In vivo visualisation of nanoparticle entry into central nervous system tissue

Because the potential neurotoxicity of nanoparticles is a significant issue, characterisation of nanoparticle entry into the brain is essential. Here, we describe an in vivo confocal neuroimaging method (ICON) of visualising the entry of fluorescent particles into the parenchyma of the central nervo...

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Bibliographic Details
Published in:Archives of toxicology 2012-07, Vol.86 (7), p.1099-1105
Main Authors: Henrich-Noack, Petra, Prilloff, Sylvia, Voigt, Nadine, Jin, Jing, Hintz, Werner, Tomas, Jürgen, Sabel, Bernhard A.
Format: Article
Language:English
Subjects:
Animals
Biomedical and Life Sciences
Biomedicine
Blood-Brain Barrier - metabolism
Blood-Retinal Barrier - metabolism
Cell Death - drug effects
Enbucrilate - administration & dosage
Enbucrilate - chemistry
Enbucrilate - pharmacokinetics
Enbucrilate - toxicity
Environmental Health
Fluorescent Dyes - chemistry
Injections, Intravenous
Inorganic Compounds
Male
Medical imaging
Microscopy, Confocal
Microscopy, Fluorescence
Microscopy, Video
Nanoparticles
Nanoparticles - administration & dosage
Nanoparticles - chemistry
Nanoparticles - toxicity
Nervous system
Occupational Medicine/Industrial Medicine
Particle Size
Pharmacology/Toxicology
Photomicrography
Rats
Rats, Inbred Strains
Retina
Retina - cytology
Retina - drug effects
Retina - metabolism
Retinal Ganglion Cells - cytology
Retinal Ganglion Cells - drug effects
Retinal Ganglion Cells - metabolism
Retinal Vessels - drug effects
Retinal Vessels - metabolism
Tissue Distribution
Toxicity
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Summary:Because the potential neurotoxicity of nanoparticles is a significant issue, characterisation of nanoparticle entry into the brain is essential. Here, we describe an in vivo confocal neuroimaging method (ICON) of visualising the entry of fluorescent particles into the parenchyma of the central nervous system (CNS) in live animals using the retina as a model. Rats received intravenous injections of fluorescence-labelled polybutyl cyanoacrylate nanoparticles that had been synthesised by a standard miniemulsion polymerisation process. We performed live recording with ICON from before and up to 9 days after particle injection and took photomicrographs of the retina. In addition, selective retrograde labelling of the retinal ganglion cells was achieved by stereotaxic injection of a fluorescent dye into the superior colliculus. Using ICON, we observed vascular kinetics of nanoparticles (wash-in within seconds), their passage to the retina parenchyma (within minutes) and their distribution (mainly cellular) under in vivo conditions. For the detection of cell loss—which is important for the evaluation of toxic effects—in another experiment, we semi-quantitatively analysed the selectively labelled retinal neurons. Our results suggest that the dye per se does not lead to neuronal death. With ICON, it is possible to study nanoparticle kinetics in the retina as a model of the blood-brain barrier. Imaging data can be acquired within seconds after the injection, and the long-term fate of cellular uptake can be followed for many days to study the cellular/extracellular distribution of the nanoparticles. ICON is thus an effective and meaningful tool to investigate nanoparticle/CNS interactions.
ISSN:0340-5761
1432-0738
DOI:10.1007/s00204-012-0832-4