Multitype drug interaction prediction based on the deep fusion of drug features and topological relationships

Kang, Li-Ping; Lin, Kai-Biao; Lü, Ping; Yang, Fan; Chen, Jinpo

doi:10.1371/journal.pone.0273764

Cited by 12 publications

(13 citation statements)

References 44 publications

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Section: Methodsmentioning

confidence: 99%

“…However, chemical substructures, targets, pathways and enzymes contain more valuable information, making them beneficial for the analysis and commonly selected for comprehensive learning. 41,56 In this study, we focus on building a machine learning model to learn patterns and relationships between four specific features and DDI types, without discussing other influencing factors such as administration routes. However, the results obtained from this model provide theoretical and data support for subsequent research on designing more complex models and incorporating additional influencing features.…”

Section: Data Preparationmentioning

confidence: 99%

See 1 more Smart Citation

A low-cost machine learning framework for predicting drug–drug interactions based on fusion of multiple features and a parameter self-tuning strategy

Liang,

Lin,

Tan

et al. 2024

Phys. Chem. Chem. Phys.

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Section: Methodsmentioning

confidence: 99%

Section: Data Preparationmentioning

confidence: 99%

A low-cost machine learning framework for predicting drug–drug interactions based on fusion of multiple features and a parameter self-tuning strategy

Liang,

Lin,

Tan

et al. 2024

Phys. Chem. Chem. Phys.

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“…However, it is important to note that drug−target interaction prediction using machine learning is a dichotomous problem and cannot accurately predict the specific type of action of a drug target. Nonetheless, this approach remains a promising avenue for accelerating the 31 Chemical structural, Side effects Similarity, Logistic regression Undirected DDI Ferdousi et al 32 Carriers, Transporters Enzymes, Targets Similarity, Conventional classifier Undirected DDI Li et al 35 Chemical structural Similarity, Bayesian network Undirected DDI Kim et al 36 Medical terms, Semantic information SVM classifier, Huber loss function, Undirected DDI Cheng et al 37 Chemical structural Phenotypic Similarity, Conventional classifier Undirected DDI Park et al 45 Drug, Protein Similarity, Random walk Undirected DDI Zhang et al 61 Drug features Similarity, Matrix factorization Undirected DDI Rohani et al 51 Drug features Similarity, Matrix factorization Undirected DDI Kastrin et al 62 Chemical structural, Enzymes, Targets, Pathway Neighborhood recommendation, Random walk Undirected DDI Yan et al 38 Chemical structural, Biological, Phenotypic Similarity, RLS classifier Undirected DDI Ryu et al 78 Chemical structural Deep Neural Network, Multitask DDI events Lee et al 79 Chemical structural, Target gene, GO terms Deep Neural Network, Autoencoders DDI events Hou et al 100 Chemical structural Deep Neural Network DDI events Huang et al 101 Chemical structural Similarity, Graph neural networks DDI events Deng et al 12 Chemical structural, Enzymes, Targets, Pathway Similarity, Deep Neural Network DDI events Wang et al 102 Chemical structural, Enzymes, Targets Transformer, Autoencoders DDI events Lyu et al 103 Chemical structural, Enzymes, Targets Knowledge graph, Graph neural networks DDI events Zhu et al 114 Chemical structural Dual-view, Graph neural networks DDI events Deng et al 104 Chemical structural Small-sample learning DDI events Kang et al 105 Chemical structural, Enzymes, Targets, Pathway Deep Neural Network, Graph neural networks DDI events Shao et al 106 Chemical structural, Semantic information Pretrained transformer DDI events Lin et al 107 Drug features Attention, Contrastive learning DDI events Feng et al 29 Chemical drug discovery process and identifying potential therapeutic targets. 109 Zhang et al proposed a method for predicting drug target interactions us...…”

Section: Based On Matrix Factorization Prediction Methodsmentioning

confidence: 99%

“…Kang et al 105 improved upon the work of Deng et al 12 by proposing a deep learning-based multitype drug−drug interaction (DDI) prediction model called DM-DDI, which mixes topological linkages and pharmacological characteristics. The method for DDI prediction utilizes a deep fusion approach that integrates both drug features and topological structures in order to learn relevant feature vectors.…”

Section: The Prediction Of Drug−drug Interaction Eventsmentioning

confidence: 99%

Application of Artificial Intelligence in Drug–Drug Interactions Prediction: A Review

Zhang

Deng

et al. 2023

J. Chem. Inf. Model.

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Drug–drug interactions (DDI) are a critical aspect of drug research that can have adverse effects on patients and can lead to serious consequences. Predicting these events accurately can significantly improve clinicians’ ability to make better decisions and establish optimal treatment regimens. However, manually detecting these interactions is time-consuming and labor-intensive. Utilizing the advancements in Artificial Intelligence (AI) is essential for achieving accurate forecasts of DDIs. In this review, DDI prediction tasks are classified into three types according to the type of DDI prediction: undirected DDI prediction, DDI events prediction, and Asymmetric DDI prediction. The paper then reviews the progress of AI for each of these three prediction tasks in DDI and provides a summary of the data sets used as well as the representative methods used in these three prediction directions. In this review, we aim to provide a comprehensive overview of drug interaction prediction. The first section introduces commonly used databases and presents an overview of current research advancements and techniques across three domains of DDI. Additionally, we introduce classical machine learning techniques for predicting undirected drug interactions and provide a timeline for the progression of the predicted drug interaction events. At last, we debate the difficulties and prospects of AI approaches at predicting DDI, emphasizing their potential for improving clinical decision-making and patient outcomes.

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“…For DDI prediction, feature or topological similarity-based approaches are the most common. Many methods have been developed based on these methods in different ways, including aggregating multiple types of drug features ( Gottlieb et al, 2012 ), predicting multi-class drug reaction events ( Ryu et al, 2018 ), and integrating drug attribute features with drug interaction relationship ( Kang et al, 2022 ). These optimized methods are effective and make the DDI predictions more complete.…”

Section: Introductionmentioning

confidence: 99%

MFDA: Multiview fusion based on dual-level attention for drug interaction prediction

et al. 2022

Self Cite

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Drug-drug interaction prediction plays an important role in pharmacology and clinical applications. Most traditional methods predict drug interactions based on drug attributes or network structure. They usually have three limitations: 1) failing to integrate drug features and network structures well, resulting in less informative drug embeddings; 2) being restricted to a single view of drug interaction relationships; 3) ignoring the importance of different neighbors. To tackle these challenges, this paper proposed a multiview fusion based on dual-level attention to predict drug interactions (called MFDA). The MFDA first constructed multiple views for the drug interaction relationship, and then adopted a cross-fusion strategy to deeply fuse drug features with the drug interaction network under each view. To distinguish the importance of different neighbors and views, MFDA adopted a dual-level attention mechanism (node level and view level) to obtain the unified drug embedding for drug interaction prediction. Extensive experiments were conducted on real datasets, and the MFDA demonstrated superior performance compared to state-of-the-art baselines. In the multitask analysis of new drug reactions, MFDA obtained higher scores on multiple metrics. In addition, its prediction results corresponded to specific drug reaction events, which achieved more accurate predictions.

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Multitype drug interaction prediction based on the deep fusion of drug features and topological relationships

Cited by 12 publications

References 44 publications

A low-cost machine learning framework for predicting drug–drug interactions based on fusion of multiple features and a parameter self-tuning strategy

A low-cost machine learning framework for predicting drug–drug interactions based on fusion of multiple features and a parameter self-tuning strategy

Application of Artificial Intelligence in Drug–Drug Interactions Prediction: A Review

MFDA: Multiview fusion based on dual-level attention for drug interaction prediction

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