Takuya Terai
Saitama University
101 Papers
535 Citations
Takuya Terai is an academic researcher from Saitama University. The author has contributed to research in topics: Chemistry & Fluorescence. The author has an hindex of 43, co-authored 95 publications. Previous affiliations of Takuya Terai include Osaka University & University of Tokyo.
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Papers
Development of a highly selective fluorescence probe for hydrogen sulfide.
Kiyoshi Sasakura,Kenjiro Hanaoka,Norihiro Shibuya,Yoshinori Mikami,Yuka Kimura,Toru Komatsu,Tasuku Ueno,Takuya Terai,Hideo Kimura,Tetsuo Nagano +9 more
TL;DR: The design and synthesis of a novel fluorescence probe for H(2)S, HSip-1 is reported, utilizing azamacrocyclic copper(II) ion complex chemistry to control the fluorescence.
663
Development of an Si-Rhodamine-Based Far-Red to Near-Infrared Fluorescence Probe Selective for Hypochlorous Acid and Its Applications for Biological Imaging
TL;DR: A far-red to near-infrared (NIR) fluorescence probe, MMSiR, based on Si-rhodamine, was designed and synthesized for sensitive and selective detection of HOCl in real time and permitted effective in vivo imaging ofHOCl generation in a mouse peritonitis model.
575
Fluorescent probes for bioimaging applications.
Takuya Terai,Tetsuo Nagano +1 more
TL;DR: This review recounts some recent achievements in the field of small-molecular fluorescent probes, and methodologies to visualize proteases are discussed, with special emphasis on activity-based probes for use in vivo.
417
Evolution of group 14 rhodamines as platforms for near-infrared fluorescence probes utilizing photoinduced electron transfer.
TL;DR: This approach was employed to design two kinds of novel fluorescence probes emitting in the far-red to NIR region, i.e., a series of pH-sensors for use in acidic environments and a Zn(2+) sensor, and confirmed that they work well.
386
Development of a highly sensitive fluorescence probe for hydrogen peroxide.
TL;DR: The design and synthesis of a novel fluorescence probe for hydrogen peroxide is reported, utilizing a photoinduced electron transfer strategy based on benzil chemistry to control the fluorescence.
366