类有机物
生物标志物
转录组
癌症研究
计算生物学
生物标志物发现
蛋白质组学
医学
药品
细胞外基质
药物发现
生物
肿瘤微环境
药物开发
去细胞化
靶向治疗
生物信息学
精密医学
转化研究
病理
癌症生物标志物
循环肿瘤细胞
放射治疗
液体活检
精确肿瘤学
诊断生物标志物
作者
Beibei Liu,Huiyan Cheng,Keke Yu,Wen Xu,Xiaoting Tian,Yuhan Xu,Yanbin Kuang,Jun Lu,Rong Li,Xiao Zhang,Min Tang,Jianxin Xue,Yuqing Lou
标识
DOI:10.1016/j.mtbio.2026.102878
摘要
Thymic epithelial tumors (TETs), including thymic carcinoma and thymoma, are rare malignancies lacking both effective therapies and validated biomarkers to guide treatment. Here, we report the first 3D (three-dimensional) bioprinted organoid model of TETs, established through a proteomic data-driven biomaterial design strategy. Patient tumor tissues were first decellularized and analyzed by proteomics to determine their extracellular matrix (ECM) composition. The results revealed distributions of ECM proteins which guided the formulation of photocurable bioinks. The resulting 3D-bioprinted organoids supported primary TET cell proliferation, and more faithfully replicated the biophysical properties and molecular characteristics of native tumors than traditional Matrigel-cultured organoids. Leveraging this biomimetic platform, we conducted high-throughput drug screening and identified lurbinectedin as a potent therapeutic candidate for TETs. Transcriptomic profiling revealed its anti-TET mechanism. Integrating RNAseq data with TCGA survival analysis further identified PBX3, REPS2, and CXCR4 as potential efficacy-predictive biomarkers. This study establishes a translational framework linking 3D bioprinted TET models with biomarker discovery, offering a standardized platform for precision drug screening and mechanistic exploration in thymic epithelial tumors.
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