医学部
Profile Information
- Affiliation
- Associate Professor, Department of Computational Biology, School of Medicine, Fujita Health University(Concurrent)(Associate Professor), The International Center for Brain Sciences (ICBS)
- Degree
- Ph.D (Medicine)(Kyoto University)
- Contact information
- katsuyuki.kunida
fujita-hu.ac.jp - J-GLOBAL ID
- 201701001948114655
- researchmap Member ID
- B000284473
- External link
I am engaged in the research of data analysis and mathematical modeling of molecular networks controlling cellular functions (such as movement, proliferation, neural differentiation, and substance production), including protein modification, gene expression, and metabolic changes. By leveraging domain information from molecular data, I am developing methods to construct mathematical models of molecular networks driven by data (data-driven modeling). Additionally, I am working on research for future prediction and optimal control of molecular networks using mathematical models (model-based control).
Research Interests
24Research Areas
4Major Research History
14Committee Memberships
6-
2024 - Present
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2024 - Present
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2021 - Present
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2021 - Present
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2017 - Present
Awards
2Papers
34-
Scientific Reports, 14(27252), Nov, 2024 Peer-reviewedLast author
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Pediatric Cardiology, Mar 13, 2024 Peer-reviewed
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New Generation Computing, 42 283-302, Nov 4, 2023 Peer-reviewedCorresponding author
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Journal of Biomechanical Science and Engineering, 18(4) 23-00336, Oct 14, 2023 Peer-reviewed
Misc.
2-
Aug, 2024Abstract Recent advancements in machine learning-based data processing techniques have facilitated the inference of gene regulatory interactions and the identification of key genes from multidimensional gene expression data. In this study, we applied a stepwise Bayesian framework to uncover a novel regulatory component involved in differentiation of specific neural and neuronal cells. We treated naive neural precursor cells with Sonic Hedgehog (Shh) at various concentrations and time points, generating comprehensive whole-genome sequencing data that captured dynamic gene expression profiles during differentiation. The genes were categorized into 224 subsets based on their expression profiles, and the relationships between these subsets were extrapolated. To accurately predict gene regulation among subsets, known networks were used as a core model and subsets to be added were tested stepwise. This approach led to the identification of a novel component involved in neural tube patterning within gene regulatory networks (GRNs), which was experimentally validated. Our study highlights the effectiveness of in silico modeling for extrapolating GRNs during neural development.
Presentations
43-
EMBL Symposium AI and biology (EMBL Heidelberg)
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Integrated analysis for identifying the network controllability of intracellular molecular signalingEMBL Symposium AI and biology (EMBL Heidelberg)
Major Teaching Experience
11-
2023 - PresentBiology with data science (Nara Institute of Science and Technology)
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2023 - Present
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2022 - PresentアセンブリⅢ (藤田医大)
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2022 - Present
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2021 - Present基礎データサイエンス (藤田医大)
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2020 - PresentStatistics and Mathematics in Bioscience (Nara Institute of Science and Technology)
Professional Memberships
5Research Projects
6-
一般共同研究, 北海道大学遺伝子病制御研究所, Apr, 2024 - Mar, 2025
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科学研究費補助金 若手研究(生命、健康および医療情報学関連), 文部科学省, Apr, 2019 - Mar, 2023
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次世代融合領域研究推進プロジェクト, NAIST, Jun, 2019 - Mar, 2021
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未来社会創造事業 特定課題調査, JST, Nov, 2019 - Mar, 2020
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科学研究費補助金 若手研究B(医化学一般), 文部科学省, Apr, 2016 - Mar, 2019
Industrial Property Rights
1Media Coverage
5-
AAAS(American Association for the Advancement of Science), EurekAlert!, Oct 12, 2023 Internet
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Mary Ann Liebert, Inc., Genetic Engineering & Biotechnology News (GEN), Oct, 2023 Newspaper, magazine
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AAAS(American Association for the Advancement of Science), EurekAlert!, Mar 17, 2023 Internet