基线临床数据、肿瘤代谢和肿瘤血流对预测 HER2 和三阴性乳腺癌新辅助化疗后 pCR 的贡献。

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC
Neree Payan, Benoit Presles, Charles Coutant, Isabelle Desmoulins, Sylvain Ladoire, Françoise Beltjens, François Brunotte, Jean-Marc Vrigneaud, Alexandre Cochet
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Prediction of pCR was performed using logistic regression, random forest and support vector classification algorithms. Models were built using clinical (C), clinical and metabolic (C+M) and clinical, metabolic and tumour BF (C+M+BF) information combined. Algorithms were trained on 80% of the dataset and tested on the remaining 20%. Univariate and multivariate features selections were carried out on the training dataset. A total of 50 shuffle splits were performed. The analysis was carried out on the whole dataset (HER2 and Triple Negative (TN)), and separately in HER2 (N=76) and TN (N=52) tumours.</p><p><strong>Results: </strong>In the whole dataset, the highest classification performances were observed for C+M models, significantly (p-value<0.01) higher than C models and better than C+M+BF models (mean balanced accuracy of 0.66, 0.61, and 0.64 respectively). 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引用次数: 0

摘要

研究背景本研究旨在探讨将肿瘤血流(BF)和代谢参数(包括纹理特征)与临床参数相结合,在基线预测新诊断乳腺癌(BC)患者对新辅助化疗(NAC)的病理完全反应(pCR)的附加价值:方法:128 名乳腺癌患者在接受任何治疗前均接受了 18F-FDG PET/CT 检查。分别从一过动态和延迟 PET 图像中提取肿瘤 BF 和代谢参数。从BF和代谢图像中提取标准和纹理特征。使用逻辑回归、随机森林和支持向量分类算法预测 pCR。使用临床(C)、临床和代谢(C+M)以及临床、代谢和肿瘤 BF(C+M+BF)信息建立模型。算法在 80% 的数据集上进行了训练,并在剩余的 20% 数据集上进行了测试。对训练数据集进行了单变量和多变量特征选择。总共进行了 50 次洗牌分割。分析在整个数据集(HER2 和三阴性(TN))上进行,并分别在 HER2(N=76)和 TN(N=52)肿瘤上进行:结果:在整个数据集中,C+M 模型的分类性能最高,显著(p-value):通过18F-FDG PET/CT评估的基线临床数据与肿瘤整体和纹理代谢参数相结合,能更好地预测BC患者NAC后的pCR,而对于TN肿瘤以及HER2和TN肿瘤,仅靠临床参数能更好地预测pCR。相比之下,在模型中加入BF参数并不能提高预测效果,无论分析的是哪种肿瘤亚组。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Respective contribution of baseline clinical data, tumour metabolism and tumour blood-flow in predicting pCR after neoadjuvant chemotherapy in HER2 and Triple Negative breast cancer.

Background: The aim of this study is to investigate the added value of combining tumour blood flow (BF) and metabolism parameters, including texture features, with clinical parameters to predict, at baseline, the pathological complete response (pCR) to neoadjuvant chemotherapy (NAC) in patients with newly diagnosed breast cancer (BC).

Methods: One hundred and twenty-eight BC patients underwent a 18F-FDG PET/CT before any treatment. Tumour BF and metabolism parameters were extracted from first-pass dynamic and delayed PET images, respectively. Standard and texture features were extracted from BF and metabolic images. Prediction of pCR was performed using logistic regression, random forest and support vector classification algorithms. Models were built using clinical (C), clinical and metabolic (C+M) and clinical, metabolic and tumour BF (C+M+BF) information combined. Algorithms were trained on 80% of the dataset and tested on the remaining 20%. Univariate and multivariate features selections were carried out on the training dataset. A total of 50 shuffle splits were performed. The analysis was carried out on the whole dataset (HER2 and Triple Negative (TN)), and separately in HER2 (N=76) and TN (N=52) tumours.

Results: In the whole dataset, the highest classification performances were observed for C+M models, significantly (p-value<0.01) higher than C models and better than C+M+BF models (mean balanced accuracy of 0.66, 0.61, and 0.64 respectively). For HER2 tumours, equal performances were noted for C and C+M models, with performances higher than C+M+BF models (mean balanced accuracy of 0.64, and 0.61 respectively). Regarding TN tumours, the best classification results were reported for C+M models, with better performances than C and C+M+BF models but not significantly (mean balanced accuracy of 0.65, 0.63, and 0.62 respectively).

Conclusion: Baseline clinical data combined with global and texture tumour metabolism parameters assessed by 18F-FDG PET/CT provide a better prediction of pCR after NAC in patients with BC compared to clinical parameters alone for TN, and HER2 and TN tumours together. In contrast, adding BF parameters to the models did not improve prediction, regardless of the tumour subgroup analysed.

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