Systematic assessment of the mechanisms and risks of micro- and nanoplastic particle exposure in marine invertebrates

Hara, Jenevieve; Vercauteren, Maaike; Janssen, Colin; Blust, Ronny; Asselman, Jana; Town, Raewyn M.

Systematic assessment of the mechanisms and risks of micro- and nanoplastic particle exposure in marine invertebrates

Jenevieve Hara (UGent) , Maaike Vercauteren (UGent) , Colin Janssen (UGent) , Ronny Blust, Jana Asselman (UGent) and Raewyn M. Town

(2026) ECOTOXICOLOGY AND ENVIRONMENTAL SAFETY. 311.

Author

Jenevieve Hara (UGent) , Maaike Vercauteren (UGent) , Colin Janssen (UGent) , Ronny Blust, Jana Asselman (UGent) and Raewyn M. Town

Organization

Department of Animal Sciences and Aquatic Ecology

Project

Towards ecological risk assessment of nanoplastics: dynamic considerations

Abstract

Marine invertebrates are among the most vulnerable organism groups to micro- and nanoplastic (MNP) exposure, yet understanding of their interspecies sensitivity and mechanistic responses remains limited. This study provides a systematic evaluation of MNP toxicity across diverse marine invertebrate taxa by (i) evaluating the effects of MNP exposure on key biological endpoints as a function of key particle characteristics, and (ii) constructing species sensitivity distributions (SSDs) to derive ecologically relevant hazard thresholds. Data were extracted from the Toxicity of Microplastic Explorer (ToMEx) for Aquatic Organisms database (version 2.0), with quality evaluated using the Technical and Risk Assessment “Red” Criteria framework to ensure the inclusion of essential experimental parameters. Chronic no-observed-effect concentration (NOEC) values, derived from mortality, fitness, and functional-related endpoints, were analyzed as a function of particle size (nanoplastics: <1 µm; microplastics: 1–5000 µm), shape (spherical vs. non-spherical), and exposure medium (water vs. sediment) to identify particle-specific toxicity trends. To translate reported biological effects into ecologically relevant risk estimates, SSDs were constructed using chronic fitness-related endpoints, accounting for two distinct exposure mechanisms: food dilution via ingestion and tissue translocation. Psedechinus huttoni (Echinoderm) emerged as the most sensitive, while Paracentrotus lividus (Echinoderm) were the least sensitive across both models. Preliminary Safe Standards (PSS), calculated using SSD-derived HC₅ values, offer provisional thresholds for protecting marine invertebrate communities. These findings provide insights into MNP toxicity and aid in identifying sensitive taxa and endpoints, while highlighting key knowledge gaps to advance risk assessment frameworks for MNPs in marine ecosystems.

Keywords

Micro- and nanoplastics, Marine Invertebrates, Biological Effects, Species sensitivity distributions, Risk assessment, SPECIES SENSITIVITY DISTRIBUTIONS, MICROPLASTICS, RECOMMENDATIONS, IMPACTS

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Citation

Please use this url to cite or link to this publication: http://hdl.handle.net/1854/LU-01KHGTGV6JK0P8RG8PZEZPC2FM

MLA: Hara, Jenevieve, et al. “Systematic Assessment of the Mechanisms and Risks of Micro- and Nanoplastic Particle Exposure in Marine Invertebrates.” ECOTOXICOLOGY AND ENVIRONMENTAL SAFETY, vol. 311, 2026, doi:10.1016/j.ecoenv.2026.119877.
APA: Hara, J., Vercauteren, M., Janssen, C., Blust, R., Asselman, J., & Town, R. M. (2026). Systematic assessment of the mechanisms and risks of micro- and nanoplastic particle exposure in marine invertebrates. ECOTOXICOLOGY AND ENVIRONMENTAL SAFETY, 311. https://doi.org/10.1016/j.ecoenv.2026.119877
Chicago author-date: Hara, Jenevieve, Maaike Vercauteren, Colin Janssen, Ronny Blust, Jana Asselman, and Raewyn M. Town. 2026. “Systematic Assessment of the Mechanisms and Risks of Micro- and Nanoplastic Particle Exposure in Marine Invertebrates.” ECOTOXICOLOGY AND ENVIRONMENTAL SAFETY 311. https://doi.org/10.1016/j.ecoenv.2026.119877.
Chicago author-date (all authors): Hara, Jenevieve, Maaike Vercauteren, Colin Janssen, Ronny Blust, Jana Asselman, and Raewyn M. Town. 2026. “Systematic Assessment of the Mechanisms and Risks of Micro- and Nanoplastic Particle Exposure in Marine Invertebrates.” ECOTOXICOLOGY AND ENVIRONMENTAL SAFETY 311. doi:10.1016/j.ecoenv.2026.119877.
Vancouver: 1.
Hara J, Vercauteren M, Janssen C, Blust R, Asselman J, Town RM. Systematic assessment of the mechanisms and risks of micro- and nanoplastic particle exposure in marine invertebrates. ECOTOXICOLOGY AND ENVIRONMENTAL SAFETY. 2026;311.
IEEE: [1]
J. Hara, M. Vercauteren, C. Janssen, R. Blust, J. Asselman, and R. M. Town, “Systematic assessment of the mechanisms and risks of micro- and nanoplastic particle exposure in marine invertebrates,” ECOTOXICOLOGY AND ENVIRONMENTAL SAFETY, vol. 311, 2026.

@article{01KHGTGV6JK0P8RG8PZEZPC2FM,
  abstract     = {{Marine invertebrates are among the most vulnerable organism groups to micro- and nanoplastic (MNP) exposure, yet understanding of their interspecies sensitivity and mechanistic responses remains limited. This study provides a systematic evaluation of MNP toxicity across diverse marine invertebrate taxa by (i) evaluating the effects of MNP exposure on key biological endpoints as a function of key particle characteristics, and (ii) constructing species sensitivity distributions (SSDs) to derive ecologically relevant hazard thresholds. Data were extracted from the Toxicity of Microplastic Explorer (ToMEx) for Aquatic Organisms database (version 2.0), with quality evaluated using the Technical and Risk Assessment “Red” Criteria framework to ensure the inclusion of essential experimental parameters. Chronic no-observed-effect concentration (NOEC) values, derived from mortality, fitness, and functional-related endpoints, were analyzed as a function of particle size (nanoplastics: <1 µm; microplastics: 1–5000 µm), shape (spherical vs. non-spherical), and exposure medium (water vs. sediment) to identify particle-specific toxicity trends. To translate reported biological effects into ecologically relevant risk estimates, SSDs were constructed using chronic fitness-related endpoints, accounting for two distinct exposure mechanisms: food dilution via ingestion and tissue translocation. Psedechinus huttoni (Echinoderm) emerged as the most sensitive, while Paracentrotus lividus (Echinoderm) were the least sensitive across both models. Preliminary Safe Standards (PSS), calculated using SSD-derived HC₅ values, offer provisional thresholds for protecting marine invertebrate communities. These findings provide insights into MNP toxicity and aid in identifying sensitive taxa and endpoints, while highlighting key knowledge gaps to advance risk assessment frameworks for MNPs in marine ecosystems.}},
  articleno    = {{119877}},
  author       = {{Hara, Jenevieve and Vercauteren, Maaike and Janssen, Colin and Blust, Ronny and Asselman, Jana and Town, Raewyn M.}},
  issn         = {{0147-6513}},
  journal      = {{ECOTOXICOLOGY AND ENVIRONMENTAL SAFETY}},
  keywords     = {{Micro- and nanoplastics,Marine Invertebrates,Biological Effects,Species sensitivity distributions,Risk assessment,SPECIES SENSITIVITY DISTRIBUTIONS,MICROPLASTICS,RECOMMENDATIONS,IMPACTS}},
  language     = {{eng}},
  pages        = {{13}},
  title        = {{Systematic assessment of the mechanisms and risks of micro- and nanoplastic particle exposure in marine invertebrates}},
  url          = {{http://doi.org/10.1016/j.ecoenv.2026.119877}},
  volume       = {{311}},
  year         = {{2026}},
}

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Systematic assessment of the mechanisms and risks of micro- and nanoplastic particle exposure in marine invertebrates

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