Litcius/Paper detail

RENET2: high-performance full-text gene–disease relation extraction with iterative training data expansion

Junhao Su, Ye Wu, Hing‐Fung Ting, Tak‐Wah Lam, Ruibang Luo

2021NAR Genomics and Bioinformatics22 citationsDOIOpen Access PDF

Abstract

Relation extraction (RE) is a fundamental task for extracting gene-disease associations from biomedical text. Many state-of-the-art tools have limited capacity, as they can extract gene-disease associations only from single sentences or abstract texts. A few studies have explored extracting gene-disease associations from full-text articles, but there exists a large room for improvements. In this work, we propose RENET2, a deep learning-based RE method, which implements Section Filtering and ambiguous relations modeling to extract gene-disease associations from full-text articles. We designed a novel iterative training data expansion strategy to build an annotated full-text dataset to resolve the scarcity of labels on full-text articles. In our experiments, RENET2 achieved an F1-score of 72.13% for extracting gene-disease associations from an annotated full-text dataset, which was 27.22, 30.30, 29.24 and 23.87% higher than BeFree, DTMiner, BioBERT and RENET, respectively. We applied RENET2 to (i) ∼1.89M full-text articles from PubMed Central and found ∼3.72M gene-disease associations; and (ii) the LitCovid articles and ranked the top 15 proteins associated with COVID-19, supported by recent articles. RENET2 is an efficient and accurate method for full-text gene-disease association extraction. The source-code, manually curated abstract/full-text training data, and results of RENET2 are available at GitHub.

Topics & Concepts

Relationship extractionComputer scienceRelation (database)Association (psychology)Biomedical text miningInformation retrievalNatural language processingCode (set theory)Artificial intelligenceText miningData miningPsychologyPsychotherapistProgramming languageSet (abstract data type)Biomedical Text Mining and OntologiesTopic ModelingNatural Language Processing Techniques