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Marine & Wildlife
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Environmental pharmaceuticals and climate change: The case study of carbamazepine in M. galloprovincialis under ocean acidification scenario
Environment International2020
55 citations
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Citation count from OpenAlex, updated daily. May differ slightly from the publisher's own count.
Score: 35
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Francesco Regoli
Francesco Regoli
Francesco Regoli
Ilaria Bernardini,
Ilaria Bernardini,
Francesco Regoli
Stefania Gorbi,
Marica Mezzelani,
Marica Mezzelani,
Alessandro Nardi,
Alessandro Nardi,
Massimo Milan,
Stefania Gorbi,
Stefania Gorbi,
Stefania Gorbi,
Stefania Gorbi,
Stefania Gorbi,
Alessandro Nardi,
Luca Peruzza,
Giuseppe d’Errico,
Marica Mezzelani,
Marica Mezzelani,
Marica Mezzelani,
Stefania Gorbi,
Stefania Gorbi,
Francesco Regoli
Francesco Regoli
Alessandro Nardi,
Massimo Milan,
Stefania Gorbi,
Giuseppe d’Errico,
Giuseppe d’Errico,
Giuseppe d’Errico,
Giuseppe d’Errico,
Giuseppe d’Errico,
Stefania Gorbi,
Giuseppe d’Errico,
Stefania Gorbi,
Stefania Gorbi,
Marica Mezzelani,
Stefania Gorbi,
Stefania Gorbi,
Francesco Regoli
Francesco Regoli
Francesco Regoli
Francesco Regoli
Francesco Regoli
Daniele Fattorini,
Ilaria Bernardini,
Francesco Regoli
Francesco Regoli
Francesco Regoli
Francesco Regoli
Francesco Regoli
Francesco Regoli
Francesco Regoli
Francesco Regoli
Francesco Regoli
Francesco Regoli
Francesco Regoli
Daniele Fattorini,
Francesco Regoli
Francesco Regoli
Francesco Regoli
Alessandro Nardi,
Alessandro Nardi,
Alessandro Nardi,
Marica Mezzelani,
Giuseppe d’Errico,
Giuseppe d’Errico,
Luca Peruzza,
Massimo Milan,
Massimo Milan,
Daniele Fattorini,
Francesco Regoli
Stefania Gorbi,
Francesco Regoli
Francesco Regoli
Alessandro Nardi,
Stefania Gorbi,
Stefania Gorbi,
Francesco Regoli
Giuseppe d’Errico,
Stefania Gorbi,
Stefania Gorbi,
Daniele Fattorini,
Tomaso Patarnello,
Luca Peruzza,
Daniele Fattorini,
Stefania Gorbi,
Francesco Regoli
Francesco Regoli
Stefania Gorbi,
Stefania Gorbi,
Francesco Regoli
Francesco Regoli
Ilaria Bernardini,
Stefania Gorbi,
Stefania Gorbi,
Francesco Regoli
Francesco Regoli
Francesco Regoli
Giuseppe d’Errico,
Giuseppe d’Errico,
Stefania Gorbi,
Giuseppe d’Errico,
Francesco Regoli
Francesco Regoli
Francesco Regoli
Francesco Regoli
Francesco Regoli
Francesco Regoli
Alessandro Nardi,
Alessandro Nardi,
Stefania Gorbi,
Stefania Gorbi,
Francesco Regoli
Stefania Gorbi,
Francesco Regoli
Francesco Regoli
Stefania Gorbi,
Francesco Regoli
Francesco Regoli
Francesco Regoli
Daniele Fattorini,
Francesco Regoli
Daniele Fattorini,
Francesco Regoli
Francesco Regoli
Francesco Regoli
Francesco Regoli
Francesco Regoli
Francesco Regoli
Stefania Gorbi,
Francesco Regoli
Massimo Milan,
Tomaso Patarnello,
Francesco Regoli
Francesco Regoli
Tomaso Patarnello,
Stefania Gorbi,
Francesco Regoli
Stefania Gorbi,
Francesco Regoli
Stefania Gorbi,
Francesco Regoli
Francesco Regoli
Giuseppe d’Errico,
Francesco Regoli
Francesco Regoli
Francesco Regoli
Francesco Regoli
Alessandro Nardi,
Stefania Gorbi,
Stefania Gorbi,
Stefania Gorbi,
Stefania Gorbi,
Stefania Gorbi,
Francesco Regoli
Stefania Gorbi,
Francesco Regoli
Alessandro Nardi,
Francesco Regoli
Tomaso Patarnello,
Francesco Regoli
Massimo Milan,
Daniele Fattorini,
Francesco Regoli
Stefania Gorbi,
Stefania Gorbi,
Massimo Milan,
Stefania Gorbi,
Francesco Regoli
Summary
Researchers exposed mussels simultaneously to the common pharmaceutical carbamazepine and simulated ocean acidification, finding that the combination caused greater cellular damage and immune disruption than either stressor alone. The study highlights how ocean acidification — driven by rising CO₂ — may amplify the toxicity of pharmaceutical pollutants in marine shellfish.
Contaminants of emerging concern and ocean changes are key environmental stressors for marine species with possibly synergistic, but still unexplored, deleterious effects. In the present study the influence of a simulated ocean acidification scenario (pH = 7.6) was investigated on metabolism and sub-lethal effects of carbamazepine, CBZ (1 µg/L), chosen as one of the most widely diffused pharmaceuticals in marine organisms. A multidisciplinary approach was applied on mussels, M. galloprovincialis, integrating measurement of drug bioaccumulation with changes in the whole transcriptome, responsiveness of various biochemical and cellular biomarkers including immunological parameters, lipid and oxidative metabolism, onset of genotoxic effects. Chemical analyses revealed a limited influence of hypercapnia on accumulation and excretion of CBZ, while a complex network of biological responses was observed in gene expression profile and functional changes at cellular level. The modulation of gamma-aminobutyric acid (GABA) pathway suggested similarities with the Mechanism of Action known for vertebrates: immune responses, cellular homeostasis and oxidative system represented the processes targeted by combined stressors. The overall elaboration of results through a quantitative Weight of Evidence model, revealed clearly increased cellular hazard due to interactions of CBZ with acidification compared to single stressors.