Discussion
With continuous advances in tumor diagnosis and treatment, the incidence of second primary cancers among patients with breast cancer has steadily increased. Studies indicate that lung cancer is one of the most common second primary malignancies following breast cancer, with a median onset age of 50–59 years and a median interval of 43.5–60.0 months. Lung cancer accounts for 0.8–1.4% of synchronous second primary cancers in patients with breast cancer. Smoking, radiotherapy and chemotherapy are established risk factors for dual primary breast and lung cancers (11). MBC, accounting for <1% of breast cancer cases, is exceedingly rare, and multiple primary cancers in MBC are even more uncommon. Compared with women, men are diagnosed with breast cancer at an older mean age of 67 years, with a 25% higher mortality rate (12,13). MBC is predominantly hormone-dependent. Research shows a strong correlation between estrogen and lung cancer, with numerous lung cancer cells overexpressing ER (14). While 90% of MBC cases are ER-positive, only 8.7% are HER-2-positive. Most cases present with painless sub-nipple nodules, with 40–50% involving the nipple, and left-sided breast cancer is slightly more common (15,16). Advanced cases may show skin changes, nipple retraction, ulcers or masses fixed to underlying tissues, often with axillary lymphadenopathy. Breast cancer susceptibility (BRCA) gene mutations are the most recognized risk factors for MBC. Additional risk factors include family history, chest radiation exposure, germline mutations (e.g., BRCA2, BRCA1, checkpoint kinase 2, and partner and localizer of BRCA2), and exogenous estrogen use. A large study of 2,175 cases of MBC revealed significantly higher AR/PR positivity rates in MBC vs. female breast cancer, with HER-2 negativity being more common (17). PIK3CA mutations are prevalent in breast cancers and correlate with a poor prognosis (18). The patient in the present case exhibited advanced MBC with synchronous primary lung adenocarcinoma, which is a rare combination. IHC demonstrated HR and AR positivity, HER-2 positivity and PIK3CA mutations.
Similarly, an International MBC Program analysis of 1,483 MBC cases showed 99% ER-positivity and only 9% HER2-positivity. However, the present case exhibited HER2-positivity (3+), resembling the molecular profile more common in female breast cancer. This observation aligns with a 2023 New England Journal of Medicine review stating ‘the HER2-positivity rate in men is comparable to that in older postmenopausal women’ (15). The high ER and AR expression in the present study and its potential link to lung adenocarcinoma also support Fentiman's ‘estrogen cross-talk’ theory (19). Treatment-wise, a real-world study from China retrospectively collected data from patients with MBC across 36 centers in the country. The study suggested that an anthracycline combined with taxane regimen is a protective factor for disease-free survival in these patients (20). The present case adopted a neoadjuvant TCbHP regimen, using taxane-based drugs. The stable pulmonary lesion in the present study also aligns with the study by Peng et al (21), which reported a 74.2% 5-year overall survival rate after surgical resection of synchronous multiple primary lung adenocarcinomas.
Research suggests 22.9–70.0% of patients with breast cancer and lung nodules have primary lung cancer. The epidermal growth factor receptor (EGFR) signaling pathway is vital in tumorigenesis, progression and metastasis. EGFR mutations are the most common driver mutations in lung cancer and are associated with apoptosis inhibition, angiogenesis and tumor vasculature formation (22,23). Evidence shows cross-signaling between ER/PR and EGFR pathways in patients with breast cancer and second primary lung cancer, suggesting shared biological mechanisms and overlapping risk factors such as elevated hormone levels. Clinical data indicate that EGFR mutation rates in patients with dual primary breast and lung cancers are twice those in patients with non-small cell lung cancer (NSCLC). EGFR signaling may thus be critical in lung cancer development as a second primary malignancy in patients with breast cancer (24).
Additionally, epithelial cell adhesion molecule (EpCAM), a single-pass transmembrane glycoprotein, is upregulated in epithelial-derived malignancies such as breast and lung cancers. EpCAM interferes with key tumorigenic signaling pathways, contributing to progression. A study has demonstrated its association with metastasis, drug resistance and prognosis in breast cancer, and its correlation with Tumor-Node-Metastasis staging (25) in squamous cell lung carcinoma (26). Weak EpCAM expression in normal epithelial cells vs. strong expression in cancer tissues highlights its carcinogenic role. Immunohistochemical analysis of EpCAM expression and exploration of anti-EpCAM immunotherapy may provide new treatment directions (27).
The rhodopsin family is closely associated with tumor biology, including cellular growth, differentiation and migration; its role in the initiation, progression, metastasis and drug resistance of breast and lung cancers is well-studied. Ras homolog family member A (RhoA) and RhoC regulate cytoskeletal reorganization, contributing to tumor cell invasion and metastasis. High RhoC expression promotes breast cancer cell invasion and metastasis by enhancing actin remodeling and extracellular matrix degradation through increased matrix metalloproteinase secretion. Similarly, RhoC is significantly upregulated in NSCLC, facilitating distant metastasis (28). Rac family small GTPase 1 (Rac1) modulates the tumor microenvironment, promoting invasive migration of breast cancer cells. Rac1 also activates the shared phosphatidylinositol 3-kinase (PI3K)/Akt pathway in breast and lung cancers, which is implicated in chemotherapy resistance in breast cancer and targeted therapy resistance in lung cancer (29). Both RhoA and Rac1 activate the mitogen-activated protein kinase (MAPK) signaling pathway in these cancer types, driving cell proliferation and anti-apoptotic processes (30). Additionally, RhoA and RhoC collaboratively reshape the tumor microenvironment, bolstering tumor cell immune evasion (31,32). Targeted inhibition of oncogenes such as Rac1, RhoA and RhoC presents a promising strategy to reduce the invasive potential of breast and lung cancer cells. This approach underscores the therapeutic potential of targeting shared molecular mechanisms to manage dual malignancies effectively.
Furthermore, in the present report of synchronous primary MBC and lung adenocarcinoma, potential biological associations are explored. Previous studies suggest that these cancers may share common risk factors and oncogenic pathways, such as chronic smoking, radiation exposure and elevated hormone levels (33,34). Based on large-scale genome-wide association study data, researchers have analyzed shared pathogenic mechanisms between breast and lung cancers genome-wide. Findings indicate that both malignancies converge on the erb-b2 receptor tyrosine kinase 2 signaling pathway, toll-like receptor 2 signaling cascade, and nuclear factor-κB and MAPK pathways, suggesting possible common genetic origins (35). As breast cancer is an estrogen-dependent tumor, its development and progression are closely linked to ER status. In normal breast tissue, ER mediates downstream cascades, including Ras/Raf/MAPK and PI3K/AKT/mTOR pathways, regulating proliferation, metabolism, survival and apoptosis. Dysregulated estrogen metabolism may impair ER function and contribute to tumorigenesis (36,37). Emerging evidence also indicates that ER status may influence lung cancer pathogenesis. In a study of 110 female patients with both cancer types, 80% of breast tumors were ER-negative, suggesting a potential association (38). This supports a significant association between ER-negative breast cancer and primary lung adenocarcinoma occurrence. In the present study, the patient exhibited HER2 positivity, hormone receptor positivity and a PIK3CA mutation, indicating possible molecular involvement of multiple co-activated oncogenic pathways. Based on this profile, we hypothesize the synchronous tumors may be biologically linked, although larger studies are needed for validation.
Standard MBC treatment follows female breast cancer protocols, including mastectomy and endocrine therapy for hormone receptor-positive cases (39). Currently, in clinical practice, the application of traditional Chinese medicine as an adjunct to radiotherapy and chemotherapy in the treatment of breast cancer is widespread. This addition can enhance therapeutic efficacy, reduce side effects, promote the recovery of physical function after cancer treatment, decrease recurrence and metastasis, and improve quality of life (40). Research has found that Huangqi Sijun Decoction can alleviate fatigue in patients with breast cancer after chemotherapy (41), while Wenshen Zhuanggu Formula can reduce leukopenia, nausea, vomiting, gastrointestinal reactions, hair loss and bone marrow suppression (42). Adverse events were evaluated according to the Common Terminology Criteria for Adverse Events version 5.0 (43).
In the present study, integrating traditional Chinese medicine with Western cancer treatment alleviated the patient's discomfort and chemotherapy-induced bone marrow suppression. Both traditional decoctions and Chinese herbal medicine serve as important approaches in the treatment of breast cancer, and hold important implications for breast cancer therapy. During chemotherapy, no grade 3 or greater nausea/vomiting occurred (43). Multidisciplinary management effectively controlled both malignancies, with the patient remaining recurrence-free for >1 year post-treatment. This underscores the importance of comprehensive, integrative strategies and long-term follow-up for managing rare, complex cancer cases.