Curriculum Vitaes
Profile Information
- Affiliation
- Fujita Health University
- Degree
- 医学博士(慶應義塾大学)
- Other name(s) (e.g. nickname)
- https://bantane.fujita-hu.ac.jp/department/obstericians.html
- J-GLOBAL ID
- 200901012107446377
- researchmap Member ID
- 5000096026
日本産科婦人科学会 産婦人科専門医
日本産科婦人科学会 産婦人科指導医
日本生殖医学会認定 生殖医療専門医
日本生殖医学会認定 生殖医療指導医
日本婦人科腫瘍学会 婦人科腫瘍専門医
日本婦人科腫瘍学会 婦人科腫瘍指導医
日本がん治療認定医機構 がん治療認定医
日本がん治療認定医機構 暫定教育医
Research Interests
14Research Areas
1Research History
15-
Apr, 2023 - Present
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Apr, 2020 - Mar, 2023
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Mar, 2019 - Mar, 2023
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Oct, 2018 - Mar, 2023
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Apr, 2008 - Mar, 2023
Education
2-
1995 - 1999
Committee Memberships
5-
May, 2012
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2011
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2011
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2009
Awards
5-
2013
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2009
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2008
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2008
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2004
Major Papers
55-
Nature Communications, 5(448) 1-9, Jul 22, 2014 Peer-reviewed
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Proc. Natl. Acad. Sci. USA (PNAS), 108(49) 19587-92, Dec 6, 2011 Peer-reviewed
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Proc. Natl. Acad. Sci. USA (PNAS), 106(9) 3095-100, Mar 3, 2009 Peer-reviewed
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Proc. Natl. Acad. Sci. USA (PNAS), 104(10) 3799-804, Mar 6, 2007 Peer-reviewed
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Science, 295(5552) 124-7, Jan 4, 2002 Peer-reviewed
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Nature cell biology, 4(1) 73-8, Jan, 2002 Peer-reviewedThe Ras-related small GTPase RalA is involved in controlling actin cytoskeletal remodelling and vesicle transport in mammalian cells. We identified the mammalian homologue of Sec5, a subunit of the exocyst complex determining yeast cell polarity, as a specific binding partner for GTP-ligated RalA. Inhibition of RalA binding to Sec5 prevents filopod production by tumor necrosis factor-alpha (TNF-alpha) and interleukin-1 (IL-1) and by activated forms of RalA and Cdc42, signalling intermediates downstream of these inflammatory cytokines. We propose that the RalA-exocyst complex interaction integrates the secretory and cytoskeletal pathways.
Misc.
70-
Fujita Med J., 11(1) 54-58, Feb, 2025 Peer-reviewed
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J Obstet Gynaecol Res., 51(1) 1687, Jan, 2025 Peer-reviewed
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Biochemistry and biophysics reports, 22(22) 100740-100740, Jul, 2020 Peer-reviewed
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British Journal of Cancer (Nature Publishing Group ), 2020 Peer-reviewed<title>Abstract</title> <sec> <title>Background</title> Annexin A1 is expressed specifically on the tumour vasculature surface. Intravenously injected IF7 targets tumour vasculature via annexin A1. We tested the hypothesis that IF7 overcomes the blood–brain barrier and that the intravenously injected IF7C(RR)-SN38 eradicates brain tumours in the mouse. </sec> <sec> <title>Methods</title> (1) A dual-tumour model was generated by inoculating luciferase-expressing melanoma B16 cell line, B16-Luc, into the brain and under the skin of syngeneic C57BL/6 mice. IF7C(RR)-SN38 was injected intravenously daily at 7.0 μmoles/kg and growth of tumours was assessed by chemiluminescence using an IVIS imager. A similar dual-tumour model was generated with the C6-Luc line in immunocompromised SCID mice. (2) IF7C(RR)-SN38 formulated with 10% Solutol HS15 was injected intravenously daily at 2.5 μmoles/kg into two brain tumour mouse models: B16-Luc cells in C57BL/6 mice, and C6-Luc cells in nude mice. </sec> <sec> <title>Results</title> (1) Daily IF7C(RR)-SN38 injection suppressed tumour growth regardless of cell lines or mouse strains. (2) Daily injection of Solutol-formulated IF7C(RR)-SN38 led into complete disappearance of B16-Luc brain tumour in C57BL/6 mice, whereas this did not occur in C6-Luc in nude mice. </sec> <sec> <title>Conclusions</title> IF7C(RR)-SN38 crosses the blood–brain barrier and suppresses growth of brain tumours in mouse models. Solutol HS15-formulated IF7C(RR)-SN38 may have promoted an antitumour immune response. </sec>
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Nutrition and cancer, 71(2) 312-319, Mar, 2019 Peer-reviewed
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European journal of gynaecological oncology, 39(5) 838-842, Jan, 2018 Peer-reviewed
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REPRODUCTIVE SCIENCES, 24 160A-161A, Mar, 2017 Peer-reviewed
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6 13-20, 2017 Peer-reviewed
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PLACENTA, 46 105-105, Oct, 2016 Peer-reviewed
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日本周産期・新生児医学会雑誌, 52(2) 586-586, Jun, 2016 Peer-reviewed
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JOURNAL OF REPRODUCTIVE IMMUNOLOGY, 112 122-122, Nov, 2015 Peer-reviewed
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PLACENTA, 36(10) A12-A12, Oct, 2015 Peer-reviewed
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PLACENTA, 36(10) A12-A12, Oct, 2015 Peer-reviewed
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PLACENTA, 36(10) A7-A8, Oct, 2015 Peer-reviewed
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Journal of Reproductive Immunology, 110 74-80, Aug, 2015 Peer-reviewed
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REPRODUCTIVE SCIENCES, 22 128A-128A, Mar, 2015 Peer-reviewed
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GLYCOBIOLOGY, 24(11) 1104-1105, Nov, 2014 Peer-reviewed
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PLACENTA, 35(10) A14-A15, Oct, 2014 Peer-reviewed
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PLACENTA, 35(10) A11-A11, Oct, 2014 Peer-reviewed
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FASEB JOURNAL, 28(1), Apr, 2014 Peer-reviewed
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PLACENTA, 34(10) A12-A12, Oct, 2013 Peer-reviewed
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REPRODUCTIVE SCIENCES, 20(S3) 140A-140A, Mar, 2013 Peer-reviewed
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日本産科婦人科学会雑誌, 65(2) 782-782, Feb, 2013 Peer-reviewed
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GLYCOBIOLOGY, 22(11) 1604-1605, Nov, 2012 Peer-reviewed
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PLACENTA, 33(9) A120-A120, Sep, 2012 Peer-reviewed
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PLACENTA, 33(9) A99-A99, Sep, 2012 Peer-reviewed
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PLACENTA, 33(9) A17-A17, Sep, 2012 Peer-reviewed
Books and Other Publications
12Presentations
6Works
4-
2014 Othershttp://www.natureasia.com/ja-jp/ncomms/abstracts/55462
Major Research Projects
22-
基盤研究(C), Apr, 2023 - Mar, 2026
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基盤研究(B), Apr, 2019 - Mar, 2023
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AMED橋渡し研究シーズA, 2019 - 2020
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挑戦的萌芽研究, Apr, 2015 - Mar, 2018
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基盤研究(B), Apr, 2015 - Mar, 2018
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基盤研究(B), Apr, 2012 - Mar, 2015
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挑戦的萌芽研究, Apr, 2012 - Mar, 2015
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基盤研究(B), Apr, 2011 - Mar, 2014
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知財活用促進ハイウェイ, 科学技術振興機構(JST), Apr, 2012 - Mar, 2013
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Grants-in-Aid for Scientific Research, Japan Society for the Promotion of Science, Apr, 2009 - Mar, 2012
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Grants-in-Aid for Scientific Research, Japan Society for the Promotion of Science, Apr, 2008 - Mar, 2011
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上原記念生命科学財団
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高松宮妃癌研究助成基金
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創薬支援ネットワーク(日本版NIH)→AMED(日本医療研究開発機構)