Attention 3D UNET for dose distribution prediction of high-dose-rate brachytherapy of cervical cancer: Intracavitary applicators.

IF 2 4区医学 Q3 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING Journal of Applied Clinical Medical Physics Pub Date : 2024-11-15 DOI:10.1002/acm2.14568

Suman Gautam, Alexander F I Osman, Dylan Richeson, Somayeh Gholami, Binod Manandhar, Sharmin Alam, William Y Song

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Abstract

Background: Formulating a clinically acceptable plan within the time-constrained clinical setting of brachytherapy poses challenges to clinicians. Deep learning based dose prediction methods have shown favorable solutions for enhancing efficiency, but development has primarily been on external beam radiation therapy. Thus, there is a need for translation to brachytherapy.

Purpose: This study proposes a dose prediction model utilizing an attention-gating mechanism and a 3D UNET for cervical cancer high-dose-rate intracavitary brachytherapy treatment planning with tandem-and-ovoid/ring applicators.

Methods: A multi-institutional data set consisting of 77 retrospective clinical brachytherapy plans was utilized in this study. The data were preprocessed and augmented to increase the number of plans to 252. A 3D UNET architecture with attention gates was constructed and trained for mapping the contour information to dose distribution. The trained model was evaluated on a testing data set using various metrics, including dose statistics and dose-volume indices. We also trained a baseline UNET model for a fair comparison.

Results: The attention-gated 3D UNET model exhibited competitive accuracy in predicting dose distributions similar to the ground truth. The average values of the mean absolute errors were 0.46 ± 11.71 Gy (vs. 0.47 ± 9.16 Gy for a baseline UNET) in CTV_HR, 0.55 ± 0.67 Gy (vs. 0.70 ± 1.54 Gy for a baseline UNET) in bladder, 0.42 ± 0.46 Gy (vs. 0.49 ± 1.34 Gy for a baseline UNET) in rectum, and 0.31 ± 0.65 Gy (vs. 0.20 ± 3.76 Gy for a baseline UNET) in sigmoid. Our results showed that the mean individual differences in ΔD_2cc for bladder, rectum, and sigmoid were 0.38 ± 1.19 (p = 0.50), 0.43 ± 0.71 (p = 0.41), and -0.47 ± 0.79 (p = 0.30) Gy, respectively. Similarly, the mean individual differences in ΔD_1cc for bladder, rectum, and sigmoid were 0.09 ± 1.21 (p = 0.36), 0.20 ± 0.95 (p = 0.24), and -0.21 ± 0.59 (p = 0.30) Gy. The mean individual differences for ΔD₉₀, ΔV_100%, ΔV_150%, and ΔV_200% of the CTV_HR were -0.45 ± 2.42 (p = 0.26) Gy, 0.55 ± 9.42% (p = 0.78), 0.82 ± 4.21% (p = 0.81), and -0.80 ± 10.48% (p = 0.36), respectively. The model requires less than 5 s to predict a full 3D dose distribution for a new patient plan.

Conclusion: Attention-gated 3D UNET revealed a promising capability in predicting voxel-wise dose distributions compared to 3D UNET. This model could be deployed for clinical use to predict 3D dose distributions for near real-time decision-making before planning, quality assurance, and guiding future automated planning, making the current workflow more efficient.

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用于宫颈癌高剂量率近距离放射治疗剂量分布预测的 3D UNET：腔内涂抹器

背景：在近距离放射治疗时间有限的临床环境中，制定临床上可接受的计划对临床医生提出了挑战。基于深度学习的剂量预测方法已显示出提高效率的有利解决方案，但其开发主要针对体外放射治疗。目的：本研究提出了一种利用注意力门控机制和三维 UNET 的剂量预测模型，用于宫颈癌高剂量率腔内近距离治疗计划，使用串联和卵圆/环形涂抹器：本研究使用了由 77 个回顾性临床近距离治疗计划组成的多机构数据集。数据经过预处理和扩充后，计划数量增至 252 个。为了将轮廓信息映射到剂量分布，我们构建并训练了带有注意门的 3D UNET 架构。我们使用各种指标，包括剂量统计和剂量-体积指数，在测试数据集上对训练好的模型进行了评估。我们还训练了一个基准 UNET 模型，以进行公平比较：结果：注意力导向三维 UNET 模型在预测与地面实况相似的剂量分布方面表现出了极高的准确性。CTVHR 的平均绝对误差值为 0.46 ± 11.71 Gy（基线 UNET 为 0.47 ± 9.16 Gy），CTVHR 为 0.55 ± 0.67 Gy（基线 UNET 为 0.70 ± 1.54 Gy）、直肠 0.42 ± 0.46 Gy（基线 UNET 为 0.49 ± 1.34 Gy）和乙状结肠 0.31 ± 0.65 Gy（基线 UNET 为 0.20 ± 3.76 Gy）。结果显示，膀胱、直肠和乙状结肠的平均个体差异ΔD2cc分别为 0.38 ± 1.19 (p = 0.50)、0.43 ± 0.71 (p = 0.41) 和 -0.47 ± 0.79 (p = 0.30) Gy。同样，膀胱、直肠和乙状结肠的 ΔD1cc 平均个体差异分别为 0.09 ± 1.21 (p = 0.36)、0.20 ± 0.95 (p = 0.24) 和 -0.21 ± 0.59 (p = 0.30) Gy。CTVHR的ΔD90、ΔV100%、ΔV150%和ΔV200%的平均个体差异分别为-0.45 ± 2.42 (p = 0.26) Gy、0.55 ± 9.42% (p = 0.78)、0.82 ± 4.21% (p = 0.81)和-0.80 ± 10.48% (p = 0.36)。该模型预测一个新患者计划的完整三维剂量分布所需的时间不到 5 秒：结论：与三维 UNET 相比，注意力导向三维 UNET 在预测体素剂量分布方面具有良好的能力。该模型可用于临床预测三维剂量分布，以便在计划、质量保证和指导未来自动计划之前进行近乎实时的决策，从而使当前的工作流程更加高效。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Applied Clinical Medical Physics 医学-核医学

CiteScore

3.60

自引率

19.00%

发文量

331

审稿时长

3 months

期刊介绍： Journal of Applied Clinical Medical Physics is an international Open Access publication dedicated to clinical medical physics. JACMP welcomes original contributions dealing with all aspects of medical physics from scientists working in the clinical medical physics around the world. JACMP accepts only online submission. JACMP will publish: -Original Contributions: Peer-reviewed, investigations that represent new and significant contributions to the field. Recommended word count: up to 7500. -Review Articles: Reviews of major areas or sub-areas in the field of clinical medical physics. These articles may be of any length and are peer reviewed. -Technical Notes: These should be no longer than 3000 words, including key references. -Letters to the Editor: Comments on papers published in JACMP or on any other matters of interest to clinical medical physics. These should not be more than 1250 (including the literature) and their publication is only based on the decision of the editor, who occasionally asks experts on the merit of the contents. -Book Reviews: The editorial office solicits Book Reviews. -Announcements of Forthcoming Meetings: The Editor may provide notice of forthcoming meetings, course offerings, and other events relevant to clinical medical physics. -Parallel Opposed Editorial: We welcome topics relevant to clinical practice and medical physics profession. The contents can be controversial debate or opposed aspects of an issue. One author argues for the position and the other against. Each side of the debate contains an opening statement up to 800 words, followed by a rebuttal up to 500 words. Readers interested in participating in this series should contact the moderator with a proposed title and a short description of the topic