Up
to 99% of systemically administered nanoparticles are cleared
through the liver. Within the liver, most nanoparticles are thought
to be sequestered by macrophages (Kupffer cells), although significant
nanoparticle interactions with other hepatic cells have also been
observed. To achieve effective cell-specific targeting of drugs through
nanoparticle encapsulation, improved mechanistic understanding of
nanoparticle–liver interactions is required. Here, we show
the caudal vein of the embryonic zebrafish (Danio rerio) can be used as a model for assessing nanoparticle interactions
with mammalian liver sinusoidal (or scavenger) endothelial cells (SECs)
and macrophages. We observe that anionic nanoparticles are primarily
taken up by SECs and identify an essential requirement for the scavenger
receptor, stabilin-2 (stab2) in
this process. Importantly, nanoparticle–SEC interactions can
be blocked by dextran sulfate, a competitive inhibitor of stab2 and other scavenger receptors. Finally, we exploit
nanoparticle–SEC interactions to demonstrate targeted intracellular
drug delivery resulting in the selective deletion of a single blood
vessel in the zebrafish embryo. Together, we propose stab2 inhibition or targeting as a general approach for modifying nanoparticle–liver
interactions of a wide range of nanomedicines.
Lipid nanoparticles (LNPs) are the leading nonviral technologies for the delivery of exogenous RNA to target cells in vivo. As systemic delivery platforms, these technologies are exemplified by Onpattro, an approved LNP‐based RNA interference therapy, administered intravenously and targeted to parenchymal liver cells. The discovery of systemically administered LNP technologies capable of preferential RNA delivery beyond hepatocytes has, however, proven more challenging. Here, preceded by comprehensive mechanistic understanding of in vivo nanoparticle biodistribution and bodily clearance, an LNP‐based messenger RNA (mRNA) delivery platform is rationally designed to preferentially target the hepatic reticuloendothelial system (RES). Evaluated in embryonic zebrafish, validated in mice, and directly compared to LNP–mRNA systems based on the lipid composition of Onpattro, RES‐targeted LNPs significantly enhance mRNA expression both globally within the liver and specifically within hepatic RES cell types. Hepatic RES targeting requires just a single lipid change within the formulation of Onpattro to switch LNP surface charge from neutral to anionic. This technology not only provides new opportunities to treat liver‐specific and systemic diseases in which RES cell types play a key role but, more importantly, exemplifies that rational design of advanced RNA therapies must be preceded by a robust understanding of the dominant nano–biointeractions involved.
Surface charge plays a fundamental role in determining the fate of a nanoparticle, and any encapsulated contents, in vivo. Herein, we describe, and visualise in real time, light-triggered switching of liposome surface charge, from neutral to cationic, in situ and in vivo (embryonic zebrafish). Prior to light activation, intravenously administered liposomes, composed of just two lipid reagents, freely circulate and successfully evade innate immune cells present in the fish. Upon in situ irradiation and surface charge switching, however, liposomes rapidly adsorb to, and are taken up by, endothelial cells and/or are phagocytosed by blood resident macrophages. Coupling complete external control of nanoparticle targeting together with the intracellular delivery of encapsulated (and membrane impermeable) cargos, these compositionally simple liposomes are proof that advanced nanoparticle function in vivo does not require increased design complexity but rather a thorough understanding of the fundamental nano-bio interactions involved.
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