先验信息引导的深度学习模型用于乳腺癌放疗中的肿瘤床分割。

IF 2.9 3区 医学 Q2 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING BMC Medical Imaging Pub Date : 2024-11-18 DOI:10.1186/s12880-024-01469-0
Peng Huang, Hui Yan, Jiawen Shang, Xin Xie
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引用次数: 0

摘要

背景和目的:肿瘤床(TB)是手术切除肿瘤后的残留腔。从 CT 中划分肿瘤床对于生成放疗的临床靶体积至关重要。由于多种手术影响和低图像对比度,从软组织中分割肿瘤床具有挑战性。在临床实践中,人们使用钛夹作为标记来引导肺结核的搜索。然而,这种信息是有限的,可能会导致较大的误差。为了提供更多的先验定位信息,深度学习模型在分割肺结核与周围组织时,会同时使用术前和术后 CT 上的肿瘤区域:对于手术后即将接受放疗的乳腺癌患者来说,划定靶区对于制定治疗计划非常重要。在临床实践中,目标体积通常是在 TB 的基础上增加一定的边缘而产生的。因此,从软组织中识别结核至关重要。为了促进这一过程,我们开发了一种深度学习模型,以事先的肿瘤位置为指导,从 CT 中分割结核。最初,医生会根据术前 CT 上的肿瘤轮廓制定手术计划。然后,通过术前和术后成对 CT 之间的可变形图像配准,将该轮廓转换到术后 CT 上。原始肿瘤区域和转换后的肿瘤区域都将作为深度学习模型预测肺结核可能发生区域的输入:结果:与没有先验肿瘤轮廓信息的深度学习模型相比,有先验肿瘤轮廓信息的深度学习模型的骰子相似系数显著提高(0.812 vs. 0.520,P = 0.001)。与传统的灰度阈值法相比,深度学习模型与先验肿瘤轮廓信息的骰子相似系数得到了明显改善(0.812 vs.0.633, P = 0.0005):结论:术前和术后 CT 上的肿瘤轮廓为在术后 CT 上搜索结核病的精确位置提供了有价值的信息。所提出的方法为保乳手术后放疗计划中结核的自动分割提供了一种可行的辅助方法。
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Prior information guided deep-learning model for tumor bed segmentation in breast cancer radiotherapy.

Background and purpose: Tumor bed (TB) is the residual cavity of resected tumor after surgery. Delineating TB from CT is crucial in generating clinical target volume for radiotherapy. Due to multiple surgical effects and low image contrast, segmenting TB from soft tissue is challenging. In clinical practice, titanium clips were used as marks to guide the searching of TB. However, this information is limited and may cause large error. To provide more prior location information, the tumor regions on both pre-operative and post-operative CTs are both used by the deep learning model in segmenting TB from surrounding tissues.

Materials and methods: For breast cancer patient after surgery and going to be treated by radiotherapy, it is important to delineate the target volume for treatment planning. In clinical practice, the target volume is usually generated from TB by adding a certain margin. Therefore, it is crucial to identify TB from soft tissue. To facilitate this process, a deep learning model is developed to segment TB from CT with the guidance of prior tumor location. Initially, the tumor contour on the pre-operative CT is delineated by physician for surgical planning purpose. Then this contour is transformed to the post-operative CT via the deformable image registration between paired pre-operative and post-operative CTs. The original and transformed tumor regions are both used as inputs for predicting the possible region of TB by the deep-learning model.

Results: Compared to the one without prior tumor contour information, the dice similarity coefficient of the deep-learning model with the prior tumor contour information is improved significantly (0.812 vs. 0.520, P = 0.001). Compared to the traditional gray-level thresholding method, the dice similarity coefficient of the deep-learning model with the prior tumor contour information is improved significantly (0.812 vs.0.633, P = 0.0005).

Conclusions: The prior tumor contours on both pre-operative and post-operative CTs provide valuable information in searching for the precise location of TB on post-operative CT. The proposed method provided a feasible way to assist auto-segmentation of TB in treatment planning of radiotherapy after breast-conserving surgery.

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来源期刊
BMC Medical Imaging
BMC Medical Imaging RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING-
CiteScore
4.60
自引率
3.70%
发文量
198
审稿时长
27 weeks
期刊介绍: BMC Medical Imaging is an open access journal publishing original peer-reviewed research articles in the development, evaluation, and use of imaging techniques and image processing tools to diagnose and manage disease.
期刊最新文献
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