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Main Authors: Rigatou, Dionysia, Gerakaris, Vasilis, Digka, Nikoletta, Adamopoulou, Argyro, Patsiou, Danae, Hatzonikolakis, Yannis, Tsiaras, Kostas, Tsangaris, Catherine, Zeri, Christina, Kaberi, Helen, Raitsos, Dionysios E
Format: Artículo científico
Language:en
Published: Marine pollution bulletin 2025
Subjects:
Online Access:https://pubmed.ncbi.nlm.nih.gov/39689653/
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author Rigatou, Dionysia
Gerakaris, Vasilis
Digka, Nikoletta
Adamopoulou, Argyro
Patsiou, Danae
Hatzonikolakis, Yannis
Tsiaras, Kostas
Tsangaris, Catherine
Zeri, Christina
Kaberi, Helen
Raitsos, Dionysios E
author_facet Rigatou, Dionysia
Gerakaris, Vasilis
Digka, Nikoletta
Adamopoulou, Argyro
Patsiou, Danae
Hatzonikolakis, Yannis
Tsiaras, Kostas
Tsangaris, Catherine
Zeri, Christina
Kaberi, Helen
Raitsos, Dionysios E
Rigatou, Dionysia
Gerakaris, Vasilis
Digka, Nikoletta
Adamopoulou, Argyro
Patsiou, Danae
Hatzonikolakis, Yannis
Tsiaras, Kostas
Tsangaris, Catherine
Zeri, Christina
Kaberi, Helen
Raitsos, Dionysios E
collection PubMed - marine biology
contents The role of seagrass meadows (Posidonia oceanica) as microplastics sink and vector to benthic food webs. Rigatou, Dionysia Gerakaris, Vasilis Digka, Nikoletta Adamopoulou, Argyro Patsiou, Danae Hatzonikolakis, Yannis Tsiaras, Kostas Tsangaris, Catherine Zeri, Christina Kaberi, Helen Raitsos, Dionysios E Alismatales Food Chain Microplastics Water Pollutants, Chemical Environmental Monitoring Ecosystem Geologic Sediments Plant Leaves Plastic pollution in marine environments is of global concern, yet its distribution within seagrasses remains poorly understood. We explore the efficiency of Posidonia oceanica in trapping microplastics (MPs) across various components (leaves, rhizomes, sediment), examine their potential transfer through the food web and assess their dispersal using advanced modelling techniques. Field surveys confirm that P. oceanica traps MPs across all components, with the often-overlooked rhizomes accumulating over twice as many MPs (0.2 ± 0.41 items/rhizome) as leaves (0.08 ± 0.28 items/leaf). MP abundance is lower in vegetated sediments than in the adjacent unvegetated seabed (15 ± 1.9 vs. 49 items kg dry weight, respectively). While individual meadow's substrates exhibit low MP levels, the overall concentration increases substantially when accounting for its multi-dimensional structure. Species-specific traits, such as leaf height, and local hydrodynamic processes are likely influencing MPs spatiotemporal distribution. The elevated risk of MPs ingestion by seagrass-associated grazers cannot be confirmed, but further investigation is necessary. This study highlights the effectiveness of a holistic approach in assessing MP pollution within seagrass ecosystems, emphasizing its importance as the way forward.
format Artículo científico
id pubmed_39689653
institution PubMed
language en
publishDate 2025
publisher Marine pollution bulletin
record_format pubmed
spellingShingle The role of seagrass meadows (Posidonia oceanica) as microplastics sink and vector to benthic food webs.
Rigatou, Dionysia
Gerakaris, Vasilis
Digka, Nikoletta
Adamopoulou, Argyro
Patsiou, Danae
Hatzonikolakis, Yannis
Tsiaras, Kostas
Tsangaris, Catherine
Zeri, Christina
Kaberi, Helen
Raitsos, Dionysios E
Alismatales
Food Chain
Microplastics
Water Pollutants, Chemical
Environmental Monitoring
Ecosystem
Geologic Sediments
Plant Leaves
The role of seagrass meadows (Posidonia oceanica) as microplastics sink and vector to benthic food webs. Rigatou, Dionysia Gerakaris, Vasilis Digka, Nikoletta Adamopoulou, Argyro Patsiou, Danae Hatzonikolakis, Yannis Tsiaras, Kostas Tsangaris, Catherine Zeri, Christina Kaberi, Helen Raitsos, Dionysios E Alismatales Food Chain Microplastics Water Pollutants, Chemical Environmental Monitoring Ecosystem Geologic Sediments Plant Leaves Plastic pollution in marine environments is of global concern, yet its distribution within seagrasses remains poorly understood. We explore the efficiency of Posidonia oceanica in trapping microplastics (MPs) across various components (leaves, rhizomes, sediment), examine their potential transfer through the food web and assess their dispersal using advanced modelling techniques. Field surveys confirm that P. oceanica traps MPs across all components, with the often-overlooked rhizomes accumulating over twice as many MPs (0.2 ± 0.41 items/rhizome) as leaves (0.08 ± 0.28 items/leaf). MP abundance is lower in vegetated sediments than in the adjacent unvegetated seabed (15 ± 1.9 vs. 49 items kg dry weight, respectively). While individual meadow's substrates exhibit low MP levels, the overall concentration increases substantially when accounting for its multi-dimensional structure. Species-specific traits, such as leaf height, and local hydrodynamic processes are likely influencing MPs spatiotemporal distribution. The elevated risk of MPs ingestion by seagrass-associated grazers cannot be confirmed, but further investigation is necessary. This study highlights the effectiveness of a holistic approach in assessing MP pollution within seagrass ecosystems, emphasizing its importance as the way forward.
title The role of seagrass meadows (Posidonia oceanica) as microplastics sink and vector to benthic food webs.
topic Alismatales
Food Chain
Microplastics
Water Pollutants, Chemical
Environmental Monitoring
Ecosystem
Geologic Sediments
Plant Leaves
url https://pubmed.ncbi.nlm.nih.gov/39689653/