Multimodal silica nanoparticles are effective cancer-targeted probes in a model of human melanoma
Miriam Benezra, … , Ulrich Wiesner, Michelle S. Bradbury
Miriam Benezra, … , Ulrich Wiesner, Michelle S. Bradbury
Published June 13, 2011
Citation Information: J Clin Invest. 2011;121(7):2768-2780. https://doi.org/10.1172/JCI45600.
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Technical Advance Oncology

Multimodal silica nanoparticles are effective cancer-targeted probes in a model of human melanoma

Abstract

Nanoparticle-based materials, such as drug delivery vehicles and diagnostic probes, currently under evaluation in oncology clinical trials are largely not tumor selective. To be clinically successful, the next generation of nanoparticle agents should be tumor selective, nontoxic, and exhibit favorable targeting and clearance profiles. Developing probes meeting these criteria is challenging, requiring comprehensive in vivo evaluations. Here, we describe our full characterization of an approximately 7-nm diameter multimodal silica nanoparticle, exhibiting what we believe to be a unique combination of structural, optical, and biological properties. This ultrasmall cancer-selective silica particle was recently approved for a first-in-human clinical trial. Optimized for efficient renal clearance, it concurrently achieved specific tumor targeting. Dye-encapsulating particles, surface functionalized with cyclic arginine–glycine–aspartic acid peptide ligands and radioiodine, exhibited high-affinity/avidity binding, favorable tumor-to-blood residence time ratios, and enhanced tumor-selective accumulation in αvβ3 integrin–expressing melanoma xenografts in mice. Further, the sensitive, real-time detection and imaging of lymphatic drainage patterns, particle clearance rates, nodal metastases, and differential tumor burden in a large-animal model of melanoma highlighted the distinct potential advantage of this multimodal platform for staging metastatic disease in the clinical setting.

Authors

Miriam Benezra, Oula Penate-Medina, Pat B. Zanzonico, David Schaer, Hooisweng Ow, Andrew Burns, Elisa DeStanchina, Valerie Longo, Erik Herz, Srikant Iyer, Jedd Wolchok, Steven M. Larson, Ulrich Wiesner, Michelle S. Bradbury

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Figure 2

Competitive integrin receptor binding studies with 124I-cRGDY-PEG-dots, cRGDY peptide, and anti–ανβ3 antibody using 2 cell types.

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Competitive integrin receptor binding studies with 124I-cRGDY-PEG-dots, ...
(A) High-affinity and specific binding of 124I-cRGDY-PEG-dots to M21 cells by γ-counting. The inset shows Scatchard analysis of binding data, plotting the ratio of the concentration of receptor-bound (B) to unbound (or free [F]) radioligand or the bound-to-free ratio (B/F) versus the receptor-bound receptor concentration; the slope corresponds to the dissociation constant, Kd. (B) ανβ3 Integrin receptor blocking of M21 cells using flow cytometry and excess unradiolabeled cRGD or anti–ανβ3 antibody prior to incubation with cRGDY-PEG-dots and nonspecific binding with controls (RAD-PEG-dots, PEG-dots). (C) Specific binding of cRGDY-PEG-dots to M21 cells as against M21L cells lacking surface integrin expression using flow cytometry. Anti–ανβ3 integrin receptor antibody concentrations were used at 100 times (i.e., 100x) and 250 times (i.e., 250x) the particle (i.e., 124I-cRGDY-PEG-dot) concentration. (D) Specific binding of cRGDY-PEG-dots to HUVECs by flow cytometry. Each bar represents mean ± SD of 3 replicates.