Disease prediction by network information gain on a single sample basis

IF 6.3 3区综合性期刊 Q1 Multidisciplinary Fundamental Research Pub Date : 2025-01-01 DOI:10.1016/j.fmre.2023.01.009

Jinling Yan , Peiluan Li , Ying Li , Rong Gao , Cheng Bi , Luonan Chen

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Abstract

There are critical transition phenomena during the progression of many diseases. Such critical transitions are usually accompanied by catastrophic disease deterioration, and their prediction is of significant importance for disease prevention and treatment. However, predicting disease deterioration solely based on a single sample is a difficult problem. In this study, we presented the network information gain (NIG) method, for predicting the critical transitions or disease state based on network flow entropy from omics data of each individual. NIG can not only efficiently predict disease deteriorations but also detect their dynamic network biomarkers on an individual basis and further identify potential therapeutic targets. The numerical simulation demonstrates the effectiveness of NIG. Moreover, our method was validated by successfully predicting disease deteriorations and identifying their potential therapeutic targets from four real omics datasets, i.e., an influenza dataset and three cancer datasets.

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基于单样本的网络信息增益疾病预测

在许多疾病的发展过程中都存在着关键的过渡现象。这种关键转变通常伴随着疾病的灾难性恶化，其预测对疾病的预防和治疗具有重要意义。然而，仅基于单一样本预测疾病恶化是一个难题。在这项研究中，我们提出了网络信息增益（NIG）方法，用于基于每个个体的组学数据的网络流熵来预测关键转变或疾病状态。NIG不仅可以有效地预测疾病的恶化，还可以在个体基础上检测其动态网络生物标志物，从而进一步确定潜在的治疗靶点。数值模拟验证了NIG的有效性。此外，我们的方法通过成功预测疾病恶化并从四个真实的组学数据集（即流感数据集和三个癌症数据集）确定其潜在的治疗靶点而得到验证。

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