Article ID Journal Published Year Pages File Type
1423944 Journal of Controlled Release 2014 8 Pages PDF
Abstract

Alzheimer's disease (AD) is a complex neurodegenerative disease with few effective treatments. The non-targeted distribution of drugs decreases drug efficiency and cause side effects. The cascade targeting strategy has been suggested for precise drug delivery. We developed a dual-functional nanoparticle drug delivery system loaded with β-sheet breaker peptide H102 (TQNP/H102). Two targeting peptides, TGN and QSH, were conjugated to the surface of the nanoparticles for blood–brain barrier transport and Aβ42 targeting, respectively. The prepared nanoparticles were spherical and uniform. The brain distribution study of H102 was conducted with the HPLC–mass spectrometry method to evaluate whether this nano-carrier could achieve increased AD-lesion delivery. The highest uptake of H102 was observed in the hippocampi of the TQNP/H102 group mice 1 h after administration, which was 2.62 and 1.86 times the level of non-modified nanoparticles (NP/H102) and TGN modified nanoparticles (TNP/H102), respectively. The neuroprotective effects of H102 preparations were evaluated using Morris water maze experiment, biochemical indexes assay and tissue histology. The spatial learning and memory of the AD model mice in the TQNP/H102 group were significantly improved compared with the AD control group, and were also better than other preparations at the same dosage, even the TNP/H102 group. These results were consistent with the values of biochemical indexes in mouse hippocampi as well as the histological observations. The results demonstrate that TQNP is a promising carrier for peptide or protein drugs, such as H102, for entry into the central nervous system (CNS) and subsequent location of brain AD lesions, thus offering a highly-specific method for AD therapy.

Graphical abstractH102 peptide-loaded dual-functional nanoparticles (TQNP/H102) were developed for the treatment of Alzheimer's disease (AD). TQNP delivered H102 to the brain AD lesions and provided better neuroprotective effects for AD model mice than non-modified or TGN-modified nanoparticles.Figure optionsDownload full-size imageDownload high-quality image (312 K)Download as PowerPoint slide

Related Topics
Physical Sciences and Engineering Materials Science Biomaterials
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