2017
DOI: 10.1021/acs.est.7b01613
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An “EAR” on Environmental Surveillance and Monitoring: A Case Study on the Use of Exposure–Activity Ratios (EARs) to Prioritize Sites, Chemicals, and Bioactivities of Concern in Great Lakes Waters

Abstract: Current environmental monitoring approaches focus primarily on chemical occurrence. However, based on concentration alone, it can be difficult to identify which compounds may be of toxicological concern and should be prioritized for further monitoring, in-depth testing, or management. This can be problematic because toxicological characterization is lacking for many emerging contaminants. New sources of high-throughput screening (HTS) data, such as the ToxCast database, which contains information for over 9000… Show more

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Cited by 95 publications
(143 citation statements)
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“…4; Table S7) and median ( Figure S3; Table S8) exposure conditions support this conclusion. The in vitro ToxCast EAR approach informs the potential for sub-lethal effects at an observed concentration (Becker et al, 2015;Blackwell et al, 2017), provides probable effects screening consistent with traditional in vivo water-quality benchmark-based toxicity quotient (TQ) approaches (EAR = 0.001 comparable to commonly employed TQ = 0.1 effects threshold (Corsi et al, 2019)), and supports cumulative effects ( P EAR ) estimation (CA-model (Ankley et al, 2010;Conolly et al, 2017;Judson et al, 2014;Villeneuve et al, 2014)). Although sometimes restricted only to chemicals with a common mode of action, CApredicted toxicities typically agree with observed toxicities within a factor of 2-4, regardless of recognized mode of action (Belden et al, 2007;Boobis et al, 2011;Cedergreen et al, 2008;Ermler et al, 2011;Faust et al, 2003;Rodney et al, 2013;Thrupp et al, 2018;Warne, 2003;Zhang et al, 2011).…”
Section: Potential For Surface-water-contaminant Biological Effects Imentioning
confidence: 75%
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“…4; Table S7) and median ( Figure S3; Table S8) exposure conditions support this conclusion. The in vitro ToxCast EAR approach informs the potential for sub-lethal effects at an observed concentration (Becker et al, 2015;Blackwell et al, 2017), provides probable effects screening consistent with traditional in vivo water-quality benchmark-based toxicity quotient (TQ) approaches (EAR = 0.001 comparable to commonly employed TQ = 0.1 effects threshold (Corsi et al, 2019)), and supports cumulative effects ( P EAR ) estimation (CA-model (Ankley et al, 2010;Conolly et al, 2017;Judson et al, 2014;Villeneuve et al, 2014)). Although sometimes restricted only to chemicals with a common mode of action, CApredicted toxicities typically agree with observed toxicities within a factor of 2-4, regardless of recognized mode of action (Belden et al, 2007;Boobis et al, 2011;Cedergreen et al, 2008;Ermler et al, 2011;Faust et al, 2003;Rodney et al, 2013;Thrupp et al, 2018;Warne, 2003;Zhang et al, 2011).…”
Section: Potential For Surface-water-contaminant Biological Effects Imentioning
confidence: 75%
“…Table S3c contains median concentrations (all samples) by compound and site and only includes target analytes that were detected in at least half of the samples at one or more sites. Integrated effects of detected pesticide and pharmaceutical contaminants in water were estimated using the toxEval R-program (De Cicco et al, 2018) to sum (concentration addition (CA) model (Altenburger et al, 2013;Altenburger et al, 2012;Cedergreen et al, 2008;Ermler et al, 2011;Kortenkamp et al, 2009;Thrupp et al, 2018)) individual EAR (ratio of detected maximum or median concentration to activity concentration at cutoff (ACC) from Toxicity ForeCaster (ToxCast TM ; U.S. Environmental Protection Agency, 2019) high-throughput screening data (U.S. Environmental Protection Agency, 2018a, 2018b) to provide site-specific cumulative EAR ( P EAR ) (Becker et al, 2015;Blackwell et al, 2017;Li et al, 2017;Schroeder et al, 2016). EAR !…”
Section: Data Handling Statistics and P Ear Analysismentioning
confidence: 99%
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“…Data gaps in hazard assessment can be numerous in many cases which can lead to many uncertainties and sometimes can make accurate assessment impossible. In recent years, high‐throughput assay methods have been developed actively, and many of them have been used in large‐scale prioritization and evaluation on environmental mixtures, such as those research activities under the Great Lakes Restoration Initiative . However, low cost and high‐throughput assays or platforms for representative aquatic toxicity test organisms are often lacking.…”
Section: Discussionmentioning
confidence: 99%
“…Measurements from HTP assays often correspond to MIEs or early KEs (e.g., receptor activation, enzyme inhibition, etc. ), so it is possible to query/cross-reference knowledgebases such as the AOP Wiki to translate bioactivity data generated from complex mixtures into potential hazards in exposed organisms, such as fish [35,36]. The AOP framework also can serve as the basis for translating molecular/biochemical data from field-collected animals exposed to complex mixtures into endpoints useful for inferring hazard/risk [37].…”
Section: Case Example 4: Evaluating Hazards Of Complex Chemical Mixturesmentioning
confidence: 99%