利用深度关联模型整合儿童哮喘的多组学数据

IF 6.2 3区 综合性期刊 Q1 Multidisciplinary Fundamental Research Pub Date : 2024-07-01 DOI:10.1016/j.fmre.2024.03.022
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引用次数: 0

摘要

儿童哮喘是最常见的呼吸系统疾病之一,死亡率和发病率不断上升。多组学数据为探索儿童哮喘的协作生物标志物和相应的诊断模型提供了新的机会。为了捕捉多组学数据的非线性关联,提高诊断模型的可解释性,我们提出了一种新的深度关联模型(DAM)和相应的高效分析框架。首先,利用深度子空间重构(Deep Subspace Reconstruction)技术融合组学数据和诊断信息,从而校正原始组学数据的分布,减少不必要的数据噪声的影响。其次,应用联合深度半负矩阵因式分解来识别不同的潜在样本模式,并从不同的 omics 数据水平中提取生物标记物。第三,我们新提出的深度正交典型相关分析(Deep Orthogonal Canonical Correlation Analysis)可以对协作模块中的特征进行排序,从而构建出考虑到不同 omics 数据层级之间非线性相关性的诊断模型。利用 DAM,我们深入分析了儿童哮喘的转录组和甲基化数据。在独立测试数据集上,通过消融实验以及与临床和生物学研究中的许多基线方法的比较,从算法性能和生物学意义的角度验证了 DAM 的有效性。DAM诱导的诊断模型的预测AUC可达0.912,高于许多其他替代方法。同时,儿童哮喘的相关通路和生物标志物也被认为在基因表达和甲基化水平上发生了集体改变。作为一种可解释的机器学习方法,DAM 同时考虑了样本间的非线性关联和生物特征间的非线性关联,有助于从多组学数据分析中发现可解释的候选生物标记物和高效的诊断模型,用于人类复杂疾病的诊断。
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Integrating multi-omics data of childhood asthma using a deep association model

Childhood asthma is one of the most common respiratory diseases with rising mortality and morbidity. The multi-omics data is providing a new chance to explore collaborative biomarkers and corresponding diagnostic models of childhood asthma. To capture the nonlinear association of multi-omics data and improve interpretability of diagnostic model, we proposed a novel deep association model (DAM) and corresponding efficient analysis framework. First, the Deep Subspace Reconstruction was used to fuse the omics data and diagnostic information, thereby correcting the distribution of the original omics data and reducing the influence of unnecessary data noises. Second, the Joint Deep Semi-Negative Matrix Factorization was applied to identify different latent sample patterns and extract biomarkers from different omics data levels. Third, our newly proposed Deep Orthogonal Canonical Correlation Analysis can rank features in the collaborative module, which are able to construct the diagnostic model considering nonlinear correlation between different omics data levels. Using DAM, we deeply analyzed the transcriptome and methylation data of childhood asthma. The effectiveness of DAM is verified from the perspectives of algorithm performance and biological significance on the independent test dataset, by ablation experiment and comparison with many baseline methods from clinical and biological studies. The DAM-induced diagnostic model can achieve a prediction AUC of 0.912, which is higher than that of many other alternative methods. Meanwhile, relevant pathways and biomarkers of childhood asthma are also recognized to be collectively altered on the gene expression and methylation levels. As an interpretable machine learning approach, DAM simultaneously considers the non-linear associations among samples and those among biological features, which should help explore interpretative biomarker candidates and efficient diagnostic models from multi-omics data analysis for human complex diseases.

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来源期刊
Fundamental Research
Fundamental Research Multidisciplinary-Multidisciplinary
CiteScore
4.00
自引率
1.60%
发文量
294
审稿时长
79 days
期刊介绍:
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