利用多组数据进行贝叶斯同步因式分解和预测

IF 1.5 3区 数学 Q3 COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS
Sarah Samorodnitsky , Chris H. Wendt , Eric F. Lock
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引用次数: 0

摘要

多组学数据的综合因子化方法可估算出解释生物变异的因子。因子可被视为预测结果的协变量,因子化可用于缺失值的补偿。然而,目前还没有任何方法能为这些任务提供统计推断和不确定性量化的综合框架。我们提出了一个新颖的框架--贝叶斯同时因式分解(BSF),在概率框架内将多组学变异同时分解为联合结构和个体结构。BSF 使用共轭正态前验,通过求解结构化核规范惩罚目标可以估计出该模型的后验模式,该目标还能实现秩选择并激励超参数的选择。然后,BSF 被扩展为在估计潜在因子的同时预测连续或二元表型,称为贝叶斯同步因式分解和预测(BSFP)。BSF 和 BSFP 可同时进行估算,即在模型拟合过程中进行估算,并对缺失数据(包括 "顺时针 "缺失)进行完全后验推断。模拟结果表明,BSFP 在恢复潜在变异结构方面具有竞争力,并证明了在预测模型中考虑估计因式分解不确定性的重要性。在随机缺失和非随机缺失假设下,通过模拟检验了 BSF 的归因性能。最后,BSFP 被用于根据一项艾滋病相关阻塞性肺病研究中支气管肺泡灌洗液代谢组和蛋白质组预测肺功能,揭示了与肺功能下降相关的多组学模式,以及由共同代谢组和蛋白质组丰度模式驱动的阻塞性肺病患者群。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Bayesian simultaneous factorization and prediction using multi-omic data

Integrative factorization methods for multi-omic data estimate factors explaining biological variation. Factors can be treated as covariates to predict an outcome and the factorization can be used to impute missing values. However, no available methods provide a comprehensive framework for statistical inference and uncertainty quantification for these tasks. A novel framework, Bayesian Simultaneous Factorization (BSF), is proposed to decompose multi-omics variation into joint and individual structures simultaneously within a probabilistic framework. BSF uses conjugate normal priors and the posterior mode of this model can be estimated by solving a structured nuclear norm-penalized objective that also achieves rank selection and motivates the choice of hyperparameters. BSF is then extended to simultaneously predict a continuous or binary phenotype while estimating latent factors, termed Bayesian Simultaneous Factorization and Prediction (BSFP). BSF and BSFP accommodate concurrent imputation, i.e., imputation during the model-fitting process, and full posterior inference for missing data, including “blockwise” missingness. It is shown via simulation that BSFP is competitive in recovering latent variation structure, and demonstrate the importance of accounting for uncertainty in the estimated factorization within the predictive model. The imputation performance of BSF is examined via simulation under missing-at-random and missing-not-at-random assumptions. Finally, BSFP is used to predict lung function based on the bronchoalveolar lavage metabolome and proteome from a study of HIV-associated obstructive lung disease, revealing multi-omic patterns related to lung function decline and a cluster of patients with obstructive lung disease driven by shared metabolomic and proteomic abundance patterns.

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来源期刊
Computational Statistics & Data Analysis
Computational Statistics & Data Analysis 数学-计算机:跨学科应用
CiteScore
3.70
自引率
5.60%
发文量
167
审稿时长
60 days
期刊介绍: Computational Statistics and Data Analysis (CSDA), an Official Publication of the network Computational and Methodological Statistics (CMStatistics) and of the International Association for Statistical Computing (IASC), is an international journal dedicated to the dissemination of methodological research and applications in the areas of computational statistics and data analysis. The journal consists of four refereed sections which are divided into the following subject areas: I) Computational Statistics - Manuscripts dealing with: 1) the explicit impact of computers on statistical methodology (e.g., Bayesian computing, bioinformatics,computer graphics, computer intensive inferential methods, data exploration, data mining, expert systems, heuristics, knowledge based systems, machine learning, neural networks, numerical and optimization methods, parallel computing, statistical databases, statistical systems), and 2) the development, evaluation and validation of statistical software and algorithms. Software and algorithms can be submitted with manuscripts and will be stored together with the online article. II) Statistical Methodology for Data Analysis - Manuscripts dealing with novel and original data analytical strategies and methodologies applied in biostatistics (design and analytic methods for clinical trials, epidemiological studies, statistical genetics, or genetic/environmental interactions), chemometrics, classification, data exploration, density estimation, design of experiments, environmetrics, education, image analysis, marketing, model free data exploration, pattern recognition, psychometrics, statistical physics, image processing, robust procedures. [...] III) Special Applications - [...] IV) Annals of Statistical Data Science [...]
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