OWL2Vec*: embedding of OWL ontologies

Chen, Jiaoyan; Pan, Hongyu; Jiménez-Ruiz, Ernesto; Holter, Ole Magnus; Antonyrajah, Denvar; Horrocks, Ian

doi:10.1007/s10994-021-05997-6

Cited by 77 publications

(42 citation statements)

References 33 publications

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“…This is mainly due to the superiority of contextual text embeddings by BERT, and this result is consistent with BERTMap which also uses BERT to find equivalent classes using their labels alone (He et al 2022). It is worth mentioning that the performance ranking of the baselines in this study is mostly consistent with that in (Chen et al 2021) where all the named classes are considered for the negative subsumers in testing. Second, using additional synonym properties besides rdfs:label has positive impact on FoodOn but negative impact on GO.…”

Section: Resultssupporting

confidence: 69%

“…Some recent ontology embedding methods take lexical annotations into consideration and are applied in class subsumption prediction. For example, OWL2Vec * (Chen et al 2021) first transforms an OWL ontology into sequences and then uses Word2Vec (Mikolov et al 2013) to learn the embeddings of the classes, and finally trains a classifier for subsumption prediction using the ontology's existing subsumptions. OPA2Vec (Smaili, Gao, and Hoehndorf 2019) and Onto2Vec (Smaili, Gao, and Hoehndorf 2018) are similar ontology embedding methods that can be used in such a subsumption prediction pipeline.…”

Section: Introductionmentioning

confidence: 99%

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Contextual Semantic Embeddings for Ontology Subsumption Prediction

Chen¹,

He²,

Jiménez-Ruiz³

et al. 2022

Preprint

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Automating ontology curation is a crucial task in knowledge engineering. Prediction by machine learning techniques such as semantic embedding is a promising direction, but the relevant research is still preliminary. In this paper, we present a class subsumption prediction method named BERTSubs, which uses the pre-trained language model BERT to compute contextual embeddings of the class labels and customized input templates to incorporate contexts of surrounding classes. The evaluation on two large-scale real-world ontologies has shown its better performance than the state-of-the-art.

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Section: Resultssupporting

confidence: 69%

Section: Introductionmentioning

confidence: 99%

Contextual Semantic Embeddings for Ontology Subsumption Prediction

Chen¹,

He²,

Jiménez-Ruiz³

et al. 2022

Preprint

Self Cite

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“…That is why Gutiérrez-Basulto and Schockaert [16] investigate how to ensure logical consistency through geometrical constraints on embedding spaces and if classical embedding techniques respect such constraints. Similarly, OWL2Vec* [7] focus on embedding complex logical constructors as well as the graph structure and literals.…”

Section: Graph Embedding and Domain Knowledgementioning

confidence: 99%

Discovering alignment relations with Graph Convolutional Networks: A biomedical case study

Monnin

Raïssi

Napoli

et al. 2022

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Knowledge graphs are freely aggregated, published, and edited in the Web of data, and thus may overlap. Hence, a key task resides in aligning (or matching) their content. This task encompasses the identification, within an aggregated knowledge graph, of nodes that are equivalent, more specific, or weakly related. In this article, we propose to match nodes within a knowledge graph by (i) learning node embeddings with Graph Convolutional Networks such that similar nodes have low distances in the embedding space, and (ii) clustering nodes based on their embeddings, in order to suggest alignment relations between nodes of a same cluster. We conducted experiments with this approach on the real world application of aligning knowledge in the field of pharmacogenomics, which motivated our study. We particularly investigated the interplay between domain knowledge and GCN models with the two following focuses. First, we applied inference rules associated with domain knowledge, independently or combined, before learning node embeddings, and we measured the improvements in matching results. Second, while our GCN model is agnostic to the exact alignment relations (e.g., equivalence, weak similarity), we observed that distances in the embedding space are coherent with the “strength” of these different relations (e.g., smaller distances for equivalences), letting us considering clustering and distances in the embedding space as a means to suggest alignment relations in our case study.

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“…A snapshot of TERA is available on Zenodo [52], where licenses permit. 11 PubChem and ChEMBL are not included in the snapshot due to size constraints; these can be downloaded from the National Institutes of Health 12 and European Bioinformatics Institute, 13 respectively. The subgraph of TERA used for prediction is available alongside the chemical effect prediction models in our GitHub repository.…”

Section: Tera Knowledge Graphmentioning

confidence: 99%

“…Each result is composed by Table 5 Example triples from the TERA knowledge graph. For space reasons, we have added the full id or label for some of the entities using footnote marks where 1 inchikey:MMOXZBCLCQITDF-UHFFFAOYSA-N, 2 Pimephales, 3 Cyprinidae, 4 Headwater, 5 Benzamides, 6 Insect Repellents, 7 CHRNA3, 8 CHRNB4, 9 DETA-20, 10 DETA Epichlorohydrin, 11 Has component, 12 Triclocarban, 13 Trichlorocarbanilide-containing product, 14 Similar to, 15 3-Chloromethyl-N,N-diethylbenzamide. an endpoint, an effect, and a concentration (with a unit) at which the endpoint and effect are recorded.…”

Section: Effects Sub-kg Constructionmentioning

confidence: 99%

Prediction of Adverse Biological Effects of Chemicals Using Knowledge Graph Embeddings

Myklebust,

Jiménez-Ruiz,

Chen

et al. 2021

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We have created a knowledge graph based on major data sources used in ecotoxicological risk assessment. We have applied this knowledge graph to an important task in risk assessment, namely chemical effect prediction. We have evaluated nine knowledge graph embedding models from a selection of geometric, decomposition, and convolutional models on this prediction task. We show that using knowledge graph embeddings can increase the accuracy of effect prediction with neural networks. Furthermore, we have implemented a fine-tuning architecture which adapts the knowledge graph embeddings to the effect prediction task and leads to a better performance. Finally, we evaluate certain characteristics of the knowledge graph embedding models to shed light on the individual model performance.

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OWL2Vec*: embedding of OWL ontologies

Cited by 77 publications

References 33 publications

Contextual Semantic Embeddings for Ontology Subsumption Prediction

Contextual Semantic Embeddings for Ontology Subsumption Prediction

Discovering alignment relations with Graph Convolutional Networks: A biomedical case study

Prediction of Adverse Biological Effects of Chemicals Using Knowledge Graph Embeddings

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