Toward automatic prediction of EGFR mutation status in pulmonary adenocarcinoma with 3D deep learning.
Wei ZhaoJiancheng YangBingbing NiDexi BiYingli SunMengdi XuXiaoxia ZhuCheng LiLiang JinPan GaoPeijun WangYanqing HuaMing LiPublished in: Cancer medicine (2019)
To develop a deep learning system based on 3D convolutional neural networks (CNNs), and to automatically predict EGFR-mutant pulmonary adenocarcinoma in CT images. A dataset of 579 nodules with EGFR mutation status labels of mutant (Mut) or wild-type (WT) was retrospectively analyzed. A deep learning system, namely 3D DenseNets, was developed to process 3D patches of nodules from CT data, and learn strong representations with supervised end-to-end training. The 3D DenseNets were trained with a training subset of 348 nodules and tuned with a development subset of 116 nodules. A strong data augmentation technique, mixup, was used for better generalization. We evaluated our model on a holdout subset of 115 nodules. An independent public dataset of 37 nodules from the cancer imaging archive (TCIA) was also used to test the generalization of our method. Conventional radiomics analysis was also performed for comparison. Our method achieved promising performance on predicting EGFR mutation status, with AUCs of 75.8% and 75.0% for our holdout test set and public test set, respectively. Moreover, strong relations were found between deep learning feature and conventional radiomics, while deep learning worked through an enhanced radiomics manner, that is, deep learned radiomics (DLR), in terms of robustness, compactness and expressiveness. The proposed deep learning system predicts EGFR-mutant of lung adenocarcinomas in CT images noninvasively and automatically, indicating its potential to help clinical decision-making by identifying eligible patients of pulmonary adenocarcinoma for EGFR-targeted therapy.
Keyphrases
- deep learning
- convolutional neural network
- small cell lung cancer
- epidermal growth factor receptor
- tyrosine kinase
- contrast enhanced
- wild type
- artificial intelligence
- machine learning
- pulmonary hypertension
- lymph node metastasis
- squamous cell carcinoma
- computed tomography
- healthcare
- big data
- image quality
- decision making
- mental health
- magnetic resonance imaging
- magnetic resonance
- high resolution
- electronic health record
- locally advanced
- mass spectrometry
- working memory
- virtual reality
- body composition
- squamous cell
- photodynamic therapy
- prognostic factors
- radiation therapy
- resistance training
- patient reported outcomes
- young adults