Discovering protein drug targets using knowledge graph embeddings

Mohamed, Sameh K.; Nováček, Vít; Nounu, Aayah

doi:10.1093/bioinformatics/btz600

Cited by 172 publications

(124 citation statements)

References 40 publications

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“…Then, the Long Short-Term Memory (LSTM) Networks model is trained to discover candidate drugs for diseases of interest from biomedical literature. TriModel [20] is an extension of DistMultand and ComplEx models, using three embedding vectors to represent each entity and relationship. These methods have high requirements on the quality of knowledge graphs and are suitable for finding new associations between drugs and targets that have been fully studied; however, they are not suitable for drug repositioning for emerging diseases due to incomplete disease-related information in the knowledge graph.…”

Section: Related Workmentioning

confidence: 99%

Knowledge-Graph-Based Drug Repositioning against COVID-19 by Graph Convolutional Network with Attention Mechanism

et al. 2021

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The current global crisis caused by COVID-19 almost halted normal life in most parts of the world. Due to the long development cycle for new drugs, drug repositioning becomes an effective method of screening drugs for COVID-19. To find suitable drugs for COVID-19, we add COVID-19-related information into our medical knowledge graph and utilize a knowledge-graph-based drug repositioning method to screen potential therapeutic drugs for COVID-19. Specific steps are as follows. Firstly, the information about COVID-19 is collected from the latest published literature, and gene targets of COVID-19 are added to the knowledge graph. Then, the information of COVID-19 of the knowledge graph is extracted and a drug–disease interaction prediction model based on Graph Convolutional Network with Attention (Att-GCN) is established. Att-GCN is used to extract features from the knowledge graph and the prediction matrix reconstructed through matrix operation. We evaluate the model by predicting drugs for both ordinary diseases and COVID-19. The model can achieve area under curve (AUC) of 0.954 and area under the precise recall area curve (AUPR) of 0.851 for ordinary diseases. On the drug repositioning experiment for COVID-19, five drugs predicted by the models have proved effective in clinical treatment. The experimental results confirm that the model can predict drug–disease interaction effectively for both normal diseases and COVID-19.

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Section: Related Workmentioning

confidence: 99%

Knowledge-Graph-Based Drug Repositioning against COVID-19 by Graph Convolutional Network with Attention Mechanism

et al. 2021

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“…Knowledge graphs represent entities, relations, and semantic information as a graph that can be easily interpreted for a machine. Mohamed et al [18] proposed a knowledge graph embedding model named TriModel. They constructed a drug-target interaction knowledge graph from KEGG, DrugBank, InterPRo, and UniPRot.…”

Section: Network-based Approachesmentioning

confidence: 99%

Artificial Intelligence in Drug Discovery: A Comprehensive Review of Data-driven and Machine Learning Approaches

Kim

Lee

et al. 2020

Biotechnol Bioproc E

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“…The knowledge graph embedding is used to calculate several similarity measures between all drugs in the scalable and distributed framework to obtain the interaction of drugs (Ibrahim et al, 2017 ). Mohamed et al ( 2020 ) used knowledge graph embeddings to learn the vector representation of all drugs and targets to discover protein drug targets.…”

Section: Related Workmentioning

confidence: 99%

Explainable Prediction of Medical Codes With Knowledge Graphs

Teng

Yang

Chen

et al. 2020

Front. Bioeng. Biotechnol.

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International Classification of Diseases (ICD) is an authoritative health care classification system of different diseases. It is widely used for disease and health records, assisted medical reimbursement decisions, and collecting morbidity and mortality statistics. The most existing ICD coding models only translate the simple diagnosis descriptions into ICD codes. And it obscures the reasons and details behind specific diagnoses. Besides, the label (code) distribution is uneven. And there is a dependency between labels. Based on the above considerations, the knowledge graph and attention mechanism were expanded into medical code prediction to improve interpretability. In this study, a new method called G_Coder was presented, which mainly consists of Multi-CNN, graph presentation, attentional matching, and adversarial learning. The medical knowledge graph was constructed by extracting entities related to ICD-9 from freebase. Ontology contains 5 entity classes, which are disease, symptom, medicine, surgery, and examination. The result of G_Coder on the MIMIC-III dataset showed that the micro-F1 score is 69.2% surpassing the state of art. The following conclusions can be obtained through the experiment: G_Coder integrates information across medical records using Multi-CNN and embeds knowledge into ICD codes. Adversarial learning is used to generate the adversarial samples to reconcile the writing styles of doctor. With the knowledge graph and attention mechanism, most relevant segments of medical codes can be explained. This suggests that the knowledge graph significantly improves the precision of code prediction and reduces the working pressure of the human coders.

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Discovering protein drug targets using knowledge graph embeddings

Cited by 172 publications

References 40 publications

Knowledge-Graph-Based Drug Repositioning against COVID-19 by Graph Convolutional Network with Attention Mechanism

Knowledge-Graph-Based Drug Repositioning against COVID-19 by Graph Convolutional Network with Attention Mechanism

Artificial Intelligence in Drug Discovery: A Comprehensive Review of Data-driven and Machine Learning Approaches

Explainable Prediction of Medical Codes With Knowledge Graphs

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