Effect-Directed Analysis of Ah Receptor-Mediated Potencies in Microplastics Deployed in a Remote Tropical Marine Environment

Schönlau, Christine; Larsson, Maria; Dubocq, Florian; Rotander, Anna; Zande, Rene M. van der; Engwall, Magnus; Kärrman, Anna

doi:10.3389/fenvs.2019.00120

Cited by 8 publications

(5 citation statements)

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“…Our findings highlight that degrading and largely additive-free pre-production polymers have the potential to induce adverse effects on whole organisms, particularly PE; however, stronger adverse effects were observed if the polymers contained additives or other chemicals. As a future step, advanced chemical analytical tools, e.g., effect-directed analysis combined with non-target screening, would be necessary to resolve the chemicals causing these effects [44,45]. Therefore, the application of effect-based tools provides a reliable strategy to assess potential environmental risks from potentially hazardous materials like plastics.…”

Section: Discussionmentioning

confidence: 99%

Effects of leachates from UV-weathered microplastic on the microalgae Scenedesmus vacuolatus

et al. 2021

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Plastics undergo successive fragmentation and chemical leaching steps in the environment due to weathering processes such as photo-oxidation. Here, we report the effects of leachates from UV-irradiated microplastics towards the chlorophyte Scenedesmus vacuolatus. The microplastics tested were derived from an additive-containing electronic waste (EW) and a computer keyboard (KB) as well as commercial virgin polymers with low additive content, including polyethylene (PE), polyethylene terephthalate (PET), polypropylene (PP), and polystyrene (PS). Whereas leachates from additive-containing EW and KB induced severe effects, the leachates from virgin PET, PP, and PS did not show substantial adverse effects in our autotrophic test system. Leachates from PE reduced algae biomass, cell growth, and photosynthetic activity. Experimental data were consistent with predicted effect concentrations based on the ionization-corrected liposome/water distribution ratios (Dlip/w) of polymer degradation products of PE (mono- and dicarboxylic acids), indicating that leachates from weathering PE were mainly baseline toxic. This study provides insight into algae toxicity elicited by leachates from UV-weathered microplastics of different origin, complementing the current particle- vs. chemical-focused research towards the toxicity of plastics and their leachates. Graphical abstract

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Section: Discussionmentioning

confidence: 99%

Effects of leachates from UV-weathered microplastic on the microalgae Scenedesmus vacuolatus

et al. 2021

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“…In step-wise approaches, the complexity of the sample is reduced and candidates for an observed toxic effect are attempted to be identified. These approaches have been applied to plastics to a limited extent (Schönlau et al 2019) and offer possibilities of addressing toxicity and chemical identification in a complex setting. Additionally, new effects monitoring tools can be used to determine contaminant burdens across species.…”

Section: Longmentioning

confidence: 99%

Plastics as a carrier of chemical additives to the Arctic: possibilities for strategic monitoring across the circumpolar North

et al. 2023

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Plastic pollution (including microplastics) has been reported in a variety of biotic and abiotic compartments across the circumpolar Arctic. Due to their environmental ubiquity, there is a need to understand not only the fate and transport of physical plastic particles, but also the fate and transport of additive chemicals associated with plastic pollution. Further, there is a fundamental research gap in understanding long-range transport of chemical additives to the Arctic via plastics as well as their behavior under environmentally relevant, Arctic conditions. Here, we comment on the state of the science of plastic as carriers of chemical additives to the Arctic, and highlight research priorities going forward. We suggest further research on the transport pathways of chemical additives via plastics from both distant and local sources and laboratory experiments to investigate chemical behavior of plastic additives under Arctic conditions, including leaching, uptake, and bioaccumulation. Ultimately, chemical additives need to be included in strategic monitoring efforts to fully understand the contaminant burden of plastic pollution in Arctic ecosystems.

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Section: Introductionmentioning

confidence: 99%

“…Microplastics are a contaminant of emerging concern in freshwater ecosystems (Lambert and Wagner 2018;Rochman and Hoellein 2020). They can cause a range of adverse effects in freshwater biota at multiple levels of biological organization, due in part to their inherent complexity (e.g., size, polymer, morphology) (Rochman et al 2019;Bucci et al 2020). Studies that investigate microplastics as a single stressor (e.g., Li et al 2024;Malinowski et al 2023;Schür et al 2023) have demonstrated that microplastics are impacting freshwater ecosystems.…”

Section: Introductionmentioning

confidence: 99%

“…Microplastics as a physical and chemical stressor Microplastics (<5 mm; Arthur et al 2009) are inherently complex, varying in toxicity across physical and chemical characteristics (Rochman et al 2019), whose nature and interactions remain misunderstood. While it has become clear that certain morphologies, sizes, polymer types, and additives may lead to varying effects (Zimmermann et al 2020;Strungaru et al 2019;Bucci et al 2020;da Costa et al 2023), most studies do not design experiments to evaluate these characteristics in combination; thus, failing to consider the inherent complexity of microplastics.…”

Section: Introductionmentioning

confidence: 99%

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Freshwater systems in the Anthropocene: why we need to evaluate microplastics in the context of multiple stressors

Giles,

Hamilton

2024

F1000Res

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Microplastics are a diverse contaminant with complex physical and chemical properties. While microplastics have varying effects, most studies to date have focused on evaluating microplastics as a single stressor under stable environmental conditions. In reality, organisms are exposed to more than microplastics, and thus, it will be increasingly important to evaluate the effects of microplastics in the context of multiple anthropogenic stressors. Here, we highlight the need to assess the physical and chemical effects of microplastics, as well as their interactions with other anthropogenic stressors, at multiple levels of biological organization (i.e., sub-organismal, individual, population, community, ecosystem). We also outline research priorities and recommendations that will facilitate ecotoxicological assessments to better encompass the multidimensionality of microplastics as environmental conditions continue to change. By taking a multi-stressor ecotoxicological approach, we can work toward a better understanding of microplastic and other stressor effects at multiple levels of biological organization to help inform robust, evidenced-based policy and management decisions.

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Effect-Directed Analysis of Ah Receptor-Mediated Potencies in Microplastics Deployed in a Remote Tropical Marine Environment

Cited by 8 publications

References 50 publications

Effects of leachates from UV-weathered microplastic on the microalgae Scenedesmus vacuolatus

Effects of leachates from UV-weathered microplastic on the microalgae Scenedesmus vacuolatus

Plastics as a carrier of chemical additives to the Arctic: possibilities for strategic monitoring across the circumpolar North

Freshwater systems in the Anthropocene: why we need to evaluate microplastics in the context of multiple stressors

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