知能情報工学分野
基本情報
研究キーワード
5経歴
3-
2025年4月 - 現在
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2022年4月 - 2025年3月
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2019年4月 - 2022年3月
学歴
3-
2023年4月 - 2025年3月
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2017年4月 - 2019年3月
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2013年4月 - 2017年3月
受賞
4論文
33-
European Journal of Radiology Open 17(100791) 2026年7月 査読有り
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Biomedical Physics & Engineering Express 12(3) 035096-035096 2026年6月1日 査読有りAbstract Objective. Computer and artificial intelligence (AI) analyses are being increasingly used in intrapartum cardiotocography (CTG). However, fetal heart rate (FHR) signal loss, which frequently occurs in clinical practice, hinders visual interpretation and reduces accuracy. Although the impact is well recognized, there is no consensus on the maximum continuous gap length that can be reliably reconstructed under clinical conditions. Therefore, we aim to identify suitable imputation methods and clarify the clinical limits of valid missing‐segment lengths. Methods. Using an open FHR dataset (CTU-UHB), we extracted continuous segments and artificially introduced Removed data of varying lengths. Using performance metrics such as difference and similarity, we compared the performance among a Transformer‐based model and linear and spline interpolation. Additionally, we quantified the similarity between the Pre‐impute and removed data to assess task difficulty. Results. We analyzed 2727 segments from 552 cases across multiple gap lengths. In terms of numerical accuracy root mean square error (RMSE), spline consistently performed significantly worse than others. The Transformer generally maintained a better mean accuracy than linear interpolation, although significant differences were observed only under specific conditions. Conversely, for waveform preservation (correlation), the Transformer consistently outperformed linear interpolation. Notably, in highly complex imputation tasks, the Transformer proved most robust, yielding the lowest RMSE and highest correlation. However, performance systematically degraded for all methods as gap lengths increased. Conclusion. The Transformer provides an effective baseline for FHR imputation under clinical conditions, achieving a favorable balance between waveform and numerical accuracy. By clarifying the clinical limits of valid missing‐segment lengths—specifically the decline in reliability beyond 30 s—this study provides guidance for standardizing preprocessing in future CTG AI research and clinical implementation. Significance. For imputing intrapartum FHR data, the Transformer generally improves waveform reproducibility over linear interpolation for short-to-moderate gaps. Defining the reliability limit provides a crucial baseline for future CTG AI.
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Japanese Journal of Radiology. In Pres. 2026年6月 査読有り筆頭著者
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Frontiers in Radiology 5(1703927) 2025年11月 査読有り筆頭著者
講演・口頭発表等
58-
第82回日本放射線技術学会総会学術大会 2026年4月19日
担当経験のある科目(授業)
6所属学協会
4-
2026年6月 - 現在
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2025年6月 - 現在
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2022年5月 - 現在
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2019年12月 - 現在
共同研究・競争的資金等の研究課題
4-
日本学術振興会 科学研究費助成事業 2026年4月 - 2029年3月
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日本学術振興会 科学研究費助成事業 2024年4月 - 2027年3月
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日本学術振興会 科学研究費助成事業 2023年4月 - 2026年3月
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日本学術振興会 科学研究費助成事業 研究活動スタート支援 2022年8月 - 2024年3月