4.6 Article

Uptake and depuration of Ag nanoparticles versus Ag ions by zebrafish through dietary exposure: characterization of Ag nanoparticle formation and dissolution in vivo and toxicokinetic modeling

Journal

ENVIRONMENTAL SCIENCE-NANO
Volume 9, Issue 8, Pages 2788-2798

Publisher

ROYAL SOC CHEMISTRY
DOI: 10.1039/d2en00113f

Keywords

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Funding

  1. Ministry of Science and Technology (MOST) of Taiwan [107-2628-E-006-001-MY3, 109-2923-E-006-003-MY4]

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This study investigated the uptake and depuration processes of silver nanoparticles (AgNPs) and silver ions (Ag+) by zebrafish. It was found that AgNPs were partially transformed into dissolved Ag, while Ag+ was converted to Ag2S and zerovalent AgNPs. Both particulate and dissolved Ag were involved in the uptake and depuration of Ag by zebrafish, explaining the similar toxicokinetic profiles observed for AgNP and Ag+ exposure.
The uptake and depuration of silver nanoparticles (AgNPs) vs. Ag+ by zebrafish (Danio rerio) were investigated using a range of analyses including single-particle ICP-MS (spICP-MS), high resolution-TEM imaging with crystal and elemental characterization of the extracted particles, and toxicokinetic modeling. We showed for the first time that AgNPs upon uptake were partially transformed into dissolved Ag and that reversely Ag+ was converted to Ag2S and zerovalent AgNPs. The dissolution progressively resulted in smaller sized AgNPs in vivo. Regardless of initial Ag forms in exposure, both particulate and dissolved Ag were involved in the uptake and depuration of Ag by zebrafish. This obviously explained similar toxicokinetic profiles observed for AgNP vs. Ag+ exposure. A one-compartment toxicokinetic model could describe the mass concentration-based body burden data better (R-2 > 0.93) than the number concentration data (R-2 = 0.83). The observed dynamic particle fate processes such as dissolution and neo-formation of AgNPs discovered could not be totally captured by the traditionally mass concentration-based toxicokinetic model. Thus, the study highlights the dynamic biological fates of AgNPs in zebrafish that can influence the mass concentration-based vs. number concentration-based toxicokinetic behaviors.

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