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Hauptverfasser: Vermeiren, Peter, De Marchi, Lilah, Charles, Sandrine, Muñoz, Cynthia C
Format: Artículo científico
Sprache:en
Veröffentlicht: Ecotoxicology and environmental safety 2025
Schlagworte:
Online-Zugang:https://pubmed.ncbi.nlm.nih.gov/41232494/
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author Vermeiren, Peter
De Marchi, Lilah
Charles, Sandrine
Muñoz, Cynthia C
author_facet Vermeiren, Peter
De Marchi, Lilah
Charles, Sandrine
Muñoz, Cynthia C
Vermeiren, Peter
De Marchi, Lilah
Charles, Sandrine
Muñoz, Cynthia C
collection PubMed - marine biology
contents Turtles as models for the maternal transfer of organic pollutants across reptile species, chemicals, and matrices. Vermeiren, Peter De Marchi, Lilah Charles, Sandrine Muñoz, Cynthia C Animals Turtles Female Environmental Monitoring Water Pollutants, Chemical Maternal Exposure Organic Chemicals Maternal offloading of chemicals presents a first exposure for embryos during a critical window of sensitive early life development. We aimed to develop reptile-specific models to quantify this offloading. We fitted statistical models to data from two turtles (Malaclemys terrapin, Chelydra serpentina), and tested their ability to predict concentrations of organic pollutants in eggs across reptiles (turtles, snakes, crocodiles); legacy and emerging pollutants; and tissues (including blood as a low-invasive biomonitoring matrix). Maternal pollutant transfer could be quantified for several turtle species with a close alignment between lipid-normalised pollutant concentrations in mother and offspring. Concentrations were, on average, slightly lower in eggs than in females with higher transfer at higher maternal burdens. Predictions worked well between M. terrapin and C. serpentina and towards snakes and alligators where models transferred well across muscle, liver, and blood, and across several organic pollutant classes with some class-specific differences. Meanwhile, predictions did not match observations in sea turtles. Our results underscore the suitability of turtles as models to study the maternal pollutant transfer process, and the role of fresh and brackish water turtles as surrogate species to bridge the data gap in reptile ecotoxicology. Nevertheless, our study highlighted species-specific differences in maternal pollutant transfer. This cautions against blind extrapolation across species, and urges research into underlying mechanisms. We provide scientific tools (including a web application) to quantitatively predict embryonic exposure through transgenerational pollutant offloading as a prerequisite to assess risks for embryo toxicity, or, in reverse, to trace back maternal exposure from egg biomonitoring.
format Artículo científico
id pubmed_41232494
institution PubMed
language en
publishDate 2025
publisher Ecotoxicology and environmental safety
record_format pubmed
spellingShingle Turtles as models for the maternal transfer of organic pollutants across reptile species, chemicals, and matrices.
Vermeiren, Peter
De Marchi, Lilah
Charles, Sandrine
Muñoz, Cynthia C
Animals
Turtles
Female
Environmental Monitoring
Water Pollutants, Chemical
Maternal Exposure
Organic Chemicals
Turtles as models for the maternal transfer of organic pollutants across reptile species, chemicals, and matrices. Vermeiren, Peter De Marchi, Lilah Charles, Sandrine Muñoz, Cynthia C Animals Turtles Female Environmental Monitoring Water Pollutants, Chemical Maternal Exposure Organic Chemicals Maternal offloading of chemicals presents a first exposure for embryos during a critical window of sensitive early life development. We aimed to develop reptile-specific models to quantify this offloading. We fitted statistical models to data from two turtles (Malaclemys terrapin, Chelydra serpentina), and tested their ability to predict concentrations of organic pollutants in eggs across reptiles (turtles, snakes, crocodiles); legacy and emerging pollutants; and tissues (including blood as a low-invasive biomonitoring matrix). Maternal pollutant transfer could be quantified for several turtle species with a close alignment between lipid-normalised pollutant concentrations in mother and offspring. Concentrations were, on average, slightly lower in eggs than in females with higher transfer at higher maternal burdens. Predictions worked well between M. terrapin and C. serpentina and towards snakes and alligators where models transferred well across muscle, liver, and blood, and across several organic pollutant classes with some class-specific differences. Meanwhile, predictions did not match observations in sea turtles. Our results underscore the suitability of turtles as models to study the maternal pollutant transfer process, and the role of fresh and brackish water turtles as surrogate species to bridge the data gap in reptile ecotoxicology. Nevertheless, our study highlighted species-specific differences in maternal pollutant transfer. This cautions against blind extrapolation across species, and urges research into underlying mechanisms. We provide scientific tools (including a web application) to quantitatively predict embryonic exposure through transgenerational pollutant offloading as a prerequisite to assess risks for embryo toxicity, or, in reverse, to trace back maternal exposure from egg biomonitoring.
title Turtles as models for the maternal transfer of organic pollutants across reptile species, chemicals, and matrices.
topic Animals
Turtles
Female
Environmental Monitoring
Water Pollutants, Chemical
Maternal Exposure
Organic Chemicals
url https://pubmed.ncbi.nlm.nih.gov/41232494/