Oden Institute for Computational Engineering and Sciences, The University of Texas at Austin, Austin, Texas.
Livestrong Cancer Institutes, The University of Texas at Austin, Austin, Texas.
Cancer Res. 2022 Sep 16;82(18):3394-3404. doi: 10.1158/0008-5472.CAN-22-1329.
Triple-negative breast cancer (TNBC) is persistently refractory to therapy, and methods to improve targeting and evaluation of responses to therapy in this disease are needed. Here, we integrate quantitative MRI data with biologically based mathematical modeling to accurately predict the response of TNBC to neoadjuvant systemic therapy (NAST) on an individual basis. Specifically, 56 patients with TNBC enrolled in the ARTEMIS trial (NCT02276443) underwent standard-of-care doxorubicin/cyclophosphamide (A/C) and then paclitaxel for NAST, where dynamic contrast-enhanced MRI and diffusion-weighted MRI were acquired before treatment and after two and four cycles of A/C. A biologically based model was established to characterize tumor cell movement, proliferation, and treatment-induced cell death. Two evaluation frameworks were investigated using: (i) images acquired before and after two cycles of A/C for calibration and predicting tumor status after A/C, and (ii) images acquired before, after two cycles, and after four cycles of A/C for calibration and predicting response following NAST. For Framework 1, the concordance correlation coefficients between the predicted and measured patient-specific, post-A/C changes in tumor cellularity and volume were 0.95 and 0.94, respectively. For Framework 2, the biologically based model achieved an area under the receiver operator characteristic curve of 0.89 (sensitivity/specificity = 0.72/0.95) for differentiating pathological complete response (pCR) from non-pCR, which is statistically superior (P < 0.05) to the value of 0.78 (sensitivity/specificity = 0.72/0.79) achieved by tumor volume measured after four cycles of A/C. Overall, this model successfully captured patient-specific, spatiotemporal dynamics of TNBC response to NAST, providing highly accurate predictions of NAST response.
Integrating MRI data with biologically based mathematical modeling successfully predicts breast cancer response to chemotherapy, suggesting digital twins could facilitate a paradigm shift from simply assessing response to predicting and optimizing therapeutic efficacy.
三阴性乳腺癌(TNBC)持续对治疗具有抗性,因此需要寻找改善这种疾病的靶向治疗和评估治疗反应的方法。在这里,我们将定量 MRI 数据与基于生物学的数学模型相结合,以便能够准确地预测 TNBC 对新辅助全身治疗(NAST)的个体反应。具体来说,56 名参与 ARTEMIS 试验(NCT02276443)的 TNBC 患者接受了标准的多柔比星/环磷酰胺(A/C)治疗,然后接受紫杉醇进行 NAST,在治疗前以及 A/C 治疗的两个和四个周期后采集了动态对比增强 MRI 和弥散加权 MRI。建立了一种基于生物学的模型来描述肿瘤细胞的运动、增殖和治疗诱导的细胞死亡。我们研究了两种评估框架:(i)使用 A/C 治疗前和两个周期后的图像进行校准,并预测 A/C 后的肿瘤状态;(ii)使用 A/C 治疗前、两个周期后和四个周期后的图像进行校准,并预测 NAST 后的反应。对于框架 1,预测的和测量的患者特异性 A/C 后肿瘤细胞密度和体积变化之间的一致性相关系数分别为 0.95 和 0.94。对于框架 2,基于生物学的模型在区分病理完全缓解(pCR)与非 pCR 方面获得了 0.89 的受试者工作特征曲线下面积(敏感性/特异性=0.72/0.95),这明显优于 A/C 治疗四个周期后测量的肿瘤体积所获得的 0.78(敏感性/特异性=0.72/0.79)值(P < 0.05)。总体而言,该模型成功地捕捉到了 TNBC 对 NAST 的患者特异性时空动态,对 NAST 反应进行了高度准确的预测。
将 MRI 数据与基于生物学的数学模型相结合,成功地预测了乳腺癌对化疗的反应,这表明数字双胞胎可能会促进从简单地评估反应到预测和优化治疗效果的范式转变。
