A 3D deep learning model based on MRI for predicting lymphovascular invasion in rectal cancer.

Medical physics Pub Date : 2025-05-20 DOI:10.1002/mp.17882

Tangjuan Wang, Chuanyu Chen, Chang Liu, Shaopeng Li, Peng Wang, Dawei Yin, Ying Liu

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Abstract

Background: The assessment of lymphovascular invasion (LVI) is crucial in the management of rectal cancer; However, accurately evaluating LVI preoperatively using imaging remains challenging. Recent advances in radiomics have created opportunities for developing more accurate diagnostic tools.

Purpose: This study aimed to develop and validate a deep learning model for predicting LVI in rectal cancer patients using preoperative MR imaging.

Methods: These cases were randomly divided into a training cohort (n = 233) and an validation cohort (n = 101) at a ratio of 7:3. Based on the pathological reports, the patients were classified into positive and negative groups according to their LVI status. Based on the preoperative MRI T2WI axial images, the regions of interest (ROI) were defined from the tumor itself and the edges of the tumor extending outward by 5 pixels, 10 pixels, 15 pixels, and 20 pixels. The 2D and 3D deep learning features were extracted using the DenseNet121 architecture, and the deep learning models were constructed, including a total of ten models: GTV (the tumor itself), GPTV5 (the tumor itself and the tumor extending outward by 5 pixels), GPTV10, GPTV15, and GPTV20. To assess model performance, we utilized the area under the curve (AUC) and conducted DeLong test to compare different models, aiming to identify the optimal model for predicting LVI in rectal cancer.

Results: In the 2D deep learning model group, the 2D GPTV10 model demonstrated superior performance with an AUC of 0.891 (95% confidence interval [CI] 0.850-0.933) in the training cohort and an AUC of 0.841 (95% CI 0.767-0.915) in the validation cohort. The difference in AUC between this model and other 2D models was not statistically significant based on DeLong test (p > 0.05); In the group of 3D deep learning models, the 3D GPTV10 model had the highest AUC, with a training cohort AUC of 0.961 (95% CI 0.940-0.982) and a validation cohort AUC of 0.928 (95% CI 0.881-0.976). DeLong test demonstrated that the performance of the 3D GPTV10 model surpassed other 3D models as well as the 2D GPTV10 model (p < 0.05).

Conclusion: The study developed a deep learning model, namely 3D GPTV10, utilizing preoperative MRI data to accurately predict the presence of LVI in rectal cancer patients. By training on the tumor itself and its surrounding margin 10 pixels as the region of interest, this model achieved superior performance compared to other deep learning models. These findings have significant implications for clinicians in formulating personalized treatment plans for rectal cancer patients.

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基于MRI的三维深度学习模型预测直肠癌淋巴血管浸润。

背景：评估淋巴血管侵犯（LVI）在直肠癌的治疗中至关重要；然而，术前使用影像学准确评估LVI仍然具有挑战性。放射组学的最新进展为开发更准确的诊断工具创造了机会。目的：本研究旨在开发和验证一种深度学习模型，用于术前磁共振成像预测直肠癌患者的LVI。方法：将这些病例按7:3的比例随机分为训练组（n = 233）和验证组（n = 101）。根据病理报告将患者按LVI状态分为阳性组和阴性组。根据术前MRI T2WI轴向图像，从肿瘤本身和肿瘤边缘向外延伸5、10、15、20像素，定义感兴趣区域（ROI）。采用DenseNet121架构提取二维和三维深度学习特征，构建深度学习模型，共包括GTV（肿瘤本身）、GPTV5（肿瘤本身和向外延伸5个像素）、GPTV10、GPTV15和GPTV20十个模型。为了评估模型的性能，我们利用曲线下面积（area under the curve， AUC）和DeLong检验对不同模型进行比较，旨在寻找预测直肠癌LVI的最佳模型。结果：在2D深度学习模型组中，2D GPTV10模型在训练组的AUC为0.891(95%置信区间[CI] 0.850-0.933)，在验证组的AUC为0.841(95%置信区间[CI] 0.767-0.915)，表现出更优的性能。经DeLong检验，该模型与其他2D模型的AUC差异无统计学意义（p < 0.05）；在3D深度学习模型组中，3D GPTV10模型的AUC最高，训练队列AUC为0.961 (95% CI 0.940 ~ 0.982)，验证队列AUC为0.928 （95% CI 0.881 ~ 0.976）。DeLong测试表明，3D GPTV10模型的性能优于其他3D模型和2D GPTV10模型(p)。结论：本研究开发了一种深度学习模型，即3D GPTV10，利用术前MRI数据准确预测直肠癌患者LVI的存在。通过对肿瘤本身及其周围边缘10个像素作为感兴趣区域进行训练，该模型与其他深度学习模型相比取得了优越的性能。这些发现对临床医生制定直肠癌患者的个性化治疗方案具有重要意义。

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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Medical physics

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