Influence of initial speciation of platinum and palladium on their accumulation and toxicity towards phytoplankton

Julien Michaud-Valcourt; Sylvie Blanc; Louis Courtois; Jelle Mertens; Séverine Le Faucheur; Claude Fortin

Just Accepted

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Influence of initial speciation of platinum and palladium on their accumulation and toxicity towards phytoplankton

Julien Michaud-Valcourt , Sylvie Blanc, Louis Courtois, Jelle Mertens, Séverine Le Faucheur, Claude Fortin

Abstract

Rationale Chemical equilibrium-based models such as the Biotic Ligand Model (BLM) can be used to predict metal toxicity towards aquatic organisms. However, some metals such as platinum (Pt) and to a lesser extent palladium (Pd) are known to be kinetically-hindered, i.e., reactions between these elements and ligands in solution might be slow relative to the biota exposure time. The BLM applicability may thus be limited for these metals and their ecological risk assessment may require considering their initial form of entry in aquatic ecosystems. Methodology This study investigates the relationship between inorganic Pt/Pd initial speciation and their bioavailability and toxicity toward the unicellular green alga Raphidocelis subcapitata. Chloro or amino-coordinated Pt and Pd complexes as Pt(II)Cl₄^2-, Pt(IV)Cl₆^2-, and Pt(II)(NH₃)₄²⁺, Pd(II)Cl₄^2- and Pd(II)(NH₃)₄²⁺ were examined in 96-h algae exposure experiments to determine growth inhibition and metal accumulation. Investigation of the complex stability over time of the tested complexes was carried out using spectrophotometry measurements and kinetic calculations. Results Similar accumulation and no toxicity (EC₅₀ > 150 µg·L^-1) were observed for both Pt(II)Cl₄^2- and Pt(II)(NH₃)₄²⁺ in our tested conditions. Nevertheless, evidence of Pt(II)Cl₄^2- dissociation was observed whereas Pt(II)(NH₃)₄²⁺ was stable. Exposure to Pt(IV)Cl₆^2- showed stronger algal growth inhibition (EC₅₀ = 142 µg·L^-1) than exposure to Pt(II)Cl₄^2- but similar accumulation. This phenomenon might be partly explained by the generation of free chloride radicals through Pt(IV) reduction in the presence of light. Similar accumulation and toxicity were observed for both Pd(II)Cl₄^2- (EC₅₀ = 4.69 µg·L^-1) and Pd(II)(NH₃)₄²⁺ (EC₅₀ = 2.40 µg·L^-1). Discussion These results were coherent with the relatively rapid speciation changes of the Pt(II) complexes as observed and modelled. We therefore conclude that the initial speciation of the studied chloro- and amino-coordinated Pt(II) and Pd(II) complexes is not a determining parameter of their accumulation and toxicity towards R. subcapitata.

EN24062 Accepted 03 November 2024