Abstract
The increasing prevalence of distant metastases from non-small cell lung cancer (NSCLC) indicates an urgent need for novel therapeutic modalities. Brain metastasis is particularly common in NSCLC, with severe adverse effects on clinical prognosis. Although the molecular heterogeneity of NSCLC and availability of various targeted agents suggest personalized therapeutic approaches for such brain metastases, further development of appropriate preclinical models is needed to validate the strategies. We established patient-derived xenografts (PDX) using NSCLC brain metastasis surgical samples and elucidated their possible preclinical and clinical implications for personalized treatment. NSCLC brain metastases (n = 34) showed a significantly higher successful PDX establishment rate than primary specimens (n = 64; 74% vs. 23%). PDXs derived from NSCLC brain metastases recapitulated the pathologic, genetic, and functional properties of corresponding parental tumors. Furthermore, tumor spheres established in vitro from the xenografts under serum-free conditions maintained their in vivo brain metastatic potential. Differential phenotypic and molecular responses to 20 targeted agents could subsequently be screened in vitro using these NSCLC PDXs derived from brain metastases. Although PDX establishment from primary NSCLCs was significantly influenced by histologic subtype, clinical aggressiveness, and genetic alteration status, the brain metastases exhibited consistently adequate in vivo tumor take rate and in vitro tumor sphere formation capacity, regardless of clinical and molecular conditions. Therefore, PDXs from NSCLC brain metastases may better represent the heterogeneous advanced NSCLC population and could be utilized as preclinical models to meet unmet clinical needs such as drug screening for personalized treatments.
Highlights
Despite efforts to develop novel personalized therapeutic strategies and predictive biomarkers, non–small cell lung cancer (NSCLC) remains the leading cause of cancer-related mortality [1]
patient-derived xenografts (PDX) derived from NSCLC brain metastases recapitulated the pathologic, genetic, and functional properties of corresponding parental tumors
Differential phenotypic and molecular responses to 20 targeted agents could subsequently be screened in vitro using these NSCLC PDXs derived from brain metastases
Summary
Despite efforts to develop novel personalized therapeutic strategies and predictive biomarkers, non–small cell lung cancer (NSCLC) remains the leading cause of cancer-related mortality [1]. 3) tyrosine kinase inhibitors to NSCLCs highlights the importance of genotype-based individualized targeted therapies. Due to the extensive molecular and functional heterogeneity of NSCLCs, genomic abnormalities often are not the ideal therapeutic efficacy predictors for various targeted agents. The major cause of death from NSCLC is metastases that are resistant to conventional therapies. Brain metastases are detected in 10% to 25% of patients with NSCLC at initial diagnosis, and 40% to 50% of patients with lung cancer develop brain metastases during their clinical course [4, 5]. There is a clinically urgent need for improved therapeutic approaches to treat patients with NSCLC
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