Novel Approaches in Pancreatic Cancer Treatment: Bridging Mechanics, Cells, and Immunity

The heterogeneity of pancreatic cancer renders many available general therapies ineffective holding the five-year survival rate close to 10% for decades. Surgical resection eligibility, resistance to chemotherapy and limited efficacy of immunotherapy emphasize the dire need for diverse and innovative treatments to combat this challenging disease. This study evaluates co-therapy strategies that combine non-thermal, minimally invasive ablation technology and targeted drug delivery to enhance treatment efficacy.

Our research begins by uncovering the multifaceted potential of Irreversible Electroporation (IRE), a cutting-edge non-thermal tumor ablation technique. This study demonstrates IRE-mediated ability to trigger programmed necrotic cell death, induce cell cycle arrest, and modulate immune cell populations within the tumor microenvironment. This transformation from a pro-tumor state to a proinflammatory milieu, enriched with cytotoxic T lymphocytes and neutrophils. IRE-induced proinflammation in the tumor site renders immunologically "cold" tumor into immunologically "hot" tumor and holds significant promise of improving treatment efficacy. Notably, IRE-treated mice exhibited an extended period of progression-free survival, implying clinical potential. The transient nature of these effects suggests potential mechanisms of tumor recurrence highlighting the need for further studies to maximize the efficacy of IRE. Our mechanistic studies evaluated the IFN-STAT1-PD-L1 feedback loop as a possible reason for pancreatic tumor recurrence. Our data also suggest a stronger IFN-PD-L1 feedback loop compared to mammary, osteosarcoma and glioblastoma tumors rendering pancreatic cancer immunologically "cold".

This study also investigates the use of histotripsy (a non-thermal, noninvasive, nonionizing ultrasound-guided ablation modality) to treat pancreatic cancer utilizing a novel immunocompromised swine model. We successfully generated human orthotopic pancreatic tumors in the immune deficient pigs, which allowed for consequent investigation of clinical challenges presented by histotripsy. While rigorous clinical studies are indispensable for validation, the promise of histotripsy offers new hope for patients.

In parallel, we used our immunocompromised swine model of orthotopic pancreatic cancer to investigate the SonoTran® system, which employs ultrasound-activated oscillating particles to enhance drug delivery within hard-to-reach tumors. Our study demonstrates that SonoTran® significantly enhances the intratumoral penetrance of therapeutic agents, including commonly used chemotherapy drugs like paclitaxel and gemcitabine. Additionally, SonoTran® improved delivery of the anti-epidermal growth factor (EGFR) monoclonal antibody, cetuximab- which is frequently used in cancer immunotherapy. Together, our findings address challenges in the delivery of a range of therapeutics while simultaneously exposing challenges like off-target damage.

In conclusion, this study presents a multifaceted approach to confront the complex characteristics of pancreatic cancer. Given the variations in patient response and the complexity of the disease, it is clear that a singular solution is unlikely. Our research, which combines IRE, histotripsy, and SonoTran®, to interrogate a promising array of tools to tackle different challenges to provide tailored treatments. In the ever-evolving landscape of pancreatic cancer therapy, this research opens new avenues to investigate deeper into molecular mechanisms, co-therapy treatment options, future preclinical and clinical studies which eventually encourage the potential for improved patient outcomes.