Biodistribution of surfactant-free poly(lactic-acid) nanoparticles and uptake by endothelial cells and phagocytes in zebrafish: Evidence for endothelium to macrophage transfer

• Published in: Journal of controlled release Vol. 331; pp. 228 - 245
• Main Authors: Rességuier, Julien, Levraud, Jean-Pierre, Dal, Nils K., Fenaroli, Federico, Primard, Charlotte, Wohlmann, Jens, Carron, Gabrielle, Griffiths, Gareth W., Le Guellec, Dominique, Verrier, Bernard
• Format: Journal Article
• Language: English
• Published: Netherlands Elsevier B.V 10.03.2021; Elsevier BV; Elsevier
• Subjects: Biodistribution; Bioengineering; Biomaterials; Chemical Sciences; Endothelial cell to macrophage transfer; Galenic pharmacology; Human health and pathology; Hépatology and Gastroenterology; Immunology; Immunotherapy; Infectious diseases; Life Sciences; Microbiology and Parasitology; Nanoparticles; Pharmaceutical sciences; Polymers; Surfactant-free; Uptake-degradation kinetics; Vaccinology; Virology; Zebrafish; Nanoparticles; Zebrafish; Endothelial cell to macrophage transfer; Uptake-degradation kinetics; Surfactant-free; Biodistribution
• ISSN: 0168-3659; 1873-4995
• DOI: 10.1016/j.jconrel.2021.01.006

In the development of therapeutic nanoparticles (NP), there is a large gap between in vitro testing and in vivo experimentation. Despite its prominence as a model, the mouse shows severe limitations for imaging NP and the cells with which they interact. Recently, the transparent zebrafish larva, which is well suited for high-resolution live-imaging, has emerged as a powerful alternative model to investigate the in vivo behavior of NP. Poly(D,L lactic acid) (PLA) is widely accepted as a safe polymer to prepare therapeutic NP. However, to prevent aggregation, many NP require surfactants, which may have undesirable biological effects. Here, we evaluate ‘safe-by-design’, surfactant-free PLA-NP that were injected intravenously into zebrafish larvae. Interaction of fluorescent NPs with different cell types labelled in reporter animals could be followed in real-time at high resolution; furthermore, by encapsulating colloidal gold into the matrix of PLA-NP we could follow their fate in more detail by electron microscopy, from uptake to degradation. The rapid clearance of fluorescent PLA-NP from the circulation coincided with internalization by endothelial cells lining the whole vasculature and macrophages. After 30 min, when no NP remained in circulation, we observed that macrophages continued to internalize significant amounts of NP. More detailed video-imaging revealed a new mechanism of NP transfer where NP are transmitted along with parts of the cytoplasm from endothelial cells to macrophages. [Display omitted]