We will develop a family-based Quality Assurance (QA) framework for biomedical ontologies. Ontology QA is critical for increasing the use of ontologies in interdisciplinary research and in electronic health records (EHRs). We will develop computational techniques for identifying concepts with high probability of errors to improve efficiency and effectiveness of ontology QA. Biomedical ontologies are large, complex knowledge representation systems that enable the integration of knowledge from different fields. The largest, best-known ontology repository is the Bioportal of the National Center for Biomedical Ontologies, containing more than 300 ontologies and tools for editing, browsing, and visualizing these ontologies. However, many errors have been discovered in BioPortal's ontologies. QA in BioPortal has been mostly focused on use-cases and ad hoc techniques. Our computational techniques will automatically identify sets of concepts with a high likelihood of errors to empower ontology QA. In past research, we have designed many QA techniques for single ontologies and have shown that sets of complex and uncommonly classified concepts have significantly higher percentages of errors. The theoretical bases for our QA are Abstraction Networks (AbNs), which summarize ontologies in a compact way. Using AbNs, we identified many error-prone concepts. In this project, we will perform QA for whole families of ontologies. We have already identified seven preliminary families, based on structural properties. If a classification of concepts yields higher than usual error rates in several ontologies of a family F then we hypothesize that this will be true for such classifications for most ontologies of F. We will build a prototype software tool (BLUOWL) for determining AbNs for each family, to support QA of its ontologies. Our primary test beds will be seven cancer-related ontologies, e.g., the National Cancer Institute thesaurus (NCIt), with different properties and purposes. Some non-cancer ontologies will also be included. We have published preliminary QA results for four such ontologies. In evaluation studies, we will formulate and test hypotheses, statistically expressing the error expectations for various kinds of concepts. Ontologies' curators were recruited to review the suspicious concepts we will identify as part of their regular QA efforts (outside of our budget). In summary, we will: Identify families of BioPortal ontologies based on ontology structure and design a unified methodology for deriving their abstraction networks; Build a software tool (BLUOWL) for QA of each family; Investigate concept classifications more likely to be erroneous in each family; Perform evaluation of our QA methodologies and usability studies for BLUOWL.

Public Health Relevance

Biomedical ontologies are critical for interdisciplinary research and electronic health records (EHRs). The largest, best-known ontology repository is the Bioportal of the National Center for Biomedical Ontologies, containing more than 300 ontologies. However, many errors have been discovered in BioPortal's ontologies. Quality Assurance (QA) in BioPortal has been mostly focused on use-cases and ad hoc techniques. We will develop a systematic, family-based framework for QA of biomedical ontologies. The theoretical basis for our QA methods is constituted by Abstraction Networks, which summarize ontologies in a compact way. The Abstraction Networks will support the detection of sets of concepts with a high likelihood of errors, which will improve the yield of the QA activities. A prototype software tool (BLUOWL) implementing our QA theory will be built.

Agency
National Institute of Health (NIH)
Institute
National Cancer Institute (NCI)
Type
Research Project (R01)
Project #
5R01CA190779-02
Application #
9027817
Study Section
Special Emphasis Panel (ZRG1)
Program Officer
Moser, Richard
Project Start
2015-03-04
Project End
2018-02-28
Budget Start
2016-03-01
Budget End
2017-02-28
Support Year
2
Fiscal Year
2016
Total Cost
Indirect Cost
Name
Rutgers University
Department
Biostatistics & Other Math Sci
Type
Other Specialized Schools
DUNS #
075162990
City
Newark
State
NJ
Country
United States
Zip Code
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Ochs, Christopher; Case, James T; Perl, Yehoshua (2017) Analyzing structural changes in SNOMED CT's Bacterial infectious diseases using a visual semantic delta. J Biomed Inform 67:101-116
He, Zhe; Chen, Yan; Geller, James (2017) Perceiving the Usefulness of the National Cancer Institute Metathesaurus for Enriching NCIt with Topological Patterns. Stud Health Technol Inform 245:863-867
Halper, Michael; Perl, Yehoshua; Ochs, Christopher et al. (2017) Taxonomy-Based Approaches to Quality Assurance of Ontologies. J Healthc Eng 2017:3495723
Ochs, Christopher; He, Zhe; Zheng, Ling et al. (2016) Utilizing a structural meta-ontology for family-based quality assurance of the BioPortal ontologies. J Biomed Inform 61:63-76

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