Efficient delivery of Temozolomide using ultrasmall large-pore silica nanoparticles for glioblastoma

Abstract

The prognosis of brain cancers such as glioblastoma remains poor despite numerous advancements in the field of neuro-oncology. The presence of the blood brain barrier (BBB) along with the highly invasive and aggressive nature of glioblastoma presents a difficult challenge for developing effective therapies. Temozolomide (TMZ) is a first line agent used in the clinic for glioblastoma and it has been useful in increasing patient survival rates. However, TMZ suffers from issues related to its pharmacokinetics, such as a short plasma half-life (2 h), is subjected to P-gp efflux, and has limited extravasation from blood to brain (∼20%). It has been postulated that reducing its efflux and increasing glioblastoma tissue exposure to TMZ could prove useful in treating glioblastoma and preventing tumour recurrence. Herein, ultra-small, large pore silica nanoparticles (USLP) have been loaded with TMZ, surface PEGlyated to reduce efflux and decorated with the cascade targeting protein lactoferrin for efficient uptake across the BBB and into glioblastoma. Our results demonstrate that USLP improves permeability of BBB in vitro as evidenced using a transwell model which mimics endothelial tight junctions with permeation being enhanced using PEGylated particles. Data from TMZ loaded USLP in vitro transwell BBB model also suggests that the USLP formulations can significantly reduce the efflux ratio of TMZ. In vitro apoptosis studies on glioblastoma cell lines U87 and GL261 were conducted which showed an improvement in TMZ induced glioblastoma apoptosis with USLP formulations compared to pure TMZ. Finally, a proof-of-concept preclinical mouse study demonstrated that when given intravenously at 50 mg/kg, USLP particles showed accumulation in the brain within a few hours without any obvious pathophysiological changes in vital organs as assessed via histology. Overall, the data suggests our innovative delivery system is efficient in extravasation from blood and permeating the BBB and has potential to improve efficacy of TMZ in glioblastoma therapy.

Keywords: 3D glioblastoma model; Blood brain barrier; Brain imaging; Glioblastoma; Lactoferrin; Large pore; Mesoporous silica; Optical imaging; Silica functionalisation; Targeted drug delivery; Temozolomide; Ultra-small nanoparticle.