Introduction: Apatinib is a novel anti-angiogenic agent that targets vascular endothelial growth factor receptor-2, and is effective in patients with advanced lung cancer who are refractory to first-line chemotherapy. However, there are limited reports on concurrent apatinib therapy with iodine-125 radioactive seeds brachytherapy in elderly patients with advanced lung cancer. Patient concerns: We describe the first reported case of a 70-year-old woman with advanced lung cancer (T3N3M1, stage IV) who received concurrent apatinib and iodine-125 radioactive seeds brachytherapy after the failure of platinum-based doublet chemotherapy Diagnosis: The patient was diagnosed with left lower lung cancer with mediastinal lymph node metastasis by chest computed tomography. Interventions: Initially, apatinib alone was used as second-line cancer therapy. Subsequently, the patient received concurrent apatinib and iodine-125 radioactive seeds brachytherapy. Outcomes: The patient achieved partial response shortly after undergoing treatment with only apatinib. During the treatment, the tumor continued to respond to apatinib therapy, and the lung metastases were diminished eventually. However, a chest computed tomography scan showed a large cavity in the lung tumor. Thereafter, the patient received concurrent apatinib and iodine-125 radioactive seeds brachytherapy. Unfortunately, she died due to pulmonary infection. Conclusion: Apatinib alone may be a good second-line therapy for advanced lung cancer patients who are refractory to platinum-based doublet chemotherapy. However, its potential benefits, especially as combination therapy, need further investigation by future prospective clinical studies. Elderly patients with advanced lung cancer may benefit from concurrent apatinib with iodine-125 radioactive seeds brachytherapy when chemotherapy is not tolerated or effective. Further studies are needed to investigate the clinical outcomes and toxicities associated with concurrent apatinib and radiation therapy in patients with advanced lung cancer.
Epithelial-mesenchymal transformation (EMT) plays a pivotal role in embryonic development, tissue fibrosis, repair, and tumor invasiveness. Emerging studies have highlighted the close association between EMT and immune checkpoint molecules, particularly programmed cell death ligand 1 (PDL1). PDL1 exerts its influence on EMT through bidirectional regulation. EMT-associated factors, such as YB1, enhance PDL1 expression by directly binding to its promoter. Conversely, PDL1 signaling triggers downstream pathways like PI3K/AKT and MAPK, promoting EMT and facilitating cancer cell migration and invasion. Targeting PDL1 holds promise as a therapeutic strategy for EMT-related diseases, including cancer and fibrosis. Indeed, PDL1 inhibitors, such as pembrolizumab and nivolumab, have shown promising results in clinical trials for various cancers. Recent research has also indicated their potential benefit in fibrosis treatment in reducing fibroblast activation and extracellular matrix deposition, thereby addressing fibrosis. In this review, we examine the multifaceted role of PDL1 in immunomodulation, growth, and fibrosis promotion. We discuss the challenges, mechanisms, and clinical observations related to PDL1, including the limitations of the PD1/PDL1 axis in treatment and PD1-independent intrinsic PDL1 signaling. Our study highlights the dynamic changes in PDL1 expression during the EMT process across various tumor types. Through interplay between PDL1 and EMT, we uncover co-directional alterations, regulatory pathways, and diverse changes resulting from PDL1 intervention in oncology. Additionally, our findings emphasize the dual role of PDL1 in promoting fibrosis and modulating immune responses across multiple diseases, with potential implications for therapeutic approaches. We particularly investigate the therapeutic potential of targeting PDL1 in type II EMT fibrosis: strike balance between fibrosis modulation and immune response regulation. This analysis provides valuable insights into the multifaceted functions of PDL1 and contributes to our understanding of its complex mechanisms and therapeutic implications.
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