1. Abstract PO-009: Targeting a unique electrochemical vulnerability in a pediatric brain tumor to potentiate proton beam radiotherapy
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Michael Lamba, Susanne I. Wells, Mathieu Sertorio, Kamdem T. Donatien, Vaibhavkumar S. Gawali, Taukir Ahmed, Dan Ionascu, James M. Cook, Soma Sengupta, Daniel Pomeranz Krummel, Laura Kallay, Ralph E. Vatner, and Debanjan Bhattacharya
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Medulloblastoma ,Oncology ,Cancer Research ,Vincristine ,medicine.medical_specialty ,business.industry ,medicine.medical_treatment ,Cancer ,medicine.disease ,Radiation therapy ,Internal medicine ,Concomitant ,Toxicity ,medicine ,Cytotoxic T cell ,business ,Proton therapy ,medicine.drug - Abstract
Medulloblastoma (MB) is the most common malignant (WHO Grade IV) primary brain cancer in children, adolescents, and young adults. Radiotherapy (RT) is a mainstay of MB treatment, as it is for most childhood and adult cancers. RT dose and frequency needed to achieve efficacy in MB patients severely impacts survival outcomes and is the cause of long-term cognitive deficits. To improve on short-term side effects and long-term complications, scanning beam proton therapy is employed, when available. While this recent technological advance significantly reduces damage to surrounding healthy brain tissue, survivors continue to experience induced radiation damage, including neurocognitive sequelae. To impact survivors’ health-related quality of life and caregivers’ emotional and financial burden, it is critical to identify approaches that reduce RT dose to mitigate side-effects without impacting RT effectiveness. We are investigating targeting a unique MB electrochemical vulnerability as a means to sensitize MB tumor cells to RT. There are four MB molecular subgroups: wingless, sonic-hedgehog, Group 3, and Group 4. Our analysis of 763 MB tumor transcriptomes reveals that all Group 3 MB tumors share an enhanced expression of genes-coding for subunits of the Type-A GABA receptor (GABAAR), a chloride channel. Using patch-clamp electrophysiology, we found that GABAARs conduct Cl− in MB cells and that a brain-penetrant benzodiazepine (BZ) enhances this effect and triggers cytotoxic responses commensurate with mitochondrial depolarization. We find that BZ combined with RT, even at a sub-lethal dose, is highly effective in impairing the viability of MB tumor cells, greater than RT alone. Our BZis capable of penetrating the blood-brain barrier in minutes, is metabolically stable, and showed no toxicity in a primate model. We are investigating its suitability to be used concomitant with proton beam radiotherapy, replacing standard of care vincristine, to reduce radiation-induced brain toxicity experienced by MB patients and survivors while not decreasing RT effectiveness. Citation Format: Daniel Pomeranz Krummel, Laura Kallay, Debanjan Bhattacharya, Vaibhavkumar Gawali, Kamdem T. Donatien, Taukir Ahmed, James M. Cook, Michael Lamba, Susanne Wells, Ralph E. Vatner, Mathieu Sertorio, Dan T. Ionascu, Soma Sengupta. Targeting a unique electrochemical vulnerability in a pediatric brain tumor to potentiate proton beam radiotherapy [abstract]. In: Proceedings of the AACR Virtual Special Conference on Radiation Science and Medicine; 2021 Mar 2-3. Philadelphia (PA): AACR; Clin Cancer Res 2021;27(8_Suppl):Abstract nr PO-009.
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- 2021
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