Bioinformatic inspired nanoparticles engineered for enhanced delivery to the bone.

Abstract

e14637 Background: We have engineered a programmable-bioinspired nanoparticle (P-BiNP) delivery system to simultaneously target the bone and increase uptake in homotypic tumor cells by coating polymeric nanoparticles with programmed cancer cell membranes. This approach is unique in that we have incorporated relevant clinical bioinformatics data to guide the design of these nanoparticles. Methods: A gene ontology search identified potential homotypic cell-cell adhesion genes. These were cross referenced with RNAseq expression levels from patients with metastatic prostate cancer to various organ locations using the Cbioportal database. C4-2B prostate cancer cells were grown and stimulated to express membrane ɑVβ3 by treatment with recombinant human CXCL12. The cell membrane from these cancer cells were used to coat polymeric nanoparticles by an extrusion process. Physico-chemical optimization and characterization of the P-BiNPs was performed. In vitro testing was done with flow cytometry and MTT assays. A murine model was used with high resolution near infrared imaging to identify nanoparticle localization. Results: Analysis of RNAseq from mCRPC samples (n = 118) identified ITGB3 as increased in bone metastatic lesions compared to metastases from other sites (P < 0.0001). ITGB3 is a subunit of integrin ɑVβ3 and was selected as a target for enhancement to improve P-BiNP homotypic targeting and bone localization. After optimization, P-BiNPs showed optimal physico-chemical characteristics for drug delivery. Both in vitro testing and in vivo testing showed the P-BiNPs to be superior in homotypic uptake and localization to the bone. Conclusions: This platform of identifying clinically relevant targets for dual homotypic and bone targeting has potential as a strategy for treatment and imaging modalities in cancers that affects the bone as well as implications for delivering nanoparticles to other organs of interest.