Uptake of surface-functionalized thermo-responsive polymeric nanocarriers in corticospinal tract motor neurons.

Nanocarrier drug delivery systems are attractive options for targeted delivery of survival- and regeneration-enhancing therapeutics to neurons damaged by degenerative or traumatic central nervous system (CNS) lesions. Functional groups on nanocarrier surfaces allow derivatization with molecules to target specific cells but may affect cellular interactions and nanocarrier uptake. We synthesized differently sized -COOH and -NH2 surface functionalized polymeric nanocarriers (SFNCs) by emulsion copolymerization and assessed uptake by different cell types in mixed cortical cultures. Following 60-min incubation with SFNCs, mean intensity measurements of fluorescently labeled SFNCs indicated that corticospinal tract motor neurons (CSMNs) took up more COOH- or NH2- functionalized SFNCs with similar sizes (150 nm), compared to glia. However, larger diameter (750 nm) SFNCs were taken up at higher concentrations compared to smaller COOH-derivatized SFNCs (150 nm). These data suggest that larger SFNCs may provide an advantage for enhanced uptake by targeted neurons.

Photo-Magnetic Irradiation-Mediated Multimodal Therapy of Neuroblastoma Cells Using a Cluster of Multifunctional Nanostructures.

The use of high intensity chemo-radiotherapies has demonstrated only modest improvement in the treatment of high-risk neuroblastomas. Moreover, undesirable drug specific and radiation therapy-incurred side effects enhance the risk of developing into a second cancer at a later stage. In this study, a safer and alternative multimodal therapeutic strategy involving simultaneous optical and oscillating (AC) magnetic field stimulation of a multifunctional nanocarrier system has successfully been implemented to guide neuroblastoma cell destruction. This novel technique permitted the use of low-intensity photo-magnetic irradiation and reduced the required nanoparticle dose level. The combination of released cisplatin from the nanodrug reservoirs and photo-magnetic coupled hyperthermia mediated cytotoxicity led to the complete ablation of the B35 neuroblastoma cells in culture. Our study suggests that smart nanostructure-based photo-magnetic hybrid irradiation is a viable approach to remotely guide neuroblastoma cell destruction, which may be adopted in clinical management post modification to treat aggressive cancers.