The Impact of the Approach to Accounting for Age and Sex in Economic Models on Predicted Quality-Adjusted Life-Years.

IF 3.1 4区 医学 Q1 ECONOMICS
Dawn Lee, Rose Hart, Darren Burns, Grant McCarthy
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引用次数: 0

Abstract

Background: The method used to model general population mortality estimates in cohort models can make a meaningful difference in appraisals; particularly in scenarios involving potentially curative treatments where a prior National Institute for Health and Care Excellence (NICE) appraisal demonstrated that this assumption alone could make a difference of ~£10,000 to the incremental cost-effectiveness ratio.

Objective: Our objective was to evaluate the impact of different methods for calculating general population mortality estimates on the predicted total quality-adjusted life expectancy (QALE) as well as absolute and proportional quality-adjusted life year (QALY) shortfall calculations.

Methods: We employed three distinct methods for deriving general population mortality estimates: firstly, utilizing the population mean age at baseline; secondly, modelling the distribution of mean age at baseline by fitting a parametric distribution to patient-level data sourced from the Health Survey for England (HSE); and thirdly, modelling the empirical age distribution. Subsequently, we simulated patient age distributions to explore the effects of mean starting age and variance levels on the predicted QALE and applicable severity modifiers. Provided sample code in R and Visual Basic for Applications (VBA) facilitates the utilization of individual patient age and sex data to generate weighted average survival and health-related quality of life (utility) outputs.

Results: We observed differences of up to 10.4% (equivalent to a difference of 1.01 QALYs in quality-adjusted life-expectancy) between methods using the HSE dataset. In our simulation study, increasing variance in baseline age diminished the accuracy of predictions relying solely on mean age estimation. Differences of -0.30 to 2.24 QALYs were found at a standard deviation of 20%; commonly observed in trials. For potentially curative treatments this would represent a difference in economically justifiable price of -£4,500-+£33,600 at a cost-effectiveness threshold of £30,000 per QALY for a treatment with a 50% cure rate. For lower baseline ages, the population mean method tended to overestimate QALE, whereas for higher baseline ages, it tended to underestimate QALE compared with individual patient age-based approaches. The severity modifier assigned did not vary, however, apart from simulations with means at the extremes of the age distribution or with very high variance.

Conclusions: Our analysis underscores the necessity of accounting for the distribution of mean age at baseline, as failure to do so can lead to inaccurate QALE estimates, thereby affecting calculations of incremental costs and QALYs in models, which base survival and quality of life predictions on general population expectations. We would recommend that patient age and sex distribution should be accounted for when incorporating general population mortality in economic models. Provided sufficient sample size, utilizing the observed empirical distribution for the expected population in clinical practice is likely to yield the most accurate results. However, in the absence of patient-level data, selecting a suitable parametric distribution is recommended.

经济模型中考虑年龄和性别的方法对预测质量调整寿命的影响。
背景:在队列模型中模拟普通人群死亡率估计值所使用的方法可能会在评估中产生有意义的差异;尤其是在涉及潜在治愈性治疗的情况下,美国国家健康与护理优化研究所(NICE)之前的一项评估表明,仅这一假设就可使增量成本效益比相差约 10,000 英镑:我们的目标是评估计算普通人群死亡率估计值的不同方法对预测的总质量调整预期寿命 (QALE) 以及绝对和比例质量调整生命年 (QALY) 不足计算的影响:我们采用了三种不同的方法来得出一般人群的死亡率估算值:第一,利用基线时的人群平均年龄;第二,通过对来自英格兰健康调查(HSE)的患者水平数据进行参数拟合,对基线时的平均年龄分布进行建模;第三,对经验年龄分布进行建模。随后,我们模拟了患者的年龄分布,以探索平均起始年龄和方差水平对预测 QALE 和适用的严重程度修正因子的影响。提供的 R 和 Visual Basic 应用程序(VBA)示例代码便于利用患者的年龄和性别数据生成加权平均生存率和健康相关生活质量(效用)输出:我们观察到,使用 HSE 数据集的不同方法之间存在高达 10.4% 的差异(相当于质量调整预期寿命中 1.01 QALYs 的差异)。在我们的模拟研究中,基线年龄差异的增加降低了仅依靠平均年龄估计进行预测的准确性。当标准偏差为 20% 时,差异为-0.30 至 2.24 QALYs;这在试验中很常见。对于可能治愈的治疗方法而言,这意味着经济上合理的价格差异为-4,500 英镑至+33,600 英镑(成本效益阈值为每 QALY 30,000 英镑),治疗率为 50%。与基于单个患者年龄的方法相比,对于较低的基线年龄,人群平均法往往会高估QALE,而对于较高的基线年龄,人群平均法往往会低估QALE。然而,除了年龄分布极端平均值或差异非常大的模拟外,所分配的严重程度修正系数并无不同:我们的分析强调了考虑基线平均年龄分布的必要性,因为不考虑平均年龄分布会导致 QALE 估计值不准确,从而影响模型中增量成本和 QALY 的计算,因为模型是根据一般人群的预期来预测生存期和生活质量的。我们建议,在将普通人群死亡率纳入经济模型时,应考虑患者的年龄和性别分布。如果样本量足够大,利用临床实践中预期人群的经验观察分布可能会得出最准确的结果。然而,在缺乏患者层面数据的情况下,建议选择合适的参数分布。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Applied Health Economics and Health Policy
Applied Health Economics and Health Policy Economics, Econometrics and Finance-Economics and Econometrics
CiteScore
6.10
自引率
2.80%
发文量
64
期刊介绍: Applied Health Economics and Health Policy provides timely publication of cutting-edge research and expert opinion from this increasingly important field, making it a vital resource for payers, providers and researchers alike. The journal includes high quality economic research and reviews of all aspects of healthcare from various perspectives and countries, designed to communicate the latest applied information in health economics and health policy. While emphasis is placed on information with practical applications, a strong basis of underlying scientific rigor is maintained.
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