Seabed microplastics in the European continental shelf: Unravelling physical and biological transport pathways and reciprocal fauna–Polymer relationships

Marine sediments are recognized as major sinks for microplastics, including remote areas which were previously considered “plastic-free”. The understanding of microplastic dynamics in marine sediments is however limited due to the numerous pelagic and benthic pathways involved, and how these are inf...

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Veröffentlicht in:	Environmental pollution (1987) 2025-01, Vol.365, p.125392, Article 125392
Hauptverfasser:	Pantó, G., Vanreusel, A., Vercauteren, M., Asselman, J., Van Colen, C.
Format:	Artikel
Sprache:	eng
Schlagworte:	Animals Aquatic Organisms benthic organisms Biological Transport continental shelf detritus Ecosystem Environmental Monitoring Europe fauna Geologic Sediments - chemistry ingestion marine ecosystems microalgae microplastics Microplastics - analysis physiological transport Plastics - analysis pollution Polymers riparian areas risk salinity seawater Seawater - chemistry sediments temperature Water Pollutants, Chemical - analysis
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container_title	Environmental pollution (1987)
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creator	Pantó, G. Vanreusel, A. Vercauteren, M. Asselman, J. Van Colen, C.
description	Marine sediments are recognized as major sinks for microplastics, including remote areas which were previously considered “plastic-free”. The understanding of microplastic dynamics in marine sediments is however limited due to the numerous pelagic and benthic pathways involved, and how these are influenced by physico-chemical interactions with the particles. European continental shelves border densely populated areas and face a high risk of microplastic contamination. In this study we quantified microplastics in soft-sediments of European coastal seas and characterized their polymer composition separating surface sediments from deeper layers. We then analyzed the influence of water column and sediment properties on spatial variability of seabed microplastics and investigated the relationship with macrofauna communities. A higher proportion of negatively buoyant polymers in surface sediments (0–1 cm) across stations was explained by seawater salinity and sediment microalgal detritus, highlighting the role of riverine input and possibly the formation of hetero-aggregates in defining polymer deposition. Additionally, we found that seawater temperature influenced polymer composition in deeper sediment layers (0–3 cm), likely together with biological activities performed by macrobenthos such as ingestion and burial. Finally, we demonstrate that seabed microplastics contribute to the spatial variability in macrobenthos, highlighting that marine ecosystem functioning effects of microplastic pollution are likely mediated via the benthos. [Display omitted] •River proximity and polymer density explain spatial variability in microplastics•Phytodetritus aggregates can influence polymer composition in shelf sediments•Seabed microplastics partly explain spatial distribution of shelf benthos
doi_str_mv	10.1016/j.envpol.2024.125392
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The understanding of microplastic dynamics in marine sediments is however limited due to the numerous pelagic and benthic pathways involved, and how these are influenced by physico-chemical interactions with the particles. European continental shelves border densely populated areas and face a high risk of microplastic contamination. In this study we quantified microplastics in soft-sediments of European coastal seas and characterized their polymer composition separating surface sediments from deeper layers. We then analyzed the influence of water column and sediment properties on spatial variability of seabed microplastics and investigated the relationship with macrofauna communities. A higher proportion of negatively buoyant polymers in surface sediments (0–1 cm) across stations was explained by seawater salinity and sediment microalgal detritus, highlighting the role of riverine input and possibly the formation of hetero-aggregates in defining polymer deposition. Additionally, we found that seawater temperature influenced polymer composition in deeper sediment layers (0–3 cm), likely together with biological activities performed by macrobenthos such as ingestion and burial. Finally, we demonstrate that seabed microplastics contribute to the spatial variability in macrobenthos, highlighting that marine ecosystem functioning effects of microplastic pollution are likely mediated via the benthos. 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The understanding of microplastic dynamics in marine sediments is however limited due to the numerous pelagic and benthic pathways involved, and how these are influenced by physico-chemical interactions with the particles. European continental shelves border densely populated areas and face a high risk of microplastic contamination. In this study we quantified microplastics in soft-sediments of European coastal seas and characterized their polymer composition separating surface sediments from deeper layers. We then analyzed the influence of water column and sediment properties on spatial variability of seabed microplastics and investigated the relationship with macrofauna communities. A higher proportion of negatively buoyant polymers in surface sediments (0–1 cm) across stations was explained by seawater salinity and sediment microalgal detritus, highlighting the role of riverine input and possibly the formation of hetero-aggregates in defining polymer deposition. Additionally, we found that seawater temperature influenced polymer composition in deeper sediment layers (0–3 cm), likely together with biological activities performed by macrobenthos such as ingestion and burial. Finally, we demonstrate that seabed microplastics contribute to the spatial variability in macrobenthos, highlighting that marine ecosystem functioning effects of microplastic pollution are likely mediated via the benthos. 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source	MEDLINE; Elsevier ScienceDirect Journals
subjects	Animals Aquatic Organisms benthic organisms Biological Transport continental shelf detritus Ecosystem Environmental Monitoring Europe fauna Geologic Sediments - chemistry ingestion marine ecosystems microalgae microplastics Microplastics - analysis physiological transport Plastics - analysis pollution Polymers riparian areas risk salinity seawater Seawater - chemistry sediments temperature Water Pollutants, Chemical - analysis
title	Seabed microplastics in the European continental shelf: Unravelling physical and biological transport pathways and reciprocal fauna–Polymer relationships
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