Optimizing the Design of Blood-Brain Barrier-Penetrating Polymer-Lipid-Hybrid Nanoparticles for Delivering Anticancer Drugs to Glioblastoma.

PURPOSE: Chemotherapy for glioblastoma multiforme (GBM) remains ineffective due to insufficient penetration of therapeutic agents across the blood-brain barrier (BBB) and into the GBM tumor. Herein, is described, the optimization of the lipid composition and fabrication conditions for a BBB- and tumor penetrating terpolymer-lipid-hybrid nanoparticle (TPLN) for delivering doxorubicin (DOX) to GBM. METHODS: The composition of TPLNs was first screened using different lipids based on nanoparticle properties and in vitro cytotoxicity by using 23 full factorial experimental design. The leading DOX loaded TPLNs (DOX-TPLN) were prepared by further optimization of conditions and used to study cellular uptake mechanisms, in vitro cytotoxicity, three-dimensional (3D) glioma spheroid penetration, and in vivo biodistribution in a murine orthotopic GBM model. RESULTS: Among various lipids studied, ethyl arachidate (EA) was found to provide excellent nanoparticle properties e.g., size, polydispersity index (PDI), zeta potential, encapsulation efficiency, drug loading, and colloidal stability, and highest anticancer efficacy for DOX-TPLN. Further optimized EA-based TPLNs were prepared with an optimal particle size (103.8 ± 33.4 nm) and PDI (0.208 ± 0.02). The resultant DOX-TPLNs showed ~ sevenfold higher efficacy than free DOX against human GBM U87-MG-RED-FLuc cells in vitro. The interaction between the TPLNs and the low-density lipoprotein receptors also facilitated cellular uptake, deep penetration into 3D glioma spheroids, and accumulation into the in vivo brain tumor regions of DOX-TPLNs. CONCLUSION: This work demonstrated that the TPLN system can be optimized by rational selection of lipid type, lipid content, and preparation conditions to obtain DOX-TPLN with enhanced anticancer efficacy and GBM penetration and accumulation.

Evaluation of new bi-functional terpolymeric nanoparticles for simultaneous in vivo optical imaging and chemotherapy of breast cancer.

Successful development of a nanoparticulate system for cancer chemotherapy requires detailed knowledge of its biodistribution, clearance and anti-tumour efficacy in vivo. Herein we developed new bi-functional nanoparticles for simultaneous in vivo optical imaging and delivery of the anticancer drug doxorubicin (Dox) for enhanced chemotherapy. Two types of nanoparticles were synthesized, namely preformed nanoparticles (PF-NPs) and self-assembled nanoparticles (SA-NPs). The PF-NPs were prepared by cross-linking graft polymerization of methacrylic acid and polysorbate 80 with starch (PMAA-PS 80-g-St) and then loading the particles with Dox. The SA-NPs were formed upon addition of Dox to non-cross-linked PMAA-PS 80-g-St. A near infrared fluorescent probe was conjugated with the PMAA unit of the nanoparticles. The biodistribution, tumour targeting and pharmacokinetics of the Dox-loaded nanoparticles in mice were determined by in vivo/ex vivo fluorescence imaging and ex vivo fluorescence microscopy. The anti-tumour efficacy of the nanoparticles was investigated using a murine orthotopic breast cancer model. PF-NPs had an average hydrodynamic diameter and zeta potential of 137 ± 3 nm and -38 ± 1 mV, respectively. These values were measured at 62 ± 5 nm and -35 ± 5 mV for SA-NPs. PF-NPs exhibited a porous morphology while the SA-NPs appeared to have a denser structure. SA-NPs outperformed the PF-NPs in terms of blood circulation, tumour uptake and penetration. PF-NPs and SA-NPs exhibited no systemic toxicity and inhibited tumour growth significantly better than the free Dox solution with SA-NPs being the best, attributable to their excellent tumour uptake and penetration. This work demonstrates the usefulness of these bi-functional nanoparticles as nanotheranostics.

EphA4 is not required for Purkinje cell compartmentation.

The Purkinje cells of both the adult and the developing cerebellar cortex are organized into parasagittal stripes or 'segments' expressing a variety of biochemical markers. We show that in the developing mouse cerebellar cortex, members of the Eph receptor gene family are expressed in mediolaterally alternating Purkinje cell segments. Since members of the Eph receptors family have been shown to play a role in hindbrain segmentation and boundary formation (Philos. Trans. R. Soc. Lond. B: Biol. Sci. 355 (2000) 993), we analyzed the effect of a null mutation of the EphA4 gene on Purkinje cell compartmentation. Using well characterized markers of Purkinje cell compartmentation in both the developing and the adult cerebellum, we observed no significant alteration in the banding pattern of these markers between the EphA4 knockout mice and their wild type controls. The ribboned pattern of migrating granule cells in the developing cerebellum also appears unaltered. The expression of other members of this gene family, including ephrin-B2, EphA2, and ephrin-A1, in a compartmentalized pattern within the Purkinje cell layer suggests a possible redundancy and/or a compensation of EphA4 function in the segmental patterning of cerebellar Purkinje cells.