实现光子/电子 EBRT 初始图表检查的自动化：新 AAPM 工作组报告和自动化技术的临床实施。

Toward automation of initial chart check for photon/electron EBRT: the clinical implementation of new AAPM task group reports and automation techniques.

机构信息

University of Maryland School of Medicine, Baltimore, MD, USA.

出版信息

J Appl Clin Med Phys. 2021 Mar;22(3):234-245. doi: 10.1002/acm2.13200. Epub 2021 Mar 11.

DOI:10.1002/acm2.13200

PMID:33705604

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7984492/

Abstract

PURPOSE

The recently published AAPM TG-275 and the public review version of TG-315 list new recommendations for comprehensive and minimum physics initial chart checks, respectively. This article addresses the potential development and benefit of initial chart check automation when these recommendations are implemented for clinical photon/electron EBRT.

METHODS

Eight board-certified physicists with 2-20 years of clinical experience performed initial chart checks using checklists from TG-275 and TG-315. Manual check times were estimated for three types of plans (IMRT/VMAT, 3D, and 2D) and for prostate, whole pelvis, lung, breast, head and neck, and brain cancers. An expert development team of three physicists re-evaluated the automation feasibility of TG-275 checklist based on their experience of developing and implementing the in-house and the commercial automation tools in our institution. Three levels of initial chart check automation were simulated: (1) Auto_UMMS_tool (which consists of in-house program and commercially available software); (2) Auto_TG275 (with full and partial automation as indicated in TG-275); and (3) Auto_UMMS_exp (with full and partial automation as determined by our experts' re-evaluation).

RESULTS

With no automation of initial chart checks, the ranges of manual check times were 29-56 min (full TG-315 list) and 102-163 min (full TG-275 list), which varied significantly with physicists but varied little at different tumor sites. The 69 of 71 checks which were considered as "not fully automated" in TG-275 were re-evaluated with more automation feasibility. Compared to no automation, the higher levels of automation yielded a great reduction in both manual check times (by 44%-98%) and potentially residual detectable errors (by 15-85%).

CONCLUSION

The initial chart check automation greatly improves the practicality and efficiency of implementing the new TG recommendations. Revisiting the TG reports with new technology/practice updates may help develop and utilize more automation clinically.

摘要

目的

最近发布的 AAPM TG-275 和 TG-315 的公开评审版分别列出了全面和最低物理初始图表检查的新建议。当这些建议在临床光子/电子 EBRT 中实施时，本文探讨了初始图表检查自动化的潜在发展和益处。

方法

八位具有 2-20 年临床经验的认证物理学家使用 TG-275 和 TG-315 的清单进行初始图表检查。手动检查时间分别针对三种类型的计划（调强放疗/容积旋转调强放疗、三维和二维）和前列腺癌、全骨盆癌、肺癌、乳腺癌、头颈部癌和脑癌进行了估计。一个由三位物理学家组成的专家开发团队根据他们在机构中开发和实施内部和商业自动化工具的经验，重新评估了 TG-275 清单自动化的可行性。模拟了三个级别的初始图表检查自动化：（1）Auto_UMMS_tool（由内部程序和商业上可用的软件组成）；（2）Auto_TG275（具有 TG-275 中规定的完全和部分自动化）；（3）Auto_UMMS_exp（具有我们专家重新评估确定的完全和部分自动化）。

结果

在初始图表检查没有自动化的情况下，手动检查时间的范围为 29-56 分钟（完整的 TG-315 清单）和 102-163 分钟（完整的 TG-275 清单），这因物理学家而异，但在不同的肿瘤部位差异不大。在 TG-275 中被认为“未完全自动化”的 71 项检查中的 69 项，经过更多的自动化可行性评估。与没有自动化相比，更高水平的自动化大大减少了手动检查时间（减少了 44%-98%）和潜在的可检测误差（减少了 15-85%）。

结论

初始图表检查自动化极大地提高了实施新 TG 建议的实用性和效率。重新审视 TG 报告并更新新技术/实践可能有助于在临床上开发和利用更多的自动化。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/88ac/7984492/5eefeb8e5d06/ACM2-22-234-g002.jpg

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实现光子/电子 EBRT 初始图表检查的自动化：新 AAPM 工作组报告和自动化技术的临床实施。

Toward automation of initial chart check for photon/electron EBRT: the clinical implementation of new AAPM task group reports and automation techniques.

机构信息

出版信息

PURPOSE

METHODS

RESULTS

CONCLUSION

目的

方法

结果

结论

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