TY - JOUR
T1 - Quantitative human health risk assessment along the lifecycle of nano-scale copper-based wood preservatives
AU - Hristozov, Danail
AU - Pizzol, Lisa
AU - Basei, Gianpietro
AU - Zabeo, Alex
AU - Mackevica, Aiga
AU - Hansen, Steffen Foss
AU - Gosens, Ilse
AU - Cassee, Flemming R.
AU - de Jong, Wim
AU - Koivisto, Antti Joonas
AU - Neubauer, Nicole
AU - Sanchez Jimenez, Araceli
AU - Semenzin, Elena
AU - Subramanian, Vrishali
AU - Fransman, Wouter
AU - Jensen, Keld Alstrup
AU - Wohlleben, Wendel
AU - Stone, Vicki
AU - Marcomini, Antonio
PY - 2018
Y1 - 2018
N2 - The use of nano-scale copper oxide (CuO) and basic copper carbonate (Cu2(OH)2CO3) in both ionic and micronized wood preservatives has raised concerns about the potential of these substances to cause adverse humans health effects. To address these concerns, we performed quantitative (probabilistic) human health risk assessment (HHRA) along the lifecycles of these formulations used in antibacterial and antifungal wood coatings and impregnations by means of the EU FP7 SUN project’s Decision Support System (SUNDS, www.sunds.gd). The results from the risk analysis revealed inhalation risks from CuO in exposure scenarios involving workers handling dry powders and performing sanding operations as well as potential ingestion risks for children exposed to nano Cu2(OH)2CO3 in a scenario involving hand-to-mouth transfer of the substance released from impregnated wood. There are, however, substantial uncertainties in these results, so some of the identified risks may stem from the safety margin of extrapolation to fill data gaps and might be resolved by additional testing. Our stochastic approach successfully communicated the contribution of different sources of uncertainty in the risk assessment. The main source of uncertainty was the extrapolation from short to long-term exposure, which was necessary due to the lack of (sub)chronic in vivo studies with CuO and Cu2(OH)2CO3. Considerable uncertainties also stemmed from the use of default inter- and intra-species extrapolation factors.
AB - The use of nano-scale copper oxide (CuO) and basic copper carbonate (Cu2(OH)2CO3) in both ionic and micronized wood preservatives has raised concerns about the potential of these substances to cause adverse humans health effects. To address these concerns, we performed quantitative (probabilistic) human health risk assessment (HHRA) along the lifecycles of these formulations used in antibacterial and antifungal wood coatings and impregnations by means of the EU FP7 SUN project’s Decision Support System (SUNDS, www.sunds.gd). The results from the risk analysis revealed inhalation risks from CuO in exposure scenarios involving workers handling dry powders and performing sanding operations as well as potential ingestion risks for children exposed to nano Cu2(OH)2CO3 in a scenario involving hand-to-mouth transfer of the substance released from impregnated wood. There are, however, substantial uncertainties in these results, so some of the identified risks may stem from the safety margin of extrapolation to fill data gaps and might be resolved by additional testing. Our stochastic approach successfully communicated the contribution of different sources of uncertainty in the risk assessment. The main source of uncertainty was the extrapolation from short to long-term exposure, which was necessary due to the lack of (sub)chronic in vivo studies with CuO and Cu2(OH)2CO3. Considerable uncertainties also stemmed from the use of default inter- and intra-species extrapolation factors.
KW - Engineered Nanomaterials
KW - Copper oxide
KW - Copper carbonate
KW - SUN Decision Support System
KW - Probabilistic human health risk assessment
U2 - 10.1080/17435390.2018.1472314
DO - 10.1080/17435390.2018.1472314
M3 - Journal article
C2 - 29893192
SN - 1743-5390
VL - 12
SP - 747
EP - 765
JO - Nanotoxicology
JF - Nanotoxicology
IS - 7
ER -