期刊
SMALL
卷 10, 期 3, 页码 566-575出版社
WILEY-V C H VERLAG GMBH
DOI: 10.1002/smll.201301456
关键词
nanoparticles; iron oxide; cancer therapy; MR imaging; theranostic; MMP-14
类别
资金
- NIH/NCI [R21CA156124, R01CA140943, R01CA135294, R21CA138353A2]
- Yorkshire Cancer Research
- Stanford Center for Cancer Nanotechnology Excellence and Translation (CCNE-T) [NIH/NCI U54 CA151459]
- Sanofi-BioX Grant
- NIH/NCI ICMIC [P50 CA114747, R01 CA170378 PQ22]
- NIH [R01 CA105102]
- NCI Cancer Center [P30 CA124435-02]
- NCI ICMIC [P50 CA11474]
A major drawback with current cancer therapy is the prevalence of unrequired dose-limiting toxicity to non-cancerous tissues and organs, which is further compounded by a limited ability to rapidly and easily monitor drug delivery, pharmacodynamics and therapeutic response. In this report, the design and characterization of novel multifunctional theranostic nanoparticles (TNPs) is described for enzyme-specific drug activation at tumor sites and simultaneous in vivo magnetic resonance imaging (MRI) of drug delivery. TNPs are synthesized by conjugation of FDA-approved iron oxide nanoparticles ferumoxytol to an MMP-activatable peptide conjugate of azademethylcolchicine (ICT), creating CLIO-ICTs (TNPs). Significant cell death is observed in TNP-treated MMP-14 positive MMTV-PyMT breast cancer cells in vitro, but not MMP-14 negative fibroblasts or cells treated with ferumoxytol alone. Intravenous administration of TNPs to MMTV-PyMT tumor-bearing mice and subsequent MRI demonstrates significant tumor selective accumulation of the TNP, an observation confirmed by histopathology. Treatment with CLIO-ICTs induces a significant antitumor effect and tumor necrosis, a response not observed with ferumoxytol. Furthermore, no toxicity or cell death is observed in normal tissues following treatment with CLIO-ICTs, ICT, or ferumoxytol. These findings demonstrate proof of concept for a new nanotemplate that integrates tumor specificity, drug delivery and in vivo imaging into a single TNP entity through attachment of enzyme-activated prodrugs onto magnetic nanoparticles. This novel approach holds the potential to significantly improve targeted cancer therapies, and ultimately enable personalized therapy regimens.
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