The use of cellular systems to advance cancer therapeutics has expanded rapidly, spanning cell therapies to patient-specific tumor models. Platforms that recapitulate key features of the tumor microenvironment, including vascular and immune components, hold significant potential to improve the predictive power and translational relevance of preclinical models. Here, we report a vascularized tumor organoid platform that combines self-organizing microvascular networks with patient-derived tumor organoids and tumor-infiltrating lymphocytes. To minimize non-specific endothelial immunogenicity and enable broader compatibility across patient samples, we engineered the vasculature using beta-2-microglobulin-knockout endothelial cells. Leveraging this system, we established patient-specific, lymphocyte-incorporated tumor models that enabled quantitative assessment of T cell infiltration. In conjunction with immune checkpoint blockade, this platform distinguishes responder and non-responder patient samples, consistent with the clinical observations. Single-cell RNA-sequencing revealed tumor-intrinsic and immune-associated programs underlying this stratification, identifying tumor-driven hyperangiogenic signaling as a barrier to T cell extravasation. Pharmacological co-targeting of PD1 and VEGF restored T cell infiltration in non-responder organoids, shifting them from an immune-excluded to an immune-inflamed state. Together, this vascularized tumor organoid platform provides a predictive and mechanistic framework for modeling patient-specific immunotherapy responses and design of combination therapies.
Natesh, N. R., Maity, S., Kikani, R., Perikamana, S. M., Cho, G., Angel, N., Ji, Z., Varghese, S.
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