Study on the sensitivity of a volumetric modulated arc therapy plan verification equipment on multi-leaf collimator opening and closing errors and its gamma pass rate limit_Journal of Biomedical Engineering

Authors：

HU Jinyou ^1,2 , ZOU Lian ² , GU Shaoxian ¹ , WANG Ningyu ¹ , CUI Fengjie ¹ , ZHANG Shengyuan ¹ , YIN Chu’ou ¹ , CAI Yunzhu ¹ , GOU Chengjun ¹ ,  WU Zhangwen ¹

1. Key Laboratory of Radiation Physics and Technology of the Ministry of Education, Institute of Nuclear Science and Technology, Sichuan University, Chengdu 610064, P. R. China;
2. Cancer Center, Sichuan Academy of Medical Sciences & Sichuan Provincial People's Hospital, Chengdu 610072, P. R. China;

Corresponding author：

WU Zhangwen, Email: wuzhangwen@scu.edu.cn

Keywords：

Volumetric modulated arc therapy; Plan verification; Statistical process control; Receiver operating characteristic curve; Limit value of γ pass rate; Errors of multi-leaf collimator

DOI：

10.7507/1001-5515.202112018

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To investigate the γ pass rate limit of plan verification equipment for volumetric modulated arc therapy (VMAT) plan verification and its sensitivity on the opening and closing errors of multi-leaf collimator (MLC), 50 cases of nasopharyngeal carcinoma VMAT plan with clockwise and counterclockwise full arcs were randomly selected. Eight kinds of MLC opening and closing errors were introduced in 10 cases of them, and 80 plans with errors were generated. Firstly, the plan verification was conducted in the form of field-by-field measurement and true composite measurement. The γ analysis with the criteria of 3% dose difference, distance to agreement of 2 mm, 10% dose threshold, and absolute dose global normalized conditions were performed for these fields. Then gradient analysis was used to investigate the sensitivity of field-by-field measurement and true composite measurement on MLC opening and closing errors, and the receiver operating characteristic curve (ROC) was used to investigate the optimal threshold of γ pass rate for identifying errors. Tolerance limits and action limits for γ pass rates were calculated using statistical process control (SPC) method for another 40 cases. The error identification ability using the tolerance limit calculated by SPC method and the universal tolerance limit (95%) were compared with using the optimal threshold of ROC. The results show that for the true composite measurement, the clockwise arc and the counterclockwise arc, the descent gradients of the γ passing rate with per millimeter MLC opening error are 10.61%, 7.62% and 6.66%, respectively, and the descent gradients with per millimeter MLC closing error are 9.75%, 7.36% and 6.37%, respectively. The optimal thresholds obtained by the ROC method are 99.35%, 97.95% and 98.25%, respectively, and the tolerance limits obtained by the SPC method are 98.98%, 97.74% and 98.62%, respectively. The tolerance limit calculated by SPC method is close to the optimal threshold of ROC, both of which could identify all errors of ±2 mm, while the universal tolerance limit can only partially identify them, indicating that the universal tolerance limit is not sensitive on some large errors. Therefore, considering the factors such as ease of use and accuracy, it is suggested to use the true composite measurement in clinical practice, and to formulate tolerance limits and action limits suitable for the actual process of the institution based on the SPC method. In conclusion, it is expected that the results of this study can provide some references for institutions to optimize the radiotherapy plan verification process, set appropriate pass rate limit, and promote the standardization of plan verification.

Citation： HU Jinyou, ZOU Lian, GU Shaoxian, WANG Ningyu, CUI Fengjie, ZHANG Shengyuan, YIN Chu’ou, CAI Yunzhu, GOU Chengjun, WU Zhangwen. Study on the sensitivity of a volumetric modulated arc therapy plan verification equipment on multi-leaf collimator opening and closing errors and its gamma pass rate limit. Journal of Biomedical Engineering, 2023, 40(1): 133-140. doi: 10.7507/1001-5515.202112018 Copy

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11.	Pawlicki T, Whitaker M, Boyer A L. Statistical process control for radiotherapy quality assurance. Medical Physics, 2005, 32(9): 2777-2786.
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14.	Thiyagarajan R, Nambiraj A, Sinha S N, et al. Analyzing the performance of ArcCHECK diode array detector for VMAT plan. Reports of Practical Oncology and Radiotherapy, 2016, 21(1): 50-56.
15.	Aristophanous M, Suh Y, Chi P C, et al. Initial clinical experience with ArcCHECK for IMRT/VMAT QA. J Appl Clin Med Phys, 2016, 17(5): 20-33.
16.	Chang K H, Kim D W, Choi J H, et al. Dosimetric comparison of four commercial patient-specific quality assurance devices for helical tomotherapy. Journal of the Korean Physical Society, 2020, 76(3): 257-263.
17.	Liang B, Liu B, Zhou F, et al. Comparisons of volumetric modulated arc therapy (VMAT) quality assurance (QA) systems: sensitivity analysis to machine errors. Radiation Oncology, 2016, 11(1): 146.
18.	郭伟, 毛荣虎, 李兵, 等. 基于AAPM-TG218报告对调强放疗计划剂量验证容差和干预限值的初步研究. 中华放射肿瘤学杂志, 2021, 30(8): 817-821.
19.	肖青, 李光俊, 李治斌, 等. 基于AAPM TG-218报告应用统计过程控制技术监测患者个体化容积旋转调强放疗质量保证过程的初步研究. 生物医学工程学杂志, 2020, 37(5): 842-847.
20.	Xiao Q, Bai L, Li G, et al. A robust approach to establish tolerance limits for the gamma passing rate-based patient-specific quality assurance using the heuristic control charts. Med Phys, 2022, 49(2): 1312-1330.
21.	Chan G H, Chin L C L, Abdellatif A, et al. Survey of patient-specific quality assurance practice for IMRT and VMAT. J Appl Clin Med Phys, 2021, 22(7): 155-164.
22.	Sanghangthum T, Suriyapee S, Kim G G Y, et al. A method of setting limits for the purpose of quality assurance. Physics in Medicine and Biology, 2013, 58(19): 7025-7037.
23.	Fuangrod T, Greer P B, Simpson J, et al. A method for evaluating treatment quality using in vivo EPID dosimetry and statistical process control in radiation therapy. International Journal of Health Care Quality Assurance, 2017, 30(2): 90-102.
24.	Pan Y, Yang R, Zhang S, et al. National survey of patient specific IMRT quality assurance in China. Radiation oncology, 2019, 14(1): 69.
25.	Cui T, Peng J X, Jin X L, et al. Improving intensity-modulated radiation therapy quality assurance by adopting statistical process control. Cancer Radiother, 2022, 26(3): 427-432.
26.	Xiao Q, Bai S, Li G, et al. Statistical process control and process capability analysis for non-normal volumetric modulated arc therapy patient-specific quality assurance processes. Medical Physics, 2020, 47(10): 4694-4702.
27.	Tattenberg S, Hyde D, Milette M P, et al. Assessment of the Sun Nuclear ArcCHECK to detect errors in 6MV FFF VMAT delivery of brain SABR using ROC analysis. J Appl Clin Med Phys, 2021, 22(6): 35-44.
28.	Woon W, Ravindran P B, Ekayanake P, et al. A study on the effect of detector resolution on gamma index passing rate for VMAT and IMRT QA. J Appl Clin Med Phys, 2018, 19(2): 230-248.
29.	Pogson E M, Arumugam S, Hansen C R, et al. Comparison of multi-institutional pre-treatment verification for VMAT of nasopharynx with delivery errors. Physica Medica, 2018, 53: 25-31.
30.	叶淑敏, 滕建建, 石锦平, 等. MLC叶片系统误差对鼻咽癌VMAT和IMRT计划剂量影响的比较. 中国医学物理学杂志, 2019, 36(10): 1139-1144.

1. Ling C C, Zhang P, Archambault Y, et al. Commissioning and quality assurance of rapidarc radiotherapy delivery system. Int J Radiat Oncol Biol Phys, 2008, 72(2): 575-581.
2. Verbakel W F, Cuijpers J P, Hoffmans D, et al. Volumetric intensity-modulated arc therapy vs. conventional IMRT in head-and-neck cancer: a comparative planning and dosimetric study. Int J Radiat Oncol Biol Phys, 2009, 74(1): 252-259.
3. Low D A, Harms W B, Mutic S, et al. A technique for the quantitative evaluation of dose distributions. Medical Physics, 1998, 25(5): 656-661.
4. Podesta M, Nijsten S M, Persoon L C, et al. Time dependent pre-treatment EPID dosimetry for standard and FFF VMAT. Phys Med Biol, 2014, 59(16): 4749-4768.
5. Carrasco P, Jornet N, Latorre A, et al. 3D DVH-based metric analysis versus per-beam planar analysis in IMRT pretreatment verification. Medical Physics, 2012, 39(8): 5040-5049.
6. Alharthi T, Vial P, Holloway L, et al. Intrinsic detector sensitivity analysis as a tool to characterize ArcCHECK and EPID sensitivity to variations in delivery for lung SBRT VMAT plans. J Appl Clin Med Phys, 2021, 22(6): 229-240.
7. Palta J R, Mackie T R, Chen Z. Intensity-modulated radiation therapy: the state of the art. Medical Physics, 2003, 30(12): 3265.
8. Ezzell G A, Burmeister J W, Dogan N, et al. IMRT commissioning: multiple institution planning and dosimetry comparisons, a report from AAPM Task Group 119. Medical physics, 2009, 36(11): 5359-5373.
9. Carlone M, Cruje C, Rangel A, et al. ROC analysis in patient specific quality assurance. Medical Physics, 2013, 40(4): 042103.
10. Miften M, Olch A, Mihailidis D, et al. Tolerance limits and methodologies for IMRT measurement-based verification QA: recommendations of AAPM Task Group No. 218. Medical Physics, 2018, 45(4): e53-e83.
11. Pawlicki T, Whitaker M, Boyer A L. Statistical process control for radiotherapy quality assurance. Medical Physics, 2005, 32(9): 2777-2786.
12. Breen S L, Moseley D J, Zhang B, et al. Statistical process control for IMRT dosimetric verification. Medical Physics, 2008, 35(10): 4417-4425.
13. Gérard K, Grandhaye J P, Marchesi V, et al. A comprehensive analysis of the IMRT dose delivery process using statistical process control (SPC). Medical Physics, 2009, 36(4): 1275-1285.
14. Thiyagarajan R, Nambiraj A, Sinha S N, et al. Analyzing the performance of ArcCHECK diode array detector for VMAT plan. Reports of Practical Oncology and Radiotherapy, 2016, 21(1): 50-56.
15. Aristophanous M, Suh Y, Chi P C, et al. Initial clinical experience with ArcCHECK for IMRT/VMAT QA. J Appl Clin Med Phys, 2016, 17(5): 20-33.
16. Chang K H, Kim D W, Choi J H, et al. Dosimetric comparison of four commercial patient-specific quality assurance devices for helical tomotherapy. Journal of the Korean Physical Society, 2020, 76(3): 257-263.
17. Liang B, Liu B, Zhou F, et al. Comparisons of volumetric modulated arc therapy (VMAT) quality assurance (QA) systems: sensitivity analysis to machine errors. Radiation Oncology, 2016, 11(1): 146.
18. 郭伟, 毛荣虎, 李兵, 等. 基于AAPM-TG218报告对调强放疗计划剂量验证容差和干预限值的初步研究. 中华放射肿瘤学杂志, 2021, 30(8): 817-821.
19. 肖青, 李光俊, 李治斌, 等. 基于AAPM TG-218报告应用统计过程控制技术监测患者个体化容积旋转调强放疗质量保证过程的初步研究. 生物医学工程学杂志, 2020, 37(5): 842-847.
20. Xiao Q, Bai L, Li G, et al. A robust approach to establish tolerance limits for the gamma passing rate-based patient-specific quality assurance using the heuristic control charts. Med Phys, 2022, 49(2): 1312-1330.
21. Chan G H, Chin L C L, Abdellatif A, et al. Survey of patient-specific quality assurance practice for IMRT and VMAT. J Appl Clin Med Phys, 2021, 22(7): 155-164.
22. Sanghangthum T, Suriyapee S, Kim G G Y, et al. A method of setting limits for the purpose of quality assurance. Physics in Medicine and Biology, 2013, 58(19): 7025-7037.
23. Fuangrod T, Greer P B, Simpson J, et al. A method for evaluating treatment quality using in vivo EPID dosimetry and statistical process control in radiation therapy. International Journal of Health Care Quality Assurance, 2017, 30(2): 90-102.
24. Pan Y, Yang R, Zhang S, et al. National survey of patient specific IMRT quality assurance in China. Radiation oncology, 2019, 14(1): 69.
25. Cui T, Peng J X, Jin X L, et al. Improving intensity-modulated radiation therapy quality assurance by adopting statistical process control. Cancer Radiother, 2022, 26(3): 427-432.
26. Xiao Q, Bai S, Li G, et al. Statistical process control and process capability analysis for non-normal volumetric modulated arc therapy patient-specific quality assurance processes. Medical Physics, 2020, 47(10): 4694-4702.
27. Tattenberg S, Hyde D, Milette M P, et al. Assessment of the Sun Nuclear ArcCHECK to detect errors in 6MV FFF VMAT delivery of brain SABR using ROC analysis. J Appl Clin Med Phys, 2021, 22(6): 35-44.
28. Woon W, Ravindran P B, Ekayanake P, et al. A study on the effect of detector resolution on gamma index passing rate for VMAT and IMRT QA. J Appl Clin Med Phys, 2018, 19(2): 230-248.
29. Pogson E M, Arumugam S, Hansen C R, et al. Comparison of multi-institutional pre-treatment verification for VMAT of nasopharynx with delivery errors. Physica Medica, 2018, 53: 25-31.
30. 叶淑敏, 滕建建, 石锦平, 等. MLC叶片系统误差对鼻咽癌VMAT和IMRT计划剂量影响的比较. 中国医学物理学杂志, 2019, 36(10): 1139-1144.

Journal of Biomedical Engineering

Study on the sensitivity of a volumetric modulated arc therapy plan verification equipment on multi-leaf collimator opening and closing errors and its gamma pass rate limit

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