Scientific and Statistical Computing Core, National Institute of Mental Health, Bethesda, MD, USA.
Department of Psychology, University of Maryland, College Park, MD, 20742, USA.
Neuroinformatics. 2019 Oct;17(4):515-545. doi: 10.1007/s12021-018-9409-6.
Here we address the current issues of inefficiency and over-penalization in the massively univariate approach followed by the correction for multiple testing, and propose a more efficient model that pools and shares information among brain regions. Using Bayesian multilevel (BML) modeling, we control two types of error that are more relevant than the conventional false positive rate (FPR): incorrect sign (type S) and incorrect magnitude (type M). BML also aims to achieve two goals: 1) improving modeling efficiency by having one integrative model and thereby dissolving the multiple testing issue, and 2) turning the focus of conventional null hypothesis significant testing (NHST) on FPR into quality control by calibrating type S errors while maintaining a reasonable level of inference efficiency. The performance and validity of this approach are demonstrated through an application at the region of interest (ROI) level, with all the regions on an equal footing: unlike the current approaches under NHST, small regions are not disadvantaged simply because of their physical size. In addition, compared to the massively univariate approach, BML may simultaneously achieve increased spatial specificity and inference efficiency, and promote results reporting in totality and transparency. The benefits of BML are illustrated in performance and quality checking using an experimental dataset. The methodology also avoids the current practice of sharp and arbitrary thresholding in the p-value funnel to which the multidimensional data are reduced. The BML approach with its auxiliary tools is available as part of the AFNI suite for general use.
在这里,我们解决了传统的单变量方法在进行多重检验校正时效率低下和过度惩罚的问题,并提出了一种更有效的模型,该模型可以在脑区之间进行信息的汇集和共享。我们使用贝叶斯多层次(BML)建模来控制比传统的假阳性率(FPR)更相关的两种错误:错误的符号(type S)和错误的幅度(type M)。BML 还旨在实现两个目标:1)通过一个综合模型来提高建模效率,从而解决多重检验问题;2)通过校准 type S 错误,将传统的零假设显著检验(NHST)的重点从 FPR 转移到质量控制上,同时保持合理的推断效率。这种方法的性能和有效性通过在感兴趣区域(ROI)水平上的应用得到了证明,所有区域都处于平等地位:与 NHST 下的当前方法不同,小区域不会仅仅因为其物理大小而处于劣势。此外,与传统的单变量方法相比,BML 可以同时提高空间特异性和推断效率,并促进整体和透明的结果报告。BML 方法及其辅助工具通过使用实验数据集进行性能和质量检查得到了说明。该方法还避免了当前在多维数据简化为 p 值漏斗时使用的尖锐和任意阈值的做法。BML 方法及其辅助工具作为 AFNI 套件的一部分,可供一般使用。
