Comparative experiments on learning information extractors for proteins and their interactions

Comparative experiments on learning information extractors for proteins and their interactions

Automatically extracting information from biomedical text holds the promise of easily consolidating large amounts of biological knowledge in computer-accessible form. This strategy is particularly attractive for extracting data relevant to genes of the human genome from the 11 million abstracts in M...

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Bibliographic Details
Published in:Artificial intelligence in medicine Vol. 33; no. 2; pp. 139 - 155
Main Authors: Bunescu, Razvan, Ge, Ruifang, Kate, Rohit J., Marcotte, Edward M., Mooney, Raymond J., Ramani, Arun K., Wong, Yuk Wah
Format: Journal Article
Language:English
Published: Netherlands Elsevier B.V 01-02-2005
Subjects:
Algorithms
Artificial Intelligence
Automatic text analysis
Biomedical texts
Data mining
Expert Systems
Genes - genetics
Genes - physiology
Human genomes
Humans
Information extraction
Information Storage and Retrieval - methods
Machine learning
MEDLINE
Protein interactions
Proteins - classification
Proteins - physiology
Term extraction
Terminology as Topic
Text mining
Text mining
Information extraction
Protein interactions
Medline
Machine learning
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Summary:Automatically extracting information from biomedical text holds the promise of easily consolidating large amounts of biological knowledge in computer-accessible form. This strategy is particularly attractive for extracting data relevant to genes of the human genome from the 11 million abstracts in Medline. However, extraction efforts have been frustrated by the lack of conventions for describing human genes and proteins. We have developed and evaluated a variety of learned information extraction systems for identifying human protein names in Medline abstracts and subsequently extracting information on interactions between the proteins. We used a variety of machine learning methods to automatically develop information extraction systems for extracting information on gene/protein name, function and interactions from Medline abstracts. We present cross-validated results on identifying human proteins and their interactions by training and testing on a set of approximately 1000 manually-annotated Medline abstracts that discuss human genes/proteins. We demonstrate that machine learning approaches using support vector machines and maximum entropy are able to identify human proteins with higher accuracy than several previous approaches. We also demonstrate that various rule induction methods are able to identify protein interactions with higher precision than manually-developed rules. Our results show that it is promising to use machine learning to automatically build systems for extracting information from biomedical text. The results also give a broad picture of the relative strengths of a wide variety of methods when tested on a reasonably large human-annotated corpus.
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ISSN:0933-3657
1873-2860
DOI:10.1016/j.artmed.2004.07.016