Application Research of Methylation Markers in Early-stage Lung Cancer Patients Treated With Co-ablation System Therapy

Lung cancer is one of the major malignant tumors threatening human life and health, with its incidence and mortality rates consistently ranking first among all malignant tumors globally. China has a high incidence of lung cancer. According to the latest data released by the National Cancer Center, in 2022, there were 1,060,600 new cases of lung cancer in China, accounting for 22.0% of all new malignant tumor cases, and 733,300 deaths, accounting for 28.5% of all malignant tumor deaths.

Among patients with non-small cell lung cancer (NSCLC), the risk of recurrence varies significantly across different stages: the 5-year recurrence rates are 19% for stage IA, 30% for stage IB, and 48.6% for stage II, while the 3-year recurrence rate for stage III patients is as high as 52%. Early surgical resection is the primary treatment method to improve the survival rate of lung cancer patients. As a local treatment modality, Co-ablation system therapy are particularly suitable for patients who cannot tolerate surgery or are ineligible for surgical treatment. However, postoperative recurrence and metastasis remain the core challenges in lung cancer treatment. Even when imaging examinations show that the tumor has achieved a so-called "no evidence of disease" status (R0 resection)-meaning the tumor has disappeared at the macroscopic and imaging levels-minimal residual disease (MRD) that may trigger cancer recurrence could still be hidden beneath this appearance.

Currently, mainstream MRD detection methods on the market rely on the detection of mutations in circulating tumor DNA (ctDNA). However, such mutation-based MRD detection has obvious limitations. For instance, the heterogeneity of tumor mutations among different patients is extremely high, making it difficult for small-sized detection panels to cover a broader patient population. The Tumor-inform detection approach achieves MRD detection by customizing a specific panel for each patient, but this method requires obtaining the patient's tumor tissue sample for sequencing, which to some extent limits its clinical application.

In contrast, when DNA methylation markers are used for MRD detection, there is no need to pre-obtain characteristic mutation information of the primary tumor, and the detection sensitivity is not affected by the number of high-frequency mutations in the patient's tumor. Moreover, DNA methylation modifications usually occur in the early stages of tumorigenesis and exhibit tissue specificity and cancer type specificity. At the same time, DNA methylation often maintains good consistency across multiple gene regions; therefore, MRD analysis can be achieved by detecting the methylation status of multiple CpG sites.

This study selected patients diagnosed with non-small cell lung cancer through histopathology or clinical diagnosis, all of whom underwent Co-ablation system therapy. Peripheral blood samples were collected from all enrolled patients at 3 days, 1 month, 3 months, 6 months, 12 months, 18 months, and 24 months after treatment for SHOX2/PTGER4 gene methylation detection. The study aims to explore whether this gene methylation detection can serve as an effective indicator for dynamic MRD monitoring in lung cancer patients after Co-ablation system therapy and to analyze its clinical efficacy in lung cancer patients. It is expected to provide a scientific basis for predicting the risk of lung cancer recurrence and guiding individualized treatment decisions, thereby avoiding overtreatment or delayed treatment.