Abstract
The blood–brain barrier (BBB) is an efficient barrier for molecules and drugs. Multicellular 3D spheroids display reproducible BBB features and functions. The spheroids used here were composed of six brain cell types: Astrocytes, pericytes, endothelial cells, microglia cells, oligodendrocytes, and neurons. They form an in vitro BBB that regulates the transport of compounds into the spheroid. The penetration of fluorescent ultrasmall gold nanoparticles (core diameter 2 nm; hydrodynamic diameter 3–4 nm) across the BBB was studied as a function of time by confocal laser scanning microscopy, with the dissolved fluorescent dye (FAM-alkyne) as a control. The nanoparticles readily entered the interior of the spheroid, whereas the dissolved dye alone did not penetrate the BBB. We present a model that is based on a time-dependent opening of the BBB for nanoparticles, followed by a rapid diffusion into the center of the spheroid. After the spheroids underwent hypoxia (0.1% O2; 24 h), the BBB was more permeable, permitting the uptake of more nanoparticles and also of dissolved dye molecules. Together with our previous observations that such nanoparticles can easily enter cells and even the cell nucleus, these data provide evidence that ultrasmall nanoparticle can cross the blood brain barrier.
Highlights
Based on earlier observations that ultrasmall nanoparticles are able to cross cell membranes and even enter the cell nucleus[24,28,29,30,31], we have studied their effect on a well-established and innovative model for the blood–brain barrier, i.e. brain spheroids
It has been shown that they form an intact blood–brain barrier, so that this model can be used as a reproducible in vitro platform to test the permeability of nanoparticles
One of the most challenging goals in pharmacological research is the passage through the blood–brain barrier to deliver drugs to the central nerve system (CNS)
Summary
Based on earlier observations that ultrasmall nanoparticles (metallic core diameter about 2 nm) are able to cross cell membranes and even enter the cell nucleus[24,28,29,30,31], we have studied their effect on a well-established and innovative model for the blood–brain barrier, i.e. brain spheroids. These consist of six different cell types that are representative of human brain t issue[8]. We have investigated the transport of ultrasmall gold nanoparticles in comparison to a dissolved dye under normoxic and hypoxic conditions as a model of ischemic stroke
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