A stacking ensemble framework integrating radiomics and deep learning for prognostic prediction in head and neck cancer.

IF 3.3 2区医学 Q2 ONCOLOGY

Radiation Oncology Pub Date : 2025-08-13 DOI:10.1186/s13014-025-02695-8

Bingzhen Wang, Jinghua Liu, Xiaolei Zhang, Jianpeng Lin, Shuyan Li, Zhongxiao Wang, Zhendong Cao, Dong Wen, Tiange Liu, Hafiz Rashidi Harun Ramli, Hazreen Haizi Harith, Wan Zuha Wan Hasan, Xianling Dong

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引用次数: 0

Abstract

Background: Radiomics models frequently face challenges related to reproducibility and robustness. To address these issues, we propose a multimodal, multi-model fusion framework utilizing stacking ensemble learning for prognostic prediction in head and neck cancer (HNC). This approach seeks to improve the accuracy and reliability of survival predictions.

Methods: A total of 806 cases from nine centers were collected; 143 cases from two centers were assigned as the external validation cohort, while the remaining 663 were stratified and randomly split into training (n = 530) and internal validation (n = 133) sets. Radiomics features were extracted according to IBSI standards, and deep learning features were obtained using a 3D DenseNet-121 model. Following feature selection, the selected features were input into Cox, SVM, RSF, DeepCox, and DeepSurv models. A stacking fusion strategy was employed to develop the prognostic model. Model performance was evaluated using Kaplan-Meier survival curves and time-dependent ROC curves.

Results: On the external validation set, the model using combined PET and CT radiomics features achieved superior performance compared to single-modality models, with the RSF model obtaining the highest concordance index (C-index) of 0.7302. When using deep features extracted by 3D DenseNet-121, the PET + CT-based models demonstrated significantly improved prognostic accuracy, with Deepsurv and DeepCox achieving C-indices of 0.9217 and 0.9208, respectively. In stacking models, the PET + CT model using only radiomics features reached a C-index of 0.7324, while the deep feature-based stacking model achieved 0.9319. The best performance was obtained by the multi-feature fusion model, which integrated both radiomics and deep learning features from PET and CT, yielding a C-index of 0.9345. Kaplan-Meier survival analysis further confirmed the fusion model's ability to distinguish between high-risk and low-risk groups.

Conclusion: The stacking-based ensemble model demonstrates superior performance compared to individual machine learning models, markedly improving the robustness of prognostic predictions.

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基于放射组学和深度学习的头颈癌预后预测叠加集成框架。

背景：放射组学模型经常面临与再现性和稳健性相关的挑战。为了解决这些问题，我们提出了一个多模态、多模型融合框架，利用堆叠集成学习进行头颈癌（HNC）的预后预测。这种方法旨在提高生存预测的准确性和可靠性。方法：收集9个中心共806例病例；来自两个中心的143例病例被分配为外部验证队列，其余663例被分层并随机分为训练组（n = 530）和内部验证组（n = 133）。根据IBSI标准提取放射组学特征，并使用3D DenseNet-121模型获得深度学习特征。特征选择完成后，将选择的特征输入到Cox、SVM、RSF、DeepCox和DeepSurv模型中。采用堆叠融合策略建立预测模型。采用Kaplan-Meier生存曲线和随时间变化的ROC曲线评价模型的性能。结果：在外部验证集上，采用PET和CT放射组学联合特征的模型表现优于单模态模型，其中RSF模型的一致性指数（C-index）最高，为0.7302。当使用3D DenseNet-121提取的深度特征时，基于PET + ct的模型的预后准确率显著提高，Deepsurv和DeepCox的c指数分别达到0.9217和0.9208。在叠加模型中，仅使用放射组学特征的PET + CT模型的c指数为0.7324，而基于深度特征的叠加模型的c指数为0.9319。融合PET和CT放射组学特征和深度学习特征的多特征融合模型表现最佳，C-index为0.9345。Kaplan-Meier生存分析进一步证实了融合模型区分高风险和低风险群体的能力。结论：与单个机器学习模型相比，基于堆叠的集成模型表现出更好的性能，显著提高了预后预测的鲁棒性。

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

Radiation Oncology ONCOLOGY-RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING

CiteScore

6.50

自引率

2.80%

发文量

181

审稿时长

3-6 weeks

期刊介绍： Radiation Oncology encompasses all aspects of research that impacts on the treatment of cancer using radiation. It publishes findings in molecular and cellular radiation biology, radiation physics, radiation technology, and clinical oncology.