Your search keyword '"Yaphet Kebede"' showing total 12 results

1. Explainable Enrichment-Driven GrAph Reasoner (EDGAR) for Large Knowledge Graphs with Applications in Drug Repurposing.

Author

Olawumi Olasunkanmi, Evan Morris, Yaphet Kebede, Harlin Lee, Stanley C. Ahalt, Alexander Tropsha, and Chris Bizon

Published

2024

2. Dug: a semantic search engine leveraging peer-reviewed knowledge to query biomedical data repositories.

Author

Alexander M. Waldrop, John B. Cheadle, Kira Bradford, Alexander Preiss, Robert F. Chew, Jonathan R. Holt, Yaphet Kebede, Nathan Braswell, Matthew Watson, Virginia Hench, Andrew Crerar, Chris M. Ball, Carl Schreep, P. J. Linebaugh, Hannah Hiles, Rebecca R. Boyles, Chris Bizon, Ashok Kumar Krishnamurthy 0001, and Steven Cox 0001

Published

2022

3. ROBOKOP KG and KGB: Integrated Knowledge Graphs from Federated Sources.

Author

Chris Bizon, Steven Cox 0001, James P. Balhoff, Yaphet Kebede, Patrick Wang 0003, Kenneth Morton, Karamarie Fecho, and Alexander Tropsha

Published

2019

4. ROBOKOP: an abstraction layer and user interface for knowledge graphs to support question answering.

Author

Kenneth Morton, Patrick Wang 0003, Chris Bizon, Steven Cox 0001, James P. Balhoff, Yaphet Kebede, Karamarie Fecho, and Alexander Tropsha

Published

2019

5. COVID-KOP: integrating emerging COVID-19 data with the ROBOKOP database.

Author

Daniel Robert Korn, Tesia M. Bobrowski, Michael Li, Yaphet Kebede, Patrick Wang 0003, Phillips Owen, Gaurav Vaidya, Eugene N. Muratov, Rada Chirkova, Chris Bizon, and Alexander Tropsha

Published

2021

6. Dug: A Semantic Search Engine Leveraging Peer-Reviewed Knowledge to Span Biomedical Data Repositories

Author

Alexander M. Waldrop, John B. Cheadle, Kira Bradford, Alexander Preiss, Robert Chew, Jonathan R. Holt, Nathan Braswell, Matt Watson, Andrew Crerar, Chris M. Ball, Yaphet Kebede, Carl Schreep, PJ Linebaugh, Hannah Hiles, Rebecca Boyles, Chris Bizon, Ashok Krishnamurthy, and Steve Cox

Subjects

Information retrieval, Biodata, Recall, Index (publishing), Biomedical data, Knowledge graph, Computer science, business.industry, Semantic search, business, Data resources

Abstract

MotivationAs the number of public data resources continues to proliferate, identifying relevant datasets across heterogenous repositories is becoming critical to answering scientific questions. To help researchers navigate this data landscape, we developed Dug: a semantic search tool for biomedical datasets utilizing evidence-based relationships from curated knowledge graphs to find relevant datasets and explain why those results are returned.ResultsDeveloped through the National Heart, Lung, and Blood Institute’s (NHLBI) BioData Catalyst ecosystem, Dug has indexed more than 15,911 study variables from public datasets. On a manually curated search dataset, Dug’s total recall (total relevant results/total results) of 0.79 outperformed default Elasticsearch’s total recall of 0.76. When using synonyms or related concepts as search queries, Dug (0.36) far outperformed Elasticsearch (0.14) in terms of total recall with no significant loss in the precision of its top results.Availability and ImplementationDug is freely available at https://github.com/helxplatform/dug. An example Dug deployment is also available for use at https://search.biodatacatalyst.renci.org/.Contactawaldrop@rti.org or scox@renci.org

Published

2021

7. Dug: a semantic search engine leveraging peer-reviewed knowledge to query biomedical data repositories

Author

Alexander M Waldrop, John B Cheadle, Kira Bradford, Alexander Preiss, Robert Chew, Jonathan R Holt, Yaphet Kebede, Nathan Braswell, Matt Watson, Virginia Hench, Andrew Crerar, Chris M Ball, Carl Schreep, P J Linebaugh, Hannah Hiles, Rebecca Boyles, Chris Bizon, Ashok Krishnamurthy, and Steve Cox

Subjects

Statistics and Probability, Search Engine, Computational Mathematics, Computational Theory and Mathematics, Abstracting and Indexing, Molecular Biology, Biochemistry, Original Papers, Ecosystem, Computer Science Applications, Semantics

Abstract

Motivation As the number of public data resources continues to proliferate, identifying relevant datasets across heterogenous repositories is becoming critical to answering scientific questions. To help researchers navigate this data landscape, we developed Dug: a semantic search tool for biomedical datasets utilizing evidence-based relationships from curated knowledge graphs to find relevant datasets and explain why those results are returned. Results Developed through the National Heart, Lung and Blood Institute’s (NHLBI) BioData Catalyst ecosystem, Dug has indexed more than 15 911 study variables from public datasets. On a manually curated search dataset, Dug’s total recall (total relevant results/total results) of 0.79 outperformed default Elasticsearch’s total recall of 0.76. When using synonyms or related concepts as search queries, Dug (0.36) far outperformed Elasticsearch (0.14) in terms of total recall with no significant loss in the precision of its top results. Availability and implementation Dug is freely available at https://github.com/helxplatform/dug. An example Dug deployment is also available for use at https://search.biodatacatalyst.renci.org/. Supplementary information Supplementary data are available at Bioinformatics online.

Published

2021

8. COVID-KOP: integrating emerging COVID-19 data with the ROBOKOP database

Author

Patrick Wang, Yaphet Kebede, Chris Bizon, Rada Chirkova, Gaurav Vaidya, Phillips Owen, Michael Li, Daniel Korn, Tesia Bobrowski, Eugene N. Muratov, and Alexander Tropsha

Subjects

Statistics and Probability, Web server, 2019-20 coronavirus outbreak, Biomedical knowledge, AcademicSubjects/SCI01060, Coronavirus disease 2019 (COVID-19), Databases, Factual, Knowledge Graph, Computer science, Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), Knowledge Bases, 0206 medical engineering, MEDLINE, Bioinformatics and Computational Biology, 02 engineering and technology, CORD-19, computer.software_genre, Biochemistry, Article, World Wide Web, 03 medical and health sciences, Artificial Intelligence, Humans, Drug-target-disease associations, Web-server, Molecular Biology, Pandemics, Repurposing, 030304 developmental biology, 0303 health sciences, SARS-CoV-2, COVID-19, Computer Science Applications, Computational Mathematics, Applications Note, Drug Repurposing, Computational Theory and Mathematics, Knowledge graph, Graph (abstract data type), database mining, computer, 020602 bioinformatics

Abstract

Summary In response to the COVID-19 pandemic, we established COVID-KOP, a new knowledgebase integrating the existing Reasoning Over Biomedical Objects linked in Knowledge Oriented Pathways (ROBOKOP) biomedical knowledge graph with information from recent biomedical literature on COVID-19 annotated in the CORD-19 collection. COVID-KOP can be used effectively to generate new hypotheses concerning repurposing of known drugs and clinical drug candidates against COVID-19 by establishing respective confirmatory pathways of drug action. Availability and implementation COVID-KOP is freely accessible at https://covidkop.renci.org/. For code and instructions for the original ROBOKOP, see: https://github.com/NCATS-Gamma/robokop.

Published

2020

9. Visualization Environment for Federated Knowledge Graphs: Development of an Interactive Biomedical Query Language and Web Application Interface (Preprint)

Author

Steven Cox, Stanley C Ahalt, James Balhoff, Chris Bizon, Karamarie Fecho, Yaphet Kebede, Kenneth Morton, Alexander Tropsha, Patrick Wang, and Hao Xu

Abstract

BACKGROUND Efforts are underway to semantically integrate large biomedical knowledge graphs using common upper-level ontologies to federate graph-oriented application programming interfaces (APIs) to the data. However, federation poses several challenges, including query routing to appropriate knowledge sources, generation and evaluation of answer subsets, semantic merger of those answer subsets, and visualization and exploration of results. OBJECTIVE We aimed to develop an interactive environment for query, visualization, and deep exploration of federated knowledge graphs. METHODS We developed a biomedical query language and web application interphase—termed as Translator Query Language (TranQL)—to query semantically federated knowledge graphs and explore query results. TranQL uses the Biolink data model as an upper-level biomedical ontology and an API standard that has been adopted by the Biomedical Data Translator Consortium to specify a protocol for expressing a query as a graph of Biolink data elements compiled from statements in the TranQL query language. Queries are mapped to federated knowledge sources, and answers are merged into a knowledge graph, with mappings between the knowledge graph and specific elements of the query. The TranQL interactive web application includes a user interface to support user exploration of the federated knowledge graph. RESULTS We developed 2 real-world use cases to validate TranQL and address biomedical questions of relevance to translational science. The use cases posed questions that traversed 2 federated Translator API endpoints: Integrated Clinical and Environmental Exposures Service (ICEES) and Reasoning Over Biomedical Objects linked in Knowledge Oriented Pathways (ROBOKOP). ICEES provides open access to observational clinical and environmental data, and ROBOKOP provides access to linked biomedical entities, such as “gene,” “chemical substance,” and “disease,” that are derived largely from curated public data sources. We successfully posed queries to TranQL that traversed these endpoints and retrieved answers that we visualized and evaluated. CONCLUSIONS TranQL can be used to ask questions of relevance to translational science, rapidly obtain answers that require assertions from a federation of knowledge sources, and provide valuable insights for translational research and clinical practice.

Published

2020

10. ROBOKOP: an abstraction layer and user interface for knowledge graphs to support question answering

Author

Patrick Wang, Karamarie Fecho, Chris Bizon, James P. Balhoff, Alexander Tropsha, Yaphet Kebede, Steve Cox, and Kenneth D. Morton

Subjects

Statistics and Probability, 030213 general clinical medicine, 0303 health sciences, Information retrieval, Databases, Factual, Computer science, Rank (computer programming), Applications Notes, Biochemistry, Pattern Recognition, Automated, Computer Science Applications, Abstraction layer, 03 medical and health sciences, Computational Mathematics, 0302 clinical medicine, Computational Theory and Mathematics, Pattern recognition (psychology), Code (cryptography), Question answering, Data and Text Mining, User interface, Molecular Biology, Software, 030304 developmental biology

Abstract

Summary Knowledge graphs (KGs) are quickly becoming a common-place tool for storing relationships between entities from which higher-level reasoning can be conducted. KGs are typically stored in a graph-database format, and graph-database queries can be used to answer questions of interest that have been posed by users such as biomedical researchers. For simple queries, the inclusion of direct connections in the KG and the storage and analysis of query results are straightforward; however, for complex queries, these capabilities become exponentially more challenging with each increase in complexity of the query. For instance, one relatively complex query can yield a KG with hundreds of thousands of query results. Thus, the ability to efficiently query, store, rank and explore sub-graphs of a complex KG represents a major challenge to any effort designed to exploit the use of KGs for applications in biomedical research and other domains. We present Reasoning Over Biomedical Objects linked in Knowledge Oriented Pathways as an abstraction layer and user interface to more easily query KGs and store, rank and explore query results. Availability and implementation An instance of the ROBOKOP UI for exploration of the ROBOKOP Knowledge Graph can be found at http://robokop.renci.org. The ROBOKOP Knowledge Graph can be accessed at http://robokopkg.renci.org. Code and instructions for building and deploying ROBOKOP are available under the MIT open software license from https://github.com/NCATS-Gamma/robokop. Supplementary information Supplementary data are available at Bioinformatics online.

Published

2019

11. ROBOKOP KG and KGB: Integrated Knowledge Graphs from Federated Sources

Author

Patrick Wang, Kenneth D. Morton, Chris Bizon, Yaphet Kebede, James P. Balhoff, Steven Cox, Karamarie Fecho, and Alexander Tropsha

Subjects

Theoretical computer science, 010304 chemical physics, Databases, Factual, Computer science, General Chemical Engineering, Knowledge Bases, Graph query, General Chemistry, Library and Information Sciences, 01 natural sciences, 0104 chemical sciences, Computer Science Applications, Implicit knowledge, Identifier, 010404 medicinal & biomolecular chemistry, User-Computer Interface, Knowledge graph, 0103 physical sciences, Computer Graphics, Graph (abstract data type), Data Mining, Notional amount

Abstract

A proliferation of data sources has led to the notional existence of an implicit Knowledge Graph (KG) that contains vast amounts of biological knowledge contributed by distributed Application Programming Interfaces (APIs). However, challenges arise when integrating data across multiple APIs due to incompatible semantic types, identifier schemes, and data formats. We present ROBOKOP KG (http://robokopkg.renci.org), which is a KG that was initially built to support the open biomedical question-answering application, ROBOKOP (Reasoning Over Biomedical Objects linked in Knowledge-Oriented Pathways) (http://robokop.renci.org). Additionally, we present the ROBOKOP Knowledge Graph Builder (KGB), which constructs the KG and provides an extensible framework to handle graph query over and integration of federated data sources.

Published

2019

12. Visualization Environment for Federated Knowledge Graphs: Development of an Interactive Biomedical Query Language and Web Application Interface

Author

Steven Cox, Stanley C. Ahalt, Patrick Wang, Hao Xu, Karamarie Fecho, Chris Bizon, Yaphet Kebede, Kenneth D. Morton, Alexander Tropsha, and James P. Balhoff

Subjects

0301 basic medicine, 030213 general clinical medicine, translational science, Computer science, Computer applications to medicine. Medical informatics, R858-859.7, Health Informatics, Ontology (information science), Query language, Environmental data, 03 medical and health sciences, 0302 clinical medicine, federation, Health Information Management, Web application, ontologies, Use case, biomedical data, visualization, Original Paper, Information retrieval, Application programming interface, business.industry, semantic harmonization, application programming interface, clinical practice, Visualization, knowledge graphs, 030104 developmental biology, clinical data, User interface, business

Abstract

Background Efforts are underway to semantically integrate large biomedical knowledge graphs using common upper-level ontologies to federate graph-oriented application programming interfaces (APIs) to the data. However, federation poses several challenges, including query routing to appropriate knowledge sources, generation and evaluation of answer subsets, semantic merger of those answer subsets, and visualization and exploration of results. Objective We aimed to develop an interactive environment for query, visualization, and deep exploration of federated knowledge graphs. Methods We developed a biomedical query language and web application interphase—termed as Translator Query Language (TranQL)—to query semantically federated knowledge graphs and explore query results. TranQL uses the Biolink data model as an upper-level biomedical ontology and an API standard that has been adopted by the Biomedical Data Translator Consortium to specify a protocol for expressing a query as a graph of Biolink data elements compiled from statements in the TranQL query language. Queries are mapped to federated knowledge sources, and answers are merged into a knowledge graph, with mappings between the knowledge graph and specific elements of the query. The TranQL interactive web application includes a user interface to support user exploration of the federated knowledge graph. Results We developed 2 real-world use cases to validate TranQL and address biomedical questions of relevance to translational science. The use cases posed questions that traversed 2 federated Translator API endpoints: Integrated Clinical and Environmental Exposures Service (ICEES) and Reasoning Over Biomedical Objects linked in Knowledge Oriented Pathways (ROBOKOP). ICEES provides open access to observational clinical and environmental data, and ROBOKOP provides access to linked biomedical entities, such as “gene,” “chemical substance,” and “disease,” that are derived largely from curated public data sources. We successfully posed queries to TranQL that traversed these endpoints and retrieved answers that we visualized and evaluated. Conclusions TranQL can be used to ask questions of relevance to translational science, rapidly obtain answers that require assertions from a federation of knowledge sources, and provide valuable insights for translational research and clinical practice.

Published

2020