Predicting Total Dwell Time of IPSA Plan Based on Machine Learning and Dose Calculation Models
Xiufeng Cong, Jun Chen, Jingchao Zhang, Xiaoting Zhang, Wei Zheng*
Department of Clinical Oncology, Shengjing Hospital of China Medical University, Shenyang Liaoning 110024, China; Correspondence: Wei Zheng, Department of Clinical Oncology, Shengjing Hospital of China Medical University, Shenyang Liaoning 110042, China
Predicting Total Dwell Time of IPSA Plan Based on Machine Learning and Dose Calculation Models
Xiufeng Cong, Jun Chen, Jingchao Zhang, Xiaoting Zhang, Wei Zheng*
Department of Clinical Oncology, Shengjing Hospital of China Medical University, Shenyang Liaoning 110024, China Correspondence: Wei Zheng, Department of Clinical Oncology, Shengjing Hospital of China Medical University, Shenyang Liaoning 110042, China
摘要Objective To establish two models based on machine learning and dose calculation algorithm that can be used for the prediction of the total dwell time and rapid quality control of brachytherapy plans.Methods A total of 1042 cases of treated gynecologic oncology patients were selected, of which 512 were used as training data to establish the model and the rest were used as test data. Each treatment plan optimized by inverse planning simulated annealing with all three catheters of the Fletcher applicator. The source strength Sk, prescription dose D, source dwell time t, and tumor volume V were recorded for each case. RV was defined as Sk·t/D. In accordance with the prescription dosage calculation formula in the planning system and machine learning method, the following equations were established: RV=kV2/3 and RV=a+b·V+c·V2. The R2 correlation coefficient represents the accuracy of the results.Result The dose calculation algorithm-based model is RV=1272×V2/3, R2=0.959, whereas the machine learning-based model is RV=258.8×V-0.359×V2+5110, R2=0.961. The treatment time prediction of the two models, each having 13 and 15 cases, respectively, has an error rate of more than 10%, and the dose calculation algorithm -based method is more accurate.Conclusion The treatment time can be quickly predicted according to the planning target volume, and the two prediction models can be used as a way of quality control.
Abstract:Objective To establish two models based on machine learning and dose calculation algorithm that can be used for the prediction of the total dwell time and rapid quality control of brachytherapy plans.Methods A total of 1042 cases of treated gynecologic oncology patients were selected, of which 512 were used as training data to establish the model and the rest were used as test data. Each treatment plan optimized by inverse planning simulated annealing with all three catheters of the Fletcher applicator. The source strength Sk, prescription dose D, source dwell time t, and tumor volume V were recorded for each case. RV was defined as Sk·t/D. In accordance with the prescription dosage calculation formula in the planning system and machine learning method, the following equations were established: RV=kV2/3 and RV=a+b·V+c·V2. The R2 correlation coefficient represents the accuracy of the results.Result The dose calculation algorithm-based model is RV=1272×V2/3, R2=0.959, whereas the machine learning-based model is RV=258.8×V-0.359×V2+5110, R2=0.961. The treatment time prediction of the two models, each having 13 and 15 cases, respectively, has an error rate of more than 10%, and the dose calculation algorithm -based method is more accurate.Conclusion The treatment time can be quickly predicted according to the planning target volume, and the two prediction models can be used as a way of quality control.
通讯作者:
Wei Zheng, Date of birth: December 1967; Degree: Doctor of Medicine; Title: Associate Professor; Presided over 2 provincial projects and 1 municipal project.
作者简介: Xiufeng Cong, born in 1981, doctor of medicine, attending physician, graduated from clinical medicine English class of China Medical University in 2006. She is a member of IASLC of International Lung Cancer Association. She is now working in the oncology Department of Shengjing Hospital Affiliated to China Medical University. She is engaged in radiotherapy, chemotherapy, targeted therapy and other comprehensive treatment of tumors, and has published many journal articles at home and abroad.
引用本文:
Xiufeng Cong, Jun Chen, Jingchao Zhang, Xiaoting Zhang, Wei Zheng. Predicting Total Dwell Time of IPSA Plan Based on Machine Learning and Dose Calculation Models[J]. 中国生物医学工程学报(英文版), 2020, 29(1): 16-20.
Xiufeng Cong, Jun Chen, Jingchao Zhang, Xiaoting Zhang, Wei Zheng. Predicting Total Dwell Time of IPSA Plan Based on Machine Learning and Dose Calculation Models. Chinese Journal of Biomedical Engineering, 2020, 29(1): 16-20.
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