放射治疗的自动治疗计划:跨病种和方案研究

IF 2.2 Q3 ONCOLOGY
Gregory Szalkowski PhD , Xuanang Xu PhD , Shiva Das PhD , Pew-Thian Yap PhD , Jun Lian PhD
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引用次数: 0

摘要

目的本研究调查了一种模式下训练出来的模型的三维剂量预测对跨模式自动计划工作流程的适用性。此外,我们还探讨了集成多标准优化器(MCO)对预测结果适应不同临床偏好的影响。方法和材料利用之前在 2020 年美国医学物理学家协会 OpenKBP 挑战赛数据集(340 个头颈部计划,均使用 9 场静态调强放射治疗 [IMRT])上训练创建的 3 级 U-Net 内部模型,我们回顾性地生成了 20 名患者的剂量预测。这些剂量预测反过来又被用于使用 Raystation 的后备计划功能生成可交付的 IMRT、VMAT 和断层治疗计划。根据主要临床目标,对照剂量预测对可交付计划进行了评估。此外,还使用基于 MCO 的优化方法生成了一套新的计划,并将预测剂量值作为约束条件。结果模仿方法准确复制了不同模式下的预测剂量分布,脊髓和外轮廓最大剂量略有偏差。MCO 优化大大降低了高危器官的剂量,这也是我院优先考虑的器官,同时保持了目标覆盖范围。我们的研究结果表明,只在 IMRT 计划上训练过的模型可以有效促进各种模式的计划。此外,在基于 MCO 的工作流程中将预测作为约束条件,而不是直接剂量模拟,可以为治疗计划提供灵活的热启动方法,不过当训练集与机构的偏好有很大差异时,这种方法的优势就会减弱。这些方法结合在一起,有可能大大缩短计划周转时间,减少质量差异,既适用于可以训练内部模型的高资源医疗中心,也适用于可以从其他机构以最小的代价改编模型的较小中心。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Automatic Treatment Planning for Radiation Therapy: A Cross-Modality and Protocol Study

Purpose

This study investigated the applicability of 3-dimensional dose predictions from a model trained on one modality to a cross-modality automated planning workflow. Additionally, we explore the impact of integrating a multicriteria optimizer (MCO) on adapting predictions to different clinical preferences.

Methods and Materials

Using a previously created 3-stage U-Net in-house model trained on the 2020 American Association of Physicists in Medicine OpenKBP challenge data set (340 head and neck plans, all planned using 9-field static intensity modulated radiation therapy [IMRT]), we retrospectively generated dose predictions for 20 patients. These dose predictions were, in turn, used to generate deliverable IMRT, VMAT, and tomotherapy plans using the fallback plan functionality in Raystation. The deliverable plans were evaluated against the dose predictions based on primary clinical goals. A new set of plans was also generated using MCO-based optimization with predicted dose values as constraints. Delivery QA was performed on a subset of the plans to assure clinical deliverability.

Results

The mimicking approach accurately replicated the predicted dose distributions across different modalities, with slight deviations in the spinal cord and external contour maximum doses. MCO optimization significantly reduced doses to organs at risk, which were prioritized by our institution while maintaining target coverage. All tested plans met clinical deliverability standards, evidenced by a gamma analysis passing rate >98%.

Conclusions

Our findings show that a model trained only on IMRT plans can effectively contribute to planning across various modalities. Additionally, integrating predictions as constraints in an MCO-based workflow, rather than direct dose mimicking, enables a flexible, warm-start approach for treatment planning, although the benefit is reduced when the training set differs significantly from an institution's preference. Together, these approaches have the potential to significantly decrease plan turnaround time and quality variance, both at high-resource medical centers that can train in-house models and smaller centers that can adapt a model from another institution with minimal effort.
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来源期刊
Advances in Radiation Oncology
Advances in Radiation Oncology Medicine-Radiology, Nuclear Medicine and Imaging
CiteScore
4.60
自引率
4.30%
发文量
208
审稿时长
98 days
期刊介绍: The purpose of Advances is to provide information for clinicians who use radiation therapy by publishing: Clinical trial reports and reanalyses. Basic science original reports. Manuscripts examining health services research, comparative and cost effectiveness research, and systematic reviews. Case reports documenting unusual problems and solutions. High quality multi and single institutional series, as well as other novel retrospective hypothesis generating series. Timely critical reviews on important topics in radiation oncology, such as side effects. Articles reporting the natural history of disease and patterns of failure, particularly as they relate to treatment volume delineation. Articles on safety and quality in radiation therapy. Essays on clinical experience. Articles on practice transformation in radiation oncology, in particular: Aspects of health policy that may impact the future practice of radiation oncology. How information technology, such as data analytics and systems innovations, will change radiation oncology practice. Articles on imaging as they relate to radiation therapy treatment.
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