干扰素- α-治疗骨髓增殖性肿瘤个体化治疗的剂量依赖性数学模型

Rasmus K. Pedersen, Morten Andersen, Trine A. Knudsen, Vibe Skov, Lasse Kjær, Hans C. Hasselbalch, Johnny T. Ottesen
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引用次数: 3

摘要

长期使用干扰素- α (IFN)治疗可减轻骨髓增生性肿瘤(mpn)患者的疾病负担。确定个体患者对干扰素治疗的反应可能允许有效的个性化治疗,减少退出和疾病负担。提出了描述造血干细胞和免疫系统的数学模型。考虑骨髓和血液允许在没有和存在干扰素治疗的情况下建立疾病动力学模型。通过对IFN效应的综合建模,该模型与个体化患者数据相关,包括纵向血液学和分子测量。治疗反应在人群水平上建模,允许从单个预处理数据点进行个性化预测。发现个性化契合度与个体患者的数据非常吻合。这允许对治疗反应进行定量描述,从而产生对患者之间差异的机制解释。将个体患者的治疗反应结合起来,并在人群水平上描述和模拟治疗反应的公式。根据预处理数据和实际的治疗计划,发现人群水平的反应可以准确地预测特定患者在五年期间的治疗反应。基于机制的治疗效果模型表明,血液学和分子观察量可以在个体患者的水平上进行预测。个性化的患者匹配表明,尽管患者之间的血液学和分子反应存在差异,但IFN治疗的效果可以通过数学模型进行量化和解释。数学模型表明,一般情况下,血液学和分子标记都必须考虑,以避免早期复发。此外,个性化模型拟合提供血液学和分子反应的定量测量,确定何时停止治疗是合适的。基于预处理数据的治疗反应的概念验证人群水平模型成功地预测了5年期间的临床措施。我们相信这种方法具有直接的临床意义,为临床决定IFN治疗MPN患者提供专家指导。
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Dose-dependent mathematical modeling of interferon- α-treatment for personalized treatment of myeloproliferative neoplasms

Long-term treatment with interferon-alfa (IFN) can reduce the disease burden of patients diagnosed with myeloproliferative neoplasms (MPNs). Determining individual patient responses to IFN therapy may allow for efficient personalized treatment, reducing both drop-out and disease burden. A mathematical model describing hematopoietic stem cells and the immune system is suggested. Considering the bone marrow and the blood allows for modeling disease dynamics both in the absence and presence of IFN treatment. Through comprehensive modeling of the effects of IFN, the model was related to individualized patient-data consisting of longitudinal hematologic and molecular measurements. Treatment responses were modeled on a population level, allowing for personalized predictions from a single pretreatment data point. Personalized fits were found to agree well with data for individual patients. This allowed for a quantitative description of the treatment response, yielding a mechanistic interpretation of differences from patient to patient. The treatment responses of individual patients were combined and a formulation of treatment responses on the population level was described and simulated. Based on pretreatment data and the actual treatment scheduling, the population-level response was found to predict the treatment response of particular patients accurately over a five-year period. Mechanism-based modeling of treatment effects demonstrates that hematologic and molecular observable quantities can be predicted on the level of individual patients. Personalized patient-fits suggest that the effect of IFN treatment can be quantified and interpreted through mathematical modeling, despite variation in hematologic and molecular responses between patients. Mathematical modeling suggests that in general both hematologic and molecular markers must be considered to avoid early relapse. Furthermore, personalized model-fits provide quantitative measures of the hematologic and molecular responses, determining when treatment-cessation is appropriate. Proof-of-concept population-level modeling of treatment responses from pretreatment data successfully predicted clinical measures for a 5-year period. We believe that this approach could have direct clinical relevance, offering expert guidance for clinical decisions about IFN treatment of MPN patients.

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CiteScore
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审稿时长
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