Can Cancer Cell Line In Vitro Radioembolization Model Help to Understand How Beta Radiation Affects Liver Tumor and Improve Treatment Results?

Radioembolization with Y-labeled microspheres is an established locoregional therapy for primary and metastatic liver tumors, yet the molecular mechanisms underlying tumor response and resistance, particularly within hypoxic tumor microenvironments, remain poorly understood. Here, we developed an in vitro model of Y-microsphere irradiation to investigate the effects of beta radiation under normoxic and hypoxic conditions in human colon cancer (HCT 116), hepatocellular carcinoma (HepG2), and non-malignant liver (THLE2) cell lines. Cells were exposed to two microsphere dilutions, and absorbed doses were estimated using FLUKA-based Monte Carlo simulations. Cellular viability, proliferation, apoptosis-related gene expression, and secretion of angiogenic and inflammatory mediators were assessed. Y-microspheres exerted both cytotoxic and cytostatic effects in a cell type- and oxygen-dependent manner. In HCT 116 cells, radiation reduced metabolic activity and proliferation and induced expression in normoxia, whereas hypoxia conferred radioresistance associated with upregulation. HepG2 cells displayed pronounced resistance, with preserved viability but marked inhibition of proliferation, indicating a predominantly cytostatic response that was further attenuated by hypoxia. In contrast, THLE-2 cells were radiosensitive, showing reduced proliferation and increased expression, while hypoxia partially protected against radiation-induced damage. Both hypoxia and microsphere exposure promoted a pro-angiogenic phenotype, characterized by increased VEGF secretion in radiosensitive tumor and healthy cells, whereas resistant HepG2 cells exhibited angiogenic signaling linked to TIMP2 suppression and IL-8 induction. Collectively, our findings demonstrate that hypoxia diminishes cellular sensitivity to Y beta radiation while fostering a microenvironment conducive to tumor progression. This in vitro model provides mechanistic insight into radioembolization responses and may support the development of more personalized therapeutic strategies.