7):923-32.

Kiviranta H, Tuomisto JT, Tuomisto J, Tukiainen E, Vartiainen T. Polychlorinated dibenzo-p-dioxins, dibenzofurans, and biphenyls in the general population in Finland. Chemosphere. 2005 Aug;60(7):854-69.

Tuomisto et al. 1999. Synopsis on dioxins and PCBs. Publications of the National Public Health Institute B17/1999.

• Health effects related to long-term exposure
  • impairment of the immune system
  • impairment of the developing nervous system
  • impairment of the endocrine system
  • impairment of reproductive functions
  • increased cancer risk

Evidence concerning cancer risk is mainly from animal studies, and dioxins are probably quite weak carcinogens in humans. Hormesis type of dose-response is suspected. Evidence concerning other health effects is inconsistent.

In this specific case

• MSWI is likely to increase background dioxin exposure (additional low exposure)
• the risk of accidental exposure is low (dioxin emissions will increase only if burning process is working improperly)
• health effects of long-term exposure are relevant
• effects on development and endocrine functions are more relevant than the risk of cancer
• The health effects of low doses should be modelled from animal and human data. Eg. Alaluusua et al. (1996) have studied tooth development. In a study by Miettinen et al. (2005), exposure to 0.5 μg TCDD/kg body weight on GD 15 resulted in maternal adipose tissue concentration of 2185 pg/g fat. In that study, linear extrapolation of the data predicts a maternal adipose tissue concentration of 100-120 pg/g fat after exposure to 0.03 μg TCDD/kg body weight. This estimated maternal adipose tissue concentration is sufficient to induce developmental dental defects in rat offspring, and is similar to the highest values measured in the Finnish average population (PCDD/F 145.5 pg WHO-TEQ/g fat (Kiviranta et al. 2005).

Sensitive subgroups: foetuses, newborns, young females (women below or at childbearing age), individuals with high fish consumption (e.g. fishermen), individuals working in incineration plants etc. (For health effects related to short-term exposure R↻ )

• Dioxin emissions and in Hämeenkyrö (Comment: This is not actually an input, but #Dioxin exposure due to MSWI in Hämeenkyrö
• #Background incidence rates for selected diseases and causes of death in Hämeenkyrö population; susceptible groups, demographic data (Comment: This background variable is actually missing: Anne knows about the population size, but does someone know about the background disease rates?)
• #Population size in Hämeenkyrö
• #Baseline dioxin exposure in Hämeenkyrö

increased cancer incidence per pg/kg body weight OR per adipose tissue concentration (Comment: units are good for exposure-response function (as this variable used to be) but not for health effect (as it currently seems to be)

increase in lifetime risk per pg/kg body weight

tolerable daily intake (TDI): 1-4 pg/kg body weight

Crump et al. 2003. Meta-analysis of dioxin-cancer dose-response for three occupational cohorts. Environmental Health Perspectives 111 (5), 681-687.

Kiviranta et al. Chemosphere. 2005 Aug;60(7):854-69.

Kogevinas 2001. Human health effects of dioxins: cancer, reproductive and endochrine system effects. Human Reproduction Update 7 (3), 331-339.

Miettinen HM et al. Toxicol Sci. 2005 Jun;85(2):1003-12.

Tuomisto JT et al. Int J Cancer. 2004 Mar 1;108(6):893-900.

Tuomisto et al. 1999. Synopsis on dioxins and PCBs. Publications of the National Public Health Institute B17/1999.

van Leeuwen FX et.al. Chemosphere. 2000 May-Jun;40(9-11):1095-101.