Description

Pancreatic cancer is one of the most malignant digestive tract tumors, with an extremely poor prognosis and a five-year survival rate of less than 10%. Its treatment options are limited. For patients with unresectable, advanced disease, systemic chemotherapy (such as the AG regimen or FOLFIRINOX regimen) is the standard treatment, but the efficacy remains unsatisfactory, with median overall survival struggling to exceed one year.

In recent years, immunotherapy represented by PD-1/PD-L1 inhibitors has achieved revolutionary success in various solid tumors (such as lung cancer, melanoma), bringing hope for long-term survival to patients with advanced cancer. However, in the field of pancreatic cancer, immunotherapy monotherapy has repeatedly faced setbacks. Multiple clinical studies show that immune checkpoint inhibitors have a very low response rate (typically \<5%) in unselected patients with advanced pancreatic cancer, with the vast majority failing to benefit. This characteristic of being an immunologically "cold" tumor is largely attributed to the unique tumor microenvironment (TME) of pancreatic cancer: a highly fibrotic stroma, minimal infiltration of cytotoxic T lymphocytes (CTLs), and an abundance of immunosuppressive cells (such as regulatory T cells (Tregs), myeloid-derived suppressor cells (MDSCs)). These factors collectively create a state of immune exclusion and immunosuppression, preventing immune cells from recognizing and attacking tumor cells.

To convert "cold tumors" into "hot tumors," researchers are actively exploring various combination strategies. Among them, the combination of radiotherapy (RT) and immunotherapy shows great potential. Traditionally, radiotherapy was considered merely a local treatment modality. However, recent studies have found that it also has the abscopal effect - where irradiation of one lesion can lead to the shrinkage of non-irradiated, distant lesions. This suggests that radiotherapy can activate a systemic anti-tumor immune response. It is noteworthy that low-dose radiotherapy (e.g., 2Gy) plays a unique role in this process. Unlike high-dose radiotherapy, which primarily causes DNA double-strand breaks in tumor cells, low-dose radiotherapy is more capable of inducing immunogenic cell death (ICD), prompting tumor cells to release antigens and danger signal molecules, thereby enhancing antigen presentation by dendritic cells (DCs) and initiating a T-cell immune response. Multiple preclinical studies have confirmed that 2Gy radiotherapy can effectively promote the cross-presentation of tumor-specific antigens, reduce immunosuppression in the microenvironment, and increase the infiltration of lymphocytes into the tumor site, creating favorable conditions for immunotherapy to take effect.

Based on the above evidence, we propose the following scientific hypothesis: For patients with advanced pancreatic cancer who are insensitive to immunotherapy monotherapy, preemptive intervention using low-dose radiotherapy is expected to remodel the tumor immune microenvironment (TIME), converting it from "cold" to "hot." Subsequently, the follow-up combination of a PD-1 inhibitor (Pucotenlimab) and standard chemotherapy could not only activate the immune system via radiotherapy but also further kill tumor cells and expose more tumor antigens through chemotherapy, potentially suppressing immunosuppressive cells. The synergistic effect of these three modalities is expected to achieve a "1+1+1\>3" outcome, potentially breaking through the current therapeutic bottleneck for advanced pancreatic cancer.