P10.10.A Tumor Treating Fields (TTFields), temozolomide and lomustine co-application is efficacious in glioblastoma cancer cell lines

Abstract

Abstract Background Temozolomide (TMZ) is the standard of care chemotherapy for newly diagnosed glioblastoma (ndGBM), the most common primary malignant brain tumor in adults. However, 50% of patients do not respond to TMZ due to expression of O6-methylguanine-DNA methyltransferase (MGMT), the enzyme involved in repair of TMZ-induced damage. Tumor Treating Fields (TTFields) are alternating electric fields that display anti-mitotic effects on cancerous cells, and have been shown to induce a state of BRCAness in various cancer types. Concurrent treatment with TMZ and TTFields demonstrated a major advance in treatment of patients with ndGBM, and was approved by the FDA in 2014. Recently, the addition of lomustine (CCNU) to TMZ demonstrated clinical benefit in ndGBM patients, with improved overall and progression free survival. The aim of the current study was to examine in GBM cells the effect of TTFields in conjunction with TMZ and CCNU. Materials and Methods U-87 MG, LN229, U118 and LN18 human GBM cell lines were tested for their MGMT expression levels, and treated with TTFields (200 kHz, of 0.83 V/cm RMS) for 72 h using the inovitro system. Efficacy of concomitant application of TTFields with TMZ and/or CCNU was tested by measuring cell count, colony formation, and apoptosis levels. Results U-87 MG and LN229 displayed no expression of MGMT, while U118 and LN18 expressed low and high levels of MGMT, respectively. Application of TMZ and TTFields resulted in increased cytotoxicity compared with each treatment alone, with an additive interaction seen in all examined cell lines. The cytotoxic effect resulting from co-application of CCNU with TTFields suggested a synergistic interaction between the two modalities for U-87 MG, LN229, and U118, an additivity for LN18. Concurrent TTFields/TMZ/CCNU was more efficacious than TTFields or TMZ/CCNU separately in all cell lines. Conclusions Application of TTFields with TMZ was additive, irrespective of MGMT expression levels, while TTFields with CCNU was additive when MGMT was plentiful, but displayed tendency to synergism when MGMT was absent or limited. These outcomes are in line with the BRCAness state induced by TTFields, as in the absence of MGMT, DNA damage induced by CCNU requires the BRCA pathway for repair. Application of TTFields together with TMZ and CCNU demonstrated increased efficacy, suggesting potential benefit of such therapy for ndGBM treatment.