EXTH-05. ANTI-TUMOR IMMUNE RESPONSE OF ONCOMAGNETIC MONOTHERAPY IN GLIOBLASTOMA

Abstract

Abstract BACKGROUND Glioblastoma (GBM) is the most lethal primary malignant brain tumor with a median survival of 15–20 months. Concurrent temozolomide (TMZ) chemotherapy and radiation (XRT) remain the current standard of care (SOC) treatment for newly diagnosed GBM. The addition of tumor treating fields (TTFs) improves median survival for newly diagnosed GBM from 16 to 20.9 months. This modest improvement underscores the urgent need to identify a new treatment modality as a safe and effective therapy. PURPOSE The noninvasive Oncomagnetic device developed in our laboratory selectively kills glioblastoma (GBM) in vitro by generating the spinning oscillating magnetic field (sOMF) which disrupts electron transport chain, leading to a marked increase in reactive oxygen species (ROS) and consequently to cancer cell death. We studied the cellular and molecular effects of sOMF treatment on GBM cell lines and investigated the immune response to Oncomagnetic monotherapy (OMT) in a syngeneic mouse model. RESULTS sOMF significantly reduces cell proliferation and cell survival in vitro . It induces DNA damage and arrests cells in G1-phase of the cell cycle. Whole-body sOMF stimulation caused a substantial retardation of tumor growth and reduction of the contrast-enhanced tumor volume in 9.4T MRI scans. OMT showed significant increase in overall survival in treated mice. We also observed upregulated immune response indicated by RNA sequencing data obtained from sOMF-treated LN229 cells as well as in treated GBM mouse tumor sections by imaging mass cytometry analysis. The tSNE analysis of various immune clusters suggests significant increase in immune response by activating CD4+, CD8+, murine-macrophages and M1-macrophages located at tumor site in the treated group. CONCLUSION The obtained data indicate significant anti-tumor response by inhibiting cancer signaling pathways and an increased immune response. Our findings suggest unique mechanism of action for sOMF stimulation and provide a strong rationale for standalone OMT for GBM.