Abstract
Purpose: To find out the CT radiomics features of differentiating lung adenocarcinoma from another lung cancer histological type.Methods: This was a historical cohort study, three independent lung cancer cohorts included. One cohort was used to evaluate the stability of radiomics features, one cohort was used to feature selection, and the last was used to construct and evaluate classification models. The research is divided into four steps: region of interest segmentation, feature extraction, feature selection, and model building and validation. The feature selection methods included the intraclass correlation coefficient, ReliefF coefficient, and Partition-Membership filter. The performance metrics of the classification model included accuracy (Acc), precision (Pre), area under curve (AUC), and kappa statistics.Results: The 10 features (First order shape features: Sphericity and Compacity, Gray-Level Run Length Matrix: Short-Run Emphasis, Low Gray-level Run Emphasis, and High Gray-level Run Emphasis, Gray Level Co-occurrence Matrix: Homogeneity, Energy, Contrast, Correlation, and Dissimilarity) showed the most stable and classification capability. The 6 classifiers, Logistic regression classifier (LR), Sequence Minimum Optimization algorithm, Random Forest, KStar, Naive Bayes and Random Committee, have great performance both on the train and the test sets, and especially LR has the best performance on the test set (Acc = 98.72, Pre = 0.988, AUC = 1, and kappa = 0.974).Conclusion: Lung adenocarcinoma can be identified based on CT radiomics features. We can diagnose lung adenocarcinoma with CT non-invasively.
Highlights
Medical imaging can assess the characteristics of human tissues non-invasively and is often used in the diagnosis, treatment guidance and monitoring of tumors in clinical practice
The radiomics workflow is usually divided into four steps [1, 5, 6]: The first step is image collection and segmentation
All kinds of medical image formats are supported by radiomics, but in terms of the number of studies, CT radiomics has the largest number of studies, followed by PET, MR, and ultrasound
Summary
Medical imaging can assess the characteristics of human tissues non-invasively and is often used in the diagnosis, treatment guidance and monitoring of tumors in clinical practice. Radiomics can extract and quantify the differences in tumor tissues [1,2,3,4]. The radiomics workflow is usually divided into four steps [1, 5, 6]: The first step is image collection and segmentation. All kinds of medical image formats are supported by radiomics, but in terms of the number of studies, CT radiomics has the largest number of studies, followed by PET, MR, and ultrasound. This part of the work is easy to standardize
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