Metabolic Therapy Program In Conjunction With Standard Treatment For Glioblastoma Multiforme

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Gliomas are tumours that originate from glial cells in the central nervous system. The most common histological subtype is GBM, which accounts for nearly 50% of all malignant brain tumours. Despite aggressive multimodal treatment, the median survival for GBM is poor (8-15 months). Although cancer is...

Gliomas are tumours that originate from glial cells in the central nervous system. The most common histological subtype is GBM, which accounts for nearly 50% of all malignant brain tumours. Despite aggressive multimodal treatment, the median survival for GBM is poor (8-15 months). Although cancer is regarded as a genetic disease, it may be perceived as a metabolic disorder. The majority of human cancers, including GBM, display low numbers of mitochondria, most of which are structurally damaged, resulting in defective cell respiration. To compensate, cancer cells greatly increase their uptake of glucose, which is fermented (regardless of oxygen concentration, a process known as the Warburg Effect) to generate energy. Cancer cells also rely on increased growth signaling pathways involving insulin, insulin-like growth factor-1, and mammalian target of rapamycin to support their unbridled growth and proliferation. Cancer cells may therefore be vulnerable to interventions that selectively target their abnormal metabolism. Metabolic interventions, such as fasting and ketogenic diets, target cancer cell metabolism and may be effective alongside standard treatments in advanced cancers. Fasting is a voluntary abstinence from food and drink for a controlled period of time (typically, 12 hours to 3 weeks in humans), whereas ketogenic diets are high-fat, adequate-protein, low-carbohydrate diets that stimulate the body to create a fasting-like metabolic state. Fasting and ketogenic diets stimulate mitochondria biogenesis, decrease blood glucose, increase liver production of fat-derived ketones (which serve as a major alternative energy source for most normal cells within the body, but cannot be utilized by cancer cells), and decrease growth factor availability. Thus, fasting and ketogenic diets provide an advantage for normal cells but a disadvantage to cancer cells by enhancing mitochondria biogenesis and function, depriving cancer cells of their major fuel, and creating a cell environment unfavourable for unbridled growth and proliferation. Preliminary experience at Waikato Hospital has shown that a metabolic therapy program (MTP) consisting of fasting and/or a ketogenic diet is feasible, safe, and may be effective in patients with advanced cancer, including GBM. In a recent case report, a metabolic strategy (7-day fast every 1-2 months, with a ketogenic diet between fasts) resulted in the near-complete regression of a stage IVA metastatic thymoma after 2 years. Moreover, we are currently observing 8 glioblastoma patients who voluntarily consented to undergo fasting and ketogenic diet therapy in a manner similar to what we propose to use in this study; at an average of 4-5 months, all patients have completed the fasts and adhered to their ketogenic diet, experiencing only mild adverse effects. On this background, we aim to determine whether using an MTP concurrently with standard oncological treatment (chemoradiation followed by adjuvant chemotherapy) is feasible and safe, and has treatment outcomes consistent with greater overall treatment efficacy than in published trials, in patients with GBM.

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