Co-loading of Temozolomide with Oleuropein or rutin into polylactic acid core-shell nanofiber webs inhibit glioblastoma cell by controlled release.

Glioblastoma (GB) has susceptibility to post-surgical recurrence. Therefore, local treatment methods are required against recurrent GB cells in the post-surgical area. In this study, we developed a nanofiber-based local therapy against GB cells using Oleuropein (OL), and rutin and their combinations with Temozolomide (TMZ). The polylactic acid (PLA) core-shell nanofiber webs were encapsulated with OL (PLAOL), rutin (PLArutin), and TMZ (PLATMZ) by an electrospinning process. A SEM visualized the morphology and the total immersion method determined the release characteristics of PLA webs. Real-time cell tracking analysis for cell growth, dual Acridine Orange/Propidium Iodide staining for cell viability, a scratch wound healing assay for migration capacity, and a sphere formation assay for tumor spheroid aggressiveness were used. All polymeric nanofiber webs had core-shell structures with an average diameter between 133 ± 30.7-139 ± 20.5 nm. All PLA webs promoted apoptotic cell death, suppressed cell migration, and spheres growth (p < 0.0001). PLAOL and PLATMZ suppressed GB cell viability with a controlled release that increased over 120 h, while PLArutin caused rapid cell inhibition (p < 0.0001). Collectively, our findings suggest that core-shell nano-webs could be a novel and effective therapeutic tool for the controlled release of OL and TMZ against recurrent GB cells.

Investigation of the Effectiveness of Oleuropein in a Three-Dimensional In Vitro Hepatocellular Tumor Sphere Model.

OBJECTIVES: This study was conducted to examine the dose-related effects over time of oleuropein on the proliferation and area of tumor spheroids in hepatocellular carcinoma cells. MATERIALS AND METHODS: We examined the possible effects of 100 to 500 µM dose concentrations of oleuropein on HepG2 cell proliferation using a real-time cell analyzer. A 3-dimensional hepatocellular carcinoma tumor spheroid model was established by seeding HepG2 cells at a density of 160 cells/well in custom 96-well microplates with low attachment surfaces and culturing for 3 days. Tumor spheres were treated with increasing oleuropein doses for 72 hours, and images were captured every 24 hours. The dose-dependent effects of oleuropein on tumor sphere size were analyzed by measuring the area of tumor spheres with ImageJ software. We conducted oleuropein viability and cytotoxicity analyses using calcein acetoxymethyl ester-based and propidium iodide-based staining in the tumor model. RESULTS: Oleuropein inhibited cell proliferation; as the dose concentration of oleuropein increased, so did its capacity to inhibit cell proliferation (P < .001). The size of untreated tumor spheres increased at 72 hours (P < .001). However, treatment with 100 to 500 µM oleuropein reduced tumor size by 63.56% to 88.06% compared with untreated cells at the end of 72 hours (P < .001). With increasing concentrations, oleuropein inhibited the viability of tumor spheres, eliminating necrotic death caused by tumor hypoxia. CONCLUSIONS: Overall, oleuropein reduced the size of tumors by inhibiting tumor proliferation and viability. In this context, oleuropein could be a candidate molecule for further extensive studies to reduce hepatocellular carcinoma tumors to meet Milan criteria for liver transplant.