Your search keyword '"Cassone, Anne-Laure"' showing total 6 results

1. Microplastic bacterial communities in the Bay of Brest: Influence of polymer type and size

Author

Frere, Laura, Maignien, Lois, Chalopin, Morgane, Huvet, Arnaud, Rinnert, Emmanuel, Morrison, Hilary, Kerninon, Sandrine, Cassone, Anne-laure, Lambert, Christophe, Reveillaud, Julie, Paul-pont, Ika, Frere, Laura, Maignien, Lois, Chalopin, Morgane, Huvet, Arnaud, Rinnert, Emmanuel, Morrison, Hilary, Kerninon, Sandrine, Cassone, Anne-laure, Lambert, Christophe, Reveillaud, Julie, and Paul-pont, Ika

Abstract

Microplastics (<5 mm) exhibit intrinsic features such as density, hydrophobic surface, or high surface/volume ratio, that are known to promote microbial colonization and biofilm formation in marine ecosystems. Yet, a relatively low number of studies have investigated the nature of microplastic associated bacterial communities in coastal ecosystems and the potential factors influencing their composition and structure. Here, we characterized microplastics collected in the Bay of Brest by manual sorting followed by Raman spectroscopy and studied their associated bacterial assemblages using 16S amplicon high-throughput sequencing. Our methodology allowed discriminating polymer type (polyethylene, polypropylene and polystyrene) within small size ranges (0.3–1 vs. 1–2 vs. 2–5 mm) of microplastics collected. Data showed high species richness and diversity on microplastics compared to surrounding seawater samples encompassing both free living and particle attached bacteria. Even though a high proportion of operational taxonomic units (OTU; 94 ± 4%) was shared among all plastic polymers, polystyrene fragments exhibited distinct bacterial assemblages as compared to polyethylene and polypropylene samples. No effect of microplastic size was revealed regardless of polymer type, site and date of collection. The Vibrio genus was commonly detected in the microplastic fraction and specific PCR were performed to determine the presence of potentially pathogenic Vibrio strains (namely V. aestuarianus and the V. splendidus polyphyletic group). V. splendidus related species harboring putative oyster pathogens were detected on most microplastic pools (77%) emphasizing the need of further research to understand the role of microplastics on pathogen population transport and ultimate disease emergence.

Published

2018

2. Microplastic bacterial communities in the Bay of Brest: Influence of polymer type and size

Author

Frere, Laura, Maignien, Lois, Chalopin, Morgane, Huvet, Arnaud, Rinnert, Emmanuel, Morrison, Hilary, Kerninon, Sandrine, Cassone, Anne-laure, Lambert, Christophe, Reveillaud, Julie, Paul-pont, Ika, Frere, Laura, Maignien, Lois, Chalopin, Morgane, Huvet, Arnaud, Rinnert, Emmanuel, Morrison, Hilary, Kerninon, Sandrine, Cassone, Anne-laure, Lambert, Christophe, Reveillaud, Julie, and Paul-pont, Ika

Abstract

Microplastics (<5 mm) exhibit intrinsic features such as density, hydrophobic surface, or high surface/volume ratio, that are known to promote microbial colonization and biofilm formation in marine ecosystems. Yet, a relatively low number of studies have investigated the nature of microplastic associated bacterial communities in coastal ecosystems and the potential factors influencing their composition and structure. Here, we characterized microplastics collected in the Bay of Brest by manual sorting followed by Raman spectroscopy and studied their associated bacterial assemblages using 16S amplicon high-throughput sequencing. Our methodology allowed discriminating polymer type (polyethylene, polypropylene and polystyrene) within small size ranges (0.3–1 vs. 1–2 vs. 2–5 mm) of microplastics collected. Data showed high species richness and diversity on microplastics compared to surrounding seawater samples encompassing both free living and particle attached bacteria. Even though a high proportion of operational taxonomic units (OTU; 94 ± 4%) was shared among all plastic polymers, polystyrene fragments exhibited distinct bacterial assemblages as compared to polyethylene and polypropylene samples. No effect of microplastic size was revealed regardless of polymer type, site and date of collection. The Vibrio genus was commonly detected in the microplastic fraction and specific PCR were performed to determine the presence of potentially pathogenic Vibrio strains (namely V. aestuarianus and the V. splendidus polyphyletic group). V. splendidus related species harboring putative oyster pathogens were detected on most microplastic pools (77%) emphasizing the need of further research to understand the role of microplastics on pathogen population transport and ultimate disease emergence.

Published

2018

3. Microplastic bacterial communities in the Bay of Brest: Influence of polymer type and size

Author

Frere, Laura, Maignien, Lois, Chalopin, Morgane, Huvet, Arnaud, Rinnert, Emmanuel, Morrison, Hilary, Kerninon, Sandrine, Cassone, Anne-laure, Lambert, Christophe, Reveillaud, Julie, Paul-pont, Ika, Frere, Laura, Maignien, Lois, Chalopin, Morgane, Huvet, Arnaud, Rinnert, Emmanuel, Morrison, Hilary, Kerninon, Sandrine, Cassone, Anne-laure, Lambert, Christophe, Reveillaud, Julie, and Paul-pont, Ika

Abstract

Microplastics (<5 mm) exhibit intrinsic features such as density, hydrophobic surface, or high surface/volume ratio, that are known to promote microbial colonization and biofilm formation in marine ecosystems. Yet, a relatively low number of studies have investigated the nature of microplastic associated bacterial communities in coastal ecosystems and the potential factors influencing their composition and structure. Here, we characterized microplastics collected in the Bay of Brest by manual sorting followed by Raman spectroscopy and studied their associated bacterial assemblages using 16S amplicon high-throughput sequencing. Our methodology allowed discriminating polymer type (polyethylene, polypropylene and polystyrene) within small size ranges (0.3–1 vs. 1–2 vs. 2–5 mm) of microplastics collected. Data showed high species richness and diversity on microplastics compared to surrounding seawater samples encompassing both free living and particle attached bacteria. Even though a high proportion of operational taxonomic units (OTU; 94 ± 4%) was shared among all plastic polymers, polystyrene fragments exhibited distinct bacterial assemblages as compared to polyethylene and polypropylene samples. No effect of microplastic size was revealed regardless of polymer type, site and date of collection. The Vibrio genus was commonly detected in the microplastic fraction and specific PCR were performed to determine the presence of potentially pathogenic Vibrio strains (namely V. aestuarianus and the V. splendidus polyphyletic group). V. splendidus related species harboring putative oyster pathogens were detected on most microplastic pools (77%) emphasizing the need of further research to understand the role of microplastics on pathogen population transport and ultimate disease emergence.

Published

2018

4. Microplastics in seafood: Benchmark protocol for their extraction and characterization

Author

Dehaut, Alexandre, Cassone, Anne-laure, Frere, Laura, Hermabessiere, Ludovic, Himber, Charlotte, Rinnert, Emmanuel, Riviere, Gilles, Lambert, Christophe, Soudant, Philippe, Huvet, Arnaud, Duflos, Guillaume, Paul-pont, Ika, Dehaut, Alexandre, Cassone, Anne-laure, Frere, Laura, Hermabessiere, Ludovic, Himber, Charlotte, Rinnert, Emmanuel, Riviere, Gilles, Lambert, Christophe, Soudant, Philippe, Huvet, Arnaud, Duflos, Guillaume, and Paul-pont, Ika

Abstract

Pollution of the oceans by microplastics (<5 mm) represents a major environmental problem. To date, a limited number of studies have investigated the level of contamination of marine organisms collected in situ. For extraction and characterization of microplastics in biological samples, the crucial step is the identification of solvent(s) or chemical(s) that efficiently dissolve organic matter without degrading plastic polymers for their identification in a time and cost effective way. Most published papers, as well as OSPAR recommendations for the development of a common monitoring protocol for plastic particles in fish and shellfish at the European level, use protocols containing nitric acid to digest the biological tissues, despite reports of polyamide degradation with this chemical. In the present study, six existing approaches were tested and their effects were compared on up to 15 different plastic polymers, as well as their efficiency in digesting biological matrices. Plastic integrity was evaluated through microscopic inspection, weighing, pyrolysis coupled with gas chromatography and mass spectrometry, and Raman spectrometry before and after digestion. Tissues from mussels, crabs and fish were digested before being filtered on glass fibre filters. Digestion efficiency was evaluated through microscopical inspection of the filters and determination of the relative removal of organic matter content after digestion. Five out of the six tested protocols led to significant degradation of plastic particles and/or insufficient tissue digestion. The protocol using a KOH 10% solution and incubation at 60 °C during a 24 h period led to an efficient digestion of biological tissues with no significant degradation on all tested polymers, except for cellulose acetate. This protocol appeared to be the best compromise for extraction and later identification of microplastics in biological samples and should be implemented in further monitoring studies to ensure relevance and

Published

2016

5. Microplastics in seafood: Benchmark protocol for their extraction and characterization

Author

Dehaut, Alexandre, Cassone, Anne-laure, Frere, Laura, Hermabessiere, Ludovic, Himber, Charlotte, Rinnert, Emmanuel, Riviere, Gilles, Lambert, Christophe, Soudant, Philippe, Huvet, Arnaud, Duflos, Guillaume, Paul-pont, Ika, Dehaut, Alexandre, Cassone, Anne-laure, Frere, Laura, Hermabessiere, Ludovic, Himber, Charlotte, Rinnert, Emmanuel, Riviere, Gilles, Lambert, Christophe, Soudant, Philippe, Huvet, Arnaud, Duflos, Guillaume, and Paul-pont, Ika

Abstract

Pollution of the oceans by microplastics (<5 mm) represents a major environmental problem. To date, a limited number of studies have investigated the level of contamination of marine organisms collected in situ. For extraction and characterization of microplastics in biological samples, the crucial step is the identification of solvent(s) or chemical(s) that efficiently dissolve organic matter without degrading plastic polymers for their identification in a time and cost effective way. Most published papers, as well as OSPAR recommendations for the development of a common monitoring protocol for plastic particles in fish and shellfish at the European level, use protocols containing nitric acid to digest the biological tissues, despite reports of polyamide degradation with this chemical. In the present study, six existing approaches were tested and their effects were compared on up to 15 different plastic polymers, as well as their efficiency in digesting biological matrices. Plastic integrity was evaluated through microscopic inspection, weighing, pyrolysis coupled with gas chromatography and mass spectrometry, and Raman spectrometry before and after digestion. Tissues from mussels, crabs and fish were digested before being filtered on glass fibre filters. Digestion efficiency was evaluated through microscopical inspection of the filters and determination of the relative removal of organic matter content after digestion. Five out of the six tested protocols led to significant degradation of plastic particles and/or insufficient tissue digestion. The protocol using a KOH 10% solution and incubation at 60 °C during a 24 h period led to an efficient digestion of biological tissues with no significant degradation on all tested polymers, except for cellulose acetate. This protocol appeared to be the best compromise for extraction and later identification of microplastics in biological samples and should be implemented in further monitoring studies to ensure relevance and

Published

2016

6. Microplastics in seafood: Benchmark protocol for their extraction and characterization

Author

Dehaut, Alexandre, Cassone, Anne-laure, Frere, Laura, Hermabessiere, Ludovic, Himber, Charlotte, Rinnert, Emmanuel, Riviere, Gilles, Lambert, Christophe, Soudant, Philippe, Huvet, Arnaud, Duflos, Guillaume, Paul-pont, Ika, Dehaut, Alexandre, Cassone, Anne-laure, Frere, Laura, Hermabessiere, Ludovic, Himber, Charlotte, Rinnert, Emmanuel, Riviere, Gilles, Lambert, Christophe, Soudant, Philippe, Huvet, Arnaud, Duflos, Guillaume, and Paul-pont, Ika

Abstract

Pollution of the oceans by microplastics (<5 mm) represents a major environmental problem. To date, a limited number of studies have investigated the level of contamination of marine organisms collected in situ. For extraction and characterization of microplastics in biological samples, the crucial step is the identification of solvent(s) or chemical(s) that efficiently dissolve organic matter without degrading plastic polymers for their identification in a time and cost effective way. Most published papers, as well as OSPAR recommendations for the development of a common monitoring protocol for plastic particles in fish and shellfish at the European level, use protocols containing nitric acid to digest the biological tissues, despite reports of polyamide degradation with this chemical. In the present study, six existing approaches were tested and their effects were compared on up to 15 different plastic polymers, as well as their efficiency in digesting biological matrices. Plastic integrity was evaluated through microscopic inspection, weighing, pyrolysis coupled with gas chromatography and mass spectrometry, and Raman spectrometry before and after digestion. Tissues from mussels, crabs and fish were digested before being filtered on glass fibre filters. Digestion efficiency was evaluated through microscopical inspection of the filters and determination of the relative removal of organic matter content after digestion. Five out of the six tested protocols led to significant degradation of plastic particles and/or insufficient tissue digestion. The protocol using a KOH 10% solution and incubation at 60 °C during a 24 h period led to an efficient digestion of biological tissues with no significant degradation on all tested polymers, except for cellulose acetate. This protocol appeared to be the best compromise for extraction and later identification of microplastics in biological samples and should be implemented in further monitoring studies to ensure relevance and

Published

2016