Zebrafish Embryos as a Predictive Animal Model to Study Nanoparticle Behavior in vivo.

A failure to fully understand the complex in vivo behavior of systemically administered nanomedicines has stymied clinical translation. To bridge this knowledge gap, new in vivo tools are needed to rapidly and accurately assess the nearly infinite array of possible nanoparticle designs. Zebrafish embryos are small, transparent, and easily manipulated animals that allow for whole organism visualization of fluorescently labeled nanoparticles in real time and at cellular resolution using standard microscope setups. Furthermore, key nano-bio interactions present in higher vertebrates are fully conserved in zebrafish embryos, making these animal models a highly predictive and instructive addition to the nanomedicine design pipeline. Here, we present a step-by-step protocol to intravenously administer, image, and analyze nanoparticle behavior in zebrafish embryos and highlight key nano-bio interactions within the embryonic zebrafish corresponding to those commonly found within the mammalian liver. In addition, we outline practical steps required to achieve light-triggered activation of nanoparticles within the transparent embryo. Graphic abstract: Zebrafish embryos to study nanoparticle behavior in vivo. Formulation, intravenous administration, imaging, and analysis of nanoparticles.