Toward harmonizing ecotoxicity characterization in life cycle impact assessment

Fantke, Peter; Aurisano, Nicolò; Bare, Jane; Backhaus, Thomas; Bulle, Cécile; Chapman, Peter M.; Zwart, Dick de; Dwyer, Robert; Ernstoff, Alexi; Golsteijn, Laura; Holmquist, Hanna; Jolliet, Olivier; McKone, Thomas E.; Owsianiak, Mikołaj; Peijnenburg, Willie J.G.M.; Posthuma, Leo; Roos, Sandra; Saouter, Erwan; Schowanek, Diederik; Straalen, Nico M. van; Vijver, Martina G.; Hauschild, Michael Zwicky

doi:10.1002/etc.4261

Cited by 69 publications

(56 citation statements)

References 86 publications

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“…Quantifying life cycle toxicity impacts based on existing actual pollutant levels in soil will, in addition, be useful in complementing pollutant threshold levels by uncovering potential tradeoffs between different multi-media fates and multipathway exposures, related to soil contaminants contributing to potentially negative impacts on humans and the environment (Fantke et al 2018a(Fantke et al , 2018b. In the present study, we focus on the following three objectives: (1) to determine the cumulative mass of bromine in soil in the different districts of Tomsk oblast and discuss potential sources; (2) to characterize cumulative human toxicity and ecotoxicity impact potentials of bromine mass in soils of Tomsk oblast; and (3) to identify existing challenges of combining environmental studies with screeninglevel toxicity characterization, and to discuss future research needs as input to develop operational methods for mitigating contamination from emissions of inorganic substances.…”

Section: Introductionmentioning

confidence: 99%

Towards integrating toxicity characterization into environmental studies: case study of bromine in soils

Bratec

Kirchhübel

Baranovskaya

et al. 2019

Environ Sci Pollut Res

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Pollution from bromine and some of its related compounds is currently unregulated in soil from Russia and other countries, and tools for sound assessment of environmental impacts of bromine contamination are largely missing. Hence, assessing potential implications for humans and ecosystems of bromine soil contamination is urgently needed, which requires the combination of measured soil concentrations from environmental studies and quantified potential toxicity impacts. To address this need, we used data from an experimental study assessing bromine in soils (384 samples) of Tomsk oblast, Russia, starting from measured concentrations obtained by Instrumental Neutron Activation Analysis in an earlier study. From these data, we calculated the bromine mass in soils and used these as starting point to characterize related cumulative impacts on human health and ecosystems in the Tomsk region, using a global scientific consensus model for screening-level comparative toxicity characterization of chemical emissions. Results show that the combination of sampling methodology with toxicity characterization techniques presents a new approach to be used in environmental studies aimed at environmental assessment and analysis of a territory. Our results indicate that it is important to account for substance-specific chemical reaction pathways and transfer processes, as well as to consider region-specific environmental characteristics. Our approach will help complement environmental assessment results with environmental sustainability elements, to consider potential tradeoffs in impacts, related to soil pollution, in support of improved emission and pollution reduction strategies.

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Section: Introductionmentioning

confidence: 99%

Towards integrating toxicity characterization into environmental studies: case study of bromine in soils

Bratec

Kirchhübel

Baranovskaya

et al. 2019

Environ Sci Pollut Res

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“…Compared with toxicology, however, exposure science is still ill developed as an independent discipline [2,4]. Yet, it has become an indispensable element in various science and policy frameworks, from policy analysis to sustainability assessment [5][6][7][8][9][10][11][12][13], and has been proposed as an important component in chemical substitution [14,15]. Although many regulations and studies focus on exposure to chemicals, assessing and managing exposure to other stressors is increasingly acknowledged.…”

Section: Exposure Science As An Important Disciplinementioning

confidence: 99%

“…To identify such key needs, two surveys were developed targeting exposure science professionals representing a wide spectrum of stakeholders. The first survey was conducted in 2016 and sent to all 560 participants attending the ISES 26 th Annual Meeting, [9][10][11][12][13] October, in Utrecht, The Netherlands. Participants were asked to provide their visions for exposure science in Europe in five and ten years, to identify the main drivers for exposure science, and how they see the role of a European chapter of ISES for improving exposure information and its policy uptake.…”

Section: Key Needs and Building Blocksmentioning

confidence: 99%

Building a European exposure science strategy

Fantke

Goetz

Schlüter

et al. 2019

J Expo Sci Environ Epidemiol

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Exposure information is a critical element in various regulatory and non-regulatory frameworks in Europe and elsewhere. Exposure science supports to ensure safe environments, reduce human health risks, and foster a sustainable future. However, increasing diversity in regulations and the lack of a professional identity as exposure scientists currently hamper developing the field and uptake into European policy. In response, we discuss trends, and identify three key needs for advancing and harmonizing exposure science and its application in Europe. We provide overarching building blocks and define six long-term activities to address the identified key needs, and to iteratively improve guidelines, tools, data, and education. More specifically, we propose creating European networks to maximize synergies with adjacent fields and identify funding opportunities, building common exposure assessment approaches across regulations, providing tiered education and training programmes, developing an aligned and integrated exposure assessment framework, offering best practices guidance, and launching an exposure information exchange platform. Dedicated working groups will further specify these activities in a consistent action plan. Together, these elements form the foundation for establishing goals and an action roadmap for successfully developing and implementing a 'European Exposure Science Strategy' 2020-2030, which is aligned with advances in science and technology.

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“…Currently, REACH is one of the most comprehensive and updated online databases of physicochemical, human toxicity, and ecotoxicity information for chemicals. Using REACH as a potential data source in various policy and science fields has been widely discussed (Askham 2012;Luechtefeld et al 2016;Gustavsson et al 2017;Müller et al 2017;Saouter et al 2017aSaouter et al , 2017bSaouter et al , 2019aSaouter et al , 2019bFantke et al 2018). A common conclusion across studies is that data submitted under REACH require a careful curation (e.g., species name harmonization, unit checks) before they are used.…”

Section: Introductionmentioning

confidence: 99%

Extrapolation Factors for Characterizing Freshwater Ecotoxicity Effects

Aurisano

Albizzati

Hauschild

et al. 2019

Enviro Toxic and Chemistry

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Various environmental and chemical assessment frameworks including ecological risk assessment and life cycle impact assessment aim at evaluating long‐term ecotoxicity effects. Chronic test data are reported under the European Registration, Evaluation, Authorization and Restriction of Chemicals (REACH) regulation for various chemicals. However, chronic data are missing for a large fraction of marketed chemicals, for which acute test results are often available. Utilizing acute data requires robust extrapolation factors across effect endpoints, exposure durations, and species groups. We propose a decision tree based on strict criteria for curating and selecting high‐quality aquatic ecotoxicity information available in REACH for organic chemicals, to derive a consistent set of generic and species group–specific extrapolation factors. Where ecotoxicity effect data are not available at all, we alternatively provide extrapolations from octanol–water partitioning coefficients as suitable predictor for chemicals with nonpolar narcosis as mode of action. Extrapolation factors range from 0.2 to 7 and are higher when simultaneously extrapolating across effect endpoints and exposure durations. Our results are consistent with previously reported values, while considering more endpoints, providing species group–specific factors, and characterizing uncertainty. Our proposed decision tree can be adapted to curate information from additional data sources as well as data for other environments, such as sediment ecotoxicity. Our approach and robust extrapolation factors help to increase the substance coverage for characterizing ecotoxicity effects across chemical and environmental assessment frameworks. Environ Toxicol Chem 2019;38:2568–2582. © 2019 SETAC

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Toward harmonizing ecotoxicity characterization in life cycle impact assessment

Cited by 69 publications

References 86 publications

Towards integrating toxicity characterization into environmental studies: case study of bromine in soils

Towards integrating toxicity characterization into environmental studies: case study of bromine in soils

Building a European exposure science strategy

Extrapolation Factors for Characterizing Freshwater Ecotoxicity Effects

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