Cholangiocarcinoma (CCA) is a highly malignant tumor originating from the epithelium of the bile ducts. It has an insidious onset, is difficult to diagnose in its early stages, has a low rate of curative resection, and carries an extremely poor prognosis. Among these, intrahepatic cholangiocarcinoma (iCCA), as the most representative subtype, is a classic “immunologically cold tumor.” The response rate to single-agent immunotherapy is only 5–10%, and the mechanisms of immune resistance are complex and not yet fully elucidated. The tumor microenvironment, serving as the core site of immune resistance, forms a highly immunosuppressive network composed of cancer-associated fibroblasts, hypoxia, metabolic reprogramming, and epigenetic abnormalities; a population of immunosuppressive cells centered on tumor-associated macrophages further amplifies tolerance signals; and the gut–biliary microbiome exerts systemic immune regulation via the gut–liver axis. Based on mutant mouse models generated via tail vein injection and in-depth studies of mutations in key signaling pathways, our understanding of the mechanisms underlying iCCA’s immune resistance is deepening at both the molecular and systems levels. This article reviews the local and systemic regulatory mechanisms of immune resistance in primary iCCA, summarizes the research value of experimental and preclinical models, and reviews novel strategies such as tumor microenvironment remodeling, activation of immune cell networks, microbiome interventions, and multidimensional combination therapies. It analyzes current research bottlenecks and clinical challenges and outlines the future direction of precision immunotherapy, aiming to provide a theoretical basis and new insights for overcoming iCCA immunotherapy resistance and advancing clinical translation.
Kong et al. (Mon,) studied this question.