Tang Wenjie, Jin Chen, Kong Qingcong, Liu Chunling, Chen Siyi, Ding Shishen, Liu Bihua, Feng Zaihui, Li Ying, Dai Yi, Zhang Lei, Chen Yongxin, Han Xiaorui, Liu Shuang, Chen Dandan, Weng Zijin, Liu Weifeng, Wei Xinhua, Jiang Xinqing, Zhou Qianwei, Mao Ning, Guo Yuan
Department of Radiology, Guangzhou First People's Hospital, South China University of Technology, Guangzhou, 510180, China.
College of Computer Science and Technology, Zhejiang University of Technology, Hangzhou, 310023, China.
EClinicalMedicine. 2025 Jun 12;85:103298. doi: 10.1016/j.eclinm.2025.103298. eCollection 2025 Jul.
The accurate and early evaluation of response to neoadjuvant chemotherapy (NAC) in breast cancer is crucial for optimizing treatment strategies and minimizing unnecessary interventions. While deep learning (DL)-based approaches have shown promise in medical imaging analysis, existing models often fail to comprehensively integrate spatial and temporal tumor dynamics. This study aims to develop and validate a spatiotemporal interaction (STI) model based on longitudinal MRI data to predict pathological complete response (pCR) to NAC in breast cancer patients.
This study included retrospective and prospective datasets from five medical centers in China, collected from June 2018 to December 2024. These datasets were assigned to the primary cohort (including training and internal validation sets), external validation cohorts, and a prospective validation cohort. DCE-MRI scans from both pre-NAC (T0) and early-NAC (T1) stages were collected for each patient, along with surgical pathology results. A Siamese network-based STI model was developed, integrating spatial features from tumor segmentation with temporal dependencies using a transformer-based multi-head attention mechanism. This model was designed to simultaneously capture spatial heterogeneity and temporal dynamics, enabling accurate prediction of NAC response. The STI model's performance was evaluated using the area under the ROC curve (AUC) and Precision-Recall curve (AP), accuracy, sensitivity, and specificity. Additionally, the I-SPY1 and I-SPY2 datasets were used for Kaplan-Meier survival analysis and to explore the biological basis of the STI model, respectively. The prospective cohort was registered with Chinese Clinical Trial Registration Centre (ChiCTR2500102170).
A total of 1044 patients were included in this study, with the pCR rate ranging from 23.8% to 35.9%. The STI model demonstrated good performance in early prediction of NAC response in breast cancer. In the external validation cohorts, the AUC values were 0.923 (95% CI: 0.859-0.987), 0.892 (95% CI: 0.821-0.963), and 0.913 (95% CI: 0.835-0.991), all outperforming the single-timepoint T0 or T1 models, as well as models with spatial information added (all p < 0.05, Delong test). Additionally, the STI model significantly outperformed the clinical model (p < 0.05, Delong test) and radiologists' predictions. In the prospective validation cohort, the STI model identified 90.2% (37/41) of non-pCR and 82.6% (19/23) of pCR patients, reducing misclassification rates by 58.7% and 63.3% compared to radiologists. This indicates that these patients might benefit from treatment adjustment or continued therapy in the early NAC stage. Survival analysis showed a significant correlation between the STI model and both recurrence-free survival (RFS) and overall survival (OS) in breast cancer patients. Further investigation revealed that favorable NAC responses predicted by the STI model were closely linked to upregulated immune-related genes and enhanced immune cell infiltration.
Our study established a novel noninvasive STI model that integrates the spatiotemporal evolution of MRI before and during NAC to achieve early and accurate pCR prediction, offering potential guidance for personalized treatment.
This study was supported by the National Natural Science Foundation of China (82302314, 62271448, 82171920, 81901711), Basic and Applied Basic Research Foundation of Guangdong Province (2022A1515110792, 2023A1515220097, 2024A1515010653), Medical Scientific Research Foundation of Guangdong Province (A2023073, A2024116), Science and Technology Projects in Guangzhou (2023A04J1275, 2024A03J1030, 2025A03J4163, 2025A03J4162); Guangzhou First People's Hospital Frontier Medical Technology Project (QY-C04).
对乳腺癌新辅助化疗(NAC)反应进行准确且早期的评估,对于优化治疗策略以及减少不必要的干预至关重要。虽然基于深度学习(DL)的方法在医学影像分析中已显示出前景,但现有模型往往未能全面整合肿瘤的空间和时间动态变化。本研究旨在基于纵向MRI数据开发并验证一种时空交互(STI)模型,以预测乳腺癌患者对NAC的病理完全缓解(pCR)。
本研究纳入了来自中国五个医学中心的回顾性和前瞻性数据集,收集时间为2018年6月至2024年12月。这些数据集被分配到主要队列(包括训练集和内部验证集)、外部验证队列以及前瞻性验证队列。为每位患者收集了NAC前(T0)和NAC早期(T1)阶段的DCE-MRI扫描结果以及手术病理结果。开发了一种基于连体网络的STI模型,该模型使用基于Transformer的多头注意力机制,将肿瘤分割的空间特征与时间依赖性相结合。此模型旨在同时捕捉空间异质性和时间动态变化,从而实现对NAC反应的准确预测。使用ROC曲线下面积(AUC)、精确召回率曲线(AP)、准确性、敏感性和特异性来评估STI模型的性能。此外,I-SPY1和I-SPY2数据集分别用于Kaplan-Meier生存分析以及探索STI模型的生物学基础。前瞻性队列已在中国临床试验注册中心注册(ChiCTR2500102170)。
本研究共纳入1044例患者,pCR率在23.8%至35.9%之间。STI模型在乳腺癌NAC反应的早期预测中表现良好。在外部验证队列中,AUC值分别为0.923(95%CI:0.859 - 0.987)、0.892(95%CI: 0.821 - 0.963)和0.913(95%CI:0.835 - 0.991),均优于单时间点T0或T1模型以及添加了空间信息后的模型(所有p < 0.05,德龙检验)。此外,STI模型显著优于临床模型(p < 0.05,德龙检验)和放射科医生的预测。在前瞻性验证队列中,STI模型识别出90.2%(37/41)的非pCR患者和82.6%(19/23)的pCR患者,与放射科医生相比,误分类率分别降低了58.7%和63.3%。这表明这些患者可能在NAC早期阶段从治疗调整或继续治疗中获益。生存分析显示,STI模型与乳腺癌患者的无复发生存期(RFS)和总生存期(OS)均显著相关。进一步研究表明,STI模型预测的良好NAC反应与免疫相关基因上调和免疫细胞浸润增强密切相关。
我们的研究建立了一种新型无创STI模型,该模型整合了NAC前和NAC期间MRI的时空演变,以实现早期和准确的pCR预测,为个性化治疗提供了潜在指导。
本研究得到了中国国家自然科学基金(82302314、62271448、82171920、81901711)、广东省基础与应用基础研究基金(2022A1515110792、2023A1515220097、2024A1515010653)、广东省医学科研基金(A2023073、A2024116)、广州市科技项目(2023A04J1275、2024A03J1030、2025A03J4163、2025A03J4162);广州市第一人民医院前沿医疗技术项目(QY-C04)的支持。
