基于克隆数据的最小残留病随机模型预测急性髓系白血病复发时间

Khanh N. Dinh, Roman Jaksik, Seth J. Corey, Marek Kimmel
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引用次数: 3

摘要

急性髓系白血病患者的无事件生存率和总生存率仍然很差。导致复发的耐药克隆来自微小残留病(MRD)或新获得的突变。然而,包括MRD的克隆的动力学知之甚少。我们建立了一个基于多类型年龄依赖的马尔可夫分支过程的预测随机模型,以描述MRD中的随机事件如何导致治疗反应的异质性。我们对接受全基因组测序的患者进行了培训和验证,并且在诊断和复发时可以获得突变克隆频率。疾病的发展和治疗结果受随机波动的影响。通过模型拟合获得的恶性克隆生长速率估计值与已发表的数据一致。使用来自训练集的估计,我们开发了一个函数,将MRD和复发时间与从模型拟合到克隆频率和其他数据推断的MRD联系起来。一个独立的验证集证实了我们的模型。在第三个数据集中,我们将模型拟合到诊断和缓解的数据中,并预测复发的时间。综上所述,根据诊断时的骨髓基因组和缓解时或过去的MRD,该模型可以预测复发时间,并帮助指导治疗决策以减轻复发。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Predicting time to relapse in acute myeloid leukemia through stochastic modeling of minimal residual disease based on clonality data

Predicting time to relapse in acute myeloid leukemia through stochastic modeling of minimal residual disease based on clonality data

Event-free and overall survival remain poor for patients with acute myeloid leukemia. Chemoresistant clones contributing to relapse arise from minimal residual disease (MRD) or newly acquired mutations. However, the dynamics of clones comprising MRD is poorly understood. We developed a predictive stochastic model, based on a multitype age-dependent Markov branching process, to describe how random events in MRD contribute to the heterogeneity in treatment response. We employed training and validation sets of patients who underwent whole-genome sequencing and for whom mutant clone frequencies at diagnosis and relapse were available. The disease evolution and treatment outcome are subject to stochastic fluctuations. Estimates of malignant clone growth rates, obtained by model fitting, are consistent with published data. Using the estimates from the training set, we developed a function linking MRD and time of relapse with MRD inferred from the model fits to clone frequencies and other data. An independent validation set confirmed our model. In a third dataset, we fitted the model to data at diagnosis and remission and predicted the time to relapse. As a conclusion, given bone marrow genome at diagnosis and MRD at or past remission, the model can predict time to relapse and help guide treatment decisions to mitigate relapse.

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CiteScore
2.80
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