Using field data to quantify chemical impacts on wildlife population viability

Hilbers, Jelle P.; Hoondert, R.P.J.; Schipper, Aafke M.; Huijbregts, Mark A. J.

doi:10.1002/eap.1685

Cited by 7 publications

(3 citation statements)

References 79 publications

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“…Fifth, we assumed that

r (C) / r (0)

is proportional to

K (C) / K (0)

. Although many studies report relative changes in intrinsic growth rate (

r (C) / r (0))

to be proportional to those in carrying capacity

K (C) / K (0)

; Hakoyama et al 2000; Nakamaru et al 2003; Hendriks et al 2005; Hilbers et al 2018), there are also studies arguing against such a relationship (e.g., Bell 1990; Underwood 2006). Sixth, the calculations also disregard ecologically relevant processes like interspecies interactions (e.g., competition), which may lead to an underestimation of the impact of chemical stressors on a community level (de Laender et al 2008).…”

Section: Discussionmentioning

confidence: 99%

Mean Species Abundance as a Measure of Ecotoxicological Risk

Hoeks

Huijbregts

Douziech

et al. 2020

Enviro Toxic and Chemistry

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Chemical pollution of surface waters is considered an important driver for recent declines in biodiversity. Species sensitivity distributions (SSDs) are commonly used to evaluate the ecological risks of chemical exposure, accounting for variation in interspecies sensitivity. However, SSDs do not reflect the effects of chemical exposure on species abundance, considered an important endpoint in biological conservation. Although complex population modeling approaches lack practical applicability when it comes to the routine practice of lower tier chemical risk assessment, in the present study we show how information from widely available laboratory toxicity tests can be used to derive the change in mean species abundance (MSA) as a function of chemical exposure. These exposure-response MSA relationships combine insights into intraspecies exposure-response relationships and population growth theory. We showcase the practical applicability of our method for cadmium, copper, and zinc, and include a quantification of the associated statistical uncertainty. For all 3 metals, we found that concentrations hazardous for 5% of the species (HC 5 s) based on MSA relationships are systematically higher than SSD-based HC 5 values. Our proposed framework can be useful to derive abundance-based ecological protective criteria for chemical exposure, and creates the opportunity to assess abundance impacts of chemical exposure in the context of various other anthropogenic stressors.

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“…Fifth, we assumed that

r (C) / r (0)

is proportional to

K (C) / K (0)

. Although many studies report relative changes in intrinsic growth rate (

r (C) / r (0))

to be proportional to those in carrying capacity

K (C) / K (0)

Section: Discussionmentioning

confidence: 99%

Mean Species Abundance as a Measure of Ecotoxicological Risk

Hoeks

Huijbregts

Douziech

et al. 2020

Enviro Toxic and Chemistry

View full text Add to dashboard Cite

show abstract

“…In quantile regression, the response can represent any part of its probability distribution . Quantile regression is especially powerful for filtering out confounding factors in noisy explanatory data that obscure the true response and has been successfully applied to link exposure–response curves, for example, for pollution. − If the response is limited by confounding factors, quantile regression based on one of the upper boundaries of its probability distribution (e.g., the 95th percentile) is expected to reflect the response’s relationship to the corresponding explanatory variable . Conversely, one of the lower boundaries (e.g., the 5th percentile) reflects a relevant relationship if confounding factors boost the response.…”

Section: Methodsmentioning

confidence: 99%

What Is the Impact of Accidentally Transporting Terrestrial Alien Species? A New Life Cycle Impact Assessment Model

Borgelt,

Dorber,

Géron

et al. 2024

Environ. Sci. Technol.

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Alien species form one of the main threats to global biodiversity. Although Life Cycle Assessment attempts to holistically assess environmental impacts of products and services across value chains, ecological impacts of the introduction of alien species are so far not assessed in Life Cycle Impact Assessment. Here, we developed country-to-country-specific characterization factors, expressed as the time-integrated potentially disappeared fraction (PDF; regional and global) of native terrestrial species due to alien species introductions per unit of goods transported [kg] between two countries. The characterization factors were generated by analyzing global data on first records of alien species, native species distributions, and their threat status, as well as bilateral trade partnerships from 1870–2019. The resulting characterization factors vary over several orders of magnitude, indicating that impact greatly varies per transportation route and trading partner. We showcase the applicability and relevance of the characterization factors for transporting 1 metric ton of freight to France from China, South Africa, and Madagascar. The results suggest that the introduction of alien species can be more damaging for terrestrial biodiversity as climate change impacts during the international transport of commodities.

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“…Increased computational power and agreement on probabilistic risk paradigms allowed regional scale assessments to emerge (Solomon et al 1996Purucker et al 2007). Recent models may incorporate more refined predictions of exposures and effects across landscapes (Schmolke et al 2010;Dixon 2012;Bartell et al 2013;Kohler and Triebskorn 2013;Van den Brink 2013;Wang 2013;Focks et al 2014;Topping et al 2015;Dohmen et al 2016;Hilbers et al 2018). These approaches allow prediction of population exposures to pesticides and resultant responses without having to conduct painstaking multiyear field assessments of population dynamics.…”

Section: Examples Of Higher Tier Effects and Exposure Refinements Formentioning

confidence: 99%

Overcoming Challenges of Incorporating Higher Tier Data in Ecological Risk Assessments and Risk Management of Pesticides in the United States: Findings and Recommendations from the 2017 Workshop on Regulation and Innovation in Agriculture

Levine

Giddings²,

Valenti

et al. 2019

Integr Envir Assess & Manag

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Pesticide regulation requires regulatory authorities to assess the potential ecological risk of pesticides submitted for registration, and most risk assessment schemes use a tiered testing and assessment approach. Standardized ecotoxicity tests, environmental fate studies, and exposure models are used at lower tiers and follow well‐defined methods for assessing risk. If a lower tier assessment indicates that the pesticide may pose an ecological risk, higher tier studies using more environmentally realistic conditions or assumptions can be performed to refine the risk assessment and inform risk management options. However, there is limited guidance in the United States on options to refine an assessment and how the data will be incorporated into the risk assessment and risk management processes. To overcome challenges to incorporation of higher tier data into ecological risk assessments and risk management of pesticides, a workshop was held in Raleigh, North Carolina. Attendees included representatives from the United States Environmental Protection Agency, United States Department of Agriculture, National Oceanic and Atmospheric Administration, universities, commodity groups, consultants, nonprofit organizations, and the crop protection industry. Key recommendations emphasized the need for 1) more effective, timely, open communication among registrants, risk assessors, and risk managers earlier in the registration process to identify specific protection goals, address areas of potential concern where higher tier studies or assessments may be required, and if a higher tier study is necessary that there is agreement on study design; 2) minimizing the complexity of study designs while retaining high value to the risk assessment and risk management process; 3) greater transparency regarding critical factors utilized in risk management decisions with clearly defined protection goals that are operational; and 4) retrospective analyses of success–failure learnings on the acceptability of higher tier studies to help inform registrants on how to improve the application of such studies to risk assessments and the risk management process. Integr Environ Assess Manag 2019;15:714–725. © 2019 The Authors. Integrated Environmental Assessment and Management published by Wiley Periodicals, Inc. on behalf of Society of Environmental Toxicology & Chemistry (SETAC).

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Using field data to quantify chemical impacts on wildlife population viability

Cited by 7 publications

References 79 publications

Mean Species Abundance as a Measure of Ecotoxicological Risk

Mean Species Abundance as a Measure of Ecotoxicological Risk

What Is the Impact of Accidentally Transporting Terrestrial Alien Species? A New Life Cycle Impact Assessment Model

Overcoming Challenges of Incorporating Higher Tier Data in Ecological Risk Assessments and Risk Management of Pesticides in the United States: Findings and Recommendations from the 2017 Workshop on Regulation and Innovation in Agriculture

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