OME Core Ontology: An OWL-based Life Science Imaging Data Model Norio Kobayashi1 , Josh Moore2 , Shuichi Onami3 , and Jason R. Swedlow2 1 Head Office for Information Systems and Cybersecurity (ISC), RIKEN, 2-1 Hirosawa, Wako, Saitama, 351-0198 Japan norio.kobayashi@riken.jp 2 Division of Computational Biology School of Life Sciences, University of Dundee, Nethergate, Dundee, DD1 4HN, UK {j.a.moore, j.r.swedlow}@dundee.ac.uk 3 RIKEN Center for Biosystems Dynamics Research (BDR), 2-2-3 Minatojima-minamimachi, Chuo-ku, Kobe, Hyogo, 650-0047 Japan sonami@riken.jp Abstract. The Open Microscopy Environment (OME) is a consortium that produces open-source tools and format standards for microscopy data. The OME model is a specification for sharing biological imaging data in two parts: metadata as OME-XML and binary data as OME- TIFF. We built an OWL ontology translation of the OME-XML spec- ification called OME core ontology so as to catch up with the rapid progress and diversification of imaging technology and to facilitate inte- grated analysis with various life science data. This poster presents the details and status of the ontology, associated tools, and future plans. Keywords: Open Microscopy Environment, microscopy imaging, imag- ing ontology, semantic integration 1 Introduction Imaging is one of the fundamental techniques and data types for understanding life phenomena intuitively through human vision. Because imaging data itself does not describe explicit knowledge, imaging metadata is fundamental to enable data sharing and integration of multi-modal imaging data with various other types of life science data. Having multiple life science centers and laboratories, RIKEN employs vari- ous imaging apparatus covering a comprehensive range of scale, from organelle through organ to organism. For integrating the imaging data produced and the experimental conditions, a multi-modal ontology for electron microscopy, X-ray computed tomography and magnetic resonance imaging was developed as an OWL-based extension of the OME data model1 which describes imaging meta- data for OMERO2 , a de facto-standard imaging tool. Having confirmed the core ontology through this multi-modal extension in different practical research projects, the OME consortium has adopted the newly developed OWL-based OME model as an official companion to their XSD-based model. 1 https://docs.openmicroscopy.org/ome-model/6.0.0/ 2 https://www.openmicroscopy.org Copyright © 2019 for this paper by its authors. Use permitted under Creative Commons License Attribution 4.0 International (CC BY 4.0). 2 Development of the OME core ontology and tools The OME core ontology is a translation of the OME-XML format of the OME data model version 2016-063 that covers all its concepts and attributes. The ontology contains 130 classes and 210 properties. In addition, we implemented tools written in Java and a spreadsheet template for describing RDF data using the OME core ontology. The data converter is a tool for converting OME-XML format data into RDF using the OME core ontology. Another tool, the OME compatibility checker, determines if the given ontology includes OME core sub- classes and sub-properties. This checker is used for the 4DN-OME ontology for confirming if it is an extended ontology of the OME core ontology [1]. Finally, a spreadsheet template facilitates the users' description of RDF data for entry in the RIKEN MetaDatabase [2]. These tools and templates have been published at GitLab4 with sample OME-XML and converted RDF data5 . 3 Discussion and future directions Herein, we report our progress on the development of the OME core ontology and tools. With the publication of the ontology, members of the bioimaging community can develop an extended ontology converting the complete original imaging environment.Though the OME core ontology is designed for bioimaging, it can be connected to healthcare metadata such as DICOM data. Further, the distribution of imaging data in a FAIR representation accelerates advanced data analysis, critical for Open Science. Our goal is to enable integrated multi-omics knowledge analysis, artificial intelligence-supported image diagnosis, and scale- continuous image analysis as well as the realization of a standardized image analysis platform based on OMERO technology. Acknowledgements This work has been supported by JSPS KAKENHI grant numbers 17K00434, 17K00424 and 18K19766, and Japan Science and Technology Agency (JST) Core Research for Evolutionary Science and Technology (CREST) Grant Number JPMJCR1511. References 1. Hammer M, Rigano A, Farzan F, Huisman M, Grunwald D, Strambio-De-Castillia C. The 4DN-OME ontology: an OME-OWL extension with emphasis on usability, minimum information guidelines and quality control for super-resolution fluores- cence microscopy. SWAT4HCLS 2019 Poster, 2019. 2. Kobayashi N, Kume S, Lenz K, Masuya H. RIKEN MetaDatabase: A Database Platform for Health Care and Life Sciences as a Microcosm of Linked Open Data Cloud. Int J Semant Web Inf Syst. 14(1):140–164, 2018. 3 https://www.openmicroscopy.org/Schemas/Documentation/Generated/\\ OME-2016-06/ome.html 4 https://gitlab.com/openmicroscopy/incubator/ome-owl/ 5 https://downloads.openmicroscopy.org/images/OME-XML/2016-06/