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http://dx.doi.org/10.17946/JRST.2020.43.6.503

Comparison of CT Exposure Dose Prediction Models Using Machine Learning-based Body Measurement Information  

Hong, Dong-Hee (Dept. of Radiological Science, Shinhan University)
Publication Information
Journal of radiological science and technology / v.43, no.6, 2020 , pp. 503-509 More about this Journal
Abstract
This study aims to develop a patient-specific radiation exposure dose prediction model based on anthropometric data that can be easily measurable during CT examination, and to be used as basic data for DRL setting and radiation dose management system in the future. In addition, among the machine learning algorithms, the most suitable model for predicting exposure doses is presented. The data used in this study were chest CT scan data, and a data set was constructed based on the data including the patient's anthropometric data. In the pre-processing and sample selection of the data, out of the total number of samples of 250 samples, only chest CT scans were performed without using a contrast agent, and 110 samples including height and weight variables were extracted. Of the 110 samples extracted, 66% was used as a training set, and the remaining 44% were used as a test set for verification. The exposure dose was predicted through random forest, linear regression analysis, and SVM algorithm using Orange version 3.26.0, an open software as a machine learning algorithm. Results Algorithm model prediction accuracy was R^2 0.840 for random forest, R^2 0.969 for linear regression analysis, and R^2 0.189 for SVM. As a result of verifying the prediction rate of the algorithm model, the random forest is the highest with R^2 0.986 of the random forest, R^2 0.973 of the linear regression analysis, and R^2 of 0.204 of the SVM, indicating that the model has the best predictive power.
Keywords
Machine learning; Random forest; Linear regression; Support vector machine; Exposure;
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Times Cited By KSCI : 5  (Citation Analysis)
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