Accurate EVSI Estimation for Nonlinear Models Using the Gaussian Approximation Method.

IF 3.1 3区医学 Q2 HEALTH CARE SCIENCES & SERVICES

Medical Decision Making Pub Date : 2024-07-31 DOI:10.1177/0272989X241264287

Linke Li, Hawre Jalal, Anna Heath

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引用次数: 0

Abstract

Background: The expected value of sample information (EVSI) measures the expected benefits that could be obtained by collecting additional data. Estimating EVSI using the traditional nested Monte Carlo method is computationally expensive, but the recently developed Gaussian approximation (GA) approach can efficiently estimate EVSI across different sample sizes. However, the conventional GA may result in biased EVSI estimates if the decision models are highly nonlinear. This bias may lead to suboptimal study designs when GA is used to optimize the value of different studies. Therefore, we extend the conventional GA approach to improve its performance for nonlinear decision models.

Methods: Our method provides accurate EVSI estimates by approximating the conditional expectation of the benefit based on 2 steps. First, a Taylor series approximation is applied to estimate the conditional expectation of the benefit as a function of the conditional moments of the parameters of interest using a spline, which is fitted to the samples of the parameters and the corresponding benefits. Next, the conditional moments of parameters are approximated by the conventional GA and Fisher information. The proposed approach is applied to several data collection exercises involving non-Gaussian parameters and nonlinear decision models. Its performance is compared with the nested Monte Carlo method, the conventional GA approach, and the nonparametric regression-based method for EVSI calculation.

Results: The proposed approach provides accurate EVSI estimates across different sample sizes when the parameters of interest are non-Gaussian and the decision models are nonlinear. The computational cost of the proposed method is similar to that of other novel methods.

Conclusions: The proposed approach can estimate EVSI across sample sizes accurately and efficiently, which may support researchers in determining an economically optimal study design using EVSI.

Highlights: The Gaussian approximation method efficiently estimates the expected value of sample information (EVSI) for clinical trials with varying sample sizes, but it may introduce bias when health economic models have a nonlinear structure.We introduce the spline-based Taylor series approximation method and combine it with the original Gaussian approximation to correct the nonlinearity-induced bias in EVSI estimation.Our approach can provide more precise EVSI estimates for complex decision models without sacrificing computational efficiency, which can enhance the resource allocation strategies from the cost-effective perspective.

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利用高斯逼近法对非线性模型进行精确的 EVSI 估算

背景：样本信息的预期值（EVSI）衡量的是收集额外数据所能带来的预期收益。使用传统的嵌套蒙特卡罗方法估算 EVSI 的计算成本很高，但最近开发的高斯近似（GA）方法可以有效地估算不同样本量的 EVSI。不过，如果决策模型是高度非线性的，传统的 GA 可能会导致 EVSI 估计值出现偏差。当使用 GA 来优化不同研究的价值时，这种偏差可能会导致次优的研究设计。因此，我们扩展了传统的 GA 方法，以提高其在非线性决策模型中的性能：我们的方法通过两个步骤来近似收益的条件期望值，从而提供准确的 EVSI 估计值。首先，采用泰勒级数近似法估计收益的条件期望值，将其作为使用样条线的相关参数条件矩的函数。然后，用传统的 GA 和费雪信息来近似参数的条件矩。所提出的方法适用于涉及非高斯参数和非线性决策模型的若干数据收集工作。将其性能与嵌套蒙特卡罗方法、传统 GA 方法和基于非参数回归的 EVSI 计算方法进行了比较：结果：当相关参数为非高斯参数且决策模型为非线性模型时，所提出的方法可在不同样本量下提供准确的 EVSI 估计值。所提方法的计算成本与其他新方法相似：结论：所提出的方法可以准确、高效地估计不同样本量的 EVSI，从而帮助研究人员利用 EVSI 确定经济上最优的研究设计：我们引入了基于样条线的泰勒级数近似方法，并将其与原始的高斯近似方法相结合，以纠正EVSI估计中由非线性引起的偏差。我们的方法可以在不牺牲计算效率的情况下为复杂的决策模型提供更精确的EVSI估计值，从而从成本效益的角度提高资源分配策略。

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

Medical Decision Making 医学-卫生保健

CiteScore

6.50

自引率

5.60%

发文量

146

审稿时长

6-12 weeks

期刊介绍： Medical Decision Making offers rigorous and systematic approaches to decision making that are designed to improve the health and clinical care of individuals and to assist with health care policy development. Using the fundamentals of decision analysis and theory, economic evaluation, and evidence based quality assessment, Medical Decision Making presents both theoretical and practical statistical and modeling techniques and methods from a variety of disciplines.