PO.IM02.07 · 免疫学

Overcoming pancreatic ductal adenocarcinoma immunoresistance: Microfluidic-primed organoid interacting lymphocytes demonstrate superior infiltration, cytotoxicity, and tumor suppression in patient-derived models

海报缩略图:Overcoming pancreatic ductal adenocarcinoma immunoresistance: Microfluidic-primed organoid interacting lymphocytes demonstrate superior infiltration, cytotoxicity, and tumor suppression in patient-derived models
编号 6985 展板 13 时间 4/22 09:00–12:00 区域 Section 8 主讲 Eleftherios Makris, MD;PhD
分会场 Novel Models of Immunotherapy Response
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作者与单位

Eleftherios Makris, Damian Hutchins, Tiefu Liu, Adam Hall, Lance Miller, Shay Soker, Konstantinos Votanopoulos

Wake Forest University School of Medicine, Winston Salem, NC

摘要 Abstract

Background: Pancreatic ductal adenocarcinoma (PDAC) remains refractory to immunotherapy due to its immunosuppressive tumor microenvironment (TME), characterized by dense desmoplasia, immune exclusion, and T cell exhaustion. With 5-year survival <13%, novel strategies are urgently needed. We developed a platform to generate and evaluate tumor-specific cytotoxic lymphocytes using immunocompetent patient-derived organoids (PTOs) that recapitulate the PDAC TME. Methods: Immunocompetent PTOs (iPTOs) were established by co-culturing resected PDAC tissue with autologous tumor-draining lymph node cells. Autologous PBMCs were primed via microfluidic tumor-on-a-chip circulation, generating Organoid Interacting Lymphocytes (OILs). OILs were expanded for 14 days and co-cultured with patient-matched PTOs at 5× and 10× effector:target ratios. Tumor-immune dynamics were quantified using high-resolution time-lapse microscopy with automated single-cell tracking, flow cytometry (CD45, CK19, viability), and longitudinal tumor area measurements over 96 hours. Results: Flow cytometry demonstrated robust immune infiltration, with CD45+ cells comprising 26% of OIL-treated cultures versus 0.5% in tumor-only controls. OILs induced 93% tumor cell death compared to 68% with unstimulated PBMCs. Quantitative tracking revealed OILs migrated 6.1 pixels closer to tumor cells versus 0.6 pixels for PBMCs over 24 hours (P<0.05). At 27 hours, OIL-treated organoids exhibited consistent tumor area reduction (-2% to -13%), while PBMC-treated wells showed variable responses including tumor expansion (+7%). Longitudinal analysis confirmed sustained suppression with live OILs, whereas heat-killed OILs permitted 15-fold tumor expansion, demonstrating viability-dependent cytotoxicity. Time-lapse microscopy captured direct killing events, immune synapse formation, and tumor clustering consistent with immune evasion. These findings replicate observations in appendiceal and mesothelioma models where OILs outperformed tumor-infiltrating lymphocytes. Conclusions: OILs represent a potent, patient-specific adaptive cell therapy capable of overcoming PDAC's immunosuppressive TME. This immunocompetent organoid platform enables quantitative real-time assessment of personalized immunotherapies and supports clinical translation of OIL-based therapies for pancreatic cancer.
利益披露 Disclosure
E. Makris, None.. D. Hutchins, None.. T. Liu, None.. A. Hall, None.. L. Miller, None.. S. Soker, None.. K. Votanopoulos, None.

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