Modelling the Economic Impact of Next Generation Sequencing and Precision Medicine on Childhood Cancer Management—a Microsimulation Approach

Q3 Social Sciences

International Journal of Microsimulation Pub Date : 2021-04-30 DOI:10.34196/ijm.00230

Owen Tan, D. Schofield, T. O’Brien, T. Trahair, R. Shrestha

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引用次数: 0

Abstract

Precision medicine is a new approach to identify the best treatment available to patients based on their genomic information. However, no economic evaluation of genome sequencing has been reported for the treatment of childhood cancers, which is critical to evaluate the feasibility of implementing patient’s genome sequencing as part of a publicly funded treatment strategy. We have developed a microsimulation model, PeCanMOD, to evaluate the cost and benefit of applying the Next Generation Sequencing (NGS) in the management of childhood cancer. This paper describes the construction of PeCanMOD. We used linked datasets of children under 18 year of age, living in New South Wales (NSW), Australia, who have had cancer, as a base population. Their records were extracted from the NSW Central Cancer Registry and were linked to mortality and hospital datasets. In addition, we simulated the genomic landscape of the cancer registry population, through information obtained from 1,200 molecularly profiled paediatric cancer from the Foundation Medicine. The model simulated the number of individuals eligible for precision medicine, and the incremental cost of treatment per life year gained if precision medicine was introduced for late stage cancer patients as a final treatment option. Cost of drugs, and hospital admission were included in the model. Data on response rate and probability of survival was imputed based on the latest available evidence. Each unit record in the model was weighted using input from the Australian Institute of Health and Welfare (AIHW) to reflect total paediatric cancer population in Australia. The model demonstrates the application of microsimulation modelling to simulate the impacts of NGS and precision medicine on costs and health outcomes for childhood cancer. JEL classification: C1, C3, I1 DOI: https:// doi. org/ 10. 34196/ ijm. 00230

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模拟下一代测序和精准医学对儿童癌症管理的经济影响-微观模拟方法

精准医学是一种根据患者的基因组信息确定最佳治疗方案的新方法。然而，没有关于基因组测序治疗儿童癌症的经济评估报告，这对于评估将患者基因组测序作为公共资助治疗策略的一部分的可行性至关重要。我们开发了一个微观模拟模型PeCanMOD，以评估应用下一代测序(NGS)在儿童癌症管理中的成本和收益。本文介绍了PeCanMOD的构建过程。我们使用了生活在澳大利亚新南威尔士州(NSW)的18岁以下患有癌症的儿童的相关数据集作为基础人群。他们的记录是从新南威尔士州中央癌症登记处提取的，并与死亡率和医院数据集相关联。此外，我们通过从基础医学获得的1200个分子谱儿科癌症的信息，模拟了癌症登记人群的基因组景观。该模型模拟了有资格获得精准医疗的个人数量，以及如果将精准医疗引入晚期癌症患者作为最终治疗选择，每个生命年的治疗增量成本。模型中包含了药物费用和住院费用。应答率和生存概率的数据是根据最新的证据计算出来的。模型中的每个单位记录都使用澳大利亚健康与福利研究所(AIHW)的输入进行加权，以反映澳大利亚的儿科癌症总人数。该模型展示了微观模拟模型的应用，以模拟NGS和精准医疗对儿童癌症的成本和健康结果的影响。JEL分类:C1、C3、I1 DOI: https:// DOI。org/ 10。34196 / ijm。00230

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来源期刊

International Journal of Microsimulation Mathematics-Modeling and Simulation

CiteScore

0.80

自引率

0.00%

发文量

期刊介绍： The IJM covers research in all aspects of microsimulation modelling. It publishes high quality contributions making use of microsimulation models to address specific research questions in all scientific areas, as well as methodological and technical issues. IJM concern: the description, validation, benchmarking and replication of microsimulation models; results coming from microsimulation models, in particular policy evaluation and counterfactual analysis; technical or methodological aspect of microsimulation modelling; reviews of models and results, as well as of technical or methodological issues.