Part, Chapter, Paragraph
1 II, 5. 1. 1| polycyclic aromatic hydrocarbons, radon gas, asbestos); some pesticides;
2 II, 5. 8. 7| Kromhout H, Garcia-Esteban R, Radon R, Jarvis D, Toren K, Künzli
3 III, 10. 1 | association in the case of cancer/radon to a low likelihood as in
4 III, 10. 1 | radiation (incl. sunlight)~radon~dioxins~ ~Cardiovascular
5 III, 10. 3. 1| physical stressors include radon, UV radiation, electromagnetic
6 III, 10. 3. 1| environmental noise. Radiation, radon exposure and noise have
7 III, 10. 3. 1| for the radioactive gas radon. Exposure to radon increases
8 III, 10. 3. 1| radioactive gas radon. Exposure to radon increases significantly
9 III, 10. 3. 1| description and analysis~ ~Radon~ ~Current levels of ionising
10 III, 10. 3. 1| differences due to the presence of radon. Radon is a radioactive
11 III, 10. 3. 1| to the presence of radon. Radon is a radioactive gas formed
12 III, 10. 3. 1| radioactive decay of uranium; radon seeps out of the ground
13 III, 10. 3. 1| exposure is permeation of radon gas into buildings through
14 III, 10. 3. 1| through the ground, but radon from water, outdoor air
15 III, 10. 3. 1| contribute to the total exposure. Radon decays to radon daughters,
16 III, 10. 3. 1| exposure. Radon decays to radon daughters, some of which
17 III, 10. 3. 1| radiation. Alpha-emitting radon daughters are adsorbed onto
18 III, 10. 3. 1| relationship between exposure to radon and the development of lung
19 III, 10. 3. 1| Netherlands, exposure to radon in dwellings leads to 100
20 III, 10. 3. 1| cancer can be ascribed to radon exposure per year (Barns,
21 III, 10. 3. 1| on domestic exposure to radon establishes a clear linear
22 III, 10. 3. 1| cancer risk and the level of radon exposure (Darby et al, 2005).
23 III, 10. 3. 1| Europe can be ascribed to radon, which of a total of 330
24 III, 10. 3. 1| 000 deaths in Europe/year. Radon is also a well known occupational
25 III, 10. 3. 1| epidemiological data for their radon quantitative risk estimates.
26 III, 10. 3. 1| considers the combined effect of radon daughter exposure and smoking
27 III, 10. 3. 1| determining the risk associated to radon exposure. With the numbers
28 III, 10. 3. 1| numbers presented above, radon is clearly the environmental
29 III, 10. 3. 1| if childhood exposure to radon increases the risk of lung
30 III, 10. 3. 1| studies suggesting that radon could increase the risk
31 III, 10. 3. 1| inconclusive. Gamma radiation from radon decay in construction materials (
32 III, 10. 3. 1| to confirm this.~ ~Indoor radon exposure caused by radon
33 III, 10. 3. 1| radon exposure caused by radon gas seeping into the building,
34 III, 10. 3. 1| measure. Another source of radon exposure is building materials.
35 III, 10. 3. 1| Exposure is reduced by routine radon monitoring of building material
36 III, 10. 3. 1| will likely increase indoor radon exposure. Almost all European
37 III, 10. 3. 1| monitoring programs for radon. The intensity and the type
38 III, 10. 3. 1| country and on the actual radon situation. Radon is not
39 III, 10. 3. 1| actual radon situation. Radon is not evenly distributed
40 III, 10. 3. 1| in the country. Clearly, radon monitoring and radon prevention
41 III, 10. 3. 1| Clearly, radon monitoring and radon prevention strategies are
42 III, 10. 3. 1| countries with an established radon problem. Radon mitigation
43 III, 10. 3. 1| established radon problem. Radon mitigation in these countries
44 III, 10. 3. 1| buildings and local and national radon maps. The vast majority
45 III, 10. 3. 1| lower reference levels for radon in schools and kindergartens
46 III, 10. 3. 1| monitoring of workers exposed to radon at work places.~ ~UV radiation~ ~
47 III, 10. 3. 1| factors such as air pollution, radon and UV-radiation, the disease
48 III, 10. 3. 1| the public against indoor radon exposure (90/143/Euratom).
49 III, 10. 3. 1| of the public, the indoor radon reference level (annual
50 III, 10. 3. 1| developments~ ~For what concerns radon, all EU Member States already
51 III, 10. 3. 1| radiation sources (including radon) in work places, laid down
52 III, 10. 3. 1| gaps and needs in indoor radon policymaking vary greatly
53 III, 10. 3. 1| countries have well developed radon policies, while in others
54 III, 10. 3. 1| including establishing radon maps, reference values for
55 III, 10. 3. 1| Wichmann HE, Doll R, (2005): Radon in homes and risk of lung
56 III, 10. 3. 1| associated to exposure to radon and smoking in a case-control
57 III, 10. 3. 1| Morrison HI, Lane R (2007). Radon and lung cancer risk: An
58 III, 10. 3. 2| radiation (incl. sunlight)~radon~dioxins~ ~Cardiovascular
59 III, 10. 4. 3| such as arsenic, uranium radon or fluoride. In addition,
60 III, 10. 4. 3| elements such as arsenic, radon, uranium or fluoride, industrial
61 III, 10. 4. 3| contaminants such as arsenic, radon, uranium and fluorides depending
62 III, 10. 5. 1| Environment Agency, 2007). For radon, asbestos and lead, the
63 IV, 12. 10 | objective of public health law~Radon: objective of national plan
64 IV, 12. 10 | Environmental policy~Child policy~Radon~Radon levels in schools,
65 IV, 12. 10 | policy~Child policy~Radon~Radon levels in schools, preschools
66 IV, 13. 2. 3| ulcers~1,000-3,000~ ~ ~ ~ ~Radon (interior)~Bacterial meningitis,
67 Key, Ap5. 0. 0| rabies~radiation~radioactive~radon~rainfall~rare diseases~rash~
