Erschienen in:
29.03.2022 | Imaging Informatics and Artificial Intelligence
Predicting EGFR mutation status in lung adenocarcinoma presenting as ground-glass opacity: utilizing radiomics model in clinical translation
verfasst von:
Bo Cheng, Hongsheng Deng, Yi Zhao, Junfeng Xiong, Peng Liang, Caichen Li, Hengrui Liang, Jiang Shi, Jianfu Li, Shan Xiong, Ting Lai, Zhuxing Chen, Jianrong Wu, Tianyi Qian, Wenjing Huan, Man Tat Alexander Ng, Jianxing He, Wenhua Liang
Erschienen in:
European Radiology
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Ausgabe 9/2022
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Abstract
Objectives
This study aimed to establish a non-invasive radiomics model based on computed tomography (CT), with favorable sensitivity and specificity to predict EGFR mutation status in GGO-featured lung adenocarcinoma subsequently guiding the administration of targeted therapy.
Methods
Clinical-pathological information and preoperative CT images of 636 lung adenocarcinoma patients (464, 100, and 72 in the training, internal, and external validation sets, respectively) that underwent GGO lesions resection were included. A total of 1476 radiomics features were extracted with gradient boosting decision tree (GBDT).
Results
The established radiomics model containing 102 selected features showed an encouraging discrimination performance of EGFR mutation status (mutant or wild type), and the predictive ability was superior to that of the clinical model (AUC: 0.838 vs. 0.674, 0.822 vs. 0.730, and 0.803 vs. 0.746 for the training, internal validation, and external validation sets, respectively). The combined radiomics plus clinical model showed no additional benefit over the radiomics model in predicting EGFR status (AUC: 0.846 vs. 0.838, 0.816 vs. 0.822, and 0.811 vs. 0.803, respectively, in three cohorts). Uniquely, this model was validated in a cohort of lung adenocarcinoma patients who have undertaken adjuvant EGFR-TKI treatment and harbored unresected GGOs during the medication, leading to a significantly improved potency of EGFR-TKIs (response rate: 25.9% vs. 53.8%, p = 0.006; before and after prediction, respectively).
Conclusion
This presented radiomics model can be served as a non-invasive and time-saving approach for predicting the EGFR mutation status in lung adenocarcinoma presenting as GGO.
Key Points
• We developed a GGO-specific radiomics model containing 102 radiomics features for EGFR mutation status differentiation.
• An AUC of 0.822 and 0.803 in the internal and external validation cohorts, respectively, were achieved.
• The radiomics model was utilized in clinical translation in an adjuvant EGFR-TKI treatment cohort with unresected GGOs. A significant improvement in the potency of EGFR-TKIs was achieved (response rate: 25.9% vs. 53.8%, p = 0.006; before and after prediction).